KR20140087604A - Method of Precision Processing for Inner and Outer Diameter of Fixed Primary Piston with Forging Processing - Google Patents

Abstract

The present invention relates to a precision processing method for internal and external diameters of a fixed primary piston using a forging process and, more specifically, a precision processing method for internal and external diameters of a fixed primary piston using a forging process, which improves productivity of the primary piston corresponding to a brake piston of a master cylinder by simplifying a processing process including press punching and compression forming process for the internal and external diameters of the primary piston. The precision processing method for the internal and external diameters of the fixed primary piston using the forging process, comprises a step of preparing multiple forming dieses corresponding to the shape of the primary piston and a permanent cold forming device corresponding to each forming dies; a step of determining a position of a formed body by using the permanent cold forming device corresponding to one forming dies on which the formed body is placed; a step of forming multiple hollows inside the position-determined formed body by using the forming dieses different from each other and a corresponding permanent cold forming device to punch and press the formed body; a step of forming rounds and a bottom surface of the formed body having the hollows formed therein; and a step of piercing the internal and external diameters of the formed body having the rounds and the bottom surface formed thereon.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of precisely machining an inner and outer diameters of a fixed primary piston by a forging process,

The present invention relates to a method of precisely machining an inner and outer diameter of a fixed primary piston by a forging process, and more particularly, to a method of manufacturing a brake cylinder, To improve the productivity of the primary piston by the forging process.

In automotive engineering, a master cylinder refers to a control device that converts the mechanical force exerted from the outside (the force exerted on the brake pedal) into hydraulic pressure. By the operation of the master cylinder, the hydraulic pressure is generated by the two pistons moving along the bore formed therein, and the control device controls the movement of the slave cylinder connected to the master cylinder. The master cylinder can be applied to a brake system and a clutch system, and Fig. 3 shows an example of a tandem master cylinder having a known structure.

3, the master cylinder 30 has a primary piston 32 and a secondary piston 33 spaced from each other and capable of mutual movement in a cylindrical cylinder body 31 having a bore formed therein. . A stem 34 in which a compression spring 341 is disposed is provided in a compression space formed between the primary piston 32 and the secondary piston 33 so that the primary piston 32 can be moved. On the other hand, the secondary piston 33 can be installed on one end of the cylinder body 31 and movable along the stem 34 on which the compression spring 331 is disposed. A push rod (not shown) is coupled to the push hole 321 formed in the primary piston 32 so that the back-and-forth motion of the primary piston 32 can be induced. The oil stored in the oil tank 36 can be introduced into the interior of the cylinder body 31 through the inlet ports 361 and 362 formed in the cylinder body 32. The oil introduced into the internal piston generates a hydraulic pressure by the relative movement of the primary piston 31 and the secondary piston 32, thereby enabling the vehicle to be controlled, for example, by operating the disc brake.

Prior art relating to the manufacture of a master cylinder is disclosed in Korean Patent Publication No. 2000-0037247, which is an apparatus for manufacturing a master cylinder for an automobile and a manufacturing method thereof. The prior art includes a material cutting step of cutting an aluminum material for forming a master cylinder into a predetermined size using a cutting device; Heating the cut material to 570 to 585 using an induction heater so that the liquid material and the solid phase are uniformly mixed together while having the spheroidizing structure as a whole; Preheating the mold for injecting the heated material and injecting the heated material with the preheated mold; A material pressing step in which the heating material injected into the mold is pressurized at a rate of 0.45 to 1.5 m / s when the material is mixed in a liquid phase and a solid phase when the material is filled in the cavity of the mold, A molding step of applying a multi-stage speed control system for preventing liquid segregation during pressurization; Coagulating the product molded by the press for about 5 to 10 seconds, and taking out the coagulated product using an ejector; And a quenching step of rapidly cooling the product taken out by the ejector into the cooling water, thereby producing a master cylinder for an automobile.

Another prior art related to the manufacture of master cylinders and pistons is US Pat. No. 6,494,040 entitled " METHOD FOR MAKING A MASTER CYLINDER AND MASTER CYLINDER OBTAINED BY SAID METHOD ". The prior art discloses a method of manufacturing a master cylinder of a tandem type having a reliable and quick reaction capability.

Another prior art related to the manufacture of master cylinders is US Patent No. 7,866,155 to MASTER CYLINDER AND METHOD OF MANUFACTURING THE SAME. The prior art discloses a method of manufacturing a master cylinder capable of relieving stress concentration so that damage to the cup seal can be prevented.

The prior art does not disclose a method for solving the problems that may occur in the operation of the master cylinder itself or the master cylinder and can improve the production efficiency of the piston operating in the master cylinder.

The present invention has been made in order to solve the problems of a method of manufacturing a piston brake that is mounted inside a master assembly and moves back and forth to generate a hydraulic pressure of the brake.

It is an object of the present invention to provide a method of manufacturing a piston by using a permanent cold forming device for press-punching a piston formed body to simplify a process of compression molding an inner diameter and an outer diameter of the piston in a plurality of process steps, And to provide a method for precisely machining the inner and outer diameters of a fixed primary piston by a forging process in which workability and productivity are greatly improved.

According to a preferred embodiment of the present invention, a method for precisely machining the inner and outer diameters of a primary piston by a forging process includes the steps of preparing a plurality of molding dies corresponding to the shape of the primary piston and a permanent cold forming machine corresponding to each molding die ; Placing the molded body in one molding die and positioning it with the corresponding permanent cold forming machine; Forming a plurality of hollow portions by punching the formed molded article with different molding dies and corresponding permanent cold forming machines; Performing round and bottom surface molding on a formed product having a hollow portion; And molding inner and outer diameter piercing for the round and bottom molded articles.

According to another preferred embodiment of the present invention, the inner surface of the molded body receiving portion of each of the molding dies is a special carbide coating.

According to another preferred embodiment of the present invention, a method for precisely machining an inner and outer diameters of a primary piston by a forging process is a method for machining an inner and outer diameter of a primary piston by drawing a first formed body into a first molded body receiving portion of a first forming die having a positioning round and chamfer forming die, Pressing the upper portion of the first formed body by a first perforated cold forming machine to position the outer portion to form a second formed body; Machining the second formed body by punching and pressing the upper portion of the second formed body from a second molding die having a positioning round and chamfer forming mold to a second perm cold forming machine; Pressing the third molded body from the third molding die to a third permanent cold forming machine to process a fourth formed body having the first hollow portion; Pressing the fourth formed body by punching with a fourth permanent cold forming machine in a fourth molding die having a horseshoe-shaped metal mold to form a fifth formed body having a second hollow portion; Machining the fifth formed body by punching with a fifth permanent cold forming machine in a fifth molding die having a horn end face forming mold, thereby forming a round formed on the lower face of the first hollow portion; And machining the inner and outer diameters of the sixth formed body by punching and pressing the sixth formed body with a sixth permanent cold forming machine in a sixth molding die having a horn and an inner diameter piercing die.

The manufacturing method according to the present invention separates the piston formed body into a first hollow, a second hollow, a third hollow, a fourth hollow, a fifth hollow and a sixth hollow by pressurizing and punching the piston with a permanent cold forming machine to compress the inner and outer diameters The molding process can be simplified to shorten the post-process time, and at the same time, the workability and productivity can be improved. More specifically, by manufacturing the hollow piston by punching and pressing the inside of the molded body during the manufacturing process of the brake piston of the master cylinder, it is possible to maintain a certain inner diameter or outer diameter, thereby shortening the working process, It can be improved.

FIGS. 1A to 1K show an embodiment of a method for precisely machining an inner and outer diameter of a fixed primary piston by a forging process according to the present invention.
Figure 2 shows an embodiment of a primary piston made by the method according to the invention.
Figure 3 shows an embodiment of a known master cylinder.

The following detailed description is merely illustrative, and is merely an example of the present invention. Further, the principles and concepts of the present invention are provided for the purpose of being most useful and readily explaining. Therefore, it is not intended to provide a more detailed structure than is necessary for a basic understanding of the present invention, and it is to be understood by those skilled in the art that various forms that can be practiced in the present invention are illustrated in the drawings.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1A to 1J show an embodiment of a method for precisely machining an inner and outer diameter of a fixed primary piston by a forging process according to the present invention.

A method for precisely machining an inner and outer diameters of a primary piston by a forging process according to the present invention comprises the steps of: preparing a plurality of molding dies corresponding to the shape of a primary piston and a permanent cold forming machine corresponding to each molding die; Placing the molded body in one molding die and positioning it with the corresponding permanent cold forming machine; Forming a plurality of hollow portions by punching the formed molded article with different molding dies and corresponding permanent cold forming machines; Performing round and bottom surface molding on a formed product having a hollow portion; And molding inner and outer diameter piercing for the round and bottom molded articles. Specifically, the method according to the present invention is characterized in that the first molded body is drawn into a first molded body pull-in portion of a first molding die having a position round and chamfer forming die, and the upper portion of the first molded body is pushed and pressed by a first permanent cold forming machine To form a second molded body; Machining the second formed body by punching and pressing the upper portion of the second formed body from a second molding die having a positioning round and chamfer forming mold to a second perm cold forming machine; Pressing the third molded body from the third molding die to a third permanent cold forming machine to process a fourth formed body having the first hollow portion; Pressing the fourth formed body by punching with a fourth permanent cold forming machine in a fourth molding die having a horseshoe-shaped metal mold to form a fifth formed body having a second hollow portion; Machining the fifth formed body by punching with a fifth permanent cold forming machine in a fifth molding die having a horn end face forming mold, thereby forming a round formed on the lower face of the first hollow portion; And machining the inner and outer diameters of the sixth formed body by punching and pressing the sixth formed body with a sixth permanent cold forming machine in a sixth molding die having a horn and an inner diameter piercing die.

1A to 1J, a method for precisely machining an inner and outer diameters of a primary piston of a master cylinder by a forging process includes steps S1 and S2 for rounding and chamfering for positioning using a permanent cold forming machine and a forming die, (S2) of forming a positioning groove on an upper portion of the molding for positioning, (S3) of machining a first hollow portion in the molding, (S4) of machining a second hollow portion in the molding, (S5) of forming the inner bottom surface of the first hollow portion and the third hollow portion by machining the bottom surface of the second hollow portion at a right angle and forming the inner diameter of the molded body having the first hollow portion and the third hollow portion, And piercing the outer diameter (S6).

A cold forging process with a high surface accuracy and high dimensional accuracy can be applied to the primary piston of the master cylinder. The material for the production of the primary piston of the master cylinder may be aluminum or an aluminum alloy and may be Al 6061-0 corresponding to an aluminum alloy which is not heat treated or Al 6061-T4 corresponding to a heat- Al 6061-T6. ≪ / RTI >

A press such as a hydraulic press or a mechanical press may be used for forging the primary piston, and the forging may be carried out by two forging molds, and a lubricant such as mineral oil may be used if necessary. The forging temperature may be, for example, 15 deg. C to 30 deg. C or room temperature, but is not limited thereto.

The following is a description of the inner and outer diameters of the primary piston by using a forming die and a permanent cold forming machine applied to each step, The details of the outer diameter precision machining method will be described.

1A and 1B, the first molding die 12 includes a first molded body inlet portion 14 into which the first molded body 100a is drawn, A positioning round and a chamfer forming die 15 for determining the position of a round (R) or a chamfer (C) are formed below the formed body (100a). The first permanent cold forming machine 11 has a first molding die 13 for punching and molding in contact with the upper portion of the molding body so that the first molding die 13 is pressed against the first molding body 100a at a constant pressure And a punch guide 112 for performing pressure punching.

The molding die applied to each step may be formed of a molding die having a predetermined shape to form a lower structure of a primary piston such as a hollow part, a horn structure or a round, It can have a suitable structure that can stably support it. Also, a permanent cold forming machine applied to each feature may be formed of a forming mold having a predetermined shape to form the upper structure of the primary piston, for example, a hollow portion, an inner round, and operated by a device such as a hydraulic press .

The step S1 of performing the rounding and chamfering for positioning includes the step of forming the first formed body 100a in the first molded body receiving portion 14 of the first forming die 12 having the positioning round and chamfering mold 15, . Thereafter, in step S1, the first molding die 13 of the permanent cold forming machine 11 punches and presses the upper part of the first formed body 100a to form a round for positioning on the outside of the first formed body 100a 101 or the chamfered portion C of the second formed body 100b. As shown in FIG. 1B, the second formed body 100b forms a round (R) 101 outside the first formed body 100a so that the position of the next continuous process can be determined.

Referring to FIGS. 1C and 1D, step S2 of machining the positioning groove 102 on the upper side of the second forming body for positioning comprises positioning the second forming body 100b on the positioning round and chamfer forming die 25 (24) of the second forming die (22) having the first molding die (22). Thereafter, the second molding die 23 of the second permanent cold forming machine 21 punches and presses the upper portion of the second formed body 100b in step S2. A position forming groove 102 for forming the positioning groove 102 is formed at one end of the second molding die 23 and the positioning groove 102 is formed on the upper side of the second molding body 100b, (100c) can be machined. 1D, when the positions of the round 101 and the positioning groove 102 are determined on the outer surface of the third formed body 100c, a subsequent process is performed to determine the processing position of the horn structure of the first hollow portion .

1E and 1F, a step S3 of processing the first hollow portion 103 in the third formed body 100c is performed by moving the third formed body 100c to the third molded body of the third molded dice 32 (34). ≪ / RTI > Then, in the step S3, the third molding die 33 of the third permanent cold forming machine 31 presses the upper portion of the third molded body 100c, and the process can proceed. That is, the third forming die 33 is for forming the first hollow portion 103 forming the inner diameter of the primary cylinder by pressing the positioning groove 102, and by pressing the upper portion of the third molding, So that the fourth molded body 100d having the portion 103 formed thereon can be machined.

1G and 1H, the step S4 of machining the second hollow portion 104 to the fourth formed body is to draw the fourth formed body into the fourth molded body receiving portion 44 of the fourth molded dice 42 . In the step S4, an inner diameter cone piercing die and a bottom surface forming mold 45 which are in close contact with the lower end of the fourth molded body intake part 44 are used to form the fourth permanent cold forming machine 41 A step of pressing the fourth formed body 103d in a state where the forming die 43 is inserted into the first hollow portion 103 of the fourth formed body 103d is performed. The fifth molding body 100e having the second hollow portion 104 formed at the lower portion thereof can be processed by the piercing die and the bottom surface molding die 45, The bottom surface 104a of the second hollow portion 104 forms an inclined surface and a round R is formed at an edge.

1I and 1J, the inner surface and the inner bottom surface 105 of the first hollow portion 103 of the fifth formed body 100e are formed in a round (R) shape, and the inner surface of the second hollow portion 104 (S5) of processing the third hollow portion 106 by processing the bottom surface at a right angle may be performed. In the step S5, the fifth molded body 100e is drawn into the fifth molded body receiving portion 54 of the fifth molded dice 52 having the horn end face forming die 55, and the fifth permanent cold forming machine 51, And a fifth molding die 53 for inner round molding and cross-sectional molding of the fifth molded body 100e punches and presses the upper portion of the fifth molded body 100e. A round is formed on the inner surface and the inner bottom surface (105) of the first hollow portion (103) by using the fifth molding die for the inner round molding and the cross section molding, and the round ) Is progressed through the forging process rather than the cutting process, the machining process can be shortened. On the other hand, the bottom surface of the second hollow portion is formed with the third hollow portion 106 having the bottom surface 106a formed at a right angle through the horn end surface forming mold 55. [ Accordingly, the sixth molded body 100f having the inner bottom surface of the first hollow portion in the round (R) shape and having the third hollow portion formed at the right angle of the bottom surface can be processed. .

1K, the step (S6) of piercing the inner diameter and the outer diameter of the sixth formed body 100f is performed by moving the sixth formed body 100f in a direction away from the sixth molded dice 62 having the lower horn and the inner diameter piercing die 65 Into the sixth molded body inlet portion 64. [0064] Then, in the step S6, a sixth molding die 63 having an inner round shape and an inner diameter piercing die located in the sixth permanent cold forming machine 61 punches and presses the sixth molding body 100f. Through such a process, inner horn formation, the right angle of the bottom face, and the rounded round shape are completed, and at the same time, the overall length dimension can be determined.

Meanwhile, the inner surface of the sixth molded product inlet portion 64 may be made of a special carbide coating, and the special carbide coating may be formed by, for example, titanium carbide coating (TiC), aluminum coating (Al ₂ O ₃ ) But are not limited to, titanium nitride (TiN) coating or titanium nitride carbon coating (MT-TiCN). Can be applied in each step (S1 to S6) of the forging by the special coating of the cemented carbide, and the uniformity of the surface, the surface strength or the dimensional uniformity of the molded article can be improved in the forging process.

According to the present invention, the inner diameter and outer diameter of the sixth formed body 100f inserted into the sixth formed body intake portion 64 through the step (S6) of piercing the inner diameter and the outer diameter of the sixth formed body 100f, The manufacturing process of the primary piston can be simplified by proceeding to the forging process using the sixth permanent cold forming machine 61 and the sixth forming die 62.

Figure 2 shows an embodiment of a primary piston made by the method according to the invention.

Referring to FIG. 2, the primary piston 200 has a cone 107, a first hollow 103 and a third hollow 106 formed by a plurality of forming dies and a permanent cold forming machine. The inner bottom surface 105 of the first hollow portion 103 and the bottom surface 106a of the third hollow portion 106 can be precision machined by cold working. Therefore, the primary piston can be formed by punching and pressing the molded body through a forging process using a permanent cold forming machine and a molding die, and the molded body after each step during the respective steps (S1 to S6) Can be mass-produced without cutting and polishing processes.

In the illustrated embodiment, each of the permanent cold forming machines or the forging molds may have a proper shape depending on the processing of the formed body or the formed body, and the present invention is not limited to the illustrated embodiments. Further, the manufacturing method according to the present invention can appropriately select the number or order of the processing steps, and the shape or shape of the round or chamfer can be appropriately selected according to the processing method.

In the manufacturing method according to the present invention, for example, an aluminum alloy material (Al6061-T6) cut to a predetermined size can be used to punch and press the inside of a molded body into a desired shape by pressing with a permanent cold molding machine. By sequentially forming the first hollow portion or the second hollow portion having a uniform structure, the outer surface of the piston, the round shape, the lower inner horn and the cross section can be processed in order. The manufacturing method according to the present invention can be developed so that the CNC (Computerized Numerical Control) processing can be performed by a simple method, thereby improving productivity and work efficiency.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, I will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the scope of the appended claims, as well as the appended claims.

11: first permanent cold forming machine 12: first forming die
13: first molding die 14: first molded product inlet part
15, 25: Position round and chamfer forming mold
21: second permanent cold forming machine 22: second forming die
23: second molding die 24: second molded body inlet part
31: Third permanent cold forming machine 32: Third mold die
33: third forming die 34: third forming body drawing part
35: Support
41: fourth permanent cold forming machine 42: fourth mold die
43: Fourth molding die 44: Fourth molding die inlet
45: inner diameter horn piercing die and bottom mold
51: fifth permanent cold forming machine 52: fifth mold die
53: fifth molding die 54: fifth molding inlet
55: Horn section forming mold
61: sixth permanent cold forming machine 62: sixth mold die
63: Sixth molding die 64: Sixth molding die inlet
65: Horn and inner diameter piercing mold
100a: First molded body 100b: Second molded body
100c: Third formed body 100d: Fourth formed body
100e: fifth molded body 100f: sixth molded body
101: Round 102: Positioning home
103: first hollow portion 104: second hollow portion
104a: bottom surface 105: bottom surface
106: third hollow portion
112: punch guide 160: inner diameter
170: Outer diameter

Claims (3)

In a method for precisely machining an inner and outer diameter of a primary piston by a forging process,
Preparing a plurality of molding dies corresponding to the shape of the primary piston and a permanent cold forming machine corresponding to each molding die;
Placing the molded body in one molding die and positioning it with the corresponding permanent cold forming machine;
Forming a plurality of hollow portions by punching the formed molded article with different molding dies and corresponding permanent cold forming machines;
Performing round and bottom surface molding on a formed product having a hollow portion; And
And forming the inner and outer diametric piercing on the round and bottom molded product. The method according to claim 1, characterized in that the inner surface of the molded body inlet portion of the molded dice is made of a special carbide coating. In a method for precisely machining an inner and outer diameter of a primary piston by a forging process,
The first molded body is pulled into the first molded body pull-in portion of the first molding die having the positioning round and chamfer forming die, and the upper portion of the first molded body is pushed and pressed by the first permanent cold forming machine, ;
Machining the second formed body by punching and pressing the upper portion of the second formed body from a second molding die having a positioning round and chamfer forming mold to a second perm cold forming machine;
Pressing the third molded body from the third molding die to a third permanent cold forming machine to process a fourth formed body having the first hollow portion;
Pressing the fourth formed body by punching with a fourth permanent cold forming machine in a fourth molding die having a horseshoe-shaped metal mold to form a fifth formed body having a second hollow portion;
Machining the fifth formed body by punching with a fifth permanent cold forming machine in a fifth molding die having a horn end face forming mold, thereby forming a round formed on the lower face of the first hollow portion; And
And a step of machining the inner and outer diameters of the sixth formed body by punching and pressing the sixth molded body with a sixth permanent cold forming machine in a sixth molding die having a horn and an inner diameter piercing die, Outer diameter precision machining method.

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