JP321I - Punch Die - Google Patents

Description

[Detailed Description of the Invention] [Purpose of the Invention] (Field of Industrial Application) This invention relates to a punch die used in a punch press, and more specifically, to a punch die that can prevent, for example, the punched piece from floating up from the hole of the lower die after punching the work with the upper die cooperating with the lower die. (Prior Art) Conventionally, in a punch press, a work is punched with an upper die cooperating with the lower die. In order to forcibly drop, for example, the punched piece from the hole of the lower die after punching the work, a means is known in which air holes are formed in the ram and the upper die, and the air is blown out from the lower end of the upper die by communicating with an air hole formed in the ram guide near the bottom dead center of the ram (see Japanese Utility Model Publication No. 55-55887). (Problem to be Solved by the Invention) However, the mounting height of a die, for example, an upper die in a punch press is not necessarily constant. Therefore, in the case of a short upper die after it has been re-ground due to wear, there is a problem that the air ejection is slower, which reduces the effect of preventing, for example, punched pieces from floating up. The object of this invention is to provide a punch die which, for example, allows punched pieces to be forcibly and reliably dropped without floating up regardless of die height, and which allows automatic lubrication of the upper die guide member. [Configuration of the invention] (Means for solving the problem) In order to achieve the above object, the invention provides a punch die in which an upper die is mounted so as to be movable up and down within a cylindrical guide member which is supported so as to be movable up and down in a mounting hole of an upper die holder,
The upper die is provided with a second fluid hole capable of communicating with a first fluid hole provided in a ram provided to be movable up and down to strike the head of the upper die, and a fluid chamber formed between the bottom of the guide member and the lower part of the upper die and around a narrow lower end part provided in the lower part of the upper die is provided so as to be communicated with the second fluid hole, and the fluid filled in the fluid chamber is configured to be able to be ejected from the fluid hole provided around the lower end part of the upper die or at the lower end part, and a part of the guide member is provided with
The lubricating fluid introduction portion is formed so as to be connected to the second fluid hole or fluid chamber and to introduce the fluid to the outer peripheral surface of the guide member. (Embodiment) Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. Referring to Fig. 1, a rotatable upper turret 3 as an upper die holder and a lower turret 5 as a lower die holder in a punch press, for example, a mechanically driven turret punch press 1, are supported by a frame (not shown) so as to rotate synchronously with each other. The upper turret 3 is provided with a mounting hole 7H, and a cylindrical guide member 7 is mounted in the mounting hole 7H so as to be movable up and down. Between the upper flange 7A of the guide member 7 and the recess 3A formed in the upper part of the upper turret 3, a soft spring 11 biased upwards is interposed to lift the guide member 7 from the workpiece W. An upper die 9 is mounted in the guide member 7 so as to be movable up and down, and a head 9A is fixed integrally to the upper part of the upper die 9 by, for example, a screw. A strip spring 13 is attached to the outer periphery of the head 9A, which is biased upward in order to remove the upper die 9 from the work W after the work W has been punched. A thin lower end 9B is provided at the bottom of the upper die 9, which protrudes downward, and this lower end 9B moves up and down within a guide hole formed in the bottom 7B at the bottom of the guide member 7. A lower die 15 corresponding to the upper die 9 is attached to the lower turret 5 with their axes aligned. Lower die 15
The back escape portion 17 is designed so that, for example, punched pieces do not get caught. A ram 19 that can move up and down in the punch press is provided above the head 9A of the upper die 9, and a crankshaft 21 is rotatably attached to the axial center of the upper part of the ram 19. A drive motor 23 such as a servo motor is provided on the crankshaft 21 for applying rotational drive to the crankshaft 21. A position detection device 25 such as a pulse encoder is attached to the drive motor 23 for detecting the position of the stroke of the ram 19 moving up and down. With the above-mentioned configuration, when a workpiece W is placed on the lower die 15 and the drive motor 23 is detected, the crankshaft 21 is rotated. As the crankshaft 21 rotates, the ram 1
9 moves up and down. When the ram 19 descends, the lower end of the ram 19 comes into contact with the head 9A of the upper die 9, and when the ram 19 is further lowered, the guide member 7 descends against the biasing force of the soft spring 11. Thus, the lower surface of the bottom 7B of the guide member 7 presses the work W against the lower die 15, and the upper die 9 is lowered against the strip spring 13, and the work W is punched. After the work W has been punched,
The upper die 9 and the guide member 7 are raised and returned to their original positions, and the punched piece is pushed into the back escape portion 1 of the lower die 15.
When the workpiece W is punched by the upper die 9, the punched piece may rise together with the upper die 9.
In this embodiment, a floating prevention device is provided to prevent the punched piece from floating up. That is, a first fluid hole 27 for passing a fluid, such as oil mist, is formed in the lower part of the ram 19, penetrating downward from the side. A second fluid hole 29 is formed in the upper die 9 so as to communicate with the first fluid hole 27. One side of the first fluid hole 27 is connected to one side of a pipe 31, and the other side of the pipe 31 is connected to a tank T containing a fluid, such as oil. A fluid opening and closing device 33 for supplying or cutting off a fluid, such as oil mist, is provided in the middle of the pipe 31. The fluid opening and closing device 33 is operated and opened by detecting an appropriate lowered position of the ram 19 by the position detection device 25. In this embodiment, the second fluid hole 29 is connected to the upper die 9.
The upper mold 9 has a fluid hole 29A formed at approximately the center near the upper end thereof and extending in the vertical direction, a fluid hole 29B connected to the lower end of the fluid hole 29A, extending in the horizontal direction and led to the outer peripheral surface of the upper mold 9, and a fluid hole 29C connected to the side portion of the fluid hole 29B and extending in the vertical direction.
The lower end of the fluid hole 29C is connected to an annular fluid chamber 35 formed around a narrow lower end 9B of the lower part of the upper die 9 between the bottom 7B of the guide member 7 and the lower part of the upper die 9.
1 and 2, a plurality of fluid grooves 37 are formed on the circumferential surface of the guide hole in the bottom portion 7B of the guide member 7.
A guide member 7 is connected to the fluid hole to guide a fluid such as oil mist.
Fluid hole 3 as a lubricating fluid introduction part for introducing the lubricating fluid to the outer peripheral surface of
9 is formed. This fluid hole 39 may also be used as a key groove provided for moving the upper die 9 up and down relative to the guide member 7. With the above configuration, when the ram 19 descends and the lower end of the ram 19 abuts against the head 9A of the upper die 9 (state shown in FIG. 1), the first fluid hole 27 formed in the ram 19 communicates with the fluid hole 29A of the second fluid hole 29. When the upper die 9 and the guide member 7 are further descended and the workpiece W is pressed between the lower surface of the bottom 7B of the guide member 7 and the lower die 15, the fluid chamber 35 is closed (state shown in FIG. 1). In this state, when the fluid opening and closing device 33 is operated to open it, the fluid, for example, oil mist, contained in the tank T is supplied to the first fluid hole 27 through the piping 31. The fluid, for example, oil mist, supplied to the first fluid hole 27 passes through the fluid holes 29A, 29B and 29C of the second fluid hole 29 and fills the fluid chamber 35. A part of the fluid, for example, oil mist, filled in the fluid chamber 35 lubricates the gap between the outer peripheral surface of the upper die 9 and the inner peripheral surface of the guide member 7, and flows into the fluid hole 39 formed on one side of the guide member 7. Thus, the outer peripheral surface of the guide member 7 and the inner peripheral surface of the mounting hole 7H are lubricated. Therefore, lubrication can be automatically performed by the up and down movement of the guide member 7. When the upper die 9 descends and the workpiece W is punched, the fluid, for example, oil mist, filled in the fluid chamber 35 is ejected downward from the multiple fluid grooves 37 formed in the bottom portion 7B of the guide member 7, and the punched pieces are forcibly dropped. Thus, the punched pieces can be prevented from floating up. At this time, the upper die 9 descends relative to the guide member 7, and the fluid in the fluid chamber 35 is compressed, so that the fluid is effectively ejected toward the punched pieces. Another embodiment is shown in FIG. 3. In Fig. 3, the same reference numerals are used for the components having the same functions as those in Fig. 1, and only the components different from Fig. 1 will be described. In Fig. 3, the bottom 7B of the guide member 7 is not provided with the fluid groove 37, but instead, a third fluid hole 41 is formed in the narrow lower end 9B of the upper die 7. One end of the third fluid hole 41 communicates with the fluid chamber 35, and the other end of the third fluid hole 41 penetrates downward. With the above-mentioned configuration, part of the fluid, for example, oil mist, filled in the fluid chamber 35 flows to the fluid hole 39 formed in one side of the guide member 7, as explained in Fig. 1. Thus, the outer periphery of the guide member 7 and the inner periphery of the mounting hole 7H are lubricated. Therefore, lubrication due to the up and down movement of the guide member 7 can be automatically performed. In addition, when the upper die 9 descends to punch the workpiece W, the fluid, for example, oil mist, filled in the fluid chamber 35 is sprayed downward from the third fluid hole 41 formed in the lower end 9B of the upper die 9, forcing the punched pieces to fall. Thus, it is possible to prevent the punched pieces from floating up. This invention is not limited to the above-mentioned embodiment, and can be embodied in other forms by making appropriate modifications. For example, the above-mentioned embodiment has been described with respect to a punch press driven by a mechanical mechanism, but it can also be applied to a punch press driven by a hydraulic mechanism. [Effects of the Invention] As can be understood from the above description of the embodiment, the present invention is a punch die in which the upper die 9 is mounted in a cylindrical guide member 7 supported in a mounting hole 7H of the upper die holder 3 so as to be movable up and down, and a second fluid hole 27 connected to a first fluid hole 28 provided in a ram 19 which is provided so as to be movable up and down to press the head 9A of the upper die 9 is provided.
9A is provided in the upper die 9, and a fluid chamber 35 formed between the bottom of the guide member 7 and the lower part of the upper die 9 and around a narrow lower end 9B provided at the lower part of the upper die 9 is provided in communication with the second fluid hole 29A, and the fluid filled in the fluid chamber 35 can be ejected from a fluid hole 41 provided around or at the lower end 9B of the upper die 9. Therefore, according to the present invention, the fluid pressure chamber 35 is compressed during punching of the workpiece, and the punched piece can be effectively dropped downward by the fluid ejected from the fluid pressure chamber 35. Also, according to the present invention, a lubricating fluid introduction part 39 is formed in a part of the guide member 7, which is in communication with the second fluid hole 29A or the fluid chamber 35 and serves to introduce the fluid to the outer peripheral surface of the guide member 7, so that the outer peripheral surface of the guide member 7 is automatically lubricated. Furthermore, according to the present invention, the fluid holes provided in the upper die 9 are connected to the outer peripheral surface of the upper die 9, so that lubrication between the upper die 9 and the guide member 7 is automatically performed.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a punch press driven by a mechanism according to an embodiment of the present invention; FIG.
A cross-sectional view taken along line -II. Fig. 3 is a schematic diagram of a punch press according to another embodiment instead of Fig. 1. 7: guide member, 9: upper die 19: ram, 27: first fluid hole 29: second fluid hole, 35: fluid chamber 37: fluid groove 39: fluid hole (lubricating fluid inlet portion) 41: third fluid hole

Claims (1)

[Correction specification] [Utility model registration claim] [Claim 1] A punch die comprising an upper die (9) mounted in a cylindrical guide member (7) supported in a mounting hole (7H) of an upper die holder (3) so as to be movable up and down, and a second fluid hole (29A) capable of communicating with a first fluid hole (27) provided in a ram (19) provided in a vertically movable manner to strike a head (9A) of the upper die (9), ... provided in the upper die (9) between the bottom of the guide member (7) and the lower part of the upper die (9) and between the top of the upper die (9) and the bottom of the upper die (9).
a fluid chamber (35) formed around a narrow lower end (9B) provided at the bottom of the upper die (9) and the second fluid hole (29A) are connected to each other, and the fluid filled in the fluid chamber (35) can be ejected from a fluid hole (41) provided around the lower end (9B) of the upper die (9) or in the lower end (9B), and a lubricating fluid introduction part (39) is formed in a part of the guide member (7) and communicates with the second fluid hole (29A) or the fluid chamber (35) to introduce the fluid to the outer peripheral surface of the guide member (7).
2. The punch die according to claim 1, wherein the upper die (9) is connected to an outer peripheral surface of the upper die (9).