1. Field of the Invention
This invention relates to a method of bending a pipe and an apparatus therefor and relates, in particular, to a method of, and apparatus for, smoothly bending a thin-wall metallic pipe such as a tail pipe for use in an automobile.
2. Description of the Related Art
When this kind of metallic pipe is subjected to bending work, wrinkling or deformation is likely to occur to the bent pipe if the restriction force on both ends of the pipe is not sufficient.
As a solution, there is known the following art. Namely, when a movable die base is moved toward a stationary die base in bending a pipe, one side of the pipe is fixed by pinching or holding by a pair of holding chucks which are disposed on both the die bases. The other side of the pipe is held by a pair of bending punches which are disposed on respective die bases in a manner to be swingable about that supporting shaft serving as a center of swinging movement which is disposed in a manner deviated in position in the axial direction of the pipe. These pair of bending punches are swung to thereby perform bending work.
In the above-described arrangement, at the time of bending, one end of the pipe is fixed and the other end of the pipe is subjected to bending work by applying a force from the outside toward the inside of the pipe, both as seen in the bending direction. Consequently, a large compression force is operated on the portion lying on the inside as seen in the bending direction, resulting in the occurrence of wrinkling or deformation as well as in a consequent failure in obtaining a stable bending accuracy. In case a pipe made by welding is subjected to bending work with the welded seam lying on the inside as seen in the bending direction, a large compression force may cause damages to the welded seam.
In view of the above-described disadvantages of the conventional art, this invention has an object of providing a method of bending a pipe as well as an apparatus therefor in which the wrinkling or deformation can be prevented, thereby attaining a stable bending accuracy.
According to one aspect of this invention, there is provided a method of bending a pipe comprising the steps of: setting a pipe in a manner capable of giving in under a pressing force; inserting into the pipe a core metal having a forming section along which the pipe is to be bent, said core metal being positioned at a bending target portion of the pipe; applying a restricting force to both ends of the pipe as seen in a longitudinal direction of the pipe; and applying the pressing force to the bending target portion of the pipe in a state of restricting the pipe such that a point of operating the restricting force displaces depending on a progress of applying the pressing force, whereby the pipe remains constantly restricted while the pressing force is being applied.
According to another aspect of this invention, there is provided a method of bending a pipe comprising: moving at least one of a pair of die bases lying opposite to each other toward the other thereof; applying a pressing force to a bending target portion of a pipe by a bending punch disposed on one of the die bases, the pipe being placed on a die provided on the other of the die bases and having inserted therein a core metal so as to be bent along a forming section of the core metal; and holding both ends of the pipe by restricting means such that, when the pressing force is applied to the bending target portion by the bending punch, the restricting means is displaced to follow the pressing by the bending punch, whereby the pipe is bent in a state in which the restriction at both ends of the pipe is maintained.
According to this arrangement, the pressing force is applied by the bending punch to the pipe on the inside thereof as seen in the bending direction of the pipe which is supported by the die on the outside thereof as seen in the bending direction. The pipe is thus bent along the forming section of the core metal in a state in which both ends of the pipe are kept restricted by the restricting means. Therefore, when the pipe is subjected to the bending work, a large compression force is not applied to the inside of the pipe as seen in the bending direction thereof. As a result, the pipe can be prevented from being wrinkled or deformed, thereby attaining a stable bending accuracy.
Preferably, the pipe is formed of predetermined shape of sheet metal into a cylindrical shape with both longitudinal free ends thereof welded together.
According to this arrangement, even in case where the pipe is bent with a welded seam lying on the inside as seen in the bending direction, the welded seam can be prevented from being damaged by a large compression force.
According to another aspect of this invention, there is provided an apparatus for bending a pipe comprising: a pair of die bases lying opposite to each other; a bending punch for applying a pressing force to a bending target portion of a pipe, the bending punch being disposed on one of the die bases; a die for placing thereon the pipe, the die being disposed on the other of the die bases such that at least one of the die bases is moved toward the other thereof to apply the pressing force by the bending punch to bend the pipe along a forming section of a core metal inserted into the pipe; and restriction means for restricting the pipe by holding both longitudinal ends thereof, the restriction means being arranged to be displaceable to follow a movement of the bending punch in a pressing direction.
Preferably, the restriction means is a restriction pad disposed on said one of the die bases. The die is made up of two segments, each of the segments being arranged to be swingable, under the pressing force by the bending punch, about a supporting shaft provided respectively toward each longitudinal end of the pipe. The restriction pad displaces to follow the swinging of each of the segments of the die.
Further, in order to facilitate the mounting and dismounting of the pipe, the core metal is preferably disposed on the die in a manner to be swingable about a supporting shaft at one end of the core metal.
As described above, according to this invention, there can be obtained an advantage in that the pipe is prevented from giving rise to wrinkling, deformation, and the like, whereby a stable bending accuracy can be attained.
The above and other objects and the attendant features of this invention will become readily apparent by reference to the following detailed description when considered in conjunction with the accompanying drawings wherein:
A description will now be made about a preferred embodiment of this invention with reference to the accompanying drawings. With reference to
A metallic material of stainless steel having a thickness of 1 mm is subjected to die cutting into a sheet material A1 of a predetermined shape (see
The die 11 is made up of two segments 11a, 11b. Each of the segments 11a, 11b is mounted in a manner to be swingable about a supporting shaft (pin) 12 mounted on the stationary die base 1 at positions on both sides along the longitudinal direction of the tail pipe “A” to be placed on the die 11. Each of the segments 11a, 11b has formed therein a semicircular recessed groove 111 (see
On a lower side of each of the segments 11a, 11b of the die 11, there is disposed a cushion plate 13 which supports each of the segments 11a, 11b. On the lower side of the cushion plate 13, there is disposed an urging means (or forcing means) 14 such as an urethane spring which applies an urging force (or pushing force) in an upward direction (i.e., in a direction opposite to the pressing direction of the bending punch; to be described in detail hereinafter). The urging force of the urging means 14 is set in the following manner. Namely, in a state free from the pressing force by the bending punch 21, each of the segments 11a, 11b of the die 11 is kept horizontal by the cushion plate 13. Once the pressing force is applied by the bending punch 21, each of the segments 11a, 11b of the die 11 is swung downward with each of the pins 12 serving as the center of swinging movement so as to follow the downward movement (i.e., in the pressing direction) of the bending punch 21. There is provided a stopper bolt 15 to prevent the cushion plate 13 from getting out of position or from deviating when the pressing force of the bending punch 21 is released upon completion of the bending work.
One segment 11b of the die 11 is provided with a core-metal holder 16. A core metal 17 is attached to this core-metal holder 16 in a manner to be swingable about a pin (supporting shaft) 17a. At that front (free) end of the core metal 17 which lies opposite to the pin 17a, a forming section 17b to set the curvature at the time of bending is formed or configured in manner to bridge the recessed groove 111 in each of the segments 11a, 11b. It is thus so arranged that the tail pipe “A” is subjected to bending processing at substantially the central portion thereof.
An urging (or forcing) means 17c to apply an upward urging (or pushing) force is disposed on the lower side of the core metal 17. In a state free from the pressing force of the bending punch 21, the core metal 17 is kept to an erected state by the urging force of the urging means 17c. When the core metal 17 is subjected to the pressing force of the bending punch 21, the core metal 17 is swung downward against the urging force of the urging means 17c, so that the lower half of the tail pipe “A” is caused to fit into the recessed groove 111 of the die 11.
It is so arranged that, when the tail pipe “A” is placed on the bending apparatus, the tail pipe “A” is held in position (or aligned) by bringing one end of the tail pipe “A” into abutment with the core-metal holder 16. At the other end of the tail pipe “A,” there is disposed a substantially cylindrical deformation-prevention core metal 18 in a manner to be inserted into the tail pipe “A” in order to prevent the tail pipe “A” from being deformed by the pressing force of restriction pads (to be described hereinafter). An urging means 18a such as a spring is provided on the other segment 11a of the die 11 to prevent the deformation-prevention core metal 18 from being stricken out of position in the course of the bending work. The core metal 17 and the deformation-prevention core metal 18 may be made of a material having a strength larger than that of the tail pipe “A” which is subjected to the bending work.
On the lower surface of the bending punch 21 which applies the pressing force to the bending target portion of the tail pipe “A,” there is formed a semicircular recessed groove 211 into which is fit the longitudinally extending upper half of the tail pipe “A.” The recessed groove 211 is curved at the same curvature as that of the forming section 17b. The restriction pads 22a, 22b serving as the restriction means for restricting the tail pipe “A” by holding both ends thereof are disposed on longitudinal both ends of the tail pipe “A.”
A semicircular recessed groove 221 (
The slots 222a, 222b have the following construction. Namely, in a state in which the bending punch 21 is away from the tail pipe “A,” each of the restriction pads 22a, 22b is held in a horizontal posture by its own weight. When the movable die base 2 is moved toward the stationary die base 1, the lower surface 223 of the restriction pad 22a, 22b so far held in a horizontal posture comes into pressing contact with the upper surface 112 of the respective segments 11a, 11b of the die 11, thereby operating the restricting force on both ends of the pipe “A” through a contact point between the restriction pad 22a, 22b and the holder 24, restricting both ends of the tail pipe “A.” When the tail pipe “A” is bent under the pressing force of the bending punch 21, the restriction pads 22a, 22b are allowed to be displaced to follow the swinging movement of each of the segments 11a, 11b of the die 11, thereby maintaining the above-described pressed state.
The upper surface 224a, 224b of the restriction pad 22a, 22b is respectively formed into an arc which is substantially concentric with the slot 222a, 222b. The upper surface 224a, 224b is in abutment with the horizontal surface 242 formed in the holder 24. When the segment 11a, 11b of the die 11 is swung, the restriction pad 22a, 22b is allowed to slide along the horizontal surface 242 and is displaced accordingly (i.e., the contact point of operating the respecting force is displaced accordingly). As a result, during the time when the restriction pad 22a, 22b is displaced, the pressing force to press the lower surface 223 of the restriction pad 22a, 22b against the upper surface 112 of the segment 11a, 11b remains constantly operated.
If the restriction pad 22a, 22b gets out of position relative to the tail pipe “A” held in position (alignment) on the die 11, during the bending work to be performed by moving the movable die base 2, the quality of the products thus manufactured may vary from products to products. As a solution, a vertical hole 225 whose lower end is open to access is formed in the restriction pad 22a, 22b, and an upwardly projecting positioning pin 19 is provided in the segment 11a, 11b so as to lie opposite to the vertical hole 225. It is thus so arranged that, when the movable die base 2 is moved toward the stationary die base 1, the positioning pin 19 gets engaged with the vertical hole 225, thereby positioning the restriction pad 22a, 22b relative to the tail pipe “A.”
A description will now be made about the bending operation of the tail pipe “A” by using the above-described bending apparatus B. As shown in
Then, the movable die base 2 is moved downward (i.e., toward the stationary die base 1) by a driving means (not illustrated). The positioning pin 19 respectively gets engaged with the vertical hole 225 in the restriction pad 22a, 22b, thereby holding the restriction pad 22a, 22b in position. Subsequently, the upper half in substantially the central portion of the tail pipe “A” is fit into the recessed groove 211 of the bending punch 21. The core metal 17 is swung downward, with the pin 17a serving as the center of swinging movement, by the pressing force of the bending punch 21 against the urging force of the urging means 17c. The longitudinally extending lower half of the tail pipe “A” is thus fit into the recessed groove 111.
Then, the longitudinally extending upper half of the tail pipe “A” is fit at both ends thereof into the recessed groove 221 of the restriction pad 22a, 22b, and the lower surface 223 of the horizontally held restriction pad 22a, 22b comes into forced abutment with the upper surface 112 of the respective segments 11a, 11b of the die 11, thereby restricting both ends of the tail pipe “A.” The result is as shown in
Subsequently, the movable die base 2 is moved downward to thereby apply the predetermined pressing force, which is set in advance, by the bending punch 21 to the tail pipe “A,” whereby the tail pipe “A” is subjected to bending. Each of the segments 11a, 11b of the die 11 is swung with the pin 12 serving as the center of swinging movement to follow the pressing force of the bending punch 21. Also, the restriction pad 22a, 22b is displaced along the respective slots 222a, 222b to follow the swinging movement of each of the segments 11a, 11b. As a result, during the bending work, both ends of the tail pipe “A” with the bending target portion lying therebetween remain constantly restricted by being firmly held (or pinched). The tail pipe “A” is thus bent along the forming section 17b of the core metal 17, thereby attaining a state as shown in
Once the bending work is finished, the movable die base 2 is moved upward to bring it to the standby state as shown in
In this manner, the pressing force is applied by the bending punch 21 to the inside, as seen in the bending direction, of the tail pipe “A” whose outside, as seen in the bending direction, is supported by the segment 11a, 11b of the die 11. The tail pipe “A” is thus bent along the forming section 17b of the core metal 17 in a state in which both ends of the tail pipe “A” are kept restricted by the restriction pads 22a, 22b. Therefore, when the tail pipe “A” is subjected to the bending work, a large compression force is not operated on the inside as seen in the bending direction. It is thus possible to prevent the occurrence of deformation and wrinkling, whereby a stable bending accuracy can be obtained, and the welded seam A2 of the tail pipe “A” can be prevented from being damaged.
A description has so far been made about the example of bending the tail pipe “A.” It is to be noted that this invention is not limited to the above, but that this invention is applicable to the bending of a thin metallic pipe in general. Needless to say, the curvature is freely variable by changing the shape of the forming section.
Number | Date | Country | Kind |
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2004-031718 | Feb 2004 | JP | national |