The present invention relates to a method of forming a through-hole or through-holes and a through-hole forming machine, more precisely relates to a method of forming a through-hole or through-holes in a circular wall of a cylindrical part of a work piece and a through-hole forming machine capable of performing the method.
Conventionally, through-holes are formed in work pieces by drill means, die-punch press means, electric spark means, etc. To form a through-hole in a circular wall of a cylindrical part of a work piece, e.g., pipe, the above described means have been used.
However, by using the drill means an the press means, burrs are formed along edges of through-holes, so they must be removed. Especially, in case of forming a thorough-hole from an outer face of the cylindrical part by the drill means or the press means, burrs are formed along an inner edge of the through-hole. In some cases, inner burrs must be removed. If the work piece is small, it is difficult to remove burrs formed in the cylindrical part of the work piece. Further, in some work pieces, it is impossible to remove inner burrs.
Conventionally, in case of forming a through-hole in a relatively thick circular wall of a cylindrical part of a work piece, the electric spark means has been used. However, it takes a long time to form the through-hole by the electric spark means, so manufacturing efficiency must be lower. Further, machining cost must be increased.
Further, in case of boring a relatively large through-hole in a small work piece, the through-hole is bored by driving a punch into an outer face of a cylindrical part, and inner burrs are manually removed in a following step. In this case too, manufacturing efficiency must be lower, and machining cost must be increased.
In the mean time, a through-hole can be formed in a flat work piece by the press means as shown in
In the method, circular grooves 174a, which correspond to an edge of a through-hole 170a to be formed, is previously formed in at least a bottom face of a flat work piece 107b, then a pierce punch 151a, which is arranged to correspond to the circular grooves 174a, is driven into the work piece 107b, so that the through-hole 170a can be bored. Note that, a symbol 178a stands for a scrap, which is a part of the work piece 107a separated by boring the through-hole 170a.
However, in the method shown in
Thus, workers have tried to bore a through-hole, by a punch, from the inside of the cylindrical part so as not to form burrs therein. However, a small punch, which can be inserted into the cylindrical part, is required, and a span of life of the punch must be short. Namely, there is no punches having such function.
Further, in case of oppositely boring through-holes in the circular wall of the cylindrical part of the work piece, there are no suitable method and no suitable through-hole forming machine.
The present invention was invented to the problems of the conventional methods of forming a through-hole or through-holes in a circular wall of a cylindrical part of a work piece.
An object of the present invention is to provide a method of forming a through-hole or through-holes, which is capable of preventing formation of burrs, improving machining efficiency and reducing machining cost.
Another object of the present invention is to provide a through-hole forming machine, which is capable of performing the method of the present invention.
To achieve the objects, the present invention has following structures.
Namely, the method of forming a through-hole in a circular wall of a cylindrical part of a work piece comprises the steps of:
setting the work piece to a die;
inserting a punch, which is provided to a rod-shaped metal core, into the cylindrical part; and
pressing and moving a press pin toward the die together with the punch so as to drive the punch into an inner face of the circular wall and bore the through-hole,
wherein the press pin is inserted in the cylindrical part via a guide through-hole, which has been formed in the circular wall of the work piece and which is located on the opposite side of a prescribed position corresponding to the through-hole to be bored, and contacts a surface of the metal core, which is located on the opposite side of the punch.
Another method is a method of oppositely forming through-holes in a circular wall of a cylindrical part of a work piece comprising the steps of:
boring a guide through-hole, whose diameter is smaller than that of a first through-hole to be bored, at a first prescribed position, at which the first through-hole will be bored, from an outer face of the cylindrical part;
setting the work piece to a die;
inserting a punch, which is provided to a rod-shaped metal core, into the cylindrical part until reaching the first prescribed position;
pressing and moving a press pin toward the die together with the punch so as to drive the punch into an inner face of the circular wall and bore the first through-hole, wherein the press pin is inserted in the cylindrical part via the guide through-hole, which is located on the opposite side of the first prescribed position, and contacts a surface of the metal core, which is located on the opposite side of the punch;
resetting the work piece in the die;
inserting the punch, which is provided to the rod-shaped metal core, into the cylindrical part until reaching a second prescribed position, which is located on the opposite side of the first prescribed position and at which a second through-hole will be bored;
pressing and moving the press pin toward the die together with the punch so as to drive the punch into the inner face of the circular wall and bore the second through-hole including the guide through-hole, wherein the press pin is inserted in the cylindrical part via the first through-hole and contacts the surface of the metal core, which is located on the opposite side of the punch.
The through-hole forming machine for forming a through-hole in a circular wall of a cylindrical part of a work piece comprises:
a die for holding the work piece, the die contacting an outer face of the circular wall of the cylindrical part at a prescribed position corresponding to the through-hole to be bored;
a punch for boring the through-hole with the die, the punch being provided to a front end of a rod-shaped metal core and being inserted into the cylindrical part;
a press pin being inserted in the cylindrical part via a guide through-hole, which is formed in the circular wall of the work piece and which is located on the opposite side of the prescribed position, the press pin contacting a surface of the metal core, which is located on the opposite side of the punch; and
a mechanism for relatively pressing and moving the press pin and the punch toward the die so as to drive the punch into an inner face of the circular wall and bore the through-hole.
In the machine, a rear end of the metal core may be detachably attached to a metal core holder.
In the machine, a front end face of the punch may be chamfered along the inner face of the cylindrical part.
The machine may further comprise a mechanism for sucking a scrap, which is formed by boring the through-hole, via a discharge hole of the die.
Another through-hole forming machine for oppositely forming through-holes in a circular wall of a cylindrical part of a work piece comprises:
a first boring unit including a punch for boring a guide through-hole, whose diameter is smaller than that of a first through-hole to be bored, at a first prescribed position, at which the first through-hole will be bored, from an outer face of the cylindrical part; and
a second boring unit including:
Further a work piece of the present invention has a cylindrical part and a through-hole or through holes formed in a circular wall of the cylindrical part, and the through-hole or through-holes are formed by the machine of the present invention.
By the method and the machine of the present invention, forming burrs inside of the cylindrical part can be prevented, machining efficiency can be improved and machining cost can be much reduced.
Embodiments of the present invention will now be described by way of examples and with reference to the accompanying drawings, in which:
a) is a sectional view of a work piece of the embodiment;
b) is a bottom view thereof;
a) is a plan view of a work piece, in which first guide through-holes are bored;
b) is a front view of the work piece, in which the first guide through-holes are bored;
a) is a plan view of the work piece, in which second guide through-holes are bored;
b) is a front view of the work piece, in which the second guide through-holes are bored;
a) is a plan view of the work piece, in which first through-holes are bored;
b) is a front view of the work piece, in which the first through-holes are bored;
a) is a plan view of the work piece, in which second through-holes are bored;
b) is a front view of the work piece, in which the second through-holes are bored;
a) is a plan view of the work piece, in which third through-holes are bored;
b) is a front view of the work piece, in which the third through-holes are bored;
a) is a plan view of the work piece, in which fourth through-holes are bored;
b) is a front view of the work piece, in which the fourth through-holes are bored; and
a) and 20(b) are explanation views of the conventional through-hole forming machine.
Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.
The through-hole forming machine of the present embodiment bores through-holes in a circular wall of a cylindrical part of a work piece by press means.
A work piece 100 has at least one cylindrical part 12. As shown in
A die 20 is used for machining the work piece 10. The die 20 contacts and receives a prescribed position of an outer face of the work piece 10, at which the through-hole 70 will be bored. Therefore, a center part 20a of an upper face of the die 20 is formed into a concave shape (see
A discharge hole 24 for discharging scraps 80 (see
A punch 30 is provided to a free end (a front end) of a rod-shaped metal core 32, whose base end (rear end) is detachably attached to an elevating block 40, and projected downward. In the present embodiment, a length of the punch 30 projected from the metal core 32 is equal to the thickness of the circumferential wall 15 of the work piece 10. Since the punch 30 is short and the metal core 32 is thick, life spans of the die 20 and the metal core 32 can be made longer. A relief stroke of the punch 30 can be short, so that the metal core 32, which is inserted into the work piece 10, can be made thicker. Therefore, rigidity of the punch 30 and the metal core 32 can be improved, so that their life spans can be made longer. By shortening the punch 30, damages of the punch 30 can be reduced. Machining efficiency can be improved, and machining cost can be highly reduced.
In the present embodiment, the punch 30 and the metal core 32 are integrally formed, but they may be separately made. In case of separately making the punch 30 and the metal core 32, the punch 30 may be fixed to the metal core 32 by proper means, e.g., implanting. In this case too, the punch 30 must be projected from the metal core 32.
As shown in
As described above, the punch 30 is provided to the front end part 32a, and the rear end part 32b of the metal core 32 is horizontally fitted in a core hole 42 of an elevating block 40. The metal core 32 is detachably attached to the elevating block 40. Note that, side faces of the metal core 32 are formed into flat faces so as not to turn in the elevating block 42. The metal core 32 can be easily exchanged.
The free end part 32a of the metal core 32 is horizontally projected from the elevating block 40, and the metal core 32 is formed into the rod-shape. If no means for pressing the free end part 32a, e.g., a press pin 35, is provided, great moment is applied to the metal core 32 by a pressing force when the press-punching is performed. Therefore, the metal core 32 is easily damaged by the pressing force.
The elevating block 40 has an extended section 40a (see
The press pin 35 is inserted in the cylindrical part 12 of the work piece 10 via a guide through-hole 72, which has been formed in the circular wall 15 of the work piece 10 and which is located on the opposite side of the prescribed position corresponding to the through-hole 70 to be bored, and contacts a surface 33 of the metal core 32, which is located on the opposite side of the punch 30.
The press pin 35 is pressed and moved together with the core metal 32 and the punch 30. With the above described structure, the press pin 35 holds the metal core 32 from the upper side, so that the press pin 35 presses the punch 30 to bore the through-hole 70. Namely, the elevating block 40 and the press pin 35 press the metal core 32 downward, so that the punch 30 is driven into the circular wall 15.
Therefore, applying the great moment to the free end part 32a of the metal core 32 can be prevented, so that damaging the punch 30 and the metal core 32 can be prevented. Life spans of the punch 30 and the metal core 32 can be made longer, machining efficiency can be improved and manufacturing cost can be reduced.
Pressing means 50 downwardly presses and moves the press pin 35, together with the punch 30 and the metal core 32, toward the die 20 so as to drive the punch 30 into the inner face of the circular wall 15 of the work piece 10 and form a sheared part and a broken part. With this action, the through-hole 70 can be bored.
In the present embodiment, firstly the press pin 35 is moved downward (see
For example, a cylinder unit may be used as the pressing means 50.
To suitably form the sheared part and the broken part, a prescribed clearance should be formed between the die 20 and the punch 30. For example, in case of boring a circular through-hole in a work piece made of iron, the suitable clearance is determined on the basis of the following formula:
(Inner diameter of the die)=(Outer diameter of the die)+[Thickness of the work piece×(5-10%)]×2
Self returning means 55 makes the elevating block 40, the metal core 32, which includes the punch 30, and the press pin 35 to initial positions when the pressing action is completed. For example, the self returning means 55 includes a coil spring 56 (see
As shown in
In the present embodiment, two chamfered parts 30a, which correspond to the inner circumferential face of the cylindrical part 12, are formed on the right and the left sides of the punch 30.
By forming the chamfered parts 30a, the lower end of the punch 30 contacts the inner circumferential face of the cylindrical part 12 at a plurality of points, so that damages of the punch 30 can be prevented. Further, by forming the chamfered parts 30a, shearing angles are made as well as scissors, so that the pressing force can be suitably dispersed and the through-hole 70 can be suitably bored.
With this merit, the life span of the parts of the machine can be made longer, and the machining cost can be reduced.
By using the punch 30 having the chamfered parts 30a, no scraps stick onto the lower end of the punch 30 so that the machining efficiency can be improved.
Vacuum sucking means 60 (see
When the scrap 80 is formed, the sucking means 60 is sucking air so that the scrap 80 is sucked immediately after the scrap 80 is separated from the work piece 10. Therefore, the through-hole 70 can be securely opened without leaving the scrap 80.
For example, a vacuum sucking unit shown in
By using the above described sucking means, an ordinary compressor may be used as the compressed air source 62. Namely, the sucking means can be easily made. Note that, other sucking means, e.g., vacuum unit, pressure reduction unit, may be employed.
By examining the sheared part and the broken part, existence of the through-hole 70 in the circumferential wall 15 of the cylindrical part 12 of the work piece 10 can be known.
Next, the process of boring the through-holes 70 in the circumferential wall 15 of the cylindrical part 12 of the work piece 10, which is performed in the above described through-hole forming machine, will be explained with reference to
Firstly, as shown in
The work piece 10 is fitted in a jig 16, which has a rectangular external shape so as not to rotate, and fixed by a screw 17. The jig 16 is received at a prescribed position by a receiving section 22, so that the work piece 10 can be correctly positioned. A guide 44 guides the vertical movement of the elevating block 40.
A press plate 45 is pressed by the pressing means 50 (see
A stripper section 52 presses the work piece 10 when the punch 30 is pulled out from the work piece 10. The stripper section 52 has two guide holes 53 through which the press pins 35 respectively pass.
The die 20 contacts the prescribed positions of the outer face of the circular wall 15, at which the through-holes 70 will be bored. Two of the punches 30, which are provided to the front end part 32a of the metal core 32, are inserted into the cylindrical part 12 of the work piece 10 until they respectively reach the prescribed positions.
In this state, the press plate 45 is located at the uppermost position, and the press pins 35 are located above the stripper section 52. Further, the pressing section 45a is located above the elevating block 40.
Next, as shown in
As shown in
The block pin 46 is moved upward, against the elasticity of the coil spring 47, and accommodated in an accommodating hole 48.
Then, as shown in
The punches 30 are driven into the circumferential wall 15 as shown in
When the through-holes 70 are completely bored, the scraps 80 are can be sucked by the vacuum sucking means 60 via the discharge hole 24 of the die 20, so that the scraps 80 can be securely removed from the through-holes 70. By securely removing the scraps 80, manufacturing efficiency can be improved.
When the punches 30 are pulled out from the work piece 10, the block pin 46 is projected downward by the elasticity of the coil spring 47 so as to press the elevating block 40 (see
This action will be explained in detail. The block pin 46 presses a rear part 40b (see
As described above, the through-holes 70 are bored by driving the punches into the inner face of the cylindrical part 12, so that no burrs are formed in the inner face thereof. Therefore, a burring step can be omitted. Since the punches 30 are pressed by the press pins 35, a great pressing force can be applied so that large through-holes can be easily bored. Further, the metal core 32 is held by the elevating block 40 and the press pins 35, so the bend or deformation of the metal core 32 can be prevented. Therefore, damages of the punches 30 and the metal core 32 can be prevented, and their life spans can be made longer.
Namely, manufacturing efficiency can be improved, and machining cost can be reduced.
Next, another embodiment of the present invention will be explained with reference to
The through-hole forming machine of the present embodiment comprises a first boring unit 100 for boring guide through-holes 72 and a second boring unit 200 (see
In
A rear end part 28b of the die core 28 is horizontally inserted in a hole 41a of a holder 41 and detachably attached therein by a screw. Note that, the die core 28 has flat side faces so as not to rotate. Therefore, the die core 28 can be easily exchanged.
A discharge through-hole 29 for discharging scraps is formed in the die core 28 and extended in the axial direction. The discharge through-hole 29 is communicated to die holes 27a of the die 27. An air path 29a, which is communicated to a compressed air source (not shown), is communicated to the discharge through-hole 29 so as to introduce compressed air to the discharge through-hole 29 from the front end 28a side. With this structure, scraps 82 (see
The work piece 10 is fitted in the jig 16, which has a rectangular external shape so as not to rotate, and fixed by the screw 17. A holding section 23 holds the jig 16 at a predetermined position, so that the work piece 10 can be correctly positioned. Another holder 25 holds and positions the cylindrical part 12 of the work piece 10.
A press plate 90 is pressed downward by pressing means 91. Two pin-shaped punches 37, each of which has a circular sectional shape, are attached to the press plate 90.
A stripper section 26 presses the work piece 10 when the punches 37 are pulled out from the work piece 10. In the present embodiment, the stripper section 26 is integrally formed with the holder 25. The stripper section 26 has two guide holes 38, through which the punches 37 pass.
Next, a method of forming the guide through-holes 72 by the first boring unit 100 will be explained with reference to
Diameters of the guide through-holes 72 may be relatively small with respect to an inner diameter of the work piece 10. Further the diameters of the guide through-holes 72 are smaller than those of the through-holes 70 to be bored.
Therefore, a sectional shape of edges of the die holes 27a of the die 27, which act as cutting edges, are not acute edges, so that a life span of the die 27 can be made longer and manufacturing efficiency can be improved.
The scraps 82 are blown away and removed via the discharge through-hole 29. Since the guide through-holes 72 are smaller than the through-holes 70, sizes of the scraps 82 are small so that they can be removed without blocking the discharge through-hole 29. Therefore, the guide through-holes 72 can be efficiently formed.
Note that, the guide through-holes 72 will be disappeared when the through-holes 70 are bored at the positions of the guide through-holes 72.
Since the guide through-holes 72 will be disappeared, the guide through-holes 72 may be roughly formed in some cases. In those cases, guide through-holes 72 may be formed by known proper methods.
Next, a method of forming eight through-holes in the work piece 10, by the first and second boring units 100 and 200, will be explained with further reference to
A first step is shown in
A second step is shown in
A third step is shown in
A fourth step is shown in
A fifth step is shown in
A sixth step is shown in
By executing the first to six steps, eight through-holes 70a, 70b, 70c and 70d can be efficiently formed. Manufacturing efficiency can be improved.
Note that, the shape of the through-hole is not limited to the above described embodiment. For example, circular, oval and elliptical through-holes may be bored by the present invention.
The invention may be embodied in other specific forms without departing from the spirit of essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.
Number | Date | Country | Kind |
---|---|---|---|
2004-375191 | Dec 2004 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5460026 | Schafer | Oct 1995 | A |
5666840 | Shah et al. | Sep 1997 | A |
6032559 | Dean, Jr. | Mar 2000 | A |
6186696 | Valin | Feb 2001 | B1 |
Number | Date | Country |
---|---|---|
004320043 | Sep 1994 | DE |
43 20 043 | Dec 1994 | DE |
195 13 519 | May 1996 | DE |
0 726 824 | Jul 1998 | EP |
5-42330 | Feb 1993 | JP |
Number | Date | Country | |
---|---|---|---|
20060137499 A1 | Jun 2006 | US |