KR0126876Y1 - Outside screw rolling device of pipe - Google Patents

Abstract

The present invention relates to an external thread rolling device of a pipe which allows a pipe formed with a screw to be automatically lowered on an outer circumferential surface thereof. When a screw is formed on the pipe by the device, the cylindrical lifting spiral cutter is in a raised position. When entering the upper part between the spiral cutter rotating the workpiece, as the cam rotates, the cylindrical lifting spiral cutter descends to press the workpiece in the direction of the cylindrical spiral cutter to form a screw on the workpiece. As the cylindrical lifting spiral cutter rises continuously, the contact rod contacts the short radius surface of the auxiliary cam and the compression spring is elastic.The first cylindrical spiral cutter rotates around the hinge point of the bearing body, and the front block is the rail of the support plate. Work piece is moved to the outside and work piece falls automatically to the lower side. There is an advantage that can be improved.

Description

External thread rolling device for pipe

1 (a) and (b) are a side view and a plan view of an external thread rolling device of a pipe according to the prior art.

Figure 2 (a) (b) is a view showing a process of forming a screw on the outer peripheral surface of the pipe by the thread external thread rolling device according to the prior art.

Figure 3 is a perspective view of the spiral cutter of the outer thread screw rolling device of the prior art.

Figure 4 (a) (b) is a side view and plan view of the outer thread screw rolling device of the present invention.

Figure 5 (a) (b) is a diagram showing the process of descending the pipe at the same time as forming the screw on the outer peripheral surface of the pipe with the outer thread screw rolling device of the present invention.

Figure 6 is a perspective view of the process of the auxiliary cam interlocked to the spiral cutter of the outer thread screw rolling device of the present invention.

* Explanation of symbols for main parts of the drawings

41: motor 42,70: gearbox, subgearbox

51: center axis of rotation 55: first axis of rotation

57 ': second rotation shaft 62: third rotation shaft

71,71 ', 72: Universal joint 80,80': First and second cylindrical spiral cutter

83,83 ': Front block 85: Compression spring

90: intermittent rocking lever body 93: cam

94: spacing adjustment rod

The present invention relates to an outer thread rolling device for a pipe, and more particularly, to an outer thread rolling device for a pipe that allows a pipe having a thread formed on its outer circumferential surface to be automatically lowered.

The present invention is directed to an improvement on an external thread cutting device for pipes announced by the applicant. Referring to the reference number 92-1763, a pair of cylindrical spiral cutters 25 and 25 'installed and rotated at positions having the same height as shown in FIGS. 1 to 3 and the cylindrical spiral cutter 25, 25 ') is positioned on the center vertical line of the cylindrical lifting spiral cutter 26 which rotates while moving up and down, and the cylindrical lifting spiral cutter 26 is connected to one side, and the gap adjusting rod 33 on the other end thereof. Is installed and the intermittent rocking lever body 30 is inserted into the hinge shaft 32 on the support block 31 on the lower side of the center and the lower end of the gap adjusting rod 33 to contact the hinge shaft 32. Cam 34 for intermittently rotating the intermittent rocking lever body 30 in the up and down direction, the driven shaft (not shown) of the gears in the sub gear box 20 and the spiral cutters 25, 25 ', 26 to be movable between the universal joints 21, 21 'and 22 connecting the 26 and a pair of cylindrical spiral cutters 25 and 25', respectively. Value is consists of a work distance adjustment lever 35 to adjust the length of the insert (4).

In the case of forming a screw on the outer circumferential surface of the pipe by the outer thread screw rolling device 1 of the pipe according to the related art configured as described above, when the motor 2 is operated, the gears in the central rotation shaft 11 and the sub-gear box 20 And a known power transmission means (first sprocket) in which the cylindrical spiral cutters 25, 25 'and the cylindrical lifting spiral cutter 26 are rotated through the universal joints 21, 21', and 22, respectively, and are connected to the central rotating shaft 11; 12, the first chain 14, the first connecting sprocket 13, the second connecting sprocket 16, the first rotation shaft 15, the second chain 18, the second sprocket 17 and the first The cam 35 is also rotated by the two rotation shafts 19, and when the cam 35 is rotated, the intermittent rocking lever body 30 having the central lower portion connected to the hinge shaft 32 to rotate freely is provided at the right end thereof. When the lower side of the adjusting rod 33 is in contact with the cam 34, the lifting and lowering is repeated, the lower side of the gap adjusting rod 33 is in contact with the surface of the short radius Is a position where the cylindrical lifting spiral cutter 26 is in a raised position as shown in FIG. 2 (b), and is lowered as shown in FIG. 2 (a) when in contact with a long radius surface of the cam 34. Will be in. Therefore, when the cylindrical lifting spiral cutter 26 is in an elevated position, when the workpiece is moved to the upper side between the spiral cutters 25 and 25 'which are rotating the workpiece, the cylindrical lifting is performed as the cam 34 is rotated. The spiral cutter 26 descends to press the workpiece in the direction of the cylindrical spiral cutters 25 and 25 'to form a screw in the workpiece.

However, when the cylindrical lifting spiral cutter moves to the elevated position, the threaded workpiece must be pulled out by hand, and the workpiece must also be manually inserted at that position. Therefore, each time the cam rotates, the animal is removed manually and the workpiece is removed. There was a cumbersome problem to put in.

The present invention has been made in order to solve the above problems, by connecting the cam to the rotating shaft so that the workpiece is automatically lowered as the cam rotates to reduce the manual work of the outer thread screw rolling device of the pipe The purpose is to provide.

The outer thread screw rolling device of the pipe according to the present invention for achieving the above object is a cylindrical spiral cutter located on the center vertical line of a pair of cylindrical spiral cutter rotated by being installed at the same height position as the lifting and lowering In an outer thread thread rolling device of a pipe which forms a screw in an outer diameter of a pipe positioned on a pair of cylindrical spiral cutters, a spiral cutter positioned on one side of the pair of cylindrical spiral cutters is rotatably installed and integrally formed on the outer side thereof. By forming a support, the support is connected to the driving means and the cam is rotated to the outside by rotating the screw-shaped pipe is characterized in that it is lowered between the pair of spiral cutter.

Hereinafter, with reference to the accompanying drawings an embodiment of the outer thread screw rolling device of the present invention will be described in detail.

External thread rolling device of the pipe according to the present invention is the first and second cylindrical cutters (80, 80 ') are installed and rotated at the same height position as shown in Figures 4 to 6 and the Auxiliary cam (65) for contacting the support (86) integrally located on one side of the first spiral cutter (80) to rotate the first spiral cutter (80), and the first and second cylindrical spiral cutters (80). (80 ') is located on the center vertical line of the cylindrical lifting spiral cutter 81 which rotates while moving up and down, and the cylindrical lifting spiral cutter 81 on one side is connected to the other end of the gap adjusting rod 94 Is installed and the intermittent rocking lever body (90) inserted into the hinge shaft (92) on the base block (91) on the support block (91) and the lower end of the gap adjusting rod (94) in contact with the hinge shaft (92). Cam 93 for intermittently rotating the intermittent rocking lever body 90 in the up and down direction, and driven of the gears in the sub gear box 70 Universal joints 71, 71 ′, 72 connecting the shafts (not shown) and the spiral cutters 80, 80 ′, 81, respectively, and a first rotary shaft 51 for rotating the gears of the sub box 70. Bevel gear (not shown) for driving the gear box 42 is built, and the motor 41 for driving the bevel gear of the gear box 42.

The first sprocket 52 is integrally connected to the first rotation shaft 51, and the first sprocket 52 connected to the first sprocket 52 and the first chain 54 is connected to the first sprocket 52. It is integrally connected to the first rotation shaft 55 rotatably supported by two bearing supports 55 'fixedly formed as a ball on the top of the gearbox 70. The second sprocket 57 formed on the rear side of the apparatus body 40 by fixing the second connection sprocket 56 integrally connected to the other side of the first rotation shaft 55 and engaging the second chain 58 to the outside thereof. To transmit rotational driving force. The second sprocket 57 is fixed to the second rotary shaft 57 ', and a cam 93 is formed at an end of the second rotary shaft 57' so that the cam rotates as the second rotary shaft 57 'rotates. 93 is in contact with the lower end of the gap adjusting rod 94 to intermittently rotate the intermittent rocking lever body 90 in the up and down directions.

A third connection sprocket 53 is formed at one side of the second connection sprocket 56 of the first rotation shaft 55 to be supported by the support bearing body 63 formed in front of the sub gear box 70. It is connected to the third sprocket 60 and the third chain 61 which are integrally fixed to the rotation shaft 62. An auxiliary cam 65 is formed at one end of the third rotary shaft 62, and an end thereof is supported by the support bearing body 64.

The first and second cylindrical spiral cutters 80 and 80 'and the cylindrical lifting spiral cutter 81 are three universal joints 71 and 71 fixed to the sub-gear box 70 by the rotational force transmitted from the rotation shaft 51. ', 72 is rotated to be movable. The spiral cutters 80 and 80 'of the first and second cylindrical shapes are formed on the rear block 73 with bearing bodies 82 and 82' formed at rear ends thereof, and the front ends of the spiral block cutters 83 and 83 '. Is fixed to. The first cylindrical spiral cutter 80 is hinged to allow the bearing body 82 to pivot to the rear block 73 and the front block 83 to be movable on the rail 75 of the support plate 74. It is. One end of the compression spring (85) is fixed to the inner surface of the front block body 83, the compression spring (85) the other end is a projection piece 84 is spaced apart from the inner surface of the front block (83) by a certain distance ) In addition, a vertically bolted contact rod 87 is formed at the central end of the support 86 of the first cylindrical spiral cutter 80 such that the contact rod 87 is in contact with the auxiliary cam 65. Therefore, when the auxiliary cam 65 is in contact with the surface of the short radius of the auxiliary cam 65 at the time of rotation, the contact rod 87 is detached so that the compression spring 85 moves the front block body 83 to the outside. The front block body 83 slides outward along the rail 75 of the support piece 74 because it is pushed.

The elevating cylindrical spiral cutter 81 is swung up and down by a fixed support 81 'fastened to the front wall of the intermittent rocking lever body 90 by a bolt.

A spiral is formed in the central portion of the rear block body 73, and a hole (not shown) having an upper side cut in the longitudinal direction is formed so that the gap adjusting lever 95 can be inserted into the hole so as to be able to move forward and backward.

Referring to the effect of the present invention is as follows.

In the case of forming a screw in the pipe 100 by the outer thread screw rolling device 40 of the pipe according to the present invention configured as described above, when the motor 41 is operated, the center rotation shaft 51, the sub-gear box 70 Known power transmission means (first first) in which the cylindrical spiral cutter (80, 80 ') and the cylindrical lifting spiral cutter (81) are rotated through the gear and the universal joint (71, 71', 72), respectively, and connected to the central rotating shaft (51). Sprocket 52, first chain 54, first connecting sprocket 53, second connecting sprocket 56, second chain 58, second sprocket 57) and second rotating shaft 57 ' The cam 93 is also rotated by this. In this case, when the second connection sprocket 56 is rotated, the auxiliary cam 65 is also rotated by the third connection sprocket 59, the third sprocket 60, the third chain 61, and the third rotation shaft 62. do.

When the cam 93 is rotated, the intermittent rocking lever body 90 whose center lower portion is rotatably connected to the hinge shaft 92 has a lower surface of the gap adjusting rod 94 provided at the right end thereof. As the auxiliary cam 65 is rotated while the auxiliary cam 65 is rotated while contacting, the first cylindrical spiral cutter 80 is rotatable about a hinge point (not shown) of the bearing body 82.

That is, when the lower side of the gap adjusting rod 94 is in contact with the surface of the short radius, as shown in (b) of FIG. 5, when the cylindrical lifting spiral cutter 81 is in the raised position, the auxiliary cam ( 65, as shown in (b) of FIG. 5, the short surface of the auxiliary cam 65 contacts the contact rod 87 so that the contact rod 87 receives the punch of the compression spring 85 and is separated outwardly. The first cylindrical spiral cutter 80 is rotated outwardly about the hinge point of the bearing body 82. At this time, since the first cylindrical spiral cutter 80 is connected to the universal joint 71, the rotation is free and the front block 83 moves along the rail 75 of the support plate 74.

When in contact with the long radius surface of the cam 93 is in the lowered position as shown in FIG. 5 (a), the auxiliary cam 65 is a long radius surface as shown in FIG. Compression spring 85 is compressed because it is in contact with the contact rod (87). At this time, when the elevating spiral cutter 81 pressurizes the pipe, the front block body 83 is moved to the outside, but the contact rod 87 is caught on the cam 65 to prevent the moving outward.

Therefore, when the cylindrical lifting spiral cutter 81 is in an elevated position, when the workpiece 100 enters the upper side between the spiral cutters 80 and 80 'which are rotating, the cam 93 is rotated. Cylindrical elevating spiral cutter 81 is lowered to form a screw on the workpiece while pressing the workpiece in the direction of the cylindrical spiral cutter (80, 80 '), at this time, the contact rod on the long radius surface of the auxiliary cam (65) Since the 87 is caught, the detachment of the front block body 83 is prevented. When the cam 93 continuously rotates and the cylindrical lifting spiral cutter 81 rises, the contact rod 87 contacts the surface of the short radius of the auxiliary cam 65 while the compression spring 85 springs and the first cylindrical spiral spirals. The cutter 80 rotates about the hinge point of the bearing body 82 and the front block 83 moves outward along the rail 75 of the support plate 74 so that the workpiece automatically falls downward. When the auxiliary cam 65 continues to rotate so that a long radius surface contacts the contact rod 87, the front block 83 of the first cylindrical spiral cutter 80 returns to its initial position along the rail 75. do.

The present invention rotates the first cylindrical spiral cutter to automatically lower the machined pipe, but includes rotating the second cylindrical spiral cutter by forming a further auxiliary cam by speaking the rotating shaft to a known power means. In addition, although not shown here, the present invention installs a hydraulic cylinder in place of the cam motion mechanism, and connects the first and second cylindrical spiral cutters to the piston which is retracted in the hydraulic cylinders so that the spiral cutters are adjacent to or separated from each other. can do.

As described above, the pipe external thread rolling device according to the present invention forms a cam and forms a spring that compresses and compresses according to the cam, thereby allowing the first cylindrical spiral cutter to be rotated to automatically lower the machined pipe to improve work efficiency. There is an advantage to this.

Claims (2)

Cylindrical lifting spiral cutters located on the center vertical line of a pair of cylindrical spiral cutters installed and rotated at the same height as each other form a screw on the outer circumferential surface of the pipe located on the pair of cylindrical spiral cutters. In the outer thread thread rolling device of the pipe, when the cylindrical lifting spiral cutter 81 moves up and down, the pair of spiral cutters 80 and 80 'are spaced apart, and when the cylindrical lifting spiral cutter 81 descends, An outer thread rolling device of a pipe, characterized in that the retracting means is formed so that the spacing of the spiral cutters (80, 80 ') is narrowed so that the pipe with the screw is automatically lowered. According to claim 1, wherein the retracting means is a support body (86) formed integrally with the outer side of the at least one cylindrical spiral cutter (80), the support member 86 is in contact with the cylindrical spiral cutter (80) to the rail (75) Compression spring that one end is bound to the cam (65) to advance on and the block body 83 formed in front of the cylindrical spiral cutter 80 and the other end is bound to the protruding piece (84) formed on one side of the block body ( 85) External thread rolling device of a pipe, characterized in that consisting of.