KR101046626B1 - Tube Groove Forming Device - Google Patents

Abstract

The present invention relates to a tube groove forming apparatus, the work table (10); A tube rotation part 20 disposed on one side of the work table 10 to axially rotate the tube body 12; A tubular support part 30 disposed on the same line as the tubular rotating part 20 to support the axial rotation of the tubular body 12 that is axially rotated; And a concave groove forming part disposed between the tube rotation part 20 and the tube support part 30 to form a plurality of concave grooves 12a continuous in a spiral direction at regular intervals on an outer circumferential surface of the tube body 12 which is axially rotated. 40 is comprised. Therefore, the groove forming member of the concave groove forming portion in which the tube rotating portion axially rotates the tube and correspondingly presses the tube and slides in a direction opposite to the forward and reverse rotational forces of the tube forms a concave groove on the outer circumferential surface of the tube. By forming a concave groove on the outer circumferential surface of the tube while the concave groove forming portions are slid by the inertia of each other without installing a separate mechanism to the concave groove forming portion for forming the concave groove, Not only does it happen quickly, but it also helps to save the cost and labor of the device as much as possible.

Pipe Groove Forming Device, Pipe Rotating Part, Pipe Supporting Part, Concave Groove Forming Part, Bearing Rotating Body

Description

Apparatus for making grooves on pipe}

The present invention relates to a tubular groove forming apparatus, and more particularly, the groove forming member of the concave groove forming portion in which the tubular rotating portion rotates the tubular body and correspondingly presses the tubular body against the positive and reverse rotational power of the tubular body. By forming the concave groove on the outer circumferential surface of the tube while sliding in the opposite direction, the concave groove forming portion is slid by the inertia of each other without the installation of a separate mechanism to the concave groove forming portion for forming the concave groove, the concave groove on the outer peripheral surface of the tube The present invention relates to a tubular groove forming apparatus that can easily and quickly form a concave groove for a tubular body, as well as to reduce the cost and labor according to the device configuration.

In general, a printing roll applied to an image forming apparatus such as a printing press has a pipe structure with an empty inside and a smooth surface.

In recent years, such printing rolls have become thinner and thinner, and in addition, as a part to increase the heat transfer area, a technique for increasing the surface area of the entire printing roll by forming protrusions or grooves on the surface thereof is proposed. It is becoming.

Meanwhile, for the first time in the process of manufacturing a printing roll, a plurality of concave grooves are formed on the outer circumferential surface by pressing a plurality of concave grooves on the outer circumferential surface for the purpose of increasing the surface area. If the outer surface of the tube is smoothly cut, only convex protrusions remain on the inner circumferential surface of the tube, resulting in an increase in the surface area of the tube.

As a technique for forming a concave groove on the outer surface of such a tubular body, for example, a schematic view of a tubular groove forming apparatus according to the prior art, a pair of tubular support portions for supporting both ends of the tubular body is provided, between the tubular support portions And a concave groove forming portion which is disposed at the outer circumferential surface of the tubular body and rotates while a predetermined concave groove forming blade is pressed.

The prior art of such a configuration has the principle of forming a spiral groove on the outer circumferential surface of the tubular body while the concave groove forming part having the concave groove forming blade is axially rotated while the tubular support is fixedly supporting both ends of the tubular body.

However, the prior art tube groove forming apparatus is a structure that forms a concave groove through a complex mechanism operation for physically rotating the concave groove forming portion and forcibly sliding along the longitudinal direction of the tube, thereby applying a rotational force to the concave groove forming portion. Since the rotary device and the sliding device according to the sliding must be provided respectively, not only the device of the concave groove forming part is complicated, but also the manufacturing work is difficult, thereby increasing the cost burden such as manufacturing cost and labor force, and also concave. As the device of the groove forming unit itself becomes complicated, the surrounding facilities also have to take a complicated structure, and overall, there is a problem that the work efficiency decreases according to the complexity of the device.

The present invention has been made in order to solve this problem, the groove forming member of the concave groove forming portion of the tube rotating portion to rotate the tube and to press the tube in response to the opposite direction to the forward and reverse rotational power of the tube By forming a concave groove on the outer circumferential surface of the tubular body while sliding to form a concave groove on the outer circumferential surface of the tubular body by sliding the concave groove forming parts by inertia between each other without installing a separate mechanism to the concave groove forming part for forming the concave groove. It is an object of the present invention to provide a concave groove forming apparatus that can easily and quickly form concave grooves on the tube as well as reduce the cost and labor according to the device configuration.

Pipe groove forming apparatus of the present invention for achieving the above object is a work table; A tube rotating part disposed at one side of the work table to axially rotate the tube; A tubular support configured to axially rotate and support the tubular body which is disposed on the same line as the tubular rotating part and rotates axially; And a concave groove forming unit disposed between the tube rotating unit and the tube supporting unit to form a plurality of concave grooves that are arranged in a spiral direction at regular intervals on an outer circumferential surface of the tube to be axially rotated.

In addition, in the tubular groove forming apparatus according to the present invention, the concave groove forming portion is provided with a plurality of groove forming members for pressing in the helical direction surrounding the entire outer circumferential surface of the axially rotated tubular body, these groove forming members are the It is preferable that the outer peripheral surface of the tubular body can be pressurized in three directions while being spaced apart and narrowed radially with respect to the outer peripheral surface.

In addition, in the tube groove forming apparatus according to the present invention, a gear tooth is formed on one side of the groove forming member, and the gear tooth is radially moved in engagement with a scroll which is rotated forward and reverse by forward and reverse rotation of the bevel gear. The scroll chuck structure is preferably enabled to radially move the groove forming member.

In the tubular groove forming apparatus according to the present invention, the front end of the groove forming member is provided with a bearing rotating body axially rotated in the opposite direction to the tubular body by the forward and reverse rotational force of the tubular body, and the edge of the bearing rotating body. A plurality of groove forming projections are placed at an angle to the outer circumferential surface of the tubular body and pushed backward along the forward and reverse rotations of the tubular body while being pushed forward while being pushed forward to form concave grooves on the outer circumferential surface of the tubular body. It is preferred that it is formed.

In addition, in the tubular groove forming apparatus according to the present invention, it is preferable that a slider is provided at a lower end of the concave groove forming portion and a sliding rail for guiding the slider to slide on an upper surface of a work table corresponding thereto is provided.

In addition, in the tubular groove forming apparatus according to the present invention, the sliding rail has a pair of rods arranged in parallel spaced at a predetermined interval, the corresponding slider is a sliding ring wrapped around the outer peripheral surface of each rod It is preferable that the block structure is provided.

In the tubular groove forming apparatus according to the present invention, the tubular support portion is fixed by being clamped by a predetermined fixed chuck and the other end is exposed to the other end of the concave groove forming portion to support the end of the tubular body which is axially rotated. It is preferable to have a pipe structure provided with a rotating member which is axially rotated like this tube.

In addition, in the tubular groove forming apparatus according to the present invention, it is preferable that a sliding ring that slides forward and backward is wrapped around the outer circumferential surface of the sliding rail at the lower end of the fixed chuck of the tubular support.

As described above, in the tube groove forming apparatus of the present invention, the groove forming member of the concave groove forming portion in which the tube rotating portion rotates the tube body and correspondingly presses the tube body in the opposite direction to the forward and reverse rotational power of the tube body. By forming concave grooves on the outer circumferential surface of the tubular body while sliding, concave grooves are formed on the outer circumferential surface of the tubular body by sliding the concave groove forming parts by inertia between each other without installing a separate mechanism to the concave groove forming part for forming the concave grooves. In this way, the concave grooves can be easily and quickly formed on the tube, and the cost and labor of the device can be reduced as much as possible.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

As shown in Figures 1 to 8, the tube groove forming apparatus according to an embodiment of the present invention is a work table 10, a pipe rotating portion for rotating the pipe body 12 is disposed on one side of the work table (10) ( 20) and the tubular support part 30 which rotationally supports the tubular body 12 which is arrange | positioned in the same line opposite to this tubular rotation part 20, and is axially rotated, and is arrange | positioned between this tubular rotation part 20 and the tubular support part 30. FIG. And the concave groove forming portion 40 which forms the concave groove 12a on the outer circumferential surface of the tubular body 12 that is axially rotated.

The work table 10 has a predetermined height upward from the bottom surface and has a rectangular shape having a tubular rotating portion 20, a tubular support portion 30, and a concave groove forming portion 40 respectively provided on the upper surface thereof.

In addition, a pair of rod-shaped sliding rails 15 arranged in parallel in the width direction to guide the slider 44 of the concave groove forming portion 40 to slide along the longitudinal direction on the upper surface of the work table 10. ) Are each provided.

The tubular rotating portion 20 is arranged on one side of the worktable 10 to axially rotate the tubular body 12, and a pair of discs 51 arranged parallel to one end of the worktable 10 and these It is arranged to be rotatable on one side plate 51 of the pulley-shaped rotary motor connecting portion 50 made of a circular tube 52 for connecting therebetween and penetrates the circular tube 52 with its rotary shaft 22 bearing-supported. It is exposed to the outside and is connected to the rotary motor 70 through a predetermined belt (60).

On the opposite side of the rotary shaft 22 of the tubular rotating part 20, a tubular fixture 24 is provided to firmly bite and fix the tubular body 12.

Here, the tubular fixture 24 may be applied to the scroll chuck of the existing structure that allows to bite or release the tubular body 12 while the radial opening and narrowing. That is, gear teeth (not shown) are formed on one side of the tubular fixture 24, and the gear teeth mesh with a scroll (not shown) which is rotated forward and backward by forward and reverse rotation of the bevel gear (not shown). As it slides, the radially expanding and narrowing movement becomes possible.

On the other hand, in addition to such a scroll chuck may be a variety of existing structures within the range that satisfies the conditions for fixing the tube (12).

The tubular support 30 is to support the rotation of the tubular body 12 is arranged on the opposite side of the same line as the tubular rotating part 20, the shaft rotation, this also applies a fixed chuck 31 of the general scroll chuck structure, The tubular support portion 30 supports the other end of the tubular body 12, one end of which is held by the fixed chuck 31 and the other end thereof is exposed to the other end of the concave groove forming part 40, and is axially rotated. It is a pipe structure provided with the rotating member 32 which is axially rotated like this tubular body 12 in the state.

Here, the rotating member 32 is connected so that one end thereof is axially rotated relative to the other end of the tube support portion 30 via a predetermined bearing (not shown), and the other end thereof is the tube body 12. It has a pointed cone structure to be inserted and supported inside the other end of the

In addition, the fixing chuck 31 is provided with a plurality of clamps 34 to pressurize and fix the outer circumferential surface of the tubular support 30 while being radially opened and narrowed in the state where one end of the tubular support 30 is inserted. have.

In addition, the support body 30 is preferably to be movable on the sliding rail 15 so as to adjust the linear distance with the tube rotation unit 20, the structure is the lower end of the fixed chuck 31 A block structure is provided with a sliding ring 36 which slides around the outer circumferential surface of the sliding rail 15.

Here, the tubular support part 30 is firmly fixed at the position after the proper working distance with the tubular rotating part 20 is determined so that the tubular body 12 can be axially rotated, and the tubular body is completed when the work is completed. It is preferable to provide a moving means such as a separate hydraulic cylinder 35 to move forward and backward so that the tubular support part 30 can be separated from the 12.

The concave groove forming portion 40 is disposed between the tubular rotating portion 20 and the tubular support portion 30, the center of which is formed on the outer circumferential surface of the tubular body 12 that is axially rotated so as to pass through the tubular body 12 so as to pass therethrough. Forming the concave groove 12a, the one side surface of the concave groove forming portion 40 is wrapped around the entire outer peripheral surface of the tubular body 12 which is axially rotated and pressed to a plurality of continuous spaced apart in the spiral direction A plurality of grooved members 42 for forming the recessed grooves 12a are provided.

Here, the groove forming member 42 is axially rotated in the opposite direction by the forward and reverse rotational force of the tubular body 12, while being engaged with the outer circumferential surface of the tubular body 12 and being pushed backward and being pulled forward, the concave groove forming part. The bearing rotating body 42a which moves 40 back and forth is provided.

In addition, a plurality of spaced apart at regular intervals are formed on the entire rim of the bearing rotating body 42a so as to form a concave groove 12a by pressing to penetrate a predetermined depth in a state arranged obliquely to the outer circumferential surface of the tubular body 12. Groove forming projections 42a1 are provided.

Here, the number and size of the torsion angle or the groove forming protrusion 42a1 in the spiral direction with respect to the tube body 12 of the bearing rotating body 42a can be adjusted, and as a result, the number and size of the concave grooves 12a can be adjusted. Will be done.

Reference numeral 42a2 denotes a pair of bearings mounted in the central through hole of the bearing rotating body 42a.

These groove forming members 42 are arranged at equal intervals with respect to the outer circumferential surface of the tubular body 12, and are combined to press the outer circumferential surface of the tubular body 12 in three directions while being radially opened and narrowed. In the radial movement operation of 42, a gear tooth 42b is formed on one side of the groove forming member 42, and this gear tooth 42b is forward and reverse by the forward and reverse rotation of the bevel gear 40a. It is preferably made by a scroll chuck structure which engages with the scroll 40b to be rotated to move radially.

In addition, at the lower end of the concave groove forming portion 40, when the concave groove 12a of the conduit 12 is formed, the concave groove forming portion 40 is formed in accordance with the forward and reverse rotation of the conduit 12. A slider 44 for sliding reciprocating along the longitudinal direction is provided on the upper surface of the sliding rail 15.

Here, the slider 44 has a block structure in which a sliding ring 44a is provided to slide around the outer circumferential surface of each rod of the sliding rail 15.

The tubular groove forming apparatus of the present invention according to the above configuration is rotatably coupled to the tubular rotating portion 20 to the rotary motor connecting portion 50 of the worktable 10, the tubular support (on the upper surface of the opposite side of the worktable 10 corresponding thereto) 30 is disposed spaced apart by an appropriate working distance, and a concave groove forming portion 40 is provided therebetween, so that the slider 44 is slidably coupled on the sliding rail 15 of the work table 10 so that the tube according to the present invention. Complete the installation of the groove forming apparatus.

When the concave groove 12a is formed into the tube body 12, one end of the tube body 12 to be worked is fixed to the tube fixing fixture 24 of the tube rotating part 20, and the other end is concave groove. Through the center of the forming portion 40 so that a certain length protrudes to the outside of the concave groove forming portion 40, the tube support portion 30 is moved toward the other end of the tube body 12 to support the tube body ( Rotating member 32 of 30 is to be in close contact with the other end of the tube (12).

Then, each groove forming member 42 of the concave groove forming portion 40 is finally tightened radially so that the groove forming protrusion 42a1 of the bearing rotating body 42a at the distal end thereof is arranged obliquely with the outer peripheral surface of the tubular body 12. In the closed state, a predetermined depth of the recessed groove 12a is formed so as to be drilled into a predetermined depth so as to prepare the work for forming the recessed groove 12a to the outer surface of the tube 12.

In this state, by rotating the tubular rotating part 20 by operating the rotary motor 70 of the work table 10, the bearing rotation is meshed diagonally to the outer peripheral surface of the tubular body 12 by the rotational force of the tubular body 12. The whole 42a is rotated in the opposite direction and is pushed along the longitudinal direction by inertia to form the concave groove 12a on the outer circumferential surface of the tubular body 12.

And, if the rotary motor 70 is rotated in reverse, this time the bearing rotating body 42a is pulled in the opposite direction along the outer circumferential surface of the tubular body 12 to continue to form the concave groove 12a.

Thus, through the reciprocating sliding of the concave groove forming part 40 according to the forward and reverse rotation of the rotary motor 70, it is possible to manufacture a tube body 12 having the desired concave groove (12a).

In addition, if the groove 12a of the tubular body 12 is to be dug further and the groove becomes deeper, the work is paused to further tighten the groove forming member 42 radially, thereby again through the rotational force of the rotating motor 70. By performing the concave groove 12a forming operation, it is possible to obtain a desired concave groove tube body.

On the other hand, in the present invention is mainly configured to be suitable for the formation of the concave groove of the tube for producing a printing roll applied to an image forming apparatus such as a printing machine, the interval between the tube rotating portion 20 and the tube support portion 30 is relatively short. On the other hand, if you want to adjust the length of the tubular body 12 to some extent, by sliding the tubular support part 30 back and forth, the distance can be adjusted to a certain extent.

1 is a perspective view showing a tube groove forming apparatus according to an embodiment of the present invention.

Figure 2 is a perspective view showing the working state of the tube groove forming apparatus according to an embodiment of the present invention.

Figure 3 is a perspective view showing the recessed groove forming portion of the tube groove forming apparatus according to an embodiment of the present invention.

Figure 4 is a side view showing the main portion of the bearing rotating body of the concave groove forming portion of the tube groove forming apparatus according to an embodiment of the present invention.

5 to 8 are schematic diagrams sequentially showing the working state of the tube groove forming apparatus according to an embodiment of the present invention.

DESCRIPTION OF REFERENCE NUMERALS

10: work table 12: pipe

12a: concave groove 15: sliding rail

20: tube rotating portion 22: rotation axis

24: tube fixing fixture 30: tube support

31: fixed chuck 32: rotating member

36: sliding 40: concave groove forming portion

40a: Bevel Gear 40b: Scroll

42: groove forming member 42a: bearing rotating body

42a1: groove forming protrusion 42a2: bearing

42b: Gear 44: Slider

44a: sliding ring 50: rotary motor connection

51: negative plate 52: original tube

60: belt 70: rotation motor

Claims (8)

Worktable 10; A tube rotation part 20 disposed on one side of the work table 10 to axially rotate the tube body 12; A tubular support part 30 disposed on the same line as the tubular rotating part 20 to support the axial rotation of the tubular body 12 that is axially rotated; And The tubular body 12 is disposed between the tubular rotation part 20 and the tubular support part 30 to be axially rotated, and a plurality of concave grooves are formed on the outer circumferential surface of the tubular body and spaced apart at regular intervals in a spiral direction. And a plurality of groove forming members 42 for pressing the spiral outer side of the tubular body 12 to be axially rotated and pressurized in a helical direction, and gear teeth are formed on one side of the groove forming members, and the gear teeth are beveled. It is radially moved by the scroll chuck structure which is engaged with the scroll by the forward and reverse rotation of the gear to move radially, and the groove forming members 42 are arranged at equal intervals with respect to the outer circumferential surface of the tubular body 12 and radially opened. A concave groove forming portion 40 configured to press the outer peripheral surface of the tubular body 12 in three directions while being narrowed; Tube groove forming apparatus configured to include. delete delete The method of claim 1, The front end of the groove forming member 42 is provided with a bearing rotator 42a which is axially rotated in the opposite direction to the tube 12 by the forward and reverse rotational forces of the tube 12, and the bearing rotator 42a. It is placed obliquely with the outer circumferential surface of the tube body 12 on the edge of the tube body 12 while being pushed backward in the forward and reverse rotation of the tube body 12 while being pushed into the outer circumferential surface of the tube body 12 and being pulled forward. Tube groove forming apparatus, characterized in that a plurality of groove forming projections (42a1) are formed on the outer peripheral surface of the concave groove (12a). The method of claim 1, Slider 44 is provided at the lower end of the concave groove forming portion 40 and the sliding rails 15 for guiding the slider 44 to slide on the upper surface of the work table 10 corresponding thereto are provided. Tube groove forming device. The method of claim 5, The sliding rail 15 has a pair of rods arranged in parallel spaced at a predetermined interval, the corresponding slider 44 is a block structure provided with a sliding ring (44a) is wrapped around the outer circumferential surface of each rod Tube groove forming apparatus, characterized in that. The method of claim 1, The tubular support portion 30 is supported by the end of the tubular body 12, one end of which is fixed by a predetermined fixed chuck 31 and the other end is exposed to the other end of the concave groove forming portion 40 and is axially rotated. Tube groove forming apparatus, characterized in that the pipe structure is provided with a rotating member 32 that is axially rotated like this tube (12). The method of claim 7, wherein Tube groove forming, characterized in that the sliding support (36) is provided at the lower end of the fixed chuck (31) of the tubular support (30) is wrapped around the outer circumferential surface of the sliding rail (15) formed on the upper surface of the worktable (10), the sliding sliding backward Device.

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