KR101546779B1 - Rounding and Chamfering device - Google Patents

Abstract

The present invention relates to an air beveling machine. The purpose of the present invention is to provide an air beveling machine, capable of easily controlling a quantity of air. To achieve this purpose in accordance to the present invention, the air beveling machine comprises: a tubular body housing having both end parts opened; an operating unit placed in the body housing, including a cutting tool exposed through an end of the body housing, and a rotation operating part rotating the cutting tool by operational air supplied through an other end part of the body housing; a connection unit combined with the other end part of the body housing, delivering the operational air from the outside to the operating unit; a valve body changing divergence of an air path in accordance to a rotation position by being inserted into the air path in a transverse direction in order to control a quantity of operational air supplied to the operating unit; and an air control valve including a manipulating knob to rotate the valve body outside the connection unit by being integrated with the valve body.

Description

{Rounding and Chamfering device}

The present invention relates to an air chamfer.

The air chamfer has a connection unit, which is generally connected to the air tank and supplied with air, and a cutting tool which is rotated by the supplied air to machine the workpiece.

However, as in Korean Laid-Open Utility Model Application No. 20-2009-0003749, " Prior Art " (hereinafter referred to as " prior art "), the conventional air chamfer 12), so that the rotational speed of the cutting tool could not be finely adjusted. Accordingly, the conventional air chamfer machine has processed the workpiece having different hardness or density, such as metal, wood, plastic, etc., at substantially the same rotational speed.

When machining workpieces having different physical properties at the same rotation speed, it is inevitable that the cutting tool is quickly worn out, shortening the life span and making it difficult to control the work quality.

An object of the present invention is to provide an air chamfer capable of adjusting the rotation speed of a cutting tool with a simple structure.

In order to achieve the above object, an air chamfer according to the present invention comprises: a main body housing of a tubular body having both ends thereof opened; a cutting tool accommodated in the main body housing and exposed through one end of the main body housing; A driving unit for driving the cutting tool by rotationally driving the cutting tool by the working air supplied through the main body housing; an air passage coupled to the other end of the main body housing, And a valve that is inserted into the air passage so as to be rotatable in the transverse direction and changes the opening degree of the air passage according to the rotation position so as to adjust the amount of working air supplied to the driving unit, And a control knob which is integrally formed with the valve body and is capable of rotating the valve body from the outside of the connection unit, An air control valve having.

Wherein the valve body has an adjusting through hole aligned with the air flow passage, and both the opening of the adjusting through hole have different diameters to control the air to be introduced.

And a detent stopper portion having a diameter smaller than that of the valve body is formed between the valve body and the operation knob, and the connection unit is provided with a pair of detent pins which are mutually opposed to each other in the transverse direction, It is advantageous to mount and operate the control valve to the connection unit.

Further, it is advantageous for the operator to precisely control the rotation speed of the cutting tool, since the operation knob has the opening display portion for indicating the degree of rotation of the valve body.

Wherein the operation knob is rotatable about an axis in the shape of a cylinder, and a plurality of grooves are formed in the outer peripheral surface of the operation knob in the transverse direction with respect to the rotational direction, And an elastic portion for pressing the operation ball against the operation knob, which is advantageous for fine manipulation of the operation knob.

The air chamfer according to the present invention can adjust the rotational speed of the cutting tool with a simple structure.

1 and 2 are an exploded perspective view and an exploded perspective view showing an air chamfer according to the present invention,
3 and 4 are a perspective view and an exploded perspective view showing an enlarged view of the connection unit,
5 is a cross-sectional view of the connection unit according to the line V-V shown in Fig. 3,
6 is a cross-sectional view of the connection unit according to the VI-VI line shown in Fig. 3,
Fig. 7 is a sectional view taken along the line VI-VI of Fig. 3,
8 to 10 are cross-sectional views taken along the line VI-VI of FIG. 3 showing the change of the air passage according to the operation of the air control valve.

1 and 2 are an assembled perspective view and an exploded perspective view showing an air chamfer according to the present invention. As shown in these drawings, the air chamfer 100 includes a tubular main body housing 100, a connection unit 300 coupled to one end of the main body housing 100 to receive operating air from the outside, and a main body housing 100 And is driven by operating air supplied from the connection unit 300. The driving unit 200 includes a driving unit 200,

The driving unit 200 includes a cutting tool 220 which is partially exposed from the main housing 100 and rotates around an axis to process a workpiece, And a rotation driving unit 210 for rotating the cutting tool 220 by receiving the working air. At the end of the main body housing 100 on the side where the cutting tool 220 is exposed, a support guide plate 120 is detachably coupled to the workpiece to support the workpiece. The support guide plate 120 is formed with a cutting tool exposure hole 121 through which the cutting tool 220 can be exposed.

3 and 4 are an exploded perspective view and an exploded perspective view showing the connection unit 300 in an enlarged scale. In FIG. 4, for convenience of explanation, the operation interval 360 is omitted. 3 and 4, the connection unit 300 is provided with an air inflow coupler 320 protruding and extending in the longitudinal direction to receive air from the outside. Coupler 320 is coupled to an air tube (not shown) extending from an air supply (not shown) such as a compressor or air storage tank. At the end of the air tube (not shown), a coupler corresponding to the air inlet coupler 320 is provided.

5 is a cross-sectional view of the connection unit according to the line V-V shown in Fig. 5 and 5, the connection unit 300 is provided with an air control valve 350 for controlling the opening of the air passage 310 inside the connection unit 300, ).

The air control valve 350 includes a valve body 357 which is inserted into the connection unit 300 and changes the opening degree of the air flow path 310 and a valve body 357 integrally formed with the valve body 357, And an operation knob 355 that can turn the valve body 357 in a rotational direction. The operation knob 355 has a cylindrical shape and the valve body 357 is formed in a cylindrical shape having a diameter smaller than that of the operation knob 355 and formed concentrically to the operation knob 355.

On the outer surface of the operation knob 355, numerals 1, 2 and 3, which are information indicating the degree of opening of the air flow path 310, are written at predetermined intervals along the circumferential direction. In addition, a plurality of fine grooves are formed along the insertion direction on the outer circumferential surface of the operation knob 350, and a deeper groove 356 is formed on the outer circumferential surface at positions corresponding to the display station 1, 2 and 3.

The non-through ball insertion port 130 is formed in the connection unit 300 along the air flow direction in an adjacent region where the operation knob 350 is mounted. A ball spring 133 is first inserted into the insertion port 130 and an operation ball 131 is inserted along the spring 133.

The outer peripheral surface of the operation knob 355 is in contact with the operation ball 131 elastically supported by the spring 133 and the operation ball 131 is rotated by the operation knob 355 355). Accordingly, the operator can operate the operation knob 355 while recognizing the sound and / or the tactile sensation that occurs in the step in which the operating ball 131 that rolls in the state of being in contact with the outer circumferential surface of the operation knob 355 is seated and removed from the fine groove, Can be finely rotated.

When the manipulation ball 131 is seated on the deep groove 356 formed in the display phrases 1, 2 and 3, the manipulation ball 131 is seated deeper than when the manipulation ball 131 is seated on the fine groove, ) Can be easily recognized by the sound or tactile sense that it is seated in the display 1, 2 or 3. Thus, the operator can easily recognize information about the degree of opening of the air passage 310 that can not be seen by the user.

The valve body 357 is provided with an adjusting through hole 351 penetrating the valve body 357 in the transverse direction with respect to the longitudinal direction of the valve body 357. The diameters of the openings on both sides of the adjustment through hole 351 are different from each other. When the valve body 357 is inserted into the connection unit 300, the adjustment through hole 351 serves to connect the air flow path 310 formed in the connection unit 300. An O-ring 331 is provided in a section where the valve body 357 and the operation knob 355 are connected to prevent air flowing through the air passage 310 from flowing out through the valve body insertion hole 330.

A pair of stop pins 354 for fixing the insertion of the air control valve 350 inserted in the connection unit 300 are inserted into the connection unit 300 in the lateral direction with respect to the longitudinal direction. The valve body 357 is formed with a detent stopper 353 for receiving a pair of detent pins 354.

The detent stopper 353 is formed in a recessed groove shape along the circumference of the valve body 357. Accordingly, the pair of detent pins 354 are inserted into the connection unit 300 and supported by the detent stopper 353, and fix the insertion of the air control valve 350. [ The detent pin 354 is preferably provided with a tongue bolt.

The connection unit 300 is provided with an operation space 360, which is a knob configuration for opening and closing the air flow path 310. The operation space 360 is coupled to the connection unit 300 by a hinge 361 and can be pivoted about the axis of the hinge 361 by the operation of the operator. The operation space 360 is pivoted by the hinge 361 so that the free end contacts the inter-operation space 362 and can press the space 362 into the connection unit 300 by a predetermined range.

6 is a cross-sectional view taken along the line VI-VI shown in Fig. Referring to FIG. 6 together with FIGS. 3 and 4, the air passage 310 includes a first section 311 extending in the longitudinal direction within the connection unit 300 and a second section 311 extending in the lateral direction in the first section 311 And a third section 315 extending downward from an end of the second section 313 and the second section 313. The working air flows from the coupler 320 and is supplied to the driving unit 200 while sequentially passing through the first section 311, the second section 313 and the third section 315.

 The inter-operation hole 362 is inserted along the second section 313 in the transverse direction of the connection unit 300 from the outside of the connection unit 300. The hole 362 includes an exposing projection 366 exposed at a predetermined position from the connection unit and an opening and closing unit 365 for opening and closing the bending region extending from the first section 311 to the second section 313. The opening / closing part 365 is formed to be larger than the air flow path diameter of the second section 313.

Accordingly, when the hole 362 is inserted into the connection unit 300, the exposing protrusion 366 is exposed at a predetermined portion outside the connection unit 300, and the opening / closing unit 365 opens the inlet of the second section 313 Closing.

Then, along the ball 362, the spring 363 is inserted into the connection unit 300. [ When the spring 363 is inserted, the ball is finally fixed to the connection unit 300 by the fixing screw 364, thereby closing the opening where the ball 362 is inserted. The spring 363 is concentrically disposed between the inter-actuation hole 362 and the fixing screw 364 so as to elastically press the hole 362 in a direction to block the second section 313.

7 is a cross-sectional view taken along the line VI-VI of Fig. 3, which shows the operation when the inter-actuation 360 is depressed. As shown in Fig. 7, the operation space 360 is rotated toward the connection unit 300 side with the hinge 361 as an axis. The operation space 360 is rotated to press the operation space 362 so that the operation space 362 is moved inside the connection unit 300 to open the air passage 310. [ At this time, the ball 362 resiliently resists against the pressurization of the inter-actuation 360 by the spring 363. The thus-viewed air chamfer can close or open the air passage 310 inside the connection unit 300 by the operator pressing the operation space 360.

8 to 10 are cross-sectional views taken along the line VI-VI of FIG. 3 illustrating the change of the air flow path 310 according to the operation of the air control valve 350. Referring to FIG. 7 together with FIGS. 8 to 10, the air chamfer 355 can change the opening degree of the air channel 310 as the operation knob 355 is rotated.

7 shows a state in which the large diameter 352b of the adjustment through hole 351 is disposed on the air inlet side and the small diameter 352a is arranged on the air outlet side. In this state, the air inflow amount is maximized, and the rotational speed of the cutting tool 220 is maximized.

8 is a view showing a state in which the operation knob 355 is rotated by about 45 degrees in the state of FIG. As shown in FIG. 8, the air flow path 310 in FIG. 8 has a reduction in opening of the air flow path 310 by about half compared with FIG. As a result, the amount of the incoming working air is reduced, and the rotational speed of the cutting tool 220 is also reduced.

9 is a view showing a state in which the operation knob 355 is rotated again by about 45 degrees in the state of FIG. As shown in Fig. 9, the air passage 310 in Fig. 9 is closed. Accordingly, the working air is not transferred to the drive unit 200 along the air flow path 310, and the cutting tool does not rotate.

7 to 9, the air chamfer can change the opening degree of the air flow path 310 by operating the air adjusting valve 350. As shown in Figs. 7 to 9 show only three explanatory states based on the drawings, and the degree of change of the opening degree according to the rotation of the operation knob 355 can be changed more finely. That is, it is possible to conveniently change from the maximum air flow path 310 in FIG. 7 to the closed air flow path 310 in FIG.

10 shows a state in which the small diameter 352a of the adjustment through hole 351 is arranged on the air inflow side. This can be changed as shown in Fig. 10 by rotating 180 degrees in a state where the large diameter 352b in Fig. 7 is arranged on the air inflow side. In the state where the small diameter 352a is disposed on the air inflow side, the air inflow amount is smaller than the state where the large diameter 352b is disposed on the air inflow side, so that the rotation speed of the cutting tool 220 becomes slow. 10, the opening degree of the air flow path 310 can be finely changed by the rotation operation of the operation knob 355 even in the state where the small diameter 352a is arranged on the air inflow side.

On the other hand, the phrases 1, 2, and 3 displayed on the operation knob 355 preferably indicate a rotational speed appropriate for the type of the workpiece, respectively. For example, 1 is metal, 2 is wood, and 3 is plastic, so that it can be displayed in accordance with the material of the workpiece so that the operator can easily select the rotational speed.

With this structure, air is introduced from the outside through the air inlet coupler 320, and working air is delivered to the driving unit 200 along the air channel 310 of the connection unit 300. The connection unit 300 is provided with an air control valve 350 for changing the degree of opening of the air passage 310 so that the amount of the working air delivered to the driving unit 200 can be adjusted. When the working air is transmitted to the driving unit 200, the cutting tool 220 is rotated by the rotation driving unit 210 about the axis. Thus, the air chamfer can be chamfered with the rotational speed of the cutting tool according to the physical properties of the workpiece.

100: Body housing 110: Body through hole
120: support guide plate 121: cutting tool exposure hole
130: Operation ball insertion port 131: Operation ball
133: ball support spring 200: drive unit
210: rotation driving part 220: cutting tool
300: connection unit 310: air passage
311: Air flow path 1 section 313: Air flow path section 2
315: air passage 3 section 320: air inlet coupler
330: valve body insertion hole 331: valve body ring
340: connection unit O-ring 350: air control valve
351: Adjustable through hole 352a: Small diameter
352b: large diameter 353: detent stop
354: stop pin 355: operation knob
356: control groove 357: valve body
360: between operations 361: between operations hinge
362: Inter-working ball 363:
364: Ball fixing screw 365:
366:

Claims (5)

In air chamfering,
A body housing of a tubular body having both ends open;
A drive unit having a cutting tool accommodated in the main body housing and exposed through one end of the main body housing and a rotation driving part for rotationally driving the cutting tool by working air supplied through the other end of the main body housing;
A connecting unit coupled to the other end of the main body housing and having an air flow path for receiving working air from the outside and transmitting the working air to the driving unit;
A valve body installed in the connection unit and inserted in a transverse direction with respect to the air passage so as to change the opening degree of the air passage according to the rotation position so as to adjust the amount of working air supplied to the driving unit, And an air control valve having an operation knob that is formed of a valve body and can rotate the valve body outside the connection unit,
Wherein the valve body has an adjusting through hole alignable with the air flow passage, both side openings of the adjusting through hole are provided at different diameters,
Wherein the valve body has a detent stop in the form of a groove recessed along the circumferential direction and the connection unit has a pair of detent pins inserted mutually opposite to the detent stop,
Wherein the operation knob has an opening display portion for indicating an opening degree of the adjusting through hole with respect to the air flow passage,
Wherein the operation knob has a cylindrical shape and has a plurality of grooves extending along the insertion direction of the valve body on the outer peripheral surface,
Wherein the connection unit includes an operation ball which contacts the outer circumferential surface of the operation knob, and an elastic portion that presses the operation ball against the operation knob. delete delete delete delete

Images