KR101205876B1 - Portable small hole electrical discharging machine - Google Patents

Abstract

PURPOSE: A portable small hole discharge machine is provided to be optimized the process of deep workpieces by supplying working liquid into a pipe electrode by using a high pressure pump. CONSTITUTION: A portable small hole discharge machine comprises a small hole machining electrode(10), a machine main shaft(20), a step motor(40), and a spindle motor(50). A spindle(21) inserted into the machine main shaft is coupled to the small hole machining electrode to supply working liquid. The machine main shaft moves back and forth according to the rotation of the step motor. A main shaft num is thread-coupled to the machine main shaft. The machine main shaft is driven by the rotating force of the step motor. The spindle motor has a spindle driven gear and a spindle driving gear. The small hole machining electrode is rotated by the rotating force delivered from the spindle driven gear and the spindle driving gear.

Description

Portable small hole electrical discharging machine

The present invention relates to a portable blood vessel discharge processing machine, and in particular, manufactured in a portable size, in the case of broken parts in the field or in the process of broken bolts, taps, drills, etc. in the work without disassembling the large workpiece powder into the discharge processing machine The present invention relates to a portable hemostatic discharge processor that can be removed by ignition.

The fine sedimentation processing device of the workpiece sedimentation type passes the processing liquid at a high pressure through a processing electrode formed in the shape of a thin pipe, and applies fine blood (fine holes) to a very hard sample (material) such as cemented carbide, quenched high speed steel, and heat resistant steel. It is a device used for drilling.

As a conventional blood-discharge machining apparatus used when puncturing blood to a very high hardness sample (material) as described above, the patent application No. 10-346557, filed by the present applicant and registered in the filed "Micropore discharge free of the position change of the head part" "Cutting Machine Surface Machining Process Enhancement Process CNC CNC Machine" and "Discharge Processing Machine" of Patent Registration No. 10-571025 are disclosed.

In these conventional processing machines, only vertical machining is possible due to the machine structure, and workpieces larger than the machine cannot be machined, and in particular, horizontal machining and inclined machining are difficult.

When the hole is completed by electric discharge machining, the processing liquid supplied through the finished hole is discharged as it is from the lower side (bottom surface), so that discharge is not completed completely, and thus, the machining cannot be efficiently performed. have.

In addition, the conventional electric discharge processing apparatus (blood discharge processing apparatus) is to supply the processing electrode stored in the electrode receiving tube to the electrode guide tube without intermediate support when supplying the processing electrode in the Z-axis feeder.

If the electrode length of 200 ~ 400㎜ is supplied from the electrode storage tube to the electrode guide tube without intermediate support, the discharge electrode and the working liquid pressure are applied to the processing electrode during the processing. The processing electrode to be supplied is a large bending phenomenon, and thus can not be precise processing can not only reduce the quality but also can not be processed quickly (use a lot of processing time) there is a problem that the productivity is reduced.

The present invention has been proposed in view of the above-mentioned conventional problems, and an object of the present invention is to supply a processing liquid at a high pressure to the inner diameter of a pipe electrode by rotating the electrode and using a high pressure pump to enable deep work processing. It is to provide a portable three-cell discharge machine.

Another object of the present invention is to provide a portable three-discharge discharge machine that can be attached to the electrode guide device to prevent the electrode shaking to enable the processing of deep holes and processing of fine holes.

Still another object of the present invention is to install a device on a support such as a magnetic stand or a tripod to allow a free rotation on the back of the device to enable a vertical and inclined processing and provide a three-cell discharge machine that can be easily attached and detached to metal. It is.

In order to achieve the above objects, the cerebro discharge machine according to the present invention comprises a cerebroprocessing electrode for cerebro discharge processing; A machine spindle coupled to the blood processing electrode to supply a processing liquid and move forward or backward according to the rotation of the step motor; A bearing case screwed to the spindle of the machine and including a spindle nut for receiving a rotational force from the step motor to drive the machine spindle forward or backward; A step motor coupled to an upper surface of the bearing case and including a prime timing pulley, a driven timing pulley and a timing belt to provide rotational force to the main shaft nut; A spindle motor including a spindle driven gear and a spindle driving gear to support the guide bracket and the spindle bracket coupled to and supported by the rear end of the machine spindle to provide rotational force to the spindle inserted into the machine spindle; Upper and lower cases coupled to a rear surface of the bearing case to protect the rear end of the main shaft of the machine and the spindle motor; It comprises a switch cover covering a step motor installed on the bearing case and having a transfer switch and an on / off switch.

According to one embodiment of the invention, the support is coupled to the spindle bracket and the support guide coupled to the support and guided by being inserted into the guide support rod and the guide support rod coupled to the upper support bracket and the movement range of the support guide It characterized in that it further comprises a machine spindle limitation including a left, right limiter to limit.

According to one embodiment of the invention, it is characterized in that it further comprises an electrode guide support attached to the bottom of the bearing case by a screw or the like to support the blood processing electrode.

According to one embodiment of the present invention, a bearing case includes: a spindle nut for screwing with a machine spindle; A spindle bearing supporting the spindle nut and reducing friction to smoothly rotate the machine spindle; It is characterized in that it comprises a driven timing pulley which is coupled to the spindle bearing and receives the rotational force of the step motor to rotate the spindle bearing.

According to one embodiment of the invention, the end plate is fixed to the rear end surface of the spindle by a screw to prevent the spindle driven gear from being separated from the rear end of the spindle, the end of the inner hole formed in the rear end of the spindle It extends to form a step so that the O-ring and two backup rings are inserted between the outer surface of the connection rod to maintain airtightness, and the protrusions of the end plate are also inserted to squeeze the O-rings and the two backup rings between the step and the protrusion. It is characterized in that the processing liquid injected into the inner hole of the spindle through the connection rod is configured so as not to leak.

As described above, according to the present invention, the electrode is rotated and the processing liquid is supplied to the inner diameter of the pipe electrode by using a high-pressure pump, so that it is optimized for deep work processing. It is possible to process and fine holes, and by installing the device on a support, such as a magnetic stand or tripod, free rotation is possible on the rear of the device to achieve the effect of vertical and inclined processing.

1 is a perspective view showing a state in which the cover of the portable hemostatic discharge machine according to the present invention is separated;
Figure 2 is a partial perspective view showing the inside of the bearing case transparent to show the coupling state of the bearing case and the machine tool spindle in accordance with the present invention,
3 is a front view showing a state in which the bearing case, the upper and lower case and the switch cover are peeled off in the processing machine according to the present invention;
Figure 4 is a cross-sectional view taken along the longitudinal axis of the blood processing electrode and the processing machine main axis according to the present invention,
5 is an exploded perspective view illustrating an exploded view of a machining spindle and a spindle inserted therein according to the present invention;
6 is a cross-sectional view taken along the longitudinal axis direction of the machine tool main shaft according to the present invention;
7 is a perspective view showing a machine spindle limitation portion which limits the forward and backward of the machine spindle by the present invention;
8A and 8B illustrate an example in which the portable cerebro discharge machine according to the present invention is attached to a stand and a tripod.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

DETAILED DESCRIPTION Hereinafter, specific configurations, effects, features, and advantages of the present invention will be apparent from the accompanying drawings and the following preferred embodiments.

1 is a perspective view showing a state in which the cover of the portable hemoelectric discharge machine according to the present invention is removed.

The portable blood cell discharge processor 100 according to the present invention includes a blood cell processing electrode 10 for blood cell discharge processing; A processor spindle 20 coupled to the blood processing electrode 10 to supply a processing liquid and move forward or backward according to the rotation of the step motor 40; A spindle nut 31 which is screwed to the machine spindle 20 and drives the machine spindle 20 forward or backward according to the rotational direction of the driven timing pulley 32 receiving the rotational force from the step motor 40. And a bearing case (30) including a bearing (33) for supporting the main shaft nut (31) and a bearing holder (34) for supporting the bearing (33); It is installed via a motor bracket 43 coupled to an upper surface of the bearing case 30 and an upper support bracket 44 supported by the motor bracket 43, and is driven to provide rotational force to the spindle nut 31. A step motor 40 including a timing pulley 41, a driven timing pulley 32, and a timing belt; The spindle driven to support the guide bracket 54 and the spindle bracket 51 coupled to and supported by the rear end of the machine spindle 20 to provide rotational force to the spindle 21 inserted into the machine spindle 20. A spindle motor 50 including a gear 53 and a spindle motive gear 52; The support 91 is coupled to the spindle bracket 51 and is supported, and the support guide 92 is coupled to the support 91 and is inserted into the guide support rod 93 and guided to the upper support bracket 44. A machine tool spindle limitation unit 90 including a guide support rod 93 and left and right limiters 94 and 95 for limiting a movement range of the support guide 92; An electrode guide support (60) attached to the bottom surface of the bearing case (30) by a screw or the like to support the blood processing electrode (10); Upper and lower cases (70a, 70b) coupled to the rear surface of the bearing case 30 to protect the rear end of the machine spindle 20 and the spindle motor (50); It comprises a switch cover 80 covering the step motor 40 installed on the bearing case 30 and having a transfer switch 81 and an on / off switch 82.

2 is a partial perspective view showing the bearing case transparently inside to show the coupling state of the bearing case and the machine spindle according to the present invention, and in FIG. 3 the bearing case, the upper and lower case and the switch in the machine according to the present invention. The state which removed the cover is shown, and sectional drawing which cut along the longitudinal axis | shaft is shown in FIG.

Referring to FIG. 2, the bearing case 30 includes a main shaft nut 31 which is screwed with the machine spindle 20; A spindle bearing (33) for supporting the spindle nut (31) and reducing frictional force so as to smoothly rotate the machine spindle (20); The driven timing pulley 32 is coupled to the spindle bearing 33 and receives the rotational force of the step motor 40 to rotate the spindle bearing 33.

A step motor 40 is installed on the upper surface of the bearing case 30, and a motive timing pulley 41 is provided on a rotation shaft of the step motor 40, and the motive timing pulley 41 is a timing belt 42. It is coupled to the driven timing pulley 32 through to transmit the rotational force of the step motor 40 to the driven timing pulley (32).

Accordingly, referring to FIGS. 3 and 4, the main shaft nut 31 is rotated by rotating the driven timing pulley 32 receiving the rotational force of the step motor 40, and thus, the main shaft 20 of the machine is moved forward or backward. Will be

5 is an exploded perspective view showing the machine spindle and the spindle inserted therein according to the present invention, and FIG. 6 is a cross-sectional view taken along the longitudinal axis of the machine spindle according to the present invention.

5 and 6, the rear end of the machine spindle 20 is coupled to and supported by a guide bracket 54 by a screw, and the spindle 21 is inserted into the machine spindle 20 to insert the spindle. The rear end of the part 21 protrudes through the rear end of the machine spindle 20.

The inner surface of the rear end of the main shaft 20 of the processing machine and the rear end of the spindle 21 are hermetically sealed by an oil bush 20a, and the rear end of the spindle 21 is a spindle driven gear (through a thrust bearing 55). 53 is fitted, and the spindle driven gear 53 is fitted with a key (not shown) interposed to rotate together with the spindle 21.

In this case, the key fixes the spindle driven gear 53 to the spindle 21 so that the spindle driven gear 53 rotates with the spindle 21.

The end plate 56 is fixed to the rear end surface of the spindle 21 by screws to prevent the spindle driven gear 53 from being separated from the rear end of the spindle 21.

In the center of the end plate 56, a connection rod insertion hole 56a through which the front end of the connection rod 57 can be inserted is drilled so that the front end of the connection rod 57 is inserted into the inner hole of the spindle 21. 21a).

The end of the inner hole 21a formed at the rear end of the spindle 21 extends to form the step 21b so that the O-ring 57a and two backup rings 57b are inserted between the outer surface of the connection rod 57. The airtightness is maintained, and the protrusion 56a of the end plate 56 is also fitted so that the O-ring 57a and the two backup rings 57b are squeezed between the stepped portion 21b and the protrusion 56a to connect the connection rod. The processing liquid injected into the inner hole 21a of the spindle 21 through the 57 is prevented from leaking.

The spindle driven gear 53 is inserted into the spindle 21 via a key so that when the spindle driven gear 53 rotates, the spindle 21 rotates together with the spindle 21. Thus, the spindle receives the rotational force from the spindle driven gear 52. When the driven gear 53 rotates, the spindle 21 also rotates.

Accordingly, the driven timing pulley 32 is rotated in accordance with the rotation of the step motor 40, and the driven timing pulley 32 is inserted while the driven timing pulley 32 received the rotational force through the timing belt 42. The main shaft nut 31 is rotated.

At this time, when the main shaft nut 31 is rotated along the screw of the machine spindle 20, the machine spindle 20 is moved forward or backward in accordance with the rotation direction, so that the blood processing electrode 10 is also forward or backward.

The spindle 21 fitted inside the main shaft 20 of the processing machine has its rear end portion fitted to the spindle driven gear 53 and rotates together with the rotation of the spindle driven gear 53 so that the fine processing electrode 10 during discharge processing. Will rotate.

That is, the blood processing electrode 10 is rotated while moving forward or backward during blood processing.

Fig. 7 is a perspective view showing a machine spindle limitation portion that limits the forward and backward of the machine spindle by the present invention.

Referring to FIG. 7, the main spindle limitation unit 90 of the present invention includes a support 91 coupled to and supported by the spindle bracket 51; A guide guide 92 coupled to the support 91 and inserted into and guided by a guide support rod 93; A guide support rod 93 coupled to and supported by the upper support bracket 44; Left and right limiters (94, 95) for limiting the movement range of the support guide 92.

Guide support rod 93 is bolted to the upper back of the upper support bracket 44, the machine spindle 20 is supported by the bearing case 30 by the spindle nut 31 and the bearing 33 Therefore, the guide support rod 93 and the machine spindle 20 are supported so that the machine spindle 20 can move forward and backward without swinging.

The right end of the guide support rod 93 has a right guide (92) is installed is coupled to the support 91 which is installed on the guide support rod 93 and fitted to the guide support rod 93, coupled to the spindle bracket 51 Is set as the reverse threshold to stop the reverse operation.

In addition, the left limiter 94 is installed to be set by the user to move arbitrarily, and when the support guide 92 is in contact with the forward movement is set to stop moving forward and automatically back to the origin (for example, the intermediate point).

When the blood processing is performed, the blood processing electrode 10 is formed to be excessively long in length compared to the thin diameter when moving forward or backward, and the end of the end swings, so that the electrode guide support 60 is prevented from the bearing case. Attached to (30) to support the blood processing electrode (10).

The electrode guide support 60 includes an electrode support tube 62 in which the blood-processed electrode 10 is inserted and supported and made of ceramic for insulation; The electrode support tube 62 is coupled to and supported, and consists of a support plate 61 coupled to and fixed to the bearing case 30.

100 to 300 mm is used for the thin blood processing electrode 10, and referring to FIG. 1, FIG. 3, and FIG. 4, the front end of the machine spindle 20 and the front end of the spindle 21 are via the oil bush 29. FIG. Is coupled by the socket 22, the front end of the spindle 21 is protruded, the chuck 23 is fixed to the fixing hole formed in the front end of the spindle 21 through the packing 24, the blood processing electrode 10 is fixed to the chuck 23.

In addition, a brush holder 26 for fixing the carbon brush 25 and a power line fixing screw 28 for supplying electricity are screwed to the side of the socket 22, and the carbon brush 25 is a brush holder 26. ) And is fixed by the brush cap 27 and in close contact with the spindle 21 to supply a voltage required for discharging the blood processing electrode 10.

Since the blood processing electrode 10 is 1 to 2 mm in diameter, it is too thin compared with the length and vibrates together by the small vibration, and it is comprised so that it may be supported by the electrode support tube 62 made of ceramic. The electrode support tube 62 has a length of about 2 cm and is supported by inserting the blood processed electrode 10 into an inner hole.

8A and 8B show an embodiment in which the portable cerebro discharge machine according to the present invention is attached to a stand and a tripod.

The portable three-cell discharge machine 100 according to the present invention is fixed to the stand 110 as shown in FIG. 8A in the field, so that the work can be performed consistently while maintaining the inclination at a predetermined angle with the workpiece. You can run

In addition, as shown in Figure 8b, it is possible to install a portable three-cell discharge machine 100 according to the present invention on a tripod 120 to enable horizontal processing and inclined processing.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

10: blood processing electrode 11: river bed protective stone
12: Reference bed 20: Machine spindle
21: Filtration Eco Network 22: Metal Mesh
23: crushed stone 30: bearing case
31: spindle nut 32: driven timing pulley
33: bearing 34: bearing holder
40: step motor 41: prime timing pulley
42: timing belt 43: motor bracket
50: spindle motor 60: electrode guide support
70a, 70b: upper and lower case 80: switch cover

Claims (5)

A blood processing electrode 10 for performing a blood discharge processing;
A processor spindle 20 coupled to the blood processing electrode 10 to supply a processing liquid and move forward or backward according to the rotation of the step motor 40;
A bearing case (30) screwed to the machine spindle (20) and including a spindle nut (31) for receiving a rotational force from the step motor (40) to drive the machine spindle (20) forward or backward;
A step motor 40 coupled to an upper surface of the bearing case 30 and including a prime timing pulley 41, a driven timing pulley 32, and a timing belt to provide rotational force to the spindle nut 31;
The spindle driven to support the guide bracket 54 and the spindle bracket 51 coupled to and supported by the rear end of the machine spindle 20 to provide rotational force to the spindle 21 inserted into the machine spindle 20. A spindle motor 50 including a gear 53 and a spindle motive gear 52;
Upper and lower cases (70a, 70b) coupled to the rear surface of the bearing case 30 to protect the rear end of the machine spindle 20 and the spindle motor (50);
Portable blood vessels comprising a switch cover 80 covering the step motor 40 installed on the bearing case 30 and having a transfer switch 81 and an on / off switch 82. Electric discharge machine. The method of claim 1,
Is coupled to the support bracket 91 is coupled to the spindle bracket 51 and the support guide 91 coupled to the support 91 and guided by being inserted into the guide support rod 93 and the upper surface of the bearing case 30 A processing machine including a guide support rod 93 coupled to and supported by an upper support bracket 44 supported by the motor bracket 43 and left and right limiters 94 and 95 for limiting a moving range of the support guide 92. Portable blood vessel discharge processing machine characterized in that it further comprises a main axis limiting portion (90). 3. The method according to claim 1 or 2,
Portable blood vessel discharge processing machine, characterized in that further comprising an electrode guide support (60) attached to the bottom surface of the bearing case (30) to support the blood processing electrode (10). The method of claim 1,
The bearing case 30 includes a spindle nut 31 which is screwed with the machine spindle 20; A spindle bearing (33) for supporting the spindle nut (31) and reducing frictional force so as to smoothly rotate the machine spindle (20); Portable triangular discharge processing machine, characterized in that it comprises a driven timing pulley (32) coupled to the spindle bearing (33) to receive the rotational force of the step motor (40) to rotate the spindle bearing (33). The method of claim 1,
End plate 56 is fixed to the rear end surface of the spindle 21 by a screw to prevent the spindle driven gear 53 from being separated from the rear end of the spindle 21,
The end of the inner hole 21a formed at the rear end of the spindle 21 extends to form the step 21b so that the O-ring 57a and two backup rings 57b are inserted between the outer surface of the connection rod 57. The airtightness is maintained, and the protrusion 56a of the end plate 56 is also fitted so that the O-ring 57a and the two backup rings 57b are squeezed between the step 21b and the protrusion 56a to connect the connection. Portable blood vessel discharge processing machine, characterized in that configured to prevent leakage of the processing liquid injected into the inner hole (21a) of the spindle (21) through the rod (57).

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