KR101930886B1 - Grinder capable precision control grinding gap - Google Patents

Abstract

The present invention relates to a grinder capable of precisely controlling grinding gaps. More specifically, the grinder includes: a motor shaft; a driving motor including bearing units axially coupled to the motor shaft; a lower housing which has the driving motor mounted on and spur gear nuts having a first screw thread formed along the inner diameter while being coupled to the lower surface by bolts; spur gears which are axially coupled to the lower end of the motor shaft of the driving motor and have a second screw thread formed thereon to correspond to the first screw thread; a bearing adjuster which is axially coupled to the lower end of the motor shaft of the driving motor while having the inner and outer diameters of the spur gears coupled in a spiral manner; and bushing units which have the lower ends coupled forcefully to the inner diameters of the upper ends of the bearing adjuster and have the bearing units of the driving motor mounted onto the upper surface. The bushing units are lifted by the normal and reverse rotation of the bearing adjuster to adjust the output height of the motor shaft. By adjusting the output height of the motor shaft, the tolerance of the assembly components, as well as the backlash between the gears, can be minimized to enhance the reliability of the grinding gap adjustment of products.

Description

[0001] The present invention relates to a grinder capable of precisely controlling grinding gap,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pulverizer, and more particularly, to a pulverizer capable of precisely controlling the crushing gap so as to minimize the tolerance between assembling components by adjusting the output height of the motor shaft of the driving motor.

BACKGROUND ART [0002] In general, the use and the kind of a mill-type crusher for crushing grain such as rice, beans, pepper, garlic, sesame and the like into a predetermined particle size are well known.

Such a mill-type crusher has a vertical structure, and a rotating millstone incorporated in a lower driving motor is adapted to crush the grains put between upper fixed mill stones to a predetermined particle size by a rotating friction force while rotating at a high speed.

The mill-type crusher grinds grains fed by the irregular projections and the irregular grooves formed by mutually opposing grains to a predetermined grain size while adjusting the gap between the upper fixed millstone and the lower rotary millstone incorporated in the driving motor.

BACKGROUND ART In recent years, a crusher having a fixed millstone and a rotating millstone, that is, a technique of adjusting the gap between the upper and lower crusher plates, has been widely used in order to vary the particle size according to crushing of grain.

For example, Korean Patent Registration No. 10-1384778 (published on Apr. 14, 2014) discloses an apparatus for controlling the crushing gap of a crusher. In the above conventional technique, the grinding clearance with the fixed millstone can be easily adjusted by rotating or rotating the rotating millstone by forward or reverse rotation of the adjustment knob exposed to the outside of the grinder lower body.

Conventionally, a crusher capable of adjusting the lifting and lowering of a rotating millstone has a structure in which various gears are meshed with each other so that the rotating millstone can be lifted and lowered by an operation of a control knob by a user. In the case where the plurality of gears are engaged with each other, there is a backlash in the structure for smooth rotation of the gear.

In addition, due to the backlash between the gears and the tolerances of the motor stator, motor shaft, housing and various injection parts, the tolerances become larger when assembling the finished product, so that the final shatter clearance at the time of product shipment is not constant, An uneven problem arises.

Korean Patent Registration No. 10-1384778 (issued on April 14, 2014)

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems and to provide a motor control apparatus and a control method thereof, which can prevent backlash between gears by adjusting an output height of a motor shaft of a drive motor, minimize tolerance of assembling components, Which is capable of precisely controlling the grinding gap.

It is a further object of the present invention to provide an apparatus and a method for controlling the milling gap between a fixed millstone and a rotating millstone by controlling lifting and lowering of the lower millstone by a simple and safe operation during use to maximize the grinding efficiency and to ensure the reliability of the mill The present invention provides a grinder capable of precisely controlling the grinding gap.

According to a first aspect of the present invention, there is provided a pulverizer capable of precisely controlling pulverization gap, comprising: a driving motor having a motor shaft and a bearing axially coupled to the motor shaft; A spur gear having a second thread corresponding to the first thread and being axially coupled to a lower end of a motor shaft of the driving motor, a spur gear coupled to the lower end of the motor shaft of the driving motor, And a bushing having a lower end coupled to an upper inner diameter of the bearing adjuster so that a bearing of the drive motor is seated on an upper surface of the bearing adjuster, And the output height of the motor shaft is adjusted while the bushing is lifted and lowered by normal / reverse rotation.

The bearing adjuster includes a throttling plate having a central opening in the upper and lower portions and an adjusting hole penetrating upward and downward along the rim, and a hollow body portion extending upwardly and integrally with the throttling portion.

The spur gear includes a hollow through hole having a threaded portion formed through an inner diameter of the bearing adjuster, a coupling portion extending upward from the through hole and coupled to the inner diameter of the spur gear nut, And a reference groove corresponding to the adjustment hole is formed on the bottom surface.

And an adjusting pin which is inserted into the adjusting hole and passes through the reference groove in order.

The bushing includes a first seating surface that is vertically opened at its center and on which an inner ring of the bearing is seated, a seating plate having a second seating surface protruded upward along the rim and on which the outer ring of the bearing is seated, And a fitting protrusion extending downwardly to the inner circumference of the bearing regulator body portion.

An operating lever shaft having a rear end assembled with the adjusting knob and having a pinion gear mounted at a front end thereof, and a driving lever shaft engaged with the pinion gear and linearly moved, Includes a rack gear provided with an adjusting gear engaged with the spur gear.

When the spur gear is rotated by the pinion gear of the operation lever shaft linearly moving the adjustment gear by the rotation of the adjustment knob, the spur gear nut spirally engaged with the spur gear is rotated to adjust the output height of the motor shaft .

The present invention has the effect of improving the reliability of the adjustment of the crushing clearance of the product by minimizing the tolerance of the assembling parts together with the backlash between the gears by adjusting the output height of the motor shaft of the driving motor.

Further, the present invention has an effect of increasing the efficiency of use of the crusher by precisely controlling the degree of grain crushing by controlling the clearance as a multi-step between the fixed millstone and the rotating millstone by controlling the elevation of the motor shaft of the drive motor.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description, serve to further the understanding of the technical idea of the invention, And shall not be construed as interpretation.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall external perspective view of a mill for milling precisely controllable milling according to an embodiment of the present invention;
Fig. 2 is an exploded perspective view of Fig. 1,
FIG. 3 is a bottom perspective view showing a grinder capable of fine grinding clearance adjustment according to an embodiment of the present invention,
FIG. 4 is an exploded perspective view of FIG. 3,
Fig. 5 is a sectional view of Fig. 3. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a crusher capable of precisely controlling the crushing clearance according to the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view of the grinding machine according to an embodiment of the present invention. FIG. 2 is an exploded perspective view of the grinding machine of FIG. 1, and FIG. 3 is a cross- FIG. 4 is an exploded perspective view of FIG. 3, and FIG. 5 is a cross-sectional view of FIG. 3.

1 to 5, a pulverizer capable of precisely controlling pulverization gap according to a preferred embodiment of the present invention includes a lower body 700 in which a driving motor 100 is accommodated, A pulverizing cylinder 10 in which a fixed millstone 11 and a rotating millstone 12 opposed to the millstone 11 are crushed to crush an object to be crushed; As shown in FIG. At this time, the adjustment knob 710 is exposed on one side of the lower body 700, and a discharge port 10a is formed on one side of the pulverizing cylinder 10.

Here, the driving motor 100 is controlled by an on-off switch 30 provided outside the lower body 700, and rotates the rotating millstone 12, while moving the object to be inserted through the upper loading unit 20 And grinds the object in cooperation with the fixed millstone 11 to discharge the pulverized object through the discharge port 10a of the pulverizing casing 10. [ This technique is commercialized in a vertical mill-type crusher, and a person skilled in the art will fully understand it if a detailed description is omitted.

The pulverizer of the present invention comprises a fixed millstone 11 provided inside the pulverizing barrel 10 and a rotating millstone 12 axially coupled to the upper end of the motor shaft 110 of the driving motor 100 The output height of the motor shaft 110 is elevated by the stepwise adjustment of the adjustment knob 710 exposed to the outside of the lower body 700 to adjust the grinding gap between the fixed millstone 11 and the rotating millstone 12 . That is, the output height of the motor shaft 110 is adjusted, and as a result, the height of the rotating millstone 12 is adjusted so that the size of the milled particles of the object is controlled during milling due to the difference in height from the fixed millstone 11.

The crusher of the present invention includes a control knob 710 exposed to the outside of the lower body 700 and a pinion gear 810 assembled to the front end of the control knob 710 And a rack gear 900 having an operating lever shaft 800 and an adjusting gear 910 which is linearly moved by engaging with the pinion gear 810. At this time, the adjusting gear 910 is gear-meshed with the spur gear 300 which is axially coupled to the lower end of the motor shaft 110 of the driving motor 100.

A spur gear nut 210 is coupled to a lower portion of the driving motor 100. A first screw thread 211 is formed on the inner diameter of the spur gear nut 210. [ That is, the first screw thread 211 is formed along the inner diameter of the spur gear nut 210.

The spur gear 300 has an engaging portion 320 inserted into the inner diameter of the spur gear nut 210 so as to protrude upward at the center thereof. At this time, a second thread 321 corresponding to the first thread 211 of the spur gear nut 210 is formed on the outer diameter of the coupling portion 320 of the spur gear 300. That is, the second thread 321 is formed along the outer diameter of the coupling part 320 of the spur gear 300, and the first thread 211 and the second thread 321 are coupled to each other.

The pinion gear 810 of the operating lever shaft 800 by linearly moving the adjusting gear 910 by the rotation of the adjusting knob 710 causes the spur gear 300 engaged with the adjusting gear 910 to rotate The second screw thread 321 formed on the spur gear 300 is coupled to the first screw thread 211 formed along the inner diameter of the spur gear nut 210 coupled to the lower portion of the driving motor 100, The gear nut 210 moves up and down while rotating along the thread.

As a result, the output height of the motor shaft 110 is adjusted so that the rotating millstone 12 coupled to the motor shaft 110 of the drive motor 100 and the particles of the object to be crushed by the gap between the fixed millstone 11 Can be made finer or rough. Of course, the clearance of the rotating millstone 12 is possible by the stepwise adjustment dimension indicated on the index plate 40 by the rotation of the adjustment knob 710. [ Particularly, adjustment of the milling clearance between the fixed mill stones 11 by lifting and lowering the rotating millstone 12 is made possible by the adjustment of the adjustment knob 710 even during grinding of the object.

The operation lever shaft 800 is assembled with the index plate 40 protruding outside the lower body 700 and displaying the stepwise gap adjustment numerically on the outside of the lower body 700, The adjustment knob 710 is set to set the gap adjustment value shown in FIG.

At this time, the gap adjustment value of the index plate 40 is composed of 15 steps in total, and the output height of the motor shaft 110 is raised up to about 5 mm at most. In other words, it is about 1 mm raised and lowered for every three steps, and about 0.3 mm raised and lowered for each step.

By controlling the adjustment knob 710, the particles of the object to be charged by the lifting and lowering of the rotating millstone 12 axially coupled to the upper end of the motor shaft 110 of the drive motor 100 are controlled finely or roughly, .

The movement of the second screw thread 321 formed on the outer diameter of the coupling part 320 of the spur gear 300 is determined by the rotation of the spur gear 300. The movement of the spur gear 300 is about 20 mm . The number of teeth of the spur gear 300 is preferably 30, and the spur gear 300 rotates by 12 degrees when a movement of one tooth occurs, and rotates by 6 when a movement of 0.5 space occurs. .

The three-step adjustment of the adjustment knob 710 corresponds to the movement of 1.5 spans of the spur gear 300 because the spur gear 300 moves 0.5 time per one-step adjustment of the adjustment knob 710, The output height of the motor shaft 110 is increased or decreased by about 1 mm due to the spiral coupling structure between the spur gear nut 210 and the spur gear nut 210.

Since the length of the motor shaft 110 provided in the driving motor 100 has a predetermined tolerance, even if it is always assembled, if the length of the motor shaft 110 is long, the fixed millstone 11 and the rotating millstone 12 ). If the length of the motor shaft 110 is short, the difference in height becomes large. Therefore, even if the same one of the same products is the same one, there is a gap, and for general consumers, some products are crushed into fine particles, A quality problem that can not be standardized due to pulverization into a slightly less fine particle occurs.

In addition, there is a tolerance not only in the motor shaft 110 but also in a stator for determining the assembling position of the motor shaft 110, which in turn affects the output height of the motor shaft 110, The height of the rotating millstone 12 is influenced. This causes the constant quality not to come out soon.

The gap between the gears must be checked by a predetermined height adjusting means in which various gears for adjusting the output height of the motor shaft 110 of the driving motor 100 are combined.

In other words, the gears are returned to meshing with each other, but after the step is finished, the position of the gears is gradually moved to a space such as a backlash for the gears to operate. In other words, it becomes impossible to fine-tune it little by little. For example, consider a situation where you can move clockwise and then stop at that position, and you can move slightly in the opposite direction due to the reaction.

Therefore, in order to prevent the gap between the fixed millstone (11) and the rotating millstone (12) from being constant during assembly due to the tolerance of the motor shaft (110), the tolerance of the housing, and the stator, Lt; / RTI > Thus, it is the most important feature that the output height of the motor shaft 110 of the finished product is made constant so that the same quality can be always maintained.

The pulverizer capable of precisely controlling the pulverizing gap according to the preferred embodiment of the present invention comprises a driving motor 100, a lower housing 200, a spur gear 300, a bearing regulator 400, and a bushing 500 Element, which will be described in detail as follows.

The drive motor 100 is provided with a motor shaft 110 and a bearing 120 axially coupled to the motor shaft 110. The spur gear nut 210 having the first screw thread 211 formed along the inner diameter of the lower housing 200 is bolted to the bottom of the lower housing 200. The spur gear 300 is axially coupled to the motor shaft 110 through a lower end of the motor shaft 110 of the driving motor 100 and a second thread 321 corresponding to the first thread 211 is formed do.

The bearing adjuster 400 is axially coupled to the motor shaft 110 through the lower end of the motor shaft 110 of the drive motor 100 and is coupled to the inner diameter of the spur gear 300 with an outer diameter. The lower end of the bushing 500 is forcedly engaged with the upper inner diameter of the bearing adjuster 400 and the bearing 120 of the drive motor 100 is seated on the upper surface.

That is, the bearing adjuster 400 can be combined with the bushing 500 to adjust the position of the bearing 120. Here, the bearing adjuster 400 is composed of a control plate 410 and a body 420.

The regulating plate 410 is vertically opened at its center and spaced upward and downward along the rim. Here, it is preferable that fifteen adjustment holes 411 are formed, and a number indicating each step is displayed on one side of each adjustment hole 411. The output height of the motor shaft can be adjusted by about 0.1mm per step.

The body portion 420 extends upward integrally with the throttle plate 410 in a vertically opened hollow form and has a thread 421 formed along the outer diameter thereof.

The spur gear 300 includes a hollow through hole 310 through which the body portion 420 of the bearing adjuster 400 passes and which has threads 311 formed along the inner diameter thereof, And a reference groove 330 corresponding to the adjustment hole 411 formed in the adjustment plate 410 is formed on the bottom surface of the spool gear nut 210. [

The screw thread 311 formed on the inner diameter of the through hole 310 of the spur gear 300 is for adjusting the position of the bearing 120 and is formed on the outer diameter of the body portion 420 of the bearing adjuster 400 Threaded engagement with the formed threads 421.

The bushing 500 is composed of a seating plate 510 and a fitting protrusion 520.

The seating plate 510 has a first seating surface 511 which is vertically opened at the center and on which the inner ring of the bearing 120 is seated, a second seating surface 511 protruding upward along the rim and on which the outer ring of the bearing 120 is seated, A surface 512 is formed. This is because the outer ring and the inner ring of the bearing 120 are independently divided so as not to affect the rotation of the bearing 120. That is, the inner and outer rings of the bearing 120 are divided to push the bearing 120.

The fitting protrusion 520 integrally extends downward to the seating plate 510 and is constrained to the inner diameter of the body portion 420 of the bearing adjuster 400. This is to fit the bushing 500 to the body 420 of the bearing adjuster 400 so that the bushing 500 does not rotate together with the rotation of the bearing 120. [

This structure is advantageous in that the threaded portion 421 formed on the outer diameter of the body portion 420 of the bearing adjuster 400 by the forward and reverse rotation of the bearing adjuster 400 is inserted into the through hole 310 of the spur gear 300, The bushing 500 on which the bearing 120 is mounted is lifted and the output height of the motor shaft 110 is adjusted.

At this time, when the control plate 410 of the bearing adjuster 400 is rotated one turn, the output height of the motor shaft 110 increases by about 1.5 mm and the output height of the motor shaft 110 is adjusted up to about 4.5 mm It is possible.

The control pin 600 may further include a control pin 600 coupled to the control hole 411 through the reference groove 330 in order. The adjustment pin 600 may be in the form of a screw and after the adjustment of the position of the bearing 120 the adjustment pin 600 penetrates through the adjustment hole 411 and the reference groove 330 in order, So that the throttle plate 410 is no longer rotated.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And such variations and modifications are intended to fall within the scope of the appended claims.

100: drive motor 110: motor shaft
120: Bearing 200: Lower housing
210: Spur gear nut 211: First thread
300: spur gear 310: through hole
311, 421: threads 320:
321: second thread 330: reference groove
400: Bearing regulator 410: Throttle plate
411: Adjusting hole 420: Body part
500: bushing 510: seat plate
511: first seating surface 512: second seating surface
520: insertion protrusion 600: regulating pin
700: Lower body 710: Adjusting knob
800: Operation lever shaft 810: Pinion gear
900: Rack gear 910: Adjusting gear

Claims (7)

A driving motor 100 having a motor shaft 110 and a bearing 120 axially coupled to the motor shaft 110;
A lower housing 200 on which the driving motor 100 is mounted and a spur gear nut 210 having a first screw thread 211 formed along an inner diameter thereof is bolted to a bottom surface thereof;
A spur gear 300 axially coupled to the lower end of the motor shaft 110 of the driving motor 100 and having a second thread 321 corresponding to the first thread 211;
A bearing regulator 400 that is axially coupled to the lower end of the motor shaft 110 of the driving motor 100 and has an outer diameter threadedly engaged with the inner diameter of the spur gear 300; And
A bushing 500 in which a lower end of the driving motor 100 is coupled to the upper inner diameter of the bearing adjuster 400 and the bearing 120 of the driving motor 100 is seated on the upper surface; / RTI >
The bearing adjuster (400)
A regulating plate 410 which is vertically opened at the center and spaced apart from the regulating hole 411 penetrating up and down along the rim; And
A hollow body portion 420 integrally extending upwardly from the throttle plate 410 and having a thread 421 formed along the outer diameter thereof; Lt; / RTI >
Wherein the bushing (500) is lifted and lowered by normal and reverse rotation of the bearing adjuster (400) to adjust the output height of the motor shaft (110). delete The spur gear (300) according to claim 1, wherein the spur gear (300)
A hollow penetration hole 310 through which the body 420 of the bearing adjuster 400 penetrates and having a thread 311 formed along an inner diameter thereof and a hollow penetrating hole 310 extending upward from the through hole 310 to form the spur gear nut 210, And a reference groove (330) corresponding to the adjustment hole (411) formed in the adjustment plate (410) is formed on the bottom surface. The method of claim 3,
An adjusting pin 600 coupled through the adjusting hole 411 and the reference groove 330 in order;
Further comprising: a pulverizer for adjusting the pulverization gap precisely. The bushing (500) according to claim 1, wherein the bushing (500)
And a second seating surface 512 protruding upward along the rim and on which the outer ring of the bearing 120 is seated is formed in the center of the first bearing surface 511. The first bearing surface 511, A seating plate 510; And
A fitting protrusion 520 integrally extending downward from the seating plate 510 to be pressed against the inner diameter of the body 420 of the bearing adjuster 400;
The grinding machine according to claim 1, The method according to claim 1,
A lower body 700 having the control knob 710 exposed to the outside and receiving the driving motor 100;
An operating lever shaft 800 having a rear end assembled with the adjusting knob 710 and a pinion gear 810 mounted at a front end thereof; And
A rack gear 900 which is linearly engaged with the pinion gear 810 and has an adjustment gear 910 fitted to the spur gear 300 at one side thereof;
A milling machine capable of precisely controlling the milling clearance. The method according to claim 6,
When the pinion gear 810 of the operating lever shaft 800 linearly moves the adjusting gear 910 by the rotation of the adjusting knob 710 and the spur gear 300 is rotated, And the output height of the motor shaft (110) is adjusted by rotating the spur gear nut (210) coupled to the spur gear nut (210).

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