KR20190041556A - Axial Flow Shot Blast - Google Patents

Abstract

The present invention relates to a shot blast for projecting an axial flow, comprising: a hollow axial motor (10) wherein a shot ball is supplied by a natural falling method through a hollow unit (102) in the center of a drive shaft (101); a rotor (20) which is rotated by the hollow axial motor (10) at a high speed; a distributor (30) installed in the center of the rotor (20) for hitting the shot ball, which is naturally falling, through the hollow unit (102) and dispersing the shot ball towards an upper side of an internal diameter unit of the rotor (20); and a blade (50) which comes in contact with the shot ball, which has been dispersed and refracted towards a lower side of an internal diameter unit of the rotor (20), and applies a centrifugal force of the rotor (20) to the shot ball for projecting the shot ball by accelerating towards a lower side of the rotor (20). The present invention is capable of projecting a shot ball in an axial direction of the blade (50), making an even distribution of projection volume of the shot ball projected towards a processed surface of a processed object, and improving efficiency and productivity of shot blasting work.

Description

{Axial Flow Shot Blast}

The present invention relates to an axial-flow projection type short blast, and more particularly, to a shot blasting apparatus which is capable of preventing a short ball from colliding with an object other than a workpiece by projecting a shot ball in the axial direction of the blade, And the shot blasting operation efficiency and the productivity are improved by uniformizing the projection amount distribution of the shot ball.

Blasting is a technique in which a surface of a product or a material is strongly sprayed with compressed air or other methods by adding sand, steel shot, grit, abrasive particles such as sand or silica particles, A coating film, and the like, and the machine used for such blast processing is called a blast machine.

Such a blast machine is divided into an air blast projecting a projection material using compressed air and a shot blast projecting a shot ball using centrifugal force.

Particularly, the shot blast projecting the shot ball is generally used for post-processing such as casting, die casting, rolling and the like, which is a production process of a metal product, and removing scale of a metal surface and giving compression residual stress.

The general shot blast structure has a control gauge 13 installed at the center of an impeller rotating at a high speed by a motor when the short ball 11 is supplied to the center of the impeller 10 through the inlet 12 as shown in FIG. And the distributor 14, the centrifugal force is added by the blade radially installed on the impeller, and the surface of the blade is slid at a high speed and is accelerated and projected.

Thus, the shot ball projected by the impeller is projected through the opening in the lower part of the case, so that when the workpiece is positioned below the opening of the case, the shot ball is priced on the machined surface of the workpiece and the shot blasting is performed.

However, in the shot blast of the prior art, as shown in FIG. 2, the shot ball is projected at one side edge of the impeller in a direction perpendicular to the rotation axis 10a of the impeller in the process of projecting the shot ball 11 to the opening at the lower portion of the case 15 do.

Therefore, the projection amount distribution of the shot ball projected on the processing surface of the workpiece is not uniform, resulting in a reduction in work efficiency.

That is, in the prior art, since the shot ball is accelerated by applying centrifugal force while sliding on the surface of the blade 10b by the rotation of the impeller 10, the width of the blade and the shape of the outer end of the blade, The projection surface is projected onto the processing surface of the workpiece.

At this time, since the distance between the outer end of the blades of the impeller rotating at a high speed by the motor and the projection surface of the planar quadrangle is not uniform as shown in FIG. 2 and is further away toward one side, The projection amount distribution is not uniformly distributed over the entire rectangular projection surface as shown in the bottom of Fig. 2, and therefore the shot blasting is not uniform depending on the position of the workpiece, which results in a deteriorated working efficiency.

In addition, in the shot blast of the related art, the scattering of the shot ball due to the nonuniform projected amount distribution in the process of projecting the shot ball occurs so that the cover installed to prevent the shot ball from scattering around the workpiece is scattered It is easily damaged by a short ball, and the cost of frequent replacement of the cover is increased.

Patent Registration No. 10-0585623

SUMMARY OF THE INVENTION It is an object of the present invention to provide an apparatus and a method for projecting a shot ball onto a work surface of a workpiece by projecting the shot ball in the axial direction of the blade, And to improve the efficiency and productivity of the shot blasting work by uniformly distributing the shot blast.

It is still another object of the present invention to provide an image forming apparatus and a method thereof, which can prevent the scattering of the shot ball by preventing the peripheral device from being damaged due to the shot ball scattering by causing the shot ball to be projected close to the processing surface of the workpiece at a right angle, Shot blast.

In order to accomplish the object of the present invention, the axial-flow projection type shot blast of the present invention is characterized in that a hollow portion 102 is formed at the center of a drive shaft 101, and a hollow shaft- (10);

A rotating body 20 formed at an inner diameter portion 203 communicating with the hollow portion 102 and detachably attached to a lower end portion of the driving shaft 101 and rotating at a high speed by the hollow shaft type motor 10;

And is disposed at the center of the rotating body 20 and rotates together with the rotating body 20 so as to strike the shot ball supplied through the hollow portion 102 and disperse toward the upper side of the inner diameter portion 203 of the rotating body 20 (30);

And an acceleration projection surface 504 for guiding the shot ball repelled downward from the upper side of the inner diameter portion 203 of the rotating body 20 and formed radially below the inner diameter portion 203 of the rotating body 20 And a blade (50) for accelerating and projecting the shot ball to below the rotating body (20).

The rotating body 20 is formed in a shape of a narrow upper portion and a lower thickening lower portion. An upper end portion of the rotating body 20 is formed with a coupling groove 201 to which the lower end of the driving shaft 101 of the hollow shaft type motor 10 is inserted and detachably coupled A center hole 202 communicating with the hollow portion 102 is formed at the center of the coupling groove 201 and an inner diameter portion 203 communicating with the center hole 202 is formed in the rotating body 20 And an opening 204 through which the shot ball is projected is formed at the lower end of the inner diameter portion 204. [

And a rotation guide 40 for striking the downwardly scattered shot ball by the distributor 30 below the inner diameter portion 203 is radially formed on the inner diameter portion 203 of the rotating body 20 do.

The rotation guide 40 protrudes from the inner diameter portion 203 of the rotating body 20 in the direction of the center of the rotating body 20 so as not to touch the inner diameter of the hollow portion 102 of the hollow shaft- The inner end of the rotation guide 40 is formed into a convex curved surface in a plane cross section.

The rotation guide 40 is inclined in a direction opposite to the rotation direction from the upper end to the lower end and forms a second striking surface 401 facing the distributor 30 on the rotating direction side.

The distributor 30 is detachably attached to the upper end of the central axis 501 of the blade 50 such that the central axis of the drive shaft 101 of the hollow shaft type motor 10 coincides with the center axis of the drive shaft 101 of the hollow shaft type motor 10, And a downwardly inclined conical shape downward.

The distributor 30 includes a dispersing blade 301 having a first striking surface 301a formed on a rotating surface thereof in a radial direction on an upper surface thereof and a shot ball that falls naturally through the hollow portion 102, And is dispersed to the upper side of the inner diameter portion (203) of the rotating body (20) by being hit by the surface (301a).

The blade 50 is integrally formed with a center shaft 501 having an inner end formed in a direction perpendicular to the central portion of the rotating body 20 and an outer end integrally formed with the inner peripheral surface of the rotating body 20, And is integrally rotated with the whole body (20).

The plane of the blade 50 is connected in a straight line from the center axis 501 to the inner circumferential face of the rotating body 20 and the bottom face of the blade 50 is connected to the center axis 501 by one connection part 502a The inner surface of the blade 50 is connected to the inner circumferential surface by two split connecting portions 502b to form a concave space 503 in the lower portion of the blade 50. The outer surface of the space 503 is inclined toward the lower end, And forms the projection surface 504.

The axial-flow projection type short blast of the present invention allows the shot ball to be projected in the axial direction of the blade, thereby uniformizing the projection amount distribution of the shot ball projected on the processing surface of the workpiece, thereby improving the efficiency and productivity of the shot blasting operation There is an effect.

Further, by causing the shot ball to project at a right angle to the machined surface of the workpiece, scattering of the shot ball can be suppressed, and damage to the peripheral device due to shot ball scattering can be prevented.

1 is an exploded view showing a shot blast of the prior art.
Fig. 2 is a side view showing a shot ball projection direction and a projection amount distribution by a shot blast of the prior art; Fig.
3 is a front cross-sectional view of a preferred embodiment of the axial flow shot blast of the present invention.
Fig. 4 is a partially broken perspective view of a rotating body according to a preferred embodiment of the axial-flow projection type shot blast of the present invention. Fig.
FIG. 5A is a perspective view of a distributor according to a preferred embodiment of the axial-flow projection type short blast of the present invention, and FIG. 5B is a perspective view of a distributor according to still another embodiment of the axial-flow projection type short blast of the present invention.
6 is a sectional view of a rotation guide plane according to a preferred embodiment of the axial flow projection type shot blast of the present invention.
7 is a front sectional view according to another embodiment of the axial-flow projection type shot blast of the present invention.
8 is a perspective view of a blade according to a preferred embodiment of the axial flow shot blast of the present invention.
Figure 9 is an illustration of a bottom surface of a blade according to a preferred embodiment of the axial flow shot blast of the present invention.
10 is a plan view illustrating a shot ball projection type and a projection amount distribution according to a preferred embodiment of the axial flow projection type short blast of the present invention.
11 is a view showing an example in which a shot ball is projected on a machined surface of a linearly moving workpiece according to a preferred embodiment of the axial-flow projection type shot blast of the present invention to perform shot blasting.
Fig. 12 is a view showing an example in which a shot ball is projected on a machined surface of a rotating workpiece according to a preferred embodiment of the axial-flow projection type shot blast of the present invention to perform shot blasting. Fig.

Hereinafter, the structure and operation of the axial-flow-type short-blast according to the embodiment of the present invention will be described in more detail with reference to the accompanying drawings. The following description is not intended to limit the technical scope of the present document to a specific embodiment, But should be understood to include various modifications, equivalents, and / or alternatives of the embodiments of the invention.

It should also be understood that similar expressions may be used for similar elements in connection with the description of the drawings, and the terms " first, " second, " It can be used in any degree of importance, and is used to distinguish one component from another, and does not limit the components.

For example, 'first part' and 'second part' may represent different parts, regardless of order or importance. For example, without departing from the scope of the invention described in the present invention, the first component can be named as the second component, and similarly, the second component can also be named as the first component.

Furthermore, the terms used in the present invention are used only to describe specific embodiments, and are not intended to limit the scope of other embodiments. The singular expressions may include plural expressions unless the context clearly dictates otherwise.

Terms used herein, including technical or scientific terms, may have the same meaning as commonly understood by one of ordinary skill in the art. The general predefined terms used in the present invention can be interpreted in the same or similar meaning as the contextual meanings of the related art, and, unless expressly defined in the present invention, mean ideal or overly formal meanings . It is needless to say that the terms defined in the present invention can not be construed as excluding the embodiments of the present invention.

The axial-flow projection type shot blast of the present invention includes a hollow shaft type motor 10 in which a shot ball is supplied in a natural dropping manner through a hollow portion 102 at the center of a drive shaft 101; A rotating body 20 rotating at a high speed by the hollow shaft type motor 10; A distributor 30 disposed at the center of the rotating body 20 to strike a shot ball that naturally drops through the hollow 102 and disperse to the upper side of the inner diameter of the rotating body 20; And a blade (50) for applying a centrifugal force of the rotating body (20) to the shot ball and accelerating and projecting the rotating body (20) downward while being in contact with the short ball refracted to the lower side of the inner diameter portion of the dispersed rotating body It is possible to project the shot ball in the axial direction of the blade 50 and thereby to uniformly distribute the projection amount of the shot ball projected on the processing surface of the workpiece so that the efficiency and the productivity of the shot blasting operation can be improved The axial-flow projection type shot blast of the present invention will be described in more detail with respect to each constituent part as follows.

The hollow shaft type motor 10 has a hollow portion 102 formed in the center of the drive shaft 101 in the axial direction, and is well known in the technical field of the present invention, and a detailed description thereof will be omitted.

The hollow part 102 is connected to a short ball supply device (not shown) so as to supply a short ball to the hollow part 102 at the center of the drive shaft 101.

The shot ball supply device is a device for circulating and supplying used shot balls after collecting them for reuse, and is well known in the technical field of the present invention, and a detailed description thereof will be omitted.

The lower end of the driving shaft 101 of the hollow shaft type motor 10 is inserted into the upper end of the rotating body 20 so as to rotate at a higher speed by the hollow shaft type motor 10 And a center hole 202 communicating with the hollow portion 102 is formed at the center of the coupling groove 201. The center hole 202 is formed in the center of the coupling groove 201,

The lower end of the drive shaft 101 of the hollow shaft type motor 10 is formed into a polygonal planar cross section and the engagement groove 201 is formed in a shape corresponding to the polygonal cross section of the lower end of the drive shaft 101, The driving shaft 101 is screwed into the coupling groove 201 by using a fastening bolt or a fastening bolt so that a more rigid coupling between the driving shaft 101 and the rotating body 20 is possible.

An inner diameter portion 203 having an opening 204 formed at a lower end thereof in communication with the center hole 202 is formed in the rotating body 20. The inner diameter of the inner diameter portion 203 corresponds to a collision impact of the shot ball The hard coat layer 203a can be formed.

Tungsten Carbide Coating is a high velocity flame spraying technique developed in 1980. It burns fuel gas (propane, methyl acetylene, heptane, hydrogen) with oxygen at high pressure to generate high speed jet And the powder is melt-sprayed by using the high-speed jet to form a hard coat layer 203a on the base material. The coating structure is dense and has excellent hardness and is excellent in abrasion resistance, corrosion resistance, oxidation resistance, fatigue characteristics and impact resistance, Thereby ensuring durability against high-speed impacts.

3 to 5, the distributor 30 is provided with a short ball dropping through the hollow portion 102 of the hollow shaft type motor 10 above the inner diameter portion 203 of the rotating body 20 (20) so as to be centered on the center axis of the driving shaft (101) of the hollow shaft type motor (10) so as to be dispersed in an annular shape.

A blade 50 integral with the inner circumferential surface of the rotating body 20 is formed below the inner circumferential portion 203 of the rotating body 20. The distributor 20 is provided at the upper end of the center axis 501 of the blade 50 30) to be detachably attached.

In order to firmly couple the upper end of the central axis 501 of the blade 50 and the distributor 30 to each other, a polygonal coupling protrusion 302 is formed on the bottom surface of the distributor 30, It is preferable that an engaging groove portion 501a corresponding to the shape of the engaging protrusion is formed at the upper end.

The distributor 30 is detachably attached to the upper end of the central axis 501 of the blade 50 such that the central axis of the drive shaft 101 of the hollow shaft motor 10 coincides with the center axis of the drive shaft 101, To a downward inclined conical shape.

Therefore, when the rotating body 20 rotates at a high speed by the hollow shaft type motor 10, the distributor 30 rotates integrally with the rotating body 20 so that the hollow portion 102 of the hollow shaft type motor 10 is rotated, So that the shot ball collides with the inclined upper surface of the distributor 30 to be dispersed above the inner diameter portion 203 of the rotating body 20.

At this time, in order to improve the acceleration of the shot ball due to the collision between the distributor 30 and the shot ball, a dispersing blade 301 having a first impact surface 301a formed on the rotating direction side is radially formed on the upper surface of the distributor 30 The shot ball spontaneously falling through the hollow portion 102 is struck by the first striking surface 301a and is rotated at a higher speed by the forming angle and shape of the first striking surface 301a Of the inner diameter portion 203 of the outer circumferential surface.

A plurality of the dispersing vanes 301 are radially formed so that a shot ball that spontaneously falls vertically downward through the hollow portion 102 of the hollow shaft type motor 10 is formed in the distributor 30, The shot ball is uniformly dispersed in a planar annular shape in a process of being blown by the first striking surface 301a of the rotating shaft 301 and dispersed to the upper side of the inner diameter portion 203 of the rotating body 20 .

5 is a view showing various embodiments of the dispersing vane 301 and may be formed so as to place a space between the dispersing vanes 301 as shown in Fig. 301 may be radially formed.

In addition, the number of the dispersing vanes 301 is not limited for the uniform dispersion of the short balls in the annular shape, but is not limited to the cross sectional area of the hollow portion 102 of the hollow shaft type motor 10 to which the shot ball is supplied, It can be added or subtracted according to the supply amount of the shot ball supplied to the ball.

The short ball dispersed on the inner diameter portion 203 of the rotating body 20 by the distributor 30 is refracted while colliding with the upper side of the inner diameter portion 203 of the rotating body 20 in the form of a bottom- (20).

At this time, the rotation guide 40 may be further provided on the inner diameter portion 203 of the rotating body 20 for the purpose of improving the speed of the shot ball which bounces downward of the rotating body 20.

3 or 6, the rotation guide 40 is hung up by the distributor 30 so as to strike the annularly dispersed short ball downward, The inner end of the rotating body 20 located on the center side of the rotating body 20 does not invade the inner diameter of the hollow portion 102 of the hollow shaft type motor 10, Is formed in a curved shape so as to be spaced apart from the dispersing vane (301) of the distributor (30).

Since the flat end surface of the inner end of the rotation guide 40 is formed into a convex curved surface without angled corners, when the shot ball hitting upward by the distributor 30 is hit downward again, the shot ball is prevented from being damaged do.

The number of the rotation guides 40 and the thickness of the rotation guides 40 are not limited and the number of the rotation guides 40 may be changed according to the supply amount of the short balls supplied to the hollow portion 102 of the hollow shaft type motor 10. [ Can be added or subtracted.

Therefore, when the rotating shaft 20 rotates integrally with the rotating body 20 when the rotating body 20 rotates at a high speed by the hollow shaft type motor 10, the rotating body 20 is rotated by the distributor 30, A second acceleration of the shot ball which is first accelerated by the distributor 30 is performed by striking the shot ball struck on the upper side of the inner diameter portion 203 of the rotary guide 40 below the rotation guide 40. [

In addition, the shot ball struck by the rotating distributor 30 and annularly dispersed is evenly reflected on a plane in an annular shape by being struck downward by the rotating guide 40.

As shown in the figure, the rotation guide 40 is inclined in a direction opposite to the rotation direction from the upper end portion to the lower end portion, and is formed on the rotation direction side By forming the second striking surface 401 facing the distributor 30, the shot ball struck upward by the distributor 30 is struck by the second striking surface 401.

The angle of the second striking surface 401 formed to be inclined in the direction opposite to the rotating direction of the rotation guide 40 causes the shot ball to move below the rotation guide 40, Secondarily acceleration of the shot ball that is first accelerated by the distributor 30 is performed while a reflection angle is formed at an angle close to parallel vertical.

8 to 9, the blade 50 is rotated in a downward direction by a rotational force of the rotating body 20 to accelerate the rotating body 20 downward The inner end of the rotating body 20 is integrally formed with the center shaft 501 located at the center of the rotating body 20 and the outer end of the rotating body 20 is integrally formed with the inner circumferential surface of the rotating body 20, An accelerating projection surface 504 for guiding a shot ball which is in contact with the shot ball repelled downward from the upper side of the inner diameter portion 203 of the inner diameter portion 203 is formed and radially formed on the lower side of the inner diameter portion 203 of the rotator 20.

The number of the blades 50 formed radially below the inner diameter portion 203 of the rotating body 20 is not limited to a certain value but may be a ratio of the supply amount of the short ball supplied to the hollow portion 102 of the hollow shaft type motor 10 Therefore, it should be noted that it can be added or subtracted.

The plane of the blade 50 extending from the central axis 501 to the inner circumferential surface of the rotating body 20 is connected in a straight line so that the bottom surface of the blade 50 is connected to the center axis 501 The bottom surface of the blade 50 is formed into a Y shape and the outer surface of the rotating body 20 is connected to the inner circumferential surface of the rotating body 20 by two connecting portions 502b, The outer cross-sectional shape of the viewing blade 50 is a " person " shape, and a concave space 503 is formed in the lower portion of the blade 50.

The upper surface of the blade 50 is formed as a curved surface so as to have no angled edge so that the curvature of the upper curved surface of the accelerating projection surface 504 located on the rotating direction side of the blade 50 is increased, The shot ball striking downward by the shutter 40 is easily brought into contact with the accelerating projection surface 504 located on the rotational direction side of the blade 50. [

Therefore, the blade 50 transmits the rotational kinetic energy of the blade 50 to the shot ball that is hit downward by the inner circumferential surface of the inner circumferential portion 203 of the rotator 20 or the rotation guide 40 to be secondarily accelerated. So that the shot ball is accelerated three times and projected downwardly of the rotating body 20.

That is, the shot ball is in a state where secondary acceleration is performed by the blow of the rotation guide 40 following the primary acceleration by the blow of the distributor 30.

On the other hand, since the rotation speed of the blade 50 is faster than the movement speed of the shot ball and the kinetic energy according to the weight is larger, the shot ball contacts the acceleration projection surface 504 located on the rotation direction side of the blade 50 The kinetic energy of the blade 50 is transferred to the shot ball.

Therefore, the shot ball in contact with the accelerating projection surface 504 of the blade 50 is subjected to third-order acceleration due to addition of kinetic energy due to the rotation of the blade 50, and at the same time, do.

The frictional heat generated by the friction between the accelerating projection surface 504 of the blade 50 and the shot ball during the third acceleration of the shot ball by the blade 50 and the projection process as described above causes the air Type cooling due to contact with the blade 50. By forming the space 503 below the blade 50, the cooling efficiency of the air-cooling type is increased through enlarging the surface area of the blade 50 to prevent damage to the blade 50 due to frictional heat In addition, the space 503 also helps to improve the rotational force by reducing the weight of the blade 50.

On the other hand, when the third projection of the shot ball is performed by the blade 50 and the final projection to the downward direction of the rotating body 20 is performed, the short ball is rotated by the curvature of the acceleration projection surface 504 of the blade 50 And is projected in an annular shape smaller than the outer diameter of the entire body 20.

That is, when viewed from the bottom, the blade 50 is connected to the central axis 501 of the blade 50 by one connection portion 502a, and the two connection portions 502b, which are separated from the inner peripheral surface of the rotating body 20, And the outer cross-sectional shape of the blade 50 viewed from the outer surface of the rotating body 20 is a "human" shape. As the blade 50 moves toward the lower end and toward the inner peripheral surface of the rotating body 20 The thickness becomes thick.

The shot ball is moved toward the center of the rotating body 20 by the curvature of the accelerating projection surface 504 of the blade 50 while being in contact with the accelerating projection surface 504 formed on the rotating direction side of the blade 50, 10, the shot ball A is projected in a planar annular shape as shown in FIG. 10, and the short ball of the annular-shaped short ball projected surface B is projected, The projection amount distribution becomes uniform as a whole.

Therefore, it is possible to uniformly concentrate the projection of the shot ball on the annular projection surface, thereby improving the shot blasting efficiency of the workpiece by the shot ball, The shot ball is projected close to the processing surface of the workpiece to be shot, thereby preventing scattering of the shot ball in the shot ball projection process, thereby preventing damage to the peripheral device due to shot ball scattering.

Figs. 11 to 12 illustrate a form in which projection is performed on the machined surface of the workpiece by the axial flow projection type short blast of the present invention. When the workpiece C linearly moves as shown in Fig. 11, The uniform projection amount distribution of the shot ball being projected uniformly acts on the processing surface of the workpiece while the workpiece is linearly moved, thereby improving the uniformity and efficiency of the shot blasting to the workpiece.

12, when the workpiece D is fixed on the rotary table and rotated, a uniform projection amount distribution of the shot ball projected in an annular shape is uniformly distributed on the work surface of the workpiece during rotation of the workpiece It is possible to improve the uniformity and efficiency of the shot blasting with respect to the workpiece.

10: Hollow shaft type motor 101: Drive shaft
102: hollow part 20: rotating body
201: coupling groove 202: center hole
203: inner diameter portion 203a:
30: Distributor 301: Dispersion blade
301a: first striking surface 40: rotation guide
401: second striking surface 50: blade
501: center axis 502a, 502b:
503: Space section 504: Accelerating projection surface

Claims (9)

A hollow shaft type motor 10 in which a hollow portion 102 is formed at the center of the drive shaft 101 and a shot ball is supplied through the hollow portion 102;
A rotating body 20 formed at an inner diameter portion 203 communicating with the hollow portion 102 and detachably attached to a lower end portion of the driving shaft 101 and rotating at a high speed by the hollow shaft type motor 10;
And is disposed at the center of the rotating body 20 and rotates together with the rotating body 20 so as to strike the shot ball supplied through the hollow portion 102 and disperse toward the upper side of the inner diameter portion 203 of the rotating body 20 (30);
And an acceleration projection surface 504 for guiding the shot ball repelled downward from the upper side of the inner diameter portion 203 of the rotating body 20 and formed radially below the inner diameter portion 203 of the rotating body 20 And a blade (50) for accelerating and projecting the shot ball to below the rotating body (20). The method according to claim 1,
The rotating body 20 is formed in a shape of a narrow upper portion and a lower thicker lower portion,
The upper end of the hollow shaft motor 10 is formed with a coupling groove 201 into which the lower end of the driving shaft 101 of the hollow shaft type motor 10 is inserted and detachably coupled. An inner diameter portion 203 communicating with the center hole 202 is formed in the rotating body 20 and an opening portion 204 through which a shot ball is projected is formed at the lower end of the inner diameter portion 204 Wherein the axial blast-type short blast is formed by the following method. The method according to claim 1 or 2,
And a rotation guide 40 for striking the downwardly scattered shot ball by the distributor 30 below the inner diameter portion 203 is radially formed on the inner diameter portion 203 of the rotating body 20 Axial blast shot blast. The method of claim 3,
The rotation guide 40 protrudes from the inner diameter portion 203 of the rotating body 20 in the direction of the center of the rotating body 20 so as not to touch the inner diameter of the hollow portion 102 of the hollow shaft- , Wherein the inner end of the rotation guide (40) has a flat cross-section in a convex curved surface. 5. The method of claim 4,
Wherein the rotation guide (40) is inclined in a direction opposite to the rotation direction from the upper end portion to the lower end portion and forms a second striking surface (401) facing the distributor (30) in the rotation direction side. Shot blast. The method according to claim 1,
The distributor 30 is detachably attached to the upper end of the central axis 501 of the blade 50 such that the central axis of the drive shaft 101 of the hollow shaft type motor 10 coincides with the center axis of the drive shaft 101 of the hollow shaft type motor 10, Wherein the bottom wall is formed as a downwardly inclined conical shape as it goes downward. The method according to claim 6,
The distributor 30 includes a dispersing blade 301 having a first striking surface 301a formed on a rotating surface thereof in a radial direction on an upper surface thereof and a shot ball that falls naturally through the hollow portion 102, And is dispersed to the upper side of the inner diameter portion (203) of the rotating body (20) by being hit by the surface (301a). The method according to claim 1,
The blade 50 is integrally formed with a center shaft 501 having an inner end formed in a direction perpendicular to the central portion of the rotating body 20 and an outer end integrally formed with the inner peripheral surface of the rotating body 20, Is rotated integrally with the entire body (20). 9. The method of claim 8,
The plane of the blade 50 is connected in a straight line from the center axis 501 to the inner circumferential face of the rotating body 20 and the bottom face of the blade 50 is connected to the center axis 501 by one connection part 502a The inner surface of the blade 50 is connected to the inner circumferential surface by two split connecting portions 502b to form a concave space 503 in the lower portion of the blade 50. The outer surface of the space 503 is inclined toward the lower end, To form a projection surface (504).

Images