KR100478610B1 - A rotary atomizer - Google Patents

Abstract

An object of the present invention is to support the rotating shaft by forming an air layer on the friction surface of the rotating shaft using compressed air, and to spray the injection by rotating the rotating body at high speed using a special motor for high speed rotation,

In order to achieve the above object, the present invention includes an insertion hole 11 through which both ends penetrate along the longitudinal direction, and a bracket 12 on the outside, and the fluid introduced from the side flows inward and ends. An injection housing (10) having a fluid flow passage (13) having a discharge hole (13a) to be discharged to the side; A rotating shaft 20 rotatably inserted into the insertion hole 11 of the injection housing 10 and a part of which protrudes a predetermined length toward the end of the injection housing 10; A motor housing (90) installed at the other end of the injection housing (10) to drive the rotation shaft (20) to rotate; A motor unit (91) installed inside the motor housing (90) and directly connected to the rotating shaft (20) integrally with the rotor and rotating at a high speed at a speed of 6,000 RPM to 24,000 RPM; Rotation guide means (50) for guiding rotation of the rotary shaft (20) by introducing air into a gap (t) between the outer surface of the rotary shaft (20) and the insertion hole (11) of the injection housing (10); In the rotary atomizer composed of a stop means 60 to allow the rotating shaft 20 in the emergency state to be stopped in the insertion hole 11 of the injection housing 10 in an emergency,

The disk 30 is fixed to one end of the rotating shaft 20 partially protruding toward the end side of the spray housing 10 to maintain the gap t1 with the end surface of the spray housing 10. 20 and rotated together, the upper surface of the disk 30 is formed in a circumferential direction at a position spaced apart from the predetermined distance in the radial direction about the rotation axis (20) single annular corresponding to the discharge hole (13a) An inlet (31a) and injection holes (31b) formed in the outer surface of the disk 30 in a direction perpendicular to the annular inlet (31a), the inside of the disk 30 and the annular inlet (31a) and the minute A fluid spray passage 31 for communicating the thread hole 31b is provided.

The motor cooling unit 92 is installed between the motor unit 91 and the motor housing 90 to cool the motor unit 91.

Description

Rotary Automator {A ROTARY ATOMIZER}

The present invention relates to a rotary automatizer, and more particularly, to support the rotating shaft by forming an air layer on the friction surface of the rotating shaft using compressed air, and to rotate the rotating body at a high speed by using a special motor for high speed rotation. It's about a rotary automator that lets you spray.

In general, rotary atomizers are used for the production of dry powder (ceramic membranes, food and pharmaceuticals) using droplets and for the microdropletisation of liquid fluids.

In particular, in the environmental field, it is used as a chemical injection device for spraying the micro-droplets to the chemical for removing harmful gases.

It is disclosed in Japanese Patent Application Laid-open No. Hei 7-328489, which is a conventional technique of a rotary automaton that plays the role as described above. Support the output shaft arranged on the same axis with the bearing through each bearing, install a planetary roller type speed increaser consisting of a planetary pin, planetary roller, fixed ring between the input shaft and the output shaft, and install a rotary disk at the bottom of the output shaft And rotation of the input shaft by the drive motor as a planetary speed increasing device, and a liquid containing a solid component supplied to the rotary disk by using centrifugal force acting on the rotary disk at a high speed of generally 6,000 to 24,000 RPM. To inject powder slurry, etc. into the chamber from a spray nozzle mounted on a rotary disk And by the atomization, to produce the atomized substance by drying or chemical reaction.

In addition, chemical treatment is performed using a slurry or a chemical agent to remove harmful waste gas.

However, since a speed increaser is used to enable high speed rotation, a lot of loads and heat are generated during continuous operation, and the internal structure of the device becomes a complicated structure due to the adoption of a lubrication device for removing such heat. There is a problem that is difficult, expensive production costs.

However, in order to solve the above problems, the applicant has previously filed the technology of Patent 2002-10201.

When this is roughly described, compressed air is supplied to the air bearing to form an air layer to support the rotating shaft, and a large amount of high-pressure compressed air is supplied to the air turbine to rotate the rotating shaft at high speed to finely inject the jet.

However, the above technology has a problem in that a large amount of high-pressure compressed air is required for high-speed rotation, and the capacity of auxiliary equipment, such as an air compressor, is excessively large, resulting in increased power consumption.

In addition, since excessive torque is difficult to instantaneously, the rotation speed of the disk is largely changed due to load variation, and thus, the rotation speed of the disk cannot be controlled.

The present invention has been made to solve the above problems, by using the compressed air to form a layer of air on the friction surface of the rotating shaft to support the rotating shaft, by using a special motor for high-speed rotation to rotate the rotor at high speed The goal is to provide a rotary automator that allows the injection of these components.

The present invention for achieving the above object, having an insertion hole through both ends along the longitudinal direction and having a bracket on the outside, the fluid introduced from the side flows to the inside and is discharged to the end side An injection housing provided with a fluid flow passage having a discharge hole; A rotating shaft which is rotatably inserted into the insertion hole of the spray housing and protrudes a predetermined length toward the end of the spray housing; A motor housing installed at the other end of the injection housing to rotationally drive the rotation shaft; A motor unit which is installed inside the motor housing and is connected directly to the rotor with the rotating shaft and rotates at a high speed at a speed of 6,000 RPM to 24,000 RPM; Rotation guide means for guiding the rotation of the rotation shaft by introducing air into the gap t between the outer surface of the rotation shaft and the inner surface of the insertion hole of the injection housing; In the rotary atomizer consisting of a stop means for stopping the rotary shaft in a state of rotation in the insertion hole of the injection housing in an emergency, the disk is fixed to one end of the rotary shaft partially protruded toward the end side of the injection housing the injection It is rotated together with the rotary shaft to maintain a predetermined gap (t1) and the end surface of the housing, the upper surface of the disk is formed in a circumferential direction at a distance spaced in the radial direction about the rotation axis to correspond to the discharge hole It has a single annular inlet, and the injection hole formed in the outer surface in the direction perpendicular to the annular inlet, the inside of the disk is provided with a fluid injection passage for communicating the annular inlet and the injection hole, the motor unit and the motor Motor coolant installed between the housing to cool the motor unit Characterized in that the bar.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of a preferred rotary atomizer of the present invention will be described in detail.

1 is a cross-sectional view showing the internal configuration of the rotary atomizer according to the present invention, Figure 2 is a view showing a state in which only the annular inlet is formed in a plan view of the disk of FIG.

As shown in the drawing, the rotary atomizer according to the present invention has a large spray housing 10, a rotating shaft 20, a disk 30, a motor housing 90, a motor unit 91, and a motor cooling means. 92, and the rotation guide means (50).

The injection housing 10 has an insertion hole 11 through which both ends penetrate along the longitudinal direction, and also has a bracket 12 on the outside.

And, it has a fluid flow path (13) having a flow path for receiving and discharging the fluid into the interior.

Here, the bracket 12 is to be attached to a specific object (not shown) via a separate fastening bolt (not shown), the bracket 12 is due to the automation of the present invention to the specific object Is installed fixed.

The rotation shaft 20 is rotatably inserted into the insertion hole 11 of the injection housing 10, and a part of the rotation shaft 20 protrudes a predetermined length toward the end of the injection housing 10.

The disk 30 is fixed to one end of the rotating shaft 20 partially protruding toward the end side of the spray housing 10 to maintain the gap t1 with the end surface of the spray housing 10. 20 and rotated together, the upper surface of the disk 30 is formed in a circumferential direction at a position spaced apart from the predetermined distance in the radial direction about the rotation axis (20) single annular corresponding to the discharge hole (13a) An inlet (31a) and injection holes (31b) formed on the outer surface of the disk 30 in a direction perpendicular to the phantom inlet (31a), the inside of the disk 30 and the annular inlet (31a) and the minute A fluid injection passage 31 for communicating the hole 31b is provided. Here, the annular inlet 31a is formed in a single annular shape on the upper surface of the disk 30, as shown in FIG. The discharge hole 13a and the annular inlet 31a correspond to each other. Which will be introduced into the discharge hole (13a), the fluid is a single annular inlet (31a) of the disk 30 is being rotated in the exhaust because.

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The motor housing 90 is fixedly installed at the other end of the injection housing 10, that is, at an end corresponding to the opposite side of the disk 30.

Inside the motor housing 90, a motor unit 91 for fast rotation at a speed of 6,000 rpm to 24,000 rpm is fixedly installed by directly connecting a rotor integrally with the rotating shaft 20.

Motor cooling means 92 for cooling the motor unit 91 is fixedly installed between the motor unit 91 and the motor housing 90.

The rotation guide means 50 introduces air into the gap t between the outer surface of the rotation shaft 20 and the inner surface of the insertion hole 11 of the split housing 10 to guide the rotation of the rotation shaft 20. Play a role.

The rotation guide means 50 is embedded in the space (S) between the outer circumferential surface of the rotary shaft 20 and the inner surface of the insertion hole 11 of the injection housing 10 and the inner surface and the outer surface of the rotary shaft 20 A rotation guide member 51 installed to maintain a predetermined gap t; A rotation guide air supply path 53 formed in the injection housing 10 to supply air to the space S; A plurality of injection nozzles 52 installed in a plurality of protrusions 51a protruding from the outer circumferential surface of the rotating guide member 51 to inject air supplied to the space S; A guide formed in the protrusion 51a to guide the air injected from the injection nozzle 52 to enter a predetermined gap t between an inner surface of the rotary guide member 5 and an outer surface of the rotary shaft 20. Furnace 51b.

In the configuration of the present invention configured as described above, it is further provided with a stop means 60 for causing the injection housing 10 of the rotating shaft 20 in the rotation state when the bar is stopped in the insertion hole (11). .

The stop means 60 forms a data portion 61 having a tapered surface narrowing downwardly on a portion of the outer circumferential surface of the rotation shaft 20, and an inner circumferential surface of the insertion hole 11 corresponding to the tapered portion 61. A stepped part 62 having a stepped shape having two steps, and having an inner surface contacting the tapered part 61, and an outer surface joined with the stepped part 62 having a stepped shape having two steps, Ascending and descending according to the inflow of air from the outside to the gap between the tapered portion 61 and the stepped portion 62 so that the inner surface is in contact or non-contact with the tapered portion 61 so that the rotating shaft 20 is rotated or non-rotated Interposed between the braking ring 63, the braking ring 63 is formed by forming a braking air supply path 64 in the interior of the injection housing 10 to supply air to the elevating.

In addition, in the configuration of the present invention described above, the fluid discharged to the discharge hole 13a of the fluid flow passage 13 flows out through the gap t1 between the disc 30 and one end of the injection housing 10. In order to prevent the leakage, an air supply passage 70 for preventing leakage may be formed at one end of the injection housing 10 so that air is injected into the gap t1 in a direction that resists the outflow direction of the fluid.

The description so far describes the configuration of the present invention.

Hereinafter, the operation of the present invention will be described.

First, when power is applied to the motor unit 91, the rotor constituting the motor unit 91 is rotated.

Since the rotating shaft 20 is directly connected directly to the rotor, the rotating force of the rotor may be immediately transmitted to the rotating shaft 20.

Therefore, the rotating shaft 20 is to rotate at high speed.

Here, since the motor unit 91 is directly connected to the rotating shaft 20 and the cooling unit 92 is installed around the rotating shaft 20, the high pressure compressed air is not required for high speed rotation as in the prior art. Due to the excessively large capacity of the auxiliary equipment, such as air compressors can solve the problem of increased power consumption.

Then, the cooling means 92 can effectively cool the heat generated by the motor unit 91.

In addition, it is possible to instantaneously generate excessive torque, and thus the rotational speed of the disk can be controlled because the change in the number of revolutions is constant.

At this time, the gap (t) between the inner surface of the rotary guide member 51 constituting the rotation guide means 50 and the outer surface of the rotary shaft 20 simultaneously with the rotation of the rotary shaft 20 or before the rotary shaft 20 rotates. Air into the air.

As described above, the air supplied to the gap t acts as a normal bearing, and the rotation shaft 20 smoothly rotates without vibration.

In addition, the gap t between the inner surface of the rotating guide member 51 constituting the rotating guide means 50 and the outer surface of the rotating shaft 20 at the same time as the rotating shaft 20 rotates or before the rotating shaft 20 rotates. In addition to introducing air into the air), the fluid flow path 13 formed in the injection housing 10 starts supplying the fluid used in the manufacture of ceramics, food, medicines, and the like.

The fluid supplied through the fluid flow path 13 as described above is discharged to the discharge hole (13a) formed in the end of the injection housing 10 on the disk 30 side and rotates with the rotating shaft 20 ( After flowing through the annular inlet 31a of the fluid injection passage 31 formed in 30, it is injected through the injection hole 31b through the fluid injection passage 31.

As described above, the rotary atomizer according to the present invention supports the rotating shaft by forming an air layer on the friction surface of the rotating shaft using compressed air, and rotates the rotating body at a high speed by using a special motor for high speed rotation. It can be sprayed.

1 is a cross-sectional view showing the internal configuration of a rotary atomizer according to the present invention. FIG. 2 is a view showing a state in which only an annular inlet is formed in a plan view of the disk of FIG.

<Description of the symbols for the main parts of the drawings>

10: injection housing 11: insertion hole

12: bracket 13: fluid flow path

20: axis of rotation 30: disk

40: air turbine 50: rotation guide means

51: rotation guide member 52: nozzle

53: rotational supply air supply path 60: stop means

61: tapered portion 62: stepped portion

63: braking ring 64: braking air supply passage

70: air supply passage for preventing leakage 90: motor housing

91: motor portion 92: motor cooling means

Claims (1)

In addition to having an insertion hole 11 through which both ends penetrate along the longitudinal direction, and having a bracket 12 on the outside, the discharge hole 13a for allowing the fluid introduced from the side to flow inside and to be discharged to the end side. An injection housing (10) having a fluid flow passage (13) having; A rotating shaft 20 rotatably inserted into the insertion hole 11 of the injection housing 10 and a part of which protrudes a predetermined length toward the end of the injection housing 10; A disk 30 installed at an end of the rotating shaft 20; A motor housing (90) installed at the other end of the injection housing (10) to drive the rotation shaft (20) to rotate; A motor unit (91) installed inside the motor housing (90) and directly connected to the rotating shaft (20) integrally with the rotor and rotating at a high speed at a speed of 6,000 RPM to 24,000 RPM; Rotation guide means (50) for guiding rotation of the rotary shaft (20) by introducing air into a gap (t) between the outer surface of the rotary shaft (20) and the insertion hole (11) of the injection housing (10); In the rotary atomizer composed of a stop means 60 to allow the rotating shaft 20 in the emergency state to be stopped in the insertion hole 11 of the injection housing 10 in an emergency, The disk 30 is fixed to one end of the rotating shaft 20 partially protruding toward the end side of the spray housing 10 to maintain the gap t1 with the end surface of the spray housing 10. 20 and rotated together, the upper surface of the disk 30 is formed in a circumferential direction at a position spaced apart from the predetermined distance in the radial direction about the rotation axis (20) single annular corresponding to the discharge hole (13a) An inlet (31a) and injection holes (31b) formed in the outer surface of the disk 30 in a direction perpendicular to the annular inlet (31a), the inside of the disk 30 and the annular inlet (31a) and the minute A fluid spray passage 31 for communicating the thread hole 31b is provided. Rotary automator is provided between the motor unit (91) and the motor housing (90), the motor cooling means (92) for cooling the motor unit (91).