KR102586366B1 - Air spindle for processing apparatus - Google Patents

Abstract

The present invention includes a mounting module configured to be mounted on processing equipment; a mounting module connected to the mounting module and configured to be mounted on processing equipment; A work module including a shaft rotationally driven by clean air; and a filtering module that communicates with the mounting module and the work module and removes foreign substances from the mixed air to generate the clean air, wherein the filtering module includes an inlet channel that receives the mixed air from the mounting module, a housing having a supply channel for supplying the clean air to the work module; and a spiral collision inducing part disposed between the inflow channel and the supply channel and guiding the mixed air to collide with the housing while flowing in a spiral shape, wherein the mixed air is generated according to the induced collision by the spiral collision inducing part. An air spindle mounted on processing equipment is provided that separates the clean air from the foreign matter.

Description

Processing equipment mounted air spindle {AIR SPINDLE FOR PROCESSING APPARATUS}

The present invention relates to an air spindle mounted on and used in processing equipment.

In general, an air spindle uses compressed air to rotate a tool, and can rotate the tool at a high speed, for example, 50,000 rpm. Accordingly, when mounted on processing equipment (e.g., a standard (old) machining center), the air spindle can perform the same as a high-speed processing machine.

The air spindle minimizes heat generation, allowing long-term processing without downtime. Additionally, there is an advantage that no problems occur with the product even if the processing load is stopped due to a processing load.

In these air spindles, air for rotating the tool can be supplied from machining equipment. However, the air supply line of processing equipment not only supplies air, but also supplies cutting oil at intervals, and at the same time, lubricating oil seeps into it. As a result, the air used to rotate the tool contains clean air as well as foreign substances such as cutting oil or lubricant residue.

When foreign matter is supplied to the air spindle along with clean air, it accumulates over time. Accumulated foreign matter may cause problems with the smooth operation of the air spindle.

One object of the present invention is to provide an air spindle mounted on processing equipment that can effectively remove foreign substances in the air supplied from processing equipment for tool rotation.

A processing equipment-mounted air spindle according to one aspect of the present invention for realizing the above-described problem includes a mounting module configured to be mounted on the processing equipment; A work module including a shaft rotationally driven by clean air; and a filtering module that communicates with the mounting module and the work module and removes foreign substances from the mixed air to generate the clean air, wherein the filtering module includes an inlet channel that receives the mixed air from the mounting module, a housing having a supply channel for supplying the clean air to the work module; and a spiral collision inducing part disposed between the inflow channel and the supply channel and guiding the mixed air to collide with the housing while flowing in a spiral shape, wherein the mixed air is generated according to the induced collision by the spiral collision inducing part. It can be separated into the clean air and the foreign matter.

Here, the housing further includes a separation space communicating with the inflow channel and the supply channel, and the spiral collision inducing part may include a spiral groove formed on a wall defining the separation space.

Here, the cross section of the separation space may have a donut shape surrounding the supply channel.

Here, the housing further includes a cover body in which the inflow channel is formed and covers the separation space, and the cover body has a size spaced apart from the supply channel, so that the clean air flows between the cover body and the supply channel. It may be allowed to flow into the supply channel through the space between channels and the top of the supply channel.

Here, the spiral collision inducing part may further include a blocking member located at the lower part of the internal space and blocking the foreign matter released from the mixed air from rising toward the inflow channel.

Here, the spiral collision inducing part may include a spiral flow channel extending spirally within the housing.

Here, the filtering module may further include a connection channel connecting the spiral flow channel and the supply channel.

Here, the filtering module may further include a discharge hole that communicates the spiral collision inducing part with the outside and allows the foreign substances to be discharged.

According to the air spindle equipped with processing equipment according to the present invention configured as described above, the filtering module disposed between the mounting module and the work module removes foreign substances from the mixed air containing foreign substances from the mounting module and supplies clean air to the work module. The filtering module causes the mixed air to collide with the housing through the spiral collision guide, causing foreign substances to fall and supply clean air to the work module, thereby removing foreign substances from the air supplied from the processing equipment for the rotation of the tool. Allows for effective removal.

By effectively removing foreign substances, problems such as malfunction or breakdown of the air spindle can be prevented in advance.

Figure 1 is a longitudinal cross-sectional view of an air spindle 100 equipped with processing equipment according to an embodiment of the present invention.
FIG. 2 is a perspective view showing the filtering module 130 of FIG. 1.
FIG. 3 is a cutaway perspective view of the filtering module 130 of FIG. 2.
Figure 4 is a cutaway perspective view of the filtering module 230 according to another embodiment of the present invention.

Hereinafter, an air spindle equipped with processing equipment according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings. In this specification, the same or similar reference numbers are assigned to the same or similar components even in different embodiments, and the description is replaced with the first description.

Figure 1 is a longitudinal cross-sectional view of an air spindle 100 equipped with processing equipment according to an embodiment of the present invention.

Referring to this drawing, the air spindle 100 may include a mounting module 110, a filtering module 130, and a work module 150.

The mounting module 110 is configured to be mounted on the main axis of processing equipment, for example, a machining center. The mounting module 110 has a substantially cylindrical housing 111. A receiving portion 113 that accommodates the main shaft is opened in the upper part of the housing 111. A supply passage 115 communicating with the receiving portion 113 is formed in the lower part of the housing 111.

The supply passage 115 is a passage that receives air from the main shaft inserted into the receiving portion 113 and delivers it to the filtering module 130. Through the supply passage 115, not only air but also cutting oil can be supplied at different times. Accordingly, the air supplied through the main shaft is usually mixed air containing foreign substances such as cutting oil or lubricant residue, rather than clean air.

The filtering module 130 is connected to the mounting module 110 and generates clean air by removing foreign substances from the mixed air flowing therefrom. To this end, the filtering module 130 may include a housing 131 and a spiral collision inducing portion 141. The filtering module 130 may be manufactured using a three-dimensional stacking method.

The housing 131 may also have a generally cylindrical shape. An inlet channel 133 communicating with the air supply path 115 is formed at the top of the housing 131. As a result, mixed air flows into the inlet channel 133. A supply channel 135 communicating with the inlet channel 133 is formed in the lower part of the housing 131. Clean air is supplied to the work module 150 through the supply channel 135.

The spiral collision inducing unit 141 is configured to induce the mixed air introduced through the inflow channel 133 to collide with the housing 131 while flowing in a spiral fashion. For this purpose, the spiral collision guide 141 is located between the inlet channel 133 and the supply channel 135 and communicates with them.

The filtering module 130 may be coupled to the mounting module 110 by a fastening portion 132 formed on the outer peripheral surface of the housing 131. Here, the fastening part 132 may be a different screw thread that is screwed to the screw thread formed in the mounting module 110.

The work module 150 is connected to the filtering module 130 and operates by receiving clean air therefrom. A shaft 153 is rotatably mounted on the housing 151 of the work module 150. A tool for cutting work may be installed on the shaft 153. The rotation of the shaft 153 is performed by the blade 155. The blade 155 is coupled to the shaft 153 and rotates by the power of clean air supplied through a supply passage (not shown) in the housing 151.

The specific configuration of the above filtering module 130 will be described with reference to FIGS. 2 and 3.

FIG. 2 is a perspective view showing the filtering module 130 of FIG. 1, and FIG. 3 is a cutaway perspective view of the filtering module 130 of FIG. 2.

Referring to these drawings, the housing 131 of the filtering module 130 further has a separation space 137 and a cover body 139 in addition to the inlet channel 133 and the supply channel 135.

The separation space 137 is a space that communicates with the inlet channel 133 and the supply channel 135. The separation space 137 surrounds the supply channel 135, and its cross-section may have a donut shape surrounding the supply channel 135.

The cover body 139 may be a plate that covers the separation space 137. The cover body 139 is located above the end 136 of the supply channel 135 and is spaced apart from the end 136. An inflow channel 133 is formed in the cover body 139. The inflow channel 133 is formed so that the mixed air (Am) flows into the separation space 137 in a spiral direction. A plurality of inlet channels 133 may be provided and arranged along the circumferential direction at the edge area of the cover body 139.

The spiral collision inducing portion 141 may be a spiral groove 143 formed on the wall of the housing 131 defining the separation space 137. The spiral groove 143 is connected to the inlet channel 133 and guides the mixed air Am in a spiral path and causes the mixed air Am to collide with the wall. The collision of the mixed air (Am) against the wall can be said to be an induced collision in that it is a collision induced by the spiral groove 143.

The mixed air (Am) collides with the wall by the spiral groove 143 and is separated into clean air (Ac) and foreign matter (Fo). Here, clean air (Ac) enters the top of the supply channel 135 through the space between the cover body 139 and the top 136 of the supply channel 135. Clean air (Ac) flows into the work module 150 (see FIG. 1) through the bottom of the supply channel 135.

The foreign matter Fo is moved to the lower part of the spiral groove 143 while colliding with the wall. As a result, foreign matter Fo accumulates in the chamber 147 located at the bottom of the spiral groove 143. In order to prevent the foreign matter (Fo) from rising and mixing again with the clean air (Ac), a blocking member 145 may be formed in the separation space 137.

The blocking member 145 may protrude radially from the outside of the supply channel 135. The blocking member 145 is arranged to be spaced apart from the wall defining the separation space 137, allowing foreign substances Fo to fall into the chamber 147, but restricting them from rising from the side close to the supply channel 135. do.

Foreign matter Fo whose rise is blocked by the blocking member 145 is discharged to the outside through the discharge hole 149. The discharge hole 149 is formed to communicate the spiral collision inducing portion 141 or the separation space 137 with the outside.

Other forms of the above filtering module 130 will be described with reference to FIG. 4. Figure 4 is a cutaway perspective view of the filtering module 230 according to another embodiment of the present invention.

Referring to this drawing, the spiral collision inducing part 241 of the filtering module 230 may be a spiral flow channel 243 formed within the housing 231. The spiral flow channel 243 is a space that starts from the upper surface of the housing 131 and extends downward in a spiral path. The inlet formed on the upper surface will be the inlet channel 233.

The supply channel 235 may start from an area near the top of the housing 131 and extend to the bottom of the housing 131, as in the previous embodiment. A connection channel 245 may be formed to connect the supply channel 135 and the spiral flow channel 243. The connection channel 245 may extend along the horizontal direction.

The air spindle equipped with processing equipment as described above is not limited to the configuration and operation method of the embodiments described above. The above embodiments may be configured so that various modifications can be made by selectively combining all or part of each embodiment.

100: air spindle 110: mounting module
130,230: Filtering module 131,231: Housing
141,241: Spiral collision guidance unit

Claims (8)

a mounting module configured to be mounted relative to the processing equipment;
A work module including a shaft rotationally driven by clean air; and
A filtering module that communicates with the mounting module and the work module and removes foreign substances from the mixed air to generate the clean air,
The filtering module is,
a housing including an inlet channel that receives the mixed air from the mounting module, a supply channel that supplies the clean air to the work module, and a separation space communicating with the inlet channel and the supply channel; and
It is disposed between the inflow channel and the supply channel, and includes a spiral collision inducing part that guides the mixed air to collide with the housing while flowing in a spiral shape,
The mixed air is separated into the clean air and the foreign matter according to the induced collision by the spiral collision inducing part,
The spiral collision inducing part is a processing equipment-mounted air spindle including a spiral groove formed on a wall defining the separation space.
According to paragraph 1,
The cross section of the separation space is,
A processing equipment mounted air spindle having a donut shape surrounding the supply channel.
According to paragraph 1,
The housing is,
The inflow channel is formed and further includes a cover body covering the separation space,
The cover body is,
An air spindle mounted on processing equipment that has a size spaced apart from the supply channel, allowing the clean air to flow into the supply channel through a space between the cover body and the supply channel and an upper end of the supply channel.
According to paragraph 1,
The spiral collision induction unit,
An air spindle mounted on processing equipment, which is located at the lower part of the internal space and further includes a blocking member that blocks the foreign matter released from the mixed air from rising toward the inflow channel.
According to paragraph 1,
The spiral collision induction unit,
A processing equipment mounted air spindle comprising a helical flow channel extending helically within the housing.
According to clause 5,
The filtering module is,
An air spindle equipped with processing equipment, further comprising a connection channel connecting the spiral flow channel and the supply channel.
According to paragraph 1,
The filtering module is,
An air spindle mounted on processing equipment, further comprising a discharge hole that communicates the spiral collision inducing portion with the outside and allows the foreign matter to be discharged. delete

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