JP2008136994A - Rotary air blowing device for cleaning screw hole - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of removing residue capable of surely and easily removing residue such as swarfs remaining inside screw holes, and to provide a rotary air blowing device for cleaning screw holes. <P>SOLUTION: The method of removing residue can remove residue such as swarfs 21a, 21b and 21c remaining inside a screw hole, by blowing upward residue 21a, 21b and 21c in the bottom part 11a of the screw hole with a rectilinear stream 53 blown off from the tip end of a rotary body and residue 21a, 21b and 21c in the bottom parts 11b of screws with a spiral stream 54 blown off from the side face of the rotary body, respectively from a screw opening part 11c to the outside 11d. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an apparatus for removing residues such as chips accumulated inside a screw hole with air after screw hole processing (tapping).

A conventional device for removing residues such as chips accumulated in a screw hole after screw hole machining (tapping) of a workpiece, which uses air, is like an air gun.
Hereinafter, a conventional apparatus will be described.
The air gun is a mechanism in which an air hose is inserted into a plug, and air is blown forward from a nozzle by grasping a handle grip to blow away residues such as chips.
In addition, by changing the length of the nozzle, it is possible to cope with a long hole.
“Esco Convenience Catalog 2006, Esco Corporation, 2006, p. 996”

  Conventionally, cleaning of residues (21a, 21b, 21c) such as chips inside a screw hole after screw hole processing (tapping) of a workpiece is performed by blowing air into the screw hole as shown in FIG. Dirt was blown outside. However, since the air outlet is in one place and the air is in a linear flow (53), the air cannot be blown well into the trough of the screw by simply moving the outlet out and through the screw hole by linear motion, and the trough (11b) Dirt was not completely removed (cannot be removed as the hole diameter increases). Therefore, the dirt of the valley (11b) is removed by circularly moving the air outlet, but it is still difficult to remove all the dirt, and if you do not work carefully over time, The inside of the screw hole cannot be removed cleanly. If the dirt (21c) is left as it is, the dirt (21c) will cause rusting and poor bolt tightening, which will affect the subsequent processes, so this work takes time and effort. The current situation is.

In order to solve the above-mentioned problem, the invention described in claim 1 is to remove residues (21a, 21b, 21c) such as chips remaining in the screw hole after the screw hole machining (tapping) of the workpiece. The method is characterized in that a linear flow (53) is blown from the tip inside the rotating body to the screw hole bottom portion (11a), and a spiral flow (54) is blown from the side surface inside the rotating body to the screw valley.
By comprising in this way, the residue (21a, 21b, 21c) inside a screw can be blown up from the screw opening part (11c) to the exterior (11d), and can be removed.

The invention described in claim 2 is a screw hole cleaning rotary air blower that removes residues (21a, 21b, 21c) such as chips remaining inside the screw holes after the screw hole processing (tapping) of the workpiece. The apparatus (1) is characterized in that a linear flow generation unit (51) is provided at the inner tip of the rotating body (1b) and a spiral flow generation unit (52) is provided on the inner side surface.
By configuring in this way, when air is blown out with the rotating body (1b) inserted inside the screw hole,
Residue on the screw bottom (11a) by air blown from the tip of the rotating body, and residue (21c) on the screw trough (11b) from the screw hole opening (11c) to the outside (11d) by air blowing from the side of the rotating body, respectively. Can be blown up and removed.

The invention described in claim 3 is a screw hole cleaning rotary air blower that removes residues (21a, 21b, 21c) such as chips remaining in the screw holes after the screw hole machining (tapping) of the workpiece. The device (1) is characterized in that the rotating body (1b) is configured to rotate by the reaction force of the generated spiral flow (54).
With this configuration, the air blown into the screw hole can draw a more accurate spiral flow (54).

The invention described in claim 4 is a rotary air blow for screw hole cleaning that removes residues (21a, 21b, 21c) such as chips remaining in the screw hole after the screw hole machining (tapping) of the workpiece. The device (1) has a plurality of through holes (52a, 52b,...) Shifted so that the through hole axis (103) does not intersect the rotating body axis (101), and the through holes (52a) , 52b, ...) is characterized in that the generated spiral flow (54) is generated in the direction of loosening the screw.
By comprising in this way, air can be directly sprayed on a screw trough part (11b), and a spiral flow (54) can be generated in the direction of screw loosening.

The invention described in claim 5 is a rotary air blow for screw hole cleaning that removes residues (21a, 21b, 21c) such as chips remaining in the screw hole after the screw hole machining (tapping) of the workpiece. The device (1) has a plurality of through holes (52a, 52b,...) Inclined by 5 to 45 degrees in the direction of the rotating body axial center line (101) from the rotating body radial core line (102). And
By comprising in this way, air can be blown out from a screw opening part (11c) to the exterior (11d).
Further, by combining with the spiral flow (54) which is the feature of claim 3, a spiral flow (54) from the screw opening (11c) to the outside (11d) is generated, and the residue in the screw valley portion (11b) is generated. (21c) can be removed.

The operation and effects of the screw hole cleaning rotary air blow device (1) according to the present invention configured as described above are as follows.
(1) By blowing a spiral flow (54) swirling in the loosening direction of the screw on the screw valley portion (11b), the air flows from the opening (11c) to the outside (11d) along the screw valley portion (11b). Because it blows up, there is a problem in removing conventional residue such as chips remaining in the screw hole after the screw hole machining (tapping) of the workpiece with air (hereinafter simply referred to as residue inside the screw hole). It became possible to remove residues such as chips and cutting water in the thread valley portion (11b). Further, since the linear flow (53) is also sprayed on the screw hole bottom part (11a), the residue on the screw hole bottom part (11a) as usual can also be removed, so that the residue inside the screw hole (21a, 21b, 21c) Can be removed.
(2) By clearly separating the mechanisms of the linear flow generation unit (51) and the spiral flow generation unit (52), no loss occurs in each generated fluid, and residues (21a, 21b, 21c inside the screw holes). ) Can be efficiently removed.
(3) Since the residue of the screw valley portion (11b) can be removed only by the longitudinal movement from the screw hole opening (11c) to the screw hole bottom portion (11a), the conventional residue of the screw valley portion (11b) ( The work of the circular motion that was essential for the removal of 21c) was omitted, and the working time was greatly reduced.
(4) Since the defective removal of the residue (21c) of the screw hole valley portion (11b), which has been a problem in the past, is eliminated, the quality is improved.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is an assembly view showing a main part of an embodiment of a rotary air blow device (1) for cleaning screw holes according to the present invention. FIG. 2 is a cross-sectional view of the screw hole cleaning rotary air blow device (1) according to the present invention. FIG. 3 is an arrow view from the tip of the rotating body. FIG. 4 is a cross-sectional view of the rotating body. FIG. 5 is an explanatory cross-sectional view showing how the residues (21a, 21b, 21c) inside the screw holes are removed. FIG. 6 is an explanatory cross-sectional view corresponding to FIG. 5 of the prior art.

  The embodiment shown in FIG. 1 will be described. This embodiment is an example of a rotary air blow device (1) for cleaning screw holes. In the figure, the screw hole cleaning rotary air blow device (1) is installed in a place where factory air can be used, such as a processing machine, and the residue (21a, 21b, 21c) inside the screw hole after the screw hole (tap) processing. Is to be removed.

  Specifically, 1 is a screw hole cleaning rotary air blow device (1) according to the present invention, 2 is a high coupler plug connected to a factory air plug, 3 is a pipe, 4 is an air flow rate adjusted by opening and closing a valve. General-purpose ball valve, 5 is a screw-type nipple, 6 is a screw-type stepped socket, 7 is a screw-type 90-degree elbow, and the above-mentioned parts 2 to 7 are not suitable depending on the diameter and location of the screw hole to be cleaned. It can be used by changing usage or model.

  For example, the screw hole cleaning rotary air blow device (1) in the same figure is an embodiment in the case where the screw hole to be cleaned is at a long distance, so that a long pipe (3a, 3b, 3c) is used. Deflection occurs due to the weight of the pipe, making it difficult to use. Therefore, by using a thick pipe for the pipe (3c) close to the hand, it is possible to suppress the deflection due to the weight of the pipe as much as possible, and it is easy to operate. Further, by using the screw-in type 90 degree elbow (7), the residue (21a, 21b, 21c) blown from the screw hole opening (11c) to the outside (11d) does not blow to the user of the present invention. It is structured.

  The pipes 3a, 3b, 3c, and 3d are respectively subjected to pipe taper thread processing on both ends in accordance with the shape of the pipe, 2 high coupler plugs, 4 general-purpose ball valves, 5 screwed nipples, 6 It can be connected to a screw-type stepped socket of No. 7 and a screw-type 90-degree elbow of No. 7.

  FIG. 2 is a cross-sectional view of a screw hole cleaning rotary air blow device (1) according to the present invention, wherein (1a) is a rod, (1b) is a rotating body, and (1c) is a rotating body (1b). (1d) is a fine U nut for retaining the bearing (1c), (1e) is a washer for preventing the bearing (1c) from being scratched and preventing air leakage, and (1f) is a resistor. The rotating body (1b) and the bolt (1h) are connected, and (1g) is a screw hole insertion guide.

  The rod (1a) is provided with a step corresponding to the diameter of the bearing (1c) in order to pass the bearing (1c), and is provided with a step for relief so as not to hinder the rotation function of the bearing (1c). Furthermore, a metric male thread processing is applied to the tip of the rod (1a), and the bearing (1c) is fixed with a fine U nut (1d). The end of the rod (1a) is processed with a taper female thread for pipe so that it can be connected to the pipe (3a). Furthermore, a through hole is provided in the longitudinal direction of the rod (1a), and the air flowing in from the connected pipe (3a) is passed. The air that has flowed into the rod (1a) is blown out from the linear flow generator (51) and the spiral flow generator (52) of the rotating body (1b).

  The rotating body (1b) has a linear flow generation unit (51) and a spiral flow generation unit (52), and blows out the air flowing in from the rod (1a) into the screw holes through the generation units. The mechanism is configured to rotate by the reaction force of the generated spiral flow (54). By rotating the rotating body without being fixed, the air blown into the screw hole can draw a more accurate spiral flow (54). Further, a step corresponding to the outer diameter of the bearing (1c) is provided in order to put the bearing (1c) inside the rotating body (1b), and the step (the bearing ( The structure is also in consideration of the contact surface with 1c). Further, a plurality of screw holes for connecting the resistor (1f) with bolts (1h) are provided on the connection surface with the resistor (1f).

  The mechanism of each generating unit will be described in detail. As shown in FIG. 3, a plurality of through holes shifted so that the through hole axis (103) of the rotating body (1b) does not intersect the rotating body axis (101) By providing the holes (52a, 52b,...), The air flowing in from the rod (1a) can be changed to a spiral flow (54). Further, by forming the through hole so as to tilt leftward when viewed from the front end side of the figure, the generated spiral flow (54) can be generated in the direction of loosening the screw.

  Further, as shown in FIG. 4, the through holes (52a, 52b,...) Are inclined by 5 to 45 degrees in the direction of the rotating body axial center line (101) with respect to the rotating body radial center line (102). The flow (54) is blown out from the screw hole opening (11c) to the outside (11d) using the screw valley (11b) as a guide.

The resistor (1f) has a plurality of wings (X) that serve as resistors, and can be connected to the rotator (1b) to reduce the rotational speed of the rotator (1b). This function is intended to prevent the generated spiral flow loss from occurring when the rotating body (1b) rotates more than necessary. In addition, a step corresponding to the outer diameter of the bearing (1c) is provided in order to insert the bearing (1c) inside, and the step contacts the bearing (1c) so as not to hinder the rotation function of the bearing (1c). The structure is also in consideration of the surface.
Furthermore, a plurality of drill holes for connecting the rotating body (1b) with bolts (1h) are provided on the connection surface with the rotating body (1b).

The screw hole insertion guide (1g) serves as a guide for inserting the rotating body (1b) and the resistor (1f) into the screw hole, and the radial shape is changed to the rotating body (1b) and It is larger than the outer diameter of the resistor (1f). Thereby, at the time of screw hole insertion, interference with a screw hole internal diameter, a rotary body (1b), and a resistor (1f) can be prevented, and it can insert smoothly.
Furthermore, the screw hole insertion guide (1g) is provided with a relief portion such as a constriction so as not to obstruct the flow path of the air blown out from the rotating body.

  It should be noted that the present invention is not limited to the above-described embodiments, but includes all modified embodiments that can be easily conceived by the parties from the above-described invention within the scope of the object of the present invention.

It is an assembly drawing which shows the principal part of one Example of the rotation air blow apparatus (1) for screw hole cleaning which concerns on this invention. It is sectional drawing of the rotation air blow apparatus (1) for screw hole cleaning which concerns on this invention. It is an arrow view from a rotary body front-end | tip. It is sectional drawing of a rotary body. It is explanatory sectional drawing which shows a mode that a residue is removed. It is explanatory sectional drawing corresponded in FIG. 5 of a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Rotating air blow apparatus 11a for screw hole cleaning Screw hole bottom part 11b Screw hole trough part 11c Screw hole opening part 11d External 21a, 21b, 21c Residue 51 Linear flow generation part 52 Spiral flow generation part 53 Linear flow 54 Spiral flow 101 Rotation Body axis core wire 102 Rotating body diameter core wire 103 Through-hole shaft core wire

Claims (6)

  As a means to remove chips and cutting water remaining inside the screw hole after machining the screw hole (tapping) on the workpiece, air is blown in two directions, the screw bottom direction and the screw radial direction, in the screw bottom direction. Generates a spiral flow in the screw radial direction, and blows away residues (21a, 21b, 21c) such as chips inside the screw toward the screw opening (11c) and the outside (11d). The removal method characterized by the above-mentioned.   In the air blow device that removes chips and cutting water remaining inside the screw hole after the screw hole machining (tapping) of the workpiece, a linear flow generator (51) is provided at the inner tip of the rotating body (1b) A rotating air blow device for cleaning screw holes, wherein a spiral flow generating section (52) is provided on a side surface.   The rotary air blow device for cleaning screw holes according to claim 2, wherein the rotating body (1b) is configured to rotate by a reaction force of the generated spiral flow (54).   The rotating body (1b) spiral flow generator (52) has a plurality of through holes (52a, 52b,...) Shifted so that the through hole axis (103) does not intersect the rotating body axis (101). The screw hole cleaning according to claim 2, wherein the through hole (52 a, 52 b,...) Has a generated spiral flow (54) in the direction of loosening the screw. Rotating air blow device.   The rotating body (1b) spiral flow generating section (52) is inclined by a plurality of through holes (52a, 52b,. The rotary air blow device for cleaning screw holes according to claim 2, wherein:   6. A rotating air blow device for cleaning screw holes according to claim 2, wherein aluminum is used as a material for the rotating body (1b), the resistor (1f), and the screw hole insertion guide (1g). .

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