KR20120132760A - Waviness measuring machine of inner sprial race for ball screw nut - Google Patents

Abstract

PURPOSE: A device for measuring grinding patterns of a nut for a ball screw is provided to consecutively measure the waviness of a spiral groove formed in the inner circumference of the nut and to measure the waviness more precisely by preventing friction generation. CONSTITUTION: A device for measuring grinding patterns of a nut for a ball screw comprises a supporting member(110), a parallel bar(120), a waviness measuring member(130), a display member(140), a transferring member(150), and a waviness regulating member(160). The supporting member supports the nut for the ball screw to be rotated. The parallel bar is installed to be parallel to a rotation center of the nut for the ball screw. The waviness measuring member measures waviness between the nut for the ball screw and spiral groove. The display member displays the waviness measured by the waviness measuring member. The transferring member transfers the waviness measuring member to a longitudinal direction of the parallel bar. The waviness regulating member provides the 3D data of the waviness of the spiral groove.

Description

Grinding pattern measuring device for nut for ball screw {Waviness measuring machine of inner sprial race for ball screw nut}

The present invention relates to a grinding pattern measuring device of a nut for a ball screw for continuously measuring the sluice of the spiral groove formed in the nut, which is one component of the ball screw for converting the rotation / linear motion to a linear / rotary motion.

In general, a ball screw is a mechanical component in which a screw in which a spiral groove is processed on an outer circumferential surface and a nut in which a spiral groove is processed on an inner circumferential surface are operated by rolling motion of a ball. And one of the nuts and the nut is configured to convert this rotational motion into linear motion upon rotation.

Therefore, the ball screw has been widely applied to a numerical control machine tool, a mechanical control device of an aircraft, or other feeding mechanism of machinery and equipment that requires precision.

The ball screw has a semicircular cross section of each of the spiral grooves formed on the inner circumferential surface of the nut and the outer circumferential surface of the screw, and the semicircular cross section forms a circular cross section when the screw is inserted into the nut to form a spiral passage.

A ball is fitted into the spiral passage formed by the combination of the nut and the screw, and the ball is circulated by rolling along the passage, thereby reducing the friction when the nut or the screw rotates. .

In addition, the spiral groove formed in the nut and the screw is wrapped to form a mirror surface in order to minimize friction when the ball between the nut and the screw is circulated.

However, since the spiral grooves of the nut formed as described above are mechanically cut and formed, the spacing between the spiral grooves or the processing state (depressed curved surface) of the spiral grooves may be different from each other.

In this case, when the ball screw is operated, a large noise is generated due to friction between the ball and the spiral groove, which is not preferable because the noise eventually causes vibration to sharply increase the wear of the ball.

In addition, there is a problem in that productivity is reduced because the measuring device for measuring the ratio between the spiral grooves of the nut is not provided, and the ball is circulated after the nut is coupled to the screw to check the noise.

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide a grinding pattern measuring device for a nut for a ball screw, which can continuously measure the bead of the spiral groove formed on the inner circumferential surface of the nut.

According to an aspect of the present invention, there is provided a grinding pattern measuring device for a nut for a ball screw, comprising: support means for rotatably supporting a ball screw nut to be measured, and a rotational center of the ball screw nut in parallel. And a means for measuring the bite between the parallel bar and the parallel bar, which is supported by the parallel bar, and the spiral groove of the ball screw nut, the display means for displaying the bite measured by the bite measuring means, and the parallel bar. And conveying means for conveying the non-measuring means in a longitudinal direction, and means for adjusting linearly reciprocating motion in a direction parallel to the parallel rods, and providing means for providing three-dimensional data on the bead of the spiral groove to be measured. do.

The support means includes a chuck restraining one side of the nut therein, a driving motor for generating rotational power, and a force transmission port for receiving rotational power from the driving motor and transmitting the rotational power to the chuck. It is characterized by.

The bidet adjusting means includes a jig having three-dimensional data on the beret of the spiral groove, a seating table on which the jig is seated and fixed, and a guide rail for guiding the seating rail in a direction parallel to the parallel bar. Characterized in that configured to include.

The non-measuring means is provided on one side of the conveying means and is combined with the spiral groove for guiding a linear movement of the conveying means when the nut for ball screw is rotated, spaced apart from the conveying means by a predetermined distance, and the spiral groove and It is characterized in that it comprises an indicator for selectively contacting to measure the distance ratio from the spiral groove where the conveying means is located to the point of contact.

Part of the outer shape of the guide is characterized by being formed with a curvature corresponding to the spiral groove.

One side of the conveying means is characterized in that the supporting means for spraying the air from the parallel bar by spraying air to the outer surface of the parallel bar.

The jig is characterized in that the portion is cut off (切除) to expose the spiral groove in the upward direction.

The rotation center of the chuck is characterized in that it coincides with the center of the jig.

As described in detail above, the grinding pattern measuring apparatus of the nut for a ball screw according to the present invention was configured to continuously measure the helical groove of the spiral groove formed on the inner circumferential surface of the nut.

That is, the conveying means is freely moved by the flotation means without friction with the parallel bar, and the non-measurement means is provided on one side of the conveying means, and the nut is rotated in place by receiving rotational power through the air spins to reduce vibration. It can rotate.

And, one side of the grinding pattern measuring device is provided with a bidet adjustment means having a bidet corresponding to the measurement target nut.

Therefore, it is possible to precisely adjust the ratio of the bidet measurement means by the bidet adjustment means, and to quickly measure the bidet using the adjusted bidet, thereby increasing the convenience of use.

In addition, there is an advantage that can be measured more precisely by blocking the occurrence of friction.

1 is a perspective view showing an external configuration of a grinding pattern measuring device of a ball screw nut according to the present invention.
Figure 2 is a front configuration diagram showing the configuration of the grinding pattern measuring device of the ball screw nut according to the present invention.
Figure 3 is a partial perspective view showing the installation state of the non-measuring means of the main configuration in the grinding pattern measuring device of the ball screw nut according to the present invention.
Figure 4 is a front configuration diagram showing an operating state of the non-regulating means of one configuration in the grinding pattern measuring device of the ball screw nut according to the present invention.
5 is a state diagram showing the state of using the grinding pattern measuring device of the ball screw nut according to the present invention.

Hereinafter, a configuration of a grinding pattern measuring device (hereinafter, referred to as 'grinding pattern measuring device 100') of a ball screw nut according to the present invention will be described with reference to FIGS. 1 and 2.

1 is a perspective view showing an external configuration of a grinding pattern measuring device 100 of a ball screw nut according to the present invention, Figure 2 is a grinding pattern measuring device 100 of a ball screw nut according to the present invention. The front view showing the configuration is shown.

Prior to this, terms and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may appropriately define the concept of the term in order to describe its invention in the best possible way It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely preferred embodiments of the present invention, and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

As shown in these drawings, the grinding pattern measuring device 100 is a spiral groove formed by grinding on the inner peripheral surface of the nut (N) while rotating the ball screw nut (hereinafter referred to as "nut (N)") having a variety of length ( It is an apparatus for continuously measuring the bite of FIG. 2 in the longitudinal direction.

That is, the grinding pattern measuring device 100 is to measure the distance ratio between adjacent spiral grooves G along a parallel imaginary line at a predetermined interval spaced apart from the center of rotation of the rotating nut N and varying lengths. Branch is not only applicable to the nut (N), it is configured to be applied to all of the spirals of various shapes.

To this end, the grinding pattern measuring device 100, the support means 110 for supporting the nut (N) that is the Vile measurement object in a rotatable state, and the parallel bar 120 is installed in parallel with the rotation center of the nut (N) And, the load is supported on the parallel bar 120, and the measuring means 130 for measuring the bite between the spiral grooves (G) of the nut (N), and the bite measured by the measuring means 130 Display means 140 to display, the conveying means 150 for transferring the non-measuring means 130 in the longitudinal direction of the parallel bar 120, linear reciprocating motion in a direction parallel to the parallel bar 120, the measurement It comprises a beret adjusting means 160 for providing three-dimensional data for the beret of the spiral groove (G) to be.

The above components are fixed to the base 170 and, if necessary, configured to linearly reciprocate.

The base 170 is fixed to the upper side of the frame 180 to maintain a predetermined height.

The support means 110 accommodates and constrains the left side of the nut (N) therein, and selectively rotates at the time of measuring the spiral groove (G), so that the support means (110) can be restrained with various sizes of nuts (N). The rotational speed and the direction are also adjustable.

In more detail, the support means 110 includes a chuck 112 that restricts movement by accommodating and pressing one end of the nut N therein, and a driving motor 114 that generates rotational power when power is applied; It is configured to include a power transmission port 116 for transmitting the rotational power of the drive motor 114 to the chuck 112, it is installed inside the protective cover 118.

The chuck 112 is provided with a plurality of fastening radially relative to the center of rotation, the plurality of fastening can be spaced at the same direction and the same speed, by pressing the nut (N) in close proximity to each other the nut (N) Can be constrained.

The drive motor 114 is configured to generate a rotational power for the chuck 112 to rotate, and transmits power to the force transmission port 116, the force transmission port 116 to the chuck 112 By rotating, the nut N can be rotated.

The force transmission port 116 is provided with the rotational power of the drive motor 114 through the belt 117, the rotational power is configured to be transmitted to the chuck 112 in a state in which vibration is minimized.

That is, the force transmission port 116 is adopted to the air spin so that the vibration is minimized when the chuck 112 is rotated. Therefore, the nut N, which rotates in conjunction with the rotation of the chuck 112, is rotated in a state where vibration is reduced, thereby enabling more precise Vile measurement.

Where the rear side is spaced apart from the chuck 112, the parallel bar 120 is provided. The parallel bar 120 is configured to guide the linear reciprocating direction of the conveying means 150, is configured in parallel with the rotation center of the chuck 112.

Accordingly, the transfer means 150 may be placed on a straight line parallel to the center of rotation of the chuck 112 during linear movement along the parallel rod 120.

And the length of the parallel bar 120 is formed long in consideration of the radius of action of the conveying means 150 and the non-measuring means 130.

That is, the conveying means 150 is provided with a non-measurement means 130, and the non-measurement means 130 must be selectively provided with the three-dimensional data of the non-receiving means through the non-lemerate adjusting means 160, the parallel bar 120 2) is elongated in the left / right direction as shown in FIG. 2, and has a circular cross section to enable rotation of the transfer means 150 (rotation in the circumferential direction of the parallel rod 120).

The transfer means 150 is provided on the outside of the parallel bar 120. The conveying means 150 is capable of conveying in the left / right direction by the longitudinal direction of the parallel bar 120, it is also configured to rotate by receiving the parallel bar 120 therein.

In addition, the transfer means 150 is a linear movement in the longitudinal direction of the parallel bar 120 at the time of measuring the bead by the contact of the non-measurement means 130 and the spiral groove (G), the parallel bar 120 The vibration is minimized by eliminating friction.

To this end, the conveying means 150 is provided with a support means 190.

3 is a partial perspective view showing the installation state of the non-measurement means 130 of the main component in the grinding pattern measuring device 100 of the ball screw nut (N) according to the present invention, with reference to the Looking at the configuration of 190, the support means 190 to suck the air to the outside of the parallel bar 120 by injecting the transport means 150 to be in a state of being supported with respect to the parallel bar 120, Accordingly, the transfer means 150 may be smoothly transferred in a state where friction does not occur in the longitudinal direction of the parallel bar 120.

To this end, the support means 190 has a cylindrical shape and an air injection port 192 for receiving the parallel bar 120 therein, and an air guide tube 194 for guiding air flow into the air injection port 192. And a pump (not shown) for forcing external air into the air guide tube 194.

In addition, a filter may be further provided between the pump and the air guide tube 194 to filter foreign matter contained in the outside air.

Therefore, the transfer means 150 maintains a state in which the air injection port 192 and the parallel bar 120 are seated on the parallel bar 120 when the pump is not operated, but when the pump is operated, the air guide tube Since the air is injected into the air injection port 192 through the 194, the transfer means 150 may maintain a state spaced apart from the parallel bar 120 at a predetermined interval.

In addition, the inner diameter of the air injection port 192 is preferably configured to be larger than the outer diameter of the parallel bar 120 by a predetermined size so that the distance from which the transfer means 150 is spaced relative to the parallel bar 120 does not vary.

The conveying means 150 is provided with a non-measuring means 130, which is a main component of the present invention. The measuring means 130 is configured to measure the distance ratio between the spiral grooves (G) in conjunction with the transfer means 150 for linear reciprocating motion in the longitudinal direction of the parallel bar (120).

Hereinafter, the configuration of the non-measuring means 130 will be described in detail with reference to FIGS. 4 and 5.

4 is a front configuration diagram showing an operating state of the non-regulating means 160, which is one configuration in the grinding pattern measuring device 100 of the ball screw nut (N) according to the present invention, Figure 5 The use state diagram which shows the Vile measurement state using the grinding pattern measuring apparatus 100 of the nut N for ballscrews by FIG.

As shown in the drawing, the non-measuring means 130 is provided in front of the conveying means 150 and is joined with the spiral groove G to guide the linear movement of the conveying means 150 when the nut N rotates. The distance between the sphere 132 and the point of contact from the spiral groove (G), which is spaced apart from the conveying means (150) by a predetermined distance and selectively contacts the spiral groove (G), is located. It comprises an indicator 134 to measure.

The guide 132 is fixed to the right rear end in front of the transfer means 150, the outer portion of the guide 132 is formed with a curvature corresponding to the spiral groove (G).

That is, the spiral groove G has a semi-circular cross section, and the lower left end of the guide 132 has a hemispherical shape.

Therefore, the lower outer surface of the guide port 132 is capable of curved line contact with the spiral groove (G), the transfer means 150 is in contact with the parallel bar 120 by the action of the air injection port (192). Since it is possible to move in a non-supported state, when the nut (N) is rotated, the guide 132 is linearly moved into the nut (N) along the spiral groove (G).

At this time, the transfer means 150 is also interlocked with the guide 132.

An indicator 134 is provided on the right side of the transfer means 150. The indicator 134 has a structure that can be bent in a number of places, the right rear end is fixedly mounted to the front of the transfer means 150.

Therefore, the left end of the indicator (134) (actually in contact with the spiral groove G) can be placed in various positions by the user's operation, to measure the distance ratio of the spiral groove (G) As shown in FIG. 5, the guide hole 132 is in contact with the inner circumferential surface of the spiral groove G adjacent to the right side.

Of course, the distance ratio of the spiral groove (G) may be measured continuously by positioning the guide 132 and the indicator 134 in the spiral groove (G) adjacent to each other, as shown in Figure 5, by rotating the nut (N), If necessary, the measurement of the distance ratio can also be performed in a state where the relative position of the indicator 134 with respect to the guide 132 is changed and maintained.

The display means 140 is provided at the rear side of the parallel bar 120. The display means 140 is a component that allows the naked eye between the spiral grooves (G) measured by the non-measurement means 130 to be easily identified with the naked eye.

Therefore, in the embodiment of the present invention, it is configured to be confirmed by rotating the needle to the left / right in accordance with the change of the Vile measured as shown in Figure 1, was also provided with an output unit 142 to output the change of the Vile at the same time .

On the other hand, in front of the non-measurement means 130 is provided with a non-leave adjustment means 160 as shown in FIG. The bidet adjusting means 160 is a configuration for setting the bidet measuring means 130 before measuring the bidet of the spiral groove (G).

That is, the non-regulating means 160 adjusts and fixes the position of the indicator 134 in advance with respect to the position of the guide 132, and then the guide 132 and the indicator (inserted inside the nut N) ( 134) when the guide 132 is seated in the spiral groove (G) is the configuration to enable the indicator 134 to start measuring the Viere at the correct position.

Therefore, the non-regulating means 160 should have three-dimensional data corresponding to the spiral groove (G) of the nut (N) to be measured, for this purpose, the non-regulating means 160 is a spiral groove (G) Jig 162 having three-dimensional data for the bile of (), a seating table 164 on which the jig 162 is seated and fixed, and the seating table 164 in a direction parallel to the parallel bar 120 It is configured to include a guide rail 166 for reciprocating movement.

The jig 162 has the same internal shape as that of the nut N to be measured, and the three-dimensional structure of the guide 132 and the indicator 134 before measuring the spiral groove G of the nut N is measured. Provide location information.

To this end, the jig 162 is partially cut to expose the spiral groove G upward, and is configured to facilitate the seating of the guide 132 and the end position setting of the indicator 134.

In addition, the bidet adjusting means 160 is configured to be easily measured after providing the three-dimensional bidet data to the bidet measuring means 130.

That is, the center of the jig 162 is configured to coincide with the center of rotation of the chuck 112.

Therefore, the position measuring means 130 is set by the position adjusting means 160, is transferred to the left direction is inserted into the nut (N), the guide 132 is the spiral groove (G) At the same time, the indicator 134 is in contact with the inner surface of the adjacent spiral groove (helical groove (G) spaced by a predetermined position in the jig 162).

Hereinafter, a process of measuring the bite of the nut (N) spiral groove (G) by using the grinding pattern measuring device 100 configured as described above will be described.

First, as shown in FIG. 1, the left side portion of the nut N is constrained to the chuck 112, and the driving motor 114 is in a state where power is not applied.

The jig 162 is installed at the seating table 164. The jig 162 has an internal shape corresponding to the nut N to be measured, and has a good state so that the upper part is opened and the bidet of the spiral groove G satisfies the tolerance.

In this case, power is applied to the support means 190 to space the transfer means 150 from the outer circumferential surface of the parallel bar 120. As a result, the transfer means 150 has friction in the longitudinal direction of the parallel bar 120. It slides in the removed state and becomes transferable.

Thereafter, the guide 132 is seated in the spiral groove G of the jig 162, and then the indicator 134 is contacted and fixed to another spiral groove G of the jig 162.

According to the process as described above, the three-dimensional position setting of the non-measurement means 130 using the non-leight adjustment means 160 is completed.

Thereafter, the non-measurement means 130 is rotated backwards (by rotating the conveying means 150 in the circumferential direction of the parallel bar 120), and then conveyed to the left side.

At this time, the non-measuring means 130 is conveyed in the same direction as the conveying direction of the conveying means 150, the guide 132 is fitted in the spiral groove (G) of the nut (N) bite to the chuck 112 It is seated.

In addition, the indicator 134 is in contact with the spiral groove (G) spaced by a predetermined distance is in a state that can be measured.

According to the above-described process, it is possible to measure the viere, and then the driving motor 114 generates the rotational power to rotate the chuck 112 through the force transmission port 116, and the display means 140 Vire data measured by the measuring means 130 is displayed in a variety of ways so that the user can visually check.

More specifically, by the movement of the indicator 134 and the guide 132, the indicator 134 is a spiral groove spaced at a predetermined interval based on the position of the spiral groove (G) where the guide 132 is located. The distance ratio up to (G) can be measured continuously.

In this case, the display unit 140 allows the measurer to easily check the beet measured by the indicator 134 with the naked eye, and output the beet using the output unit 142 for storing the beet data.

The scope of the present invention is not limited to the above-described embodiments, and many modifications may be made by those skilled in the art based on the present invention.

100. Grinding pattern measuring device 110. Supporting means
112. Chuck 114. Drive motor
116. Power Transmission 117. Belts
118. Protective cover 120. Parallel bar
130. Measuring means 132.
134. Indicator 140. Display means
142. Output 150. Transfer means
160. Non-regulating means 162. Jig
164. Mounting platform 166. Guide rail
170.Base 180.Frame
190. Supporting means 192. Air jet
194.Air Guidance G. Spiral Grooves
N. Nut

Claims (8)

Support means for rotatably supporting the ball screw nut to be measured;
Parallel rods installed in parallel with the rotation center of the ball screw nut,
A load measuring means for supporting a load between the parallel rods and measuring a bit between the spiral grooves of the ball screw nut;
Display means for displaying the Vile measured by the Vile measurement means;
A conveying means for conveying the non-measuring means in the longitudinal direction of the parallel bar;
Linear pattern reciprocating motion in a direction parallel to the parallel bar, the grinding pattern measuring device of the ball screw nut, characterized in that it comprises a non-resist adjusting means for providing three-dimensional data for the bead of the spiral groove to be measured. The method of claim 1, wherein the support means,
A chuck that restrains one side of the nut in a state accommodated therein;
A drive motor for generating rotational power,
The grinding pattern measurement device of the ball screw nut, characterized in that it comprises a force transmission port for receiving the rotational power from the drive motor to transfer to the chuck. The method of claim 2, wherein the non-regulating means,
A jig with three-dimensional data on a spiral groove,
A seating table to which the jig is seated and fixed,
Grinding pattern measuring device of the ball screw nut, characterized in that it comprises a guide rail for guiding the linear mounting in the direction parallel to the parallel bar parallel to the parallel bar. The method of claim 3, wherein the non-measuring means,
A guide provided on one side of the conveying means and engaged with the spiral groove to force a linear movement of the conveying means when the nut for ball screw rotates;
Grinding pattern of the ball screw nut characterized in that it comprises an indicator spaced apart from the conveying means at a predetermined interval, and selectively contacting the spiral groove to measure the distance to the contact point from the spiral groove in which the conveying means is located. Measuring device. 5. The apparatus of claim 4, wherein the outer portion of the guide is formed with a curvature corresponding to the spiral groove. According to claim 2, wherein the one side of the conveying means is a spiral groove ratio measuring apparatus of the nut for a ball screw, characterized in that the supporting means for spraying air from the parallel bar by spraying air to the outer surface of the parallel bar. 4. The apparatus of claim 3, wherein the jig is partially excised to expose the spiral groove upward. 8. The grinding pattern measuring apparatus of a nut for a ball screw according to claim 7, wherein the rotation center of the chuck coincides with the center of the jig.

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