KR19990057207A - Concentricity Measuring Sphere for Rack Housing - Google Patents

Abstract

The present invention relates to a concentricity measuring instrument for rack housings, to easily measure and inspect the concentricity of the yoke hole in the rack housing, as well as to improve measurement accuracy. The upper and lower ball arbors and the upper ball arbors are upwards. It consists of a holder coupled to it and a lever attached thereto, and the inspector inserts the two ball arbors into the yoke hole to be inspected, contacts the probe such as a dial gauge to the upper surface of the lever, and then By simply rotating it, the yoke hole concentricity is accurately detected by the probe.

Description

Concentricity Measuring Sphere for Rack Housing

The present invention relates to a concentricity measuring instrument for a rack housing of a vehicle, and more particularly, to easily measure the concentricity of a yoke hole formed through a rack housing body, as well as measurement accuracy. It relates to a concentricity measuring instrument for rack housing that can be improved.

In terms of securing driving safety of the vehicle, special attention is usually required to inspect the rack-related parts such as the rack housing or the rack bar.

In practice, the rack housing must not only undergo a material inspection prior to machining, but also strictly measure and inspect machining accuracy in a three-dimensional measuring room after machining. Among them, the concentricity of the yoke hole formed through the rack housing is the main object of precision measurement. This is because the stable relative motion of the yoke coupled to the yoke hole, that is, whether the vehicle is safe to drive is determined depending on the concentricity of the corresponding yoke hole.

Here, the operation overview for measuring the yoke hole concentricity will be described.

First, the finished rack housing for each lot is neatly stacked on a loading table and then transferred to a precision measuring room such as a three-dimensional measuring room. Subsequently, the overall dimensional inspection including the concentricity or the intensity measurement and inspection is performed, and the inspection is completed and sent to each assembly workshop.

On the other hand, although the task of moving a plurality of rack housings for measurement is unavoidable, there is an essential and also significant problem in measuring the rack housing concentricity. That is, due to the shape of the rack housing itself, not only excessive measurement time is required but also the measurement accuracy is not so good.

More specifically to the problem related to the rack housing shape, the yoke hole penetrating the rack housing body includes two upper and lower bearing inserts, the two parts which are the reference for measuring concentricity and strength, etc. The location on the opposite side makes the three-dimensional measurement itself quite difficult.

As a result, the rack housing concentricity measurement and inspection work has a problem that excessive air input and poor measurement accuracy follow. Considering the human and physical losses incurred in the transport process, the seriousness of the problem is reduced.

The present invention has been made in view of the above-mentioned problems in the related art, and an object of the present invention is to easily measure and inspect the concentricity of the yoke hole in the rack housing, as well as to improve the measurement accuracy. To provide.

It is still another object of the present invention to provide a concentricity measuring instrument for rack housing that can provide considerable man-hours and cost savings as a separate transport process to a measurement chamber is unnecessary.

1 is a partial cross-sectional view showing the concentricity measuring instrument used in the embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

10: rack housing 11: yoke hole

20: concentricity measuring sphere 21: lower ball arbor

22: upper ball arbor 23: lever

Concentricity measuring sphere for the rack housing of the present invention for achieving this object, the upper and lower ball arbor (Ball arbor), the upper ball arbor comprises a holder coupled to the upper and the lever attached thereto, the inspector Insert the two ball arbors into the yoke hole to be inspected, contact the probe with a dial gague on the top of the lever, and rotate these holders and levers.The probe will then accurately measure the concentricity of the yoke hole. There is a feature to be detected.

Hereinafter, the concentricity measuring instrument for the rack housing of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a partial cross-sectional view showing an embodiment of the present invention, the two upper and lower bearing inserts (A, B) in the yoke hole 11 shown in the cut state is a reference for measuring the concentricity or the progress of the hole It is a part. As mentioned above, not only is the measurement itself difficult due to its shape, but also the measurement accuracy is not so good.

Here, with reference to Figure 1 showing the concentricity measuring sphere using state of the embodiment of the present invention, the structure and actual use method of the concentricity measuring sphere for the rack housing of the present invention will be described.

First, the concentricity measuring sphere 20 has a holder 24 having a small lever 23 attached to one side thereof, and a rotating ball portion having dimensions matching the bearing insertion portion A in the yoke hole 11. It has an upper ball arbor 22 to which the holder 24 is coupled to the upper end thereof, and a rotating ball portion having dimensions corresponding to another bearing insert B in the yoke hole 11, and the upper ball arbor ( 22) It is comprised including the lower ball arbor 21 connected to the lower end part. In addition, the lower end of the upper ball arbor 22 and the upper end of the lower ball arbor 21 are respectively processed into protrusions and grooves having a shape corresponding to each other, and serve to connect them integrally during actual datum chucking.

On the other hand, it is preferable that the holder 24 is cylindrical and knurling on its outer circumferential portion so that the hand of the inspector does not slip. Of course, the shape or the outer peripheral surface processing is not particularly limited.

In order to measure the concentricity of the yoke hole 11, the rack housing 10 is placed on the lower ball arbor 21 so as to cover the rack housing 10 and the upper opening of the yoke hole 11 is provided. From the upper ball arbor 22, the two ball arbors 21 and 22 are integrally connected, and then the holder 24 is fixed to the tip of the upper ball arbor 22 using pins 26 or the like. The reference chucking is first completed. As soon as the upper ball arbor 22 and the lower ball arbor 21 are coupled, the corresponding rotating ball portion of the upper ball arbor 22 is also accurately positioned in the corresponding bearing insert A in the yoke hole 11, of course. to be.

Here, a V-shaped groove having a predetermined depth is engraved around the upper end of the upper ball arbor 22 so as to be integrated with each other by simply inserting a pin 26 having a proper size through a hole on one side of the holder 24. to be. This may also be any other shape as long as it is easy to work with.

Subsequently, the outwardly bent lower end of the lever 23 mounted on the holder 24 is positioned and fixed so as to contact the inner wall surface of the upper end of the yoke hole 11, and then the dial gauge on the upper surface of the lever 23. (25) or by setting a probe such as an electronic instrument, the preparation for the concentricity measurement and inspection work is completed.

In the state where the preparation is completed, when the operator grabs the holder 24 and rotates it, the lower end of the lever 23 also rotates along the inner wall of the upper end of the yoke hole 11 while the corresponding yoke hole 11 The concentricity or the magnitude of the bearing inserts (A, B) in the interior will be informed through the probe. This is because the two ball arbors 21 and 22 demonstrate the motion state of the yoke when the vehicle is actually driven. As a result, the concentricity measurement in a virtual real situation has perfect accuracy despite being a very simple task.

One important thing is that the concentricity measurement and inspection work by the concentricity measuring instrument for rack housing of the present invention does not need to be carried out separately in a three-dimensional measuring room or the like. In other words, the operator can simply use when necessary in the vehicle assembly work site. As mentioned at the outset, it is a matter of course that a great deal of labor and cost savings are taken into consideration, considering that the transportation work for measurement and inspection becomes unnecessary.

As described above, the concentricity measuring instrument for rack housings of the present invention facilitates concentricity measurement and inspection of the yoke hole in the rack housing, and has an effect of improving measurement accuracy.

In addition, significant man-hours and cost savings can be achieved by excluding transport operations for measurement.

Claims (5)

A holder 24 to which the small lever 23 is attached, and a rotating ball portion having a dimension corresponding to the bearing insertion portion A in the yoke hole 11 of the rack housing 10, and at the upper end thereof; 24 has an upper ball arbor 22 to which it is coupled, and a rotating ball portion having a dimension matching with another bearing insert B in the yoke hole 11 and connected to a lower end of the upper ball arbor 22. Concentricity measuring sphere for the rack housing, characterized in that comprises a lower ball arbor (21). The concentricity measuring instrument for rack housing according to claim 1, wherein the lower end portion of the upper ball arbor (22) and the upper end portion of the lower ball arbor (21) are formed of protrusions and grooves having a shape corresponding to each other. The concentricity measuring instrument for rack housing according to claim 1, wherein a groove is formed around an upper end of the upper ball arbor (22), and a pin hole penetrates one side of the holder (24). The concentricity measuring tool for rack housing according to claim 1, wherein the lever (23) has a tip portion that is bent outwardly and is adjustable in position with respect to the holder (24). The concentricity measuring instrument for rack housing according to claim 1, 3 or 4, wherein an outer circumferential portion of the holder (24) is kneaded.