KR0119285Y1 - Piston ring groove measuring base - Google Patents

Abstract

The present invention relates to a pedestal for measuring piston ring grooves, the lower portion of which is open, the lower portion and the upper surface thereof are parallel to each other, and the height exceeding the length of the connecting rod 25 coupled to the lower portion of the piston 20. The rectangular opening 5 is formed in the upper surface of the cylindrical body 10 which has a large end part of the connecting rod 25, and the small end part of the connecting rod 25 is formed in both sides of the center part of the said opening part 5 above. Consists of a structure in which each of the openings (5A) having a semi-circular shape symmetrically formed to provide a rotational space for the support so that the lower portion of the piston 20 is supported by the upper surface, and the connecting rod coupled to the lower portion of the piston (20) 25) can be accommodated through the inner space to facilitate the operation quickly in the measurement process for each dimension of the piston ring groove (20A) by the height gauge 50, and to increase the reliability of the measured value. It is configured to be.

Description

Piston ring groove measuring base

1 is an exemplary view showing a state in which a piston is settled by a block stacked on a surface plate as an example of a conventional piston ring groove measuring operation.

Figure 2 is a perspective view showing a pedestal for measuring piston ring groove according to the present invention,

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a perspective view showing a state of use of the piston ring groove measuring base according to the present invention.

* Explanation of symbols for main parts of the drawings

5 opening 5 A

10: cylinder 20: piston

25: connecting rod

The present invention relates to a pedestal for measuring piston ring grooves. Specifically, the piston is settled by using an upper portion of the cylindrical body, and the connecting rod is stored by using the internal space of the cylindrical body. It is configured to facilitate the measurement of grooves formed on the outer circumferential surface, and is particularly configured to measure the butterfly and the gap of the piston ring groove by a height gauage.

In general, after disassembling the engine for performance test or inspection of the engine, the piston ring is formed on the outer circumference of the piston to provide a space for the compression ring and oil ring to measure the exact binding state or fit of the piston ring. Accurate measurements of the groove width and spacing between grooves shall be preceded.

Conventionally, as shown in FIG. 1, several blocks 35 are stacked on the upper part of the eye 30 so that the piston can maintain a constant height from the surface plate when the piston ring groove is measured. Each dimension of the piston ring groove 20A is measured by a height gauge in a state where the piston 20 requiring measurement is placed on the upper surface of the c).

On the other hand, in the state where the connecting rod is coupled to the lower part of the piston 20, the block 35 cannot be placed directly on the upper part of the block 35, so that the block 35 of the platen 30 The lower sides of the piston 20 are supported by the upper portions of the blocks 35 stacked on both sides, respectively, by laminating them to a height that exceeds the length of the connecting rod from both upper sides, and formed between the blocks 35. In the state in which the connecting rod is interposed through the space, a measurement operation for the piston ring groove 20A formed on the outer circumferential surface of the piston 20 is performed.

On the other hand, if an error occurs in the shape and dimensions of the piston ring groove 20A, a space is formed between the cylinder lining or the friction is increased while the compression ring and the oil ring are coupled through the piston ring groove 20A. As the efficiency of the engine decreases rapidly, the measurement work on the piston ring groove 20A as described above requires high precision in nature, and the connecting rod is used in the conventional piston ring groove 20A measurement work as described above. In the settling process of the piston 20, a lot of manpower and work time were required. In particular, a large number of errors were involved in the stacking process of the block 35, so that the measured value obtained from the piston ring groove 20A Problems such as lowering of reliability have occurred.

The pedestal for measuring the piston ring groove according to the present invention is devised to solve the above-described problems, and an object of the present invention is to allow the piston to be settled by using an upper portion of the cylindrical body, and to reduce the internal space of the cylindrical body. By using the connecting rod to be accommodated to facilitate the dimensional measurement of the groove by the height gauge, while also providing a means for increasing the reliability of the measurement work.

An object of the present invention as described above, the lower surface is open, the lower surface and the upper surface are each parallel to the upper surface of the cylindrical body having a height that exceeds the length of the connecting rod coupled to the lower portion of the piston of the connecting rod A piston having a rectangular opening is formed so that a large end is inserted, and symmetrically formed extensions having semicircular shapes are provided on both sides of the central portion of the opening so as to provide a rotational space with respect to the small end of the connecting rod. By providing a pedestal for ring groove measurement.

Hereinafter, the piston ring groove measuring base according to the present invention will be described in detail with the accompanying drawings.

2 is a perspective view showing the piston ring groove measuring base 40 according to the present invention, and FIG. 3 is a cross-sectional view of the AA line of FIG. 2, and the piston ring groove measuring base 40 according to the present invention. Is a structure in which a rectangular opening 5 is formed on the upper surface of the cylindrical body 10 whose lower part is opened, and semicircular extensions 5A are symmetrically formed on both sides of the center of the opening 5, respectively. Is done.

Here, the cylindrical body 10 accommodates the connecting rod 25 by the inner space, and supports the lower part of the piston 20 by the upper surface. The upper and lower surfaces of the cylindrical body 10 are precisely parallel to each other. In addition, the height of the connecting rod 25 is higher than the length of the connecting rod 25 to accommodate the connecting rod 25.

And the opening part 5 formed in the upper surface of the cylindrical body 10 has the large end part of the connecting rod 25 connected to the lower part of the piston 20 through the said opening part 5 in the inside of the right cylinder 10; In order to be positioned, it is formed to be somewhat larger than the size of the large end of the connecting rod 25 coupled to the lower portion of the piston 20 that requires measurement, so that insertion and withdrawal can be made quickly and easily.

In addition, an extension portion 5A having a semicircular shape is formed on both sides of the central portion of the opening portion 5, and the extension portion 5A rotates the piston 20 by 90 degrees with the connecting rod 25 inserted therein. In the process of bringing the lower portion of the piston 20 and the upper portion of the cylindrical body 10 in close contact with each other to achieve a rotational space of the small end formed at the coupling portion between the piston 20 and the connecting rod 25, In order to prevent obstacles caused by contact with the small end, it should have a radius larger than the radius of rotation of the small end.

The operation and effects of the piston ring groove measuring base 40 according to the present invention having the above-described configuration will be described with reference to FIG. 4.

In order to measure the butterfly and the distance of the piston ring groove 20A continuously formed on the outer circumferential surface of the piston 20 by the piston ring groove measuring support 40 according to the present invention, the present invention is a surface plate 30. After placing the upper portion of the rod, the connecting rod 25 connected to the piston 20 is inserted into the cylindrical body 10 through the opening 5 on the upper surface of the cylindrical body 10.

At this time, since the cylindrical body 10 has a height that exceeds the length of the connecting rod 25, the large end of the connecting rod 25 inserted through the opening 5 has a state spaced apart from the surface plate.

After the completion of the above process, the piston 20 is rotated 90 degrees in the left or right direction from the top of the present invention by using the enlarged portion 5A in the state of holding the piston 20. As the lower both sides of the piston 20 are separated from the opening 5, the lower portion of the piston 20 and the upper surface of the cylindrical body 10 are correctly attached to each other. Accordingly, the piston ring groove 20A formed on the outer circumferential surface of the piston 20 is formed. It is to be exactly parallel from the upper surface of the surface plate (30).

In addition, after the completion of this process, the tip of the height gauge 50 is in close contact with one side of the piston ring groove 20A requiring the tip 50A to be measured, as in the case of the conventional piston ring groove 20A measurement operation. After the height of the height gauge 50 is appropriately adjusted, the tip 50A of the height gauge 50 is brought into contact with the numerical input device 55 to input the measured value.

Subsequently, the measurement operation for the piston ring groove 20A is repeated in accordance with the above-described process, and the ground height at each point of the piston ring groove 20A is input to the numerical input device 55, and the piston displayed on the indicator 60 is continued. The precision of the dimension and shape of the piston ring groove 20A is measured through the ground clearance of the ring groove 20A or the deviation between each ground clearance.

On the other hand, in the case of the piston 20 in which the connecting rod 25 is separated, the lower portion of the piston 20 is directly placed on the upper surface of the cylindrical body 10 to measure the piston ring groove 20A as described above.

In this process, the piston ring groove measuring base 40 according to the present invention has the height gauge 50 by allowing the piston 20 including the connecting rod 25 to be directly seated without a combination of supporting members such as the block 35. It is to be able to quickly and easily measure the piston ring groove (20A) by.

As described above, in the piston ring groove measuring base 40 according to the present invention, the piston 20 including the connecting rod 25 is settled by a simple operation without a combination operation of the block 35 requiring high skill. In the measurement process, it is possible to perform a quick measurement without consuming manpower, and as the piston 20 is placed parallel to the surface plate without the flow of the piston 20, the measurement on the piston ring groove 20A can be performed with high precision. It can be effective.

Claims (1)

The lower part is opened, and the lower part and the upper surface are parallel to each other, and a connecting rod is formed on the upper surface of the cylindrical body 10 having a height that exceeds the length of the connecting rod 25 coupled to the lower part of the piston 20. A rectangular opening 5 is formed so that the large end of 25 is inserted, and an enlarged part having a semicircular shape so as to provide a rotation space with respect to the small end of the connecting rod 25 on both sides of the center of the opening 5. A piston ring groove measuring pedestal, characterized in that the structure consisting of symmetrical formation of each 5A).