KR200448699Y1 - a bending measurement device of the shaft - Google Patents

Abstract

The present invention relates to a large shaft bending measuring apparatus capable of easily and easily measuring the bending of a large shaft, the apparatus for measuring the bending of a large shaft, the base having a vertical frame on one side of the upper surface; An angle indicator installed on the vertical frame and provided with a first driving shaft; A chuck installed on the first drive shaft to rotate by driving an angle indicator and holding one end of the large shaft; A support member installed on the base to support the other end of the shaft; A “U” shaped guide rail installed parallel to the shaft at the base; A conveying member installed to be conveyed to the guide rail; A laser sensor mounted on the transfer member and measuring a bending of the shaft; And a computer installed to be spaced apart from the base to control the angle indicator and the transfer member and to display a value measured by the laser sensor.

Shaft, sensor, laser, feed, angle, indicator, guide rail, computer

Description

Large bending bending device {a bending measurement device of the shaft}

The present invention relates to a large shaft bending measuring device that accurately rotates a large shaft at an angle using an angle indicator, reduces measurement errors by measuring bending using a laser sensor, and also displays a measured value in real time. .

In general, a straight gauge of a large shaft, that is, a bending test, is measured using a dial gauge.

In more detail, the dial gauge is mounted to the shaft center of the shaft, and after zero setting, the dial gauge is moved in the axial direction to measure the bending of the shaft, but the probe of the dial gauge is in direct contact with the shaft. Due to the mechanical friction, the reliability of the measured value was degraded, and the problem of damage to the surface of the shaft was inherent.

In the circumferential measurement, after dividing into four directions (90 °, 180 °, 270 °, 360 °) and marking, the circumferential bend was measured by placing a probe of the dial gauge at the marking position. It was difficult to find the measuring point.

Therefore, the present invention has been proposed to solve the above problems according to the prior art, the object of the present invention is to rotate the large shaft by a predetermined angle by the angle indicator, the laser sensor is automatically transferred by the conveying means It is an object of the present invention to provide a large shaft bending measuring device that can easily measure a shaft, accurately measure the bending of a large shaft without errors, and display the measured value in real time to an operator.

Large shaft bending measuring apparatus according to the present invention for achieving the above object is a device for measuring the bending of a large shaft, the base having a vertical frame on one side of the upper surface; An angle indicator installed on the vertical frame and provided with a first driving shaft; A chuck installed on the first drive shaft to rotate by driving an angle indicator and holding one end of the large shaft; A support member installed on the base to support the other end of the shaft; A “U” shaped guide rail installed parallel to the shaft at the base; A conveying member installed to be conveyed to the guide rail; A laser sensor mounted on the transfer member and measuring a bending of the shaft; And a computer installed to be spaced apart from the base to control the angle indicator and the transfer member and to display a value measured by the laser sensor.

The present invention has the effect that the laser sensor can measure the circumferential bending of the three- or four-divided shaft by rotating the chuck that is holding the shaft precisely by a predetermined angle.

In addition, the use of a laser sensor is also a problem in the use of a conventional dial gauge has the effect of reducing the measurement error.

On the other hand, the conveying means for moving the angle indicator and the laser sensor is operated by the control of the computer has the effect that it is possible to measure the bending of the shaft simply and easily.

Then, the computer displays the bending measurement value of the shaft, so that the operator can know the bending of the shaft in real time.

Hereinafter, with reference to the accompanying drawings, a large shaft bending measuring apparatus according to the present invention is as follows.

1 is a front view showing a large shaft bending measuring apparatus according to the present invention, Figure 2 is a side view showing a large shaft bending measuring apparatus according to the present invention, Figure 3 is a view showing a support member according to the present invention, Figure 4 Is a view showing another embodiment of the support member rotating body according to the present invention, Figure 5 is a view showing another embodiment of the support member rotating body according to the present invention, Figure 6 is an enlarged conveying member of FIG. 7 is a view showing another embodiment of the transfer member according to the present invention.

1 to 2, the large shaft bending measuring apparatus according to the present invention is large, the base 10, the angle indicator 20, the chuck 30, the support member 40, the guide rail 50 , A transfer member 60, a laser sensor 70, and a computer 80.

The base 10 has a rectangular shape and includes a vertical frame 11 installed on one side of the upper surface.

The angle indicator 20 is provided with a first drive shaft 21 connected to the chuck 30, it is fixed to the vertical frame (11).

The angular indicator 20 rotates the chuck 30 under the control of the computer 80, and the chuck 30 is chucked by 90 ° or 120 ° to facilitate the bending measurement of the shaft S held by the chuck 30. Rotate 30.

The chuck 30 has a central portion connected to the first driving shaft 21 to rotate by driving the angle indicator 20, and grips one end of the large shaft S.

Such, the chuck 30 is a configuration in which at least three or more jaws 31 are slidably gripped by the shaft S, and such a configuration is generally omitted.

The support member 40 is installed on the other side of the base 10, ie, on the opposite side of the vertical frame 11, to support the free end side of the shaft S held by the chuck 30.

As shown in FIG. 3, the support member 40 is installed on the other side of the upper surface of the base 10 and has a supporting plate 42 having at least one or more first bolts 41 formed vertically on the upper surface. And a housing having a lower space corresponding to the first bolt 41 and having a second bolt 43 having a thread formed in a direction opposite to that of the first bolt 41 and having an upper surface opening. 45 is installed between the first bolt 41 and the second bolt 43 to connect the first bolt 41 and the second bolt 43, and the housing 45 is moved up or down during rotation. The nut 46 and the rotating body 47 is rotatably installed in the receiving space 44 of the housing 45 and partially exposed to support the other end of the shaft S.

Here, the nut 46 is fastened to both sides of the first bolt 41 and the second bolt 43, respectively, the first bolt 41 and the second bolt ( 43 is moved to the inner side of the nut 46, the height of the housing 45 is lowered, and when the reverse rotation, the first bolt 41 and the second bolt 43 is moved to the outside of the nut 46 to the housing ( The height of 45) is raised.

That is, the rotating body 47 installed in the housing 45 is in contact with the bottom of the other end of the shaft (S) held by the chuck 30 to maintain the shaft (S) horizontal.

As shown in FIG. 3, the rotating body 47 includes a rotating shaft 47a rotatably installed in the housing 45 and a roll 47b provided on the rotating shaft 47a and in contact with the shaft S. As shown in FIG. 4, the shaft 47c is installed on the housing 45 and the bearing 47d is installed on the shaft 47c to be in contact with the shaft S. Can be done.

As shown in FIG. 5, the rotating body 47 is preferably formed in a pair so that the circular shaft S can be stably supported.

The guide rail 50 has a rectangular "U" shape and is installed on the base 10 to be parallel to the shaft S.

That is, the lower side of the shaft (S) is installed.

The conveying member 60 is installed to be conveyed to the guide rail 50 and is reciprocally conveyed by the control of the computer 80.

As shown in FIG. 6, the transfer member 60 includes a plate including a horizontal portion 61 made of a flat plate and a pair of vertical portions 62 protruding from both sides of the lower portion of the horizontal portion 61. 63), wheels 64 rotatably installed on the left and right sides of the pair of vertical parts 62 and seated on the guide rails 50, and a second driving shaft 65 connected to the center of the wheels 64. It is provided, and is provided in the lower portion of the horizontal portion 61 of the plate 63 is composed of a motor 66 for rotating the wheel 64 forward / reverse under the control of the computer (80).

Meanwhile, as illustrated in FIG. 7, the transfer member 60 may include a transfer block 67 installed on the guide rail 50 so as to be transported by a user's manual operation.

The laser sensor 70 is mounted on the transfer member 60, measures the bending of the shaft S, and transmits the measured value to the computer 80.

Here, since the laser sensor 70 is preferably located on one side of the shaft (S), the "┏" type bar 68 is further added to the plate 63 or the transfer block 67 of the transfer member 60. It is preferred that the laser sensor 70 is provided at the tip of the "┏" type bar 68.

The computer 80 is installed to be spaced apart from the base 10, and is connected by wire (not shown) or wirelessly to control the driving of the angle indicator 20 and the transfer member 60 motor 66, and the laser. The sensor 70 receives the measured value and displays it to the worker.

These computers are generally widely used configurations and will not be described in detail.

Referring to the state of use of the large shaft bending measuring apparatus according to the present invention configured as described above are as follows.

First, one end of the shaft S to be inspected is gripped by manipulating the jaw of the chuck 30.

Then, the nut 46 of the support member 40 is reversely operated.

Then, the first bolt 41 and the second bolt 43, which are fastened to the nut 46 and have threads formed in different directions, move to be spaced apart from each other. That is, the housing 45 moves up and down by moving outward from the center of the nut 46.

At this time, the roll 47b of the rotating body 47 rotatably installed in the accommodation space 44 of the housing 45 is in contact with the bottom of the other side of the shaft S to support the other side of the shaft S. This causes the shaft S to be horizontal.

Then, when operating the computer 66 of the transfer member 60 by operating the computer 80, the wheel 64 connected to the second drive shaft 65 of the motor 66 is rotated to the transfer member 60 Is carried on the guide rail (50).

That is, the transfer member 60 is transferred from one side of the shaft (S) to one side gripped by the chuck 30, and thus the laser sensor 70 installed on the transfer member 60 is the shaft (S). The bending of one side is measured and the measured value is transmitted to the computer 80.

Subsequently, the computer 80 is operated to drive the angle indicator 20 to rotate the chuck 30 holding the shaft S 90 degrees in a clockwise direction, and then the motor of the transfer member 60. By driving the 66 to the conveying member 60 is transported from one side to the other side, that is to the free end on the guide rail (50).

Then, the laser sensor 70 installed in the transfer member 60 measures the bending of another side of the shaft (S) and transmits the measured value to the computer 80.

The bending of the shaft S is measured by rotating the shaft S by 90 ° in the same manner as described above.

These measurements are displayed to the operator by computer 80 to inform the bending state of the shaft.

1 is a front view showing a large shaft bending measuring apparatus according to the present invention,

Figure 2 is a side view showing a large shaft bending measuring device according to the present invention,

3 is a view showing a support member according to the present invention,

4 is a view showing another embodiment of the support member rotating body according to the present invention,

5 is a view showing another embodiment of a support member rotating body according to the present invention,

6 is an enlarged view of the conveying member of FIG. 2;

7 is a view showing another embodiment of the transfer member according to the present invention.

<Explanation of symbols for the main parts of the drawings>

S: Shaft 10: Base 20: Angle Indicator

30: chuck 40: support member 41: first bolt

43: second bolt 45: housing 46: nut

47: rotating body 47a: rotating shaft 47b: roll

47c: shaft 47d: bearing 50: guide rail

60: transfer member 63: plate 64: wheels

66: motor 67: transfer block 70: laser sensor

80: computer

Claims (6)

In the device for measuring the bending of the large shaft (S), A base 10 having a vertical frame 11 on one side of an upper surface thereof; An angle indicator 20 installed at the vertical frame 11 and provided with a first driving shaft 21; A chuck 30 installed on the first drive shaft 21 to rotate by driving the angle indicator 20 and holding one end of the large shaft S; A support member 40 installed on the base 10 to support the other end of the shaft S; A “U” shaped guide rail 50 installed parallel to the shaft S in the base 10; A plate 63 installed to be transported to the guide rail 50, a wheel 64 rotatably installed below the plate 63, and a computer installed below the plate 63, which will be described later. A conveying member (60) comprising a motor (66) for forward and reverse rotation of the wheel (64) by control of (80); A laser sensor 70 mounted on the transfer member 60 to measure bending of the shaft S; And A computer 80 installed to be spaced apart from the base 10 to control the angle indicator 20 and the transfer member 60 and to display a value measured by the laser sensor 70; Shaft bend measuring device. The method according to claim 1, The support member 40 is A support plate 42 installed on an upper surface of the base 10 and having at least one first bolt 41 disposed on an upper surface thereof; A housing 45 corresponding to the first bolt 41 at a bottom thereof, and having a second bolt 43 formed with a thread in a direction opposite to the first bolt 41; A nut 46 installed between the first bolt 41 and the second bolt 43 to connect the first bolt 41 and the second bolt 43 to lift or lower the housing 45 during rotation. ); And And a rotating body (47) rotatably installed at the housing (45) to support the other end of the shaft (S). The method according to claim 2, The rotating body 47 A rotating shaft 47a rotatably installed in the housing 45; Large shaft bending measurement device, characterized in that formed on the rotary shaft (47a) made of a roll (47b) in contact with the shaft (S). The method according to claim 2, The rotating body 47 A shaft 47c installed in the housing 45; A large shaft bending measuring device, characterized in that formed in the shaft (47c) made of a bearing (47d) in contact with the shaft (S). The method according to claim 2, The rotating body 47 is a large shaft bending measuring apparatus, characterized in that consisting of a pair to support a circular shaft (S). delete

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