KR200455529Y1 - Testing apparatus for turbine shaft expansion sensor - Google Patents

Abstract

The present invention relates to an expansion sensor performance tester capable of measuring the performance of a large diameter sensor as well as a small diameter sensor.

The main configuration of the present invention is a base; First and second support plates detachably fixed apart from each other on the base; A sensor fixing bracket detachably coupled to the first support plate; Digimatic micrometer fixing bracket integrally formed or detachably coupled to the second support plate; And a digital micrometer fixed to the bracket for fixing the digital micrometer, including a sliding shaft, and a disc coupled to an end of the shaft to detect the performance of the sensor, wherein the first support plate has a predetermined length of the through slot. It is formed, characterized in that the zero setting is made in the state that the screw is screwed to the base through the through slot.

Turbine, expansion, sensor, zeroing, slot, guide groove, bracket

Description

Performance tester for turbine shaft expansion sensors {TESTING APPARATUS FOR TURBINE SHAFT EXPANSION SENSOR}

The present invention relates to an expansion sensor performance tester capable of measuring the performance of a large diameter sensor as well as a small diameter sensor.

Conventional turbine shaft expansion sensor refers to a field sensor that is used in the system to maintain the alarm generation and output by monitoring the expansion state of the shaft during start-up and normal operation of the steam turbine as a displacement sensor.

Therefore, the expansion sensor performance tester can diagnose the performance of the large-diameter sensor and determine the lifespan so as to grasp the purchase frequency of the expensive axis expansion sensor to reduce maintenance costs.

The expansion sensor performance tester (TK3-2) shown in Fig. 1 is used for the performance test of the displacement sensor with a diameter of 5 mm to 16 mm, but the main turbine shaft expansion sensor (relative expansion, shaft expansion) is 25 mm and 50 mm. As the performance of the displacement sensor cannot be inspected, it is being replaced after purchasing the large-diameter sensor without checking the performance during the planned preventive maintenance work.

Accordingly, it is an object of the present invention to provide an expansion sensor performance tester capable of measuring the performance of a large diameter sensor as well as a small diameter sensor.

The above object is, the base 10; First and second support plates (20,30) detachably fixed apart from one another on the base; A sensor fixing bracket (40) detachably coupled to the first support plate (20); Digimatic micrometer fixing bracket (50) integrally formed or detachably coupled to the second support plate (30); And a digimatic micrometer 70 which is fixed to the digimatic micrometer fixing bracket 50 and includes an axis for sliding and a disc coupled to an end of the axis to grasp the performance of the sensor. In the performance testing device for
The first support plate 20 has a through slot 22 having a predetermined length, and a zero point is set in a state where the screw is screwed to the base 10 through the through slot 22. The base has guide grooves 12 formed in the longitudinal direction, and guide protrusions 21 and 31 are formed on the rear surfaces of the first and second support plates 20 and 30 so that the guide protrusions slide into the guide grooves. ,
The sensor fixing bracket 40 includes a support hole 42 for fixing the sensor in the center, a gap 46 for adjusting the size of the support hole 42, a bolt hole 44 crossing the gap, and In the state inserted into the bolt hole 44, the nut is coupled to one end and the Q lever bolt 60 is formed to tighten or loosen the support hole by turning the rotary lever 61 installed at the other end,
The digimatic micrometer fixing bracket 50 includes a support hole 52 for fixing the digityl micrometer 70 at the center, a gap 56 and a gap 56 for adjusting the size of the support hole 52. Is achieved by a performance inspection device for a turbine shaft expansion sensor having a threaded hole 54 across it.

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In addition, the digimatic micro 70 may include an LCD display unit, and a portion where the LCD display unit and an operation button are formed may be rotated about the axis.

According to the above structure, it is possible to move stably and easily without shaking the sensor fixing bracket, which has the advantage of easy zero setting.

In addition, by varying the diameter of the support hole while keeping the size of the sensor fixing bracket constant, not only a small diameter but also a large diameter sensor, which is an axial expansion sensor, can be sufficiently accommodated. Therefore, replacing expensive displacement sensors regardless of performance during planned preventive maintenance only replaces deteriorated sensors, thereby reducing maintenance costs and providing accurate moving distance of the expansion sensor, thereby improving reliability.

In addition, the accurate movement distance of the straight line can be measured simply and efficiently by using a digimatic micrometer having an LCD display.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention.

Figure 2 is a block diagram showing the expansion sensor performance testing apparatus according to the present invention, Figure 3 is a photographic image showing an assembled state.

Referring to FIG. 2, the guide groove 12 is formed in the longitudinal direction of the base 10, and the support plates 20 and 30 are fixed at a predetermined distance apart therefrom.

The support plate 20 is a plate for supporting the sensor fixing bracket 40 for fixing the expansion sensor, and a guide protrusion 21 slidably fitted into the guide groove 12 of the base 10 on the rear surface thereof. Recesses 25 and 26 are formed to protrude and to be fitted with brackets 40 on opposite sides in the longitudinal direction. In addition, through slots 22 are formed on both sides of the upper surface in the width direction, and the support plate 20 is fixed to the base 10 by screwing the screws 24 to the base 10 through the through slots 22. .

In addition, the support plate 30 is a plate for supporting the digimatic micrometer fixing bracket 50 for fixing the digimatic micrometer 70, and slides in the guide groove 12 of the base 10 on the rear surface. The guide protrusion 31 to be fitted is protruded, and a recess 36 to which the bracket 50 is fitted is formed on the side opposite to the support plate 20. In addition, through holes 32 are formed at both sides of the upper surface in the width direction, and the support plate 30 is fixed to the base 10 by screwing the screw 34 to the base 10 through the through holes 32. .

According to this structure, since the through slot 22 is formed in the support plate 30 to a fixed length, the support plate 20 temporarily fixes the screw 24 to the base 10 in a state where the support plate 20 is completely fixed to the base 10. By setting the zero point by moving the support plate 20 in the fixed state and the screw 24 is completely coupled, it is easy to set the zero point. In addition, since the guide groove 12 of the base 10 and the guide protrusion 21 of the support plate 20 are fitted in the zero setting, the zero setting can be quickly performed without shaking from side to side.

The sensor fixing bracket 40 is formed in the support hole 42 for fixing the sensor at the center, and a gap 46 is formed to adjust the size of the support hole 42, and a bolt across the gap 46 is provided. A ball 44 is formed.

The support holes 42 can be formed in a variety of sizes, for example a diameter of 27.2 mm for sensors of 25 mm aperture or a diameter of 51.1 mm for sensors of 50 mm holes. Accordingly, the sensor fixing bracket 40 having the support holes 42 having different diameters may be prepared, and the bracket 40 may be replaced according to the sensor.

In addition, the Q-hole bolt 60 may be fitted to the bolt hole 44. Q-lever bolt 60 is the nut 62 is coupled to one end of the body and the rotary lever 61 is installed at the other end to insert the body into the bolt hole 44 and then tighten and tighten the nut 62, and finally Turn the rotary lever 61 to tighten it firmly. In this way, by applying the Q lever bolt 60, the sensor can be tightened or loosened quickly.

Digimatic micrometer fixing bracket 50 is formed in the support hole 52 for fixing the digityl micrometer 70 in the center, the gap 56 is formed to adjust the size of the support hole 52 A screw hole 54 is formed across the gap 56.

Unlike the sensor fixing bracket 40, the size of the support hole 52 is constant, and the screw hole 54 is coupled to the screw hole 54 so that the digital micro 70 inserted in the support hole 52 can be firmly tightened. Tighten.

Preferably, the digimatic micrometer fixing bracket 50 may be manufactured integrally with the support plate 30.

Digimatic micro 70 includes a shaft 73 slidably protrudes from the body and a disc 72 detachably coupled to the end of the shaft 73. In the state where the disc 72 is not engaged, the neck 71 of the front end of the main body is inserted into the support hole 52 of the bracket 50 and tightened with the screw 56, and then the disc 72 is attached to the end of the shaft 73. To be fixed in place. Here, the disc 72 is to grasp the performance of the shaft expansion sensor can be made of the same material as the turbine shaft, for example, can be produced about 100mm in diameter, 6mm in thickness.

Digimatic micro 70 is a battery is built in the body and the LCD panel and the operation button formed part can be rotated, the operator can operate in any direction.

According to the above structure, it is possible to move stably and easily without shaking the sensor fixing bracket, so that the zero point setting is easy. In addition, by varying the diameter of the support hole while keeping the size of the sensor fixing bracket constant, not only a small diameter but also a large diameter sensor, which is an axial expansion sensor, can be sufficiently accommodated. Therefore, replacing expensive displacement sensors regardless of performance during planned preventive maintenance only replaces deteriorated sensors, thereby reducing maintenance costs and providing accurate moving distance of the expansion sensor, thereby improving reliability. In addition, it is possible to measure the exact moving distance of a straight line simply and efficiently using a digitic micrometer with an LCD display.

In the above described an embodiment of the present invention as an example, various changes are possible at the level of those skilled in the art. Therefore, the present invention should not be construed as limited to the above embodiments, but should be interpreted by the claims set forth below.

1 is a photographic image showing a conventional expansion sensor performance tester.

Figure 2 is a block diagram showing an expansion sensor performance testing apparatus according to the present invention.

3 is a photographic image showing the assembled state.

Claims (5)

delete delete delete A base 10; First and second support plates (20,30) detachably fixed apart from one another on the base; A sensor fixing bracket (40) detachably coupled to the first support plate (20); Digimatic micrometer fixing bracket (50) integrally formed or detachably coupled to the second support plate (30); And a digimatic micrometer 70 which is fixed to the digimatic micrometer fixing bracket 50 and includes an axis for sliding and a disc coupled to an end of the axis to grasp the performance of the sensor. In the performance testing device for The first support plate 20 has a through slot 22 having a predetermined length, and a zero point is set in a state where the screw is screwed to the base 10 through the through slot 22. The base has guide grooves 12 formed in the longitudinal direction, and guide protrusions 21 and 31 are formed on the rear surfaces of the first and second support plates 20 and 30 so that the guide protrusions are inserted into the guide grooves. Slide, The sensor fixing bracket 40 includes a support hole 42 for fixing the sensor in the center, a gap 46 for adjusting the size of the support hole 42, a bolt hole 44 crossing the gap, and In the state inserted into the bolt hole 44, the nut is coupled to one end and the Q lever bolt 60 is formed to tighten or loosen the support hole by turning the rotary lever 61 installed at the other end, The digimatic micrometer fixing bracket 50 includes a support hole 52 for fixing the digityl micrometer 70 at the center, a gap 56 and a gap 56 to adjust the size of the support hole 52. A screw shaft (54) across the) is characterized in that the performance testing device for a turbine shaft expansion sensor. The method according to claim 4, The Digimatic Micro 70 has an LCD display unit, and the LCD display unit and the control button formed portion is a turbine shaft expansion sensor performance test device, characterized in that rotated about the axis.

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