KR200446675Y1 - Sensor capability testing machine for measuring active forces of valve stem - Google Patents

Abstract

The present invention relates to a sensor performance test apparatus for measuring the force of the valve stem to determine the performance and suitability of the sensor in a state in which a sensor for measuring the operating force, such as rotational force and the pressing force is mounted on the valve stem.

The present invention provides a valve stem model having an actual valve stem shape, a base member on which the valve stem model is installed, a valve stem model housing installed on the base member to surround a portion of the valve stem model, and A drive motor coupled to the valve stem model to rotate the valve stem model, and a moving tube which is helically coupled to the spiral portion of the valve stem model to move in and out of the valve stem model housing while sliding when the valve stem model rotates; A rotational resistance generating unit installed on the base member spaced apart from the outer circumferential surface of the valve stem model so as to generate a rotational resistance while interfering with the interference protrusion when the valve stem model is rotated, and a distal end portion of the movable tube on the base member. Installed in a spaced state so that the movement when the valve stem model rotates It is interference with the entry comprises a pressing force generating unit for to produce a pressing force.

Valve stem, torque, pressing force, force, sensor, performance, test

Description

Sensor capability testing machine for measuring active forces of valve stem}

The present invention relates to a sensor performance test apparatus, and in particular, the sensor performance test for measuring the force of the valve stem to determine the performance and suitability of the sensor in the state of mounting the sensor to measure the acting force, such as rotational force and the pressing force to the valve stem model Relates to a device.

The valve device, which is installed in major safety brake devices in power plants and the like, blocks or regulates the flow of working fluid. The valve device includes a valve disc, a valve seat, and a valve stem. Then, as the valve stem is raised or lowered by the driving force of the motor providing power, the valve disc is opened or closed by raising or lowering the valve disc from the valve seat.

On the other hand, since force acts on the valve stem in the rotational direction and the axial direction, damage occurs to the valve stem after use for a predetermined period. Accordingly, by installing a predetermined sensor on the surface of the valve stem and measuring the force acting on the valve stem to check whether the valve stem is abnormal, damage to the valve device due to overload is prevented.

The force acting on the valve stem is divided into torsion along with rotation and axial thrust. In addition, there are two types of sensors for measuring the force acting on the valve stem, a fixed type and a removable type. By the way, the fixed type sensor is integrally fixed to the threadless smooth portion of the valve stem, and it takes a long time to fix the fixed type sensor integrally to the valve stem, and precise work to accurately adhere to the outer circumferential surface of the valve stem. This is a disadvantage required. In addition, the detachable sensor is difficult to know how the performance is similar to the stationary sensor compared to the stationary sensor, most of the problem is that the force acting on the valve stem is not accurately measured due to the inferior accuracy compared to the stationary sensor. Therefore, there is a demand for a device capable of testing a performance difference from an existing sensor after designing a fixed sensor and a removable sensor under conditions similar to those of the actual one, and confirming the performance thereof.

The present invention has been made in view of the necessity of the sensor performance test apparatus as described above, and its purpose is to measure the rotational force and the pressing force acting on the valve stem under conditions corresponding to the actual conditions in which the fixed sensor and the detachable sensor are mounted. An object of the present invention is to provide a sensor performance test apparatus for measuring the force of a valve stem capable of comparatively testing the performance of a sensor and easily determining the suitability of a sensor applicable to the valve stem.

The present invention for achieving the above object, the valve stem model having the form of the actual valve stem, the base member is installed the valve stem model, is installed on the base member to surround a portion of the valve stem model A valve stem model housing, a drive motor coupled to the valve stem model to rotate the valve stem model, and an inner circumferential surface of the valve stem model spirally coupled to the valve stem model, while the valve stem model housing slides while the valve stem model is rotated. A moving resistance pipe which enters and exits from the base member and is spaced apart from an outer circumferential surface of the valve stem model on the base member to generate a rotational resistance while the interference protrusion interferes with the rotation of the valve stem model, and the base. The bell is provided on the member spaced apart from the distal end of the moving tube During the rotation of the system model is the interference with the Lee Dong - kwan entry comprises parts of the pressing force which occurs to generate a pressing force. Here, the valve stem model is provided with a threaded spiral portion, a sensor mounting portion made of a smooth surface to be mounted to the sensor for measuring the action force of the rotation and pressure, and the interference projection protruding between the spiral portion and the sensor mounting portion It consists of a structure.

In addition, the rotation resistance generating portion is mounted on the base member and the center portion is formed in the through hole toward the outer circumferential surface of the valve stem model, and inserted into the through hole of the body so that the interference projection of the valve stem model And a portion of the interference hole protruding from the through hole, the first elastic member installed in the through hole of the body to press the interference hole toward the interference protrusion, and the first elastic member not to be separated from the through hole of the body. It may include a stopper member for closing the rear end of the through hole.

In particular, the stopper member, the support for supporting the first elastic member in the through hole, the fixing plate is fixed and coupled to the rear end of the body, and the fixing plate is spaced apart from the rear end of the body It can be made to include a control bolt coupled to enable adjustment to adjust the pressing force of the interference hole by the first elastic member.

In addition, the pressing force generating unit, a pair of the fixed body is installed on the base member spaced apart in the direction orthogonal to the axial direction of the valve stem model, the portion facing each other so that the moving tube can enter and exit With a pair of interference plates spaced apart in the. Tightening bolts for coupling the interference plates to the fixing body so as to adjust the distance between the interference plates, and a second to elastically connect the fixing body and the interference plate to allow the interference plate to elastically move relative to the fixing body It may include an elastic member.

In particular, it is preferable that an end portion of the interference plate into which the moving tube enters is formed of a first sloped surface, and an end portion of the movable tube facing the first sloped surface is formed of a second sloped surface.

In addition, a movement guide groove is formed at an upper end of the movement pipe, and a movement guide protrusion is inserted into the movement guide groove to guide the movement of the movement pipe above the inner circumferential surface of the valve stem model housing. The moving tube may be configured to enter and exit the valve stem model housing while moving in a straight line from the valve stem model housing.

The present invention configured as described above, since the performance of the sensors for measuring the force of the rotation and pressure on the valve stem can be confirmed in advance before applying to the actual valve stem, it is easy to determine the reliability and suitability of the sensor. It has an effect.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. However, the following embodiments are provided to those skilled in the art to fully understand the present invention can be modified in various forms, the scope of the present invention is limited to the embodiments described below It doesn't happen.

1 is a side view and a partially enlarged view of a partial cross-section of the sensor performance test apparatus for measuring the force of the valve stem according to an embodiment of the present invention, Figure 2 is a plan view of the embodiment of FIG.

As shown in the figure, the sensor performance test apparatus for measuring the action force of the valve stem according to the present embodiment, for example, the force applied to the valve stem during operation of the motor drive valve installed in the main safety brake device in a power plant, etc. In order to compare the performance of the sensor to measure has a configuration installed on the ground by a base member 10 at a certain height.

On the base member 10, a valve stem model 20 having a material and a shape corresponding to the actual valve stem is installed, and the torque and the pressing force are applied while the sensor to be tested is mounted on the valve stem model 20. A thrust is generated to measure the performance of the sensor. At this time, the sensor tested by the test apparatus of the present invention includes both a fixed sensor and a removable sensor, one or more sensors to be tested on the valve stem model 20, the removable sensor and the fixed sensor as possible It is preferable to test by mounting together. On the base member 10, not only the valve stem model 20, but also the valve stem model housing 30, the drive motor 40, the moving tube 50, the rotation resistance generator 60, and the pressing force generator 70 are installed. In detail, it is as follows.

The valve stem model 20 of the present embodiment, as illustrated in FIG. 3, has a spiral portion 21 in which a thread is formed like an actual valve stem, and a fixed sensor S1 for measuring an action force such as a rotational force and a pressing force. ) And a sensor mounting part 22 formed of a smooth surface so that the removable sensor S2 can be mounted together, and an interference protrusion protruding from the spiral part 21 and the sensor mounting part 22 to the outer peripheral surface of the valve stem model 20. It consists of 23.

The valve stem model housing 30 is a component surrounding a portion of the valve stem model 20, and the drive motor 40 is a component connected to the valve stem model 20 to rotate the valve stem model 20. In this embodiment, the drive motor 40 is coupled to the rotary shaft 90, the drive shaft 41 is installed in parallel to the upper surface of the base member 10 via the coupling 80, the rotary shaft 90 ) Is coupled to the valve stem model 20, the valve stem model 20 is rotated by the driving force of the drive motor 40.

The moving tube 50 is helically coupled to the spiral portion 21 of the valve stem model 20 to slide into and out of the valve stem model housing 30 while sliding when the valve stem model 20 rotates. In particular, when the valve stem model 20 rotates, the moving tube 50 is rotated in the valve stem model housing 30 so that the moving tube 50 can enter and exit the valve stem model housing 30 while being wrapped by the valve stem model housing 30. It is not bound together. That is, as shown in Figure 4, the movement guide groove 51 is formed at a predetermined depth in the upper end of the movement pipe 50, and is inserted into the movement guide groove 51 above the inner circumferential surface of the valve stem model housing (30) The movement guide protrusion 31 which guides the movement of the copper pipe 50 is formed, and when the valve stem model 20 rotates, the moving tube 50 moves in a straight line in the valve stem model housing 30 while the valve stem is moved. It enters and exits into the model housing 30.

The rotation resistance generating unit 60 has a rotational resistance as the interference protrusion 23 of the valve stem model 20 interferes to measure the torque value applied to the valve stem model 20 when the valve stem model 20 is rotated. It is installed on the outer circumferential surface of the valve stem model 20 so as to be spaced apart. That is, as illustrated in FIG. 5, the rotation resistance generating unit 60 is mounted on the base member 10, and a body 61 in which a through hole 61 a is formed in the center portion toward the outer circumferential surface of the valve stem model 20. And an interference hole 62 protruding from the through hole 61a while being inserted into the through hole 61a of the body 61 so that the interference protrusion 23 of the valve stem model 20 can be interfered with. The first elastic member 63 is installed in the through hole 61a of the body 61 and presses the interference hole 62 toward the interference protrusion 23, and the first elastic member is formed from the through hole 61a of the body 61. It is comprised by the stopper member 64 which closes the rear end part of the through-hole 61a so that the member 63 may not separate. The stopper member 64 includes a support 64a for supporting the first elastic member 63 in the through hole 61a, and the support 64a is fixed to the rear end of the trunk 61. The fixed plate 64b to be coupled and the fixed plate 64b are coupled to the rear end of the body 61 so as to adjust the gap so as to adjust the pressing force of the interference hole 62 by the first elastic member 63. It is comprised by the bolt 64c. Accordingly, the interference hole 62 is pressed by the first elastic member 63 in the direction in which the interference protrusion 23 of the valve stem model 20 is provided, so that the interference protrusion 23 when the valve stem model 20 is rotated. The interference of the rotation of the valve stem model 20, the fixed torque (S1) and removable sensor (S2) attached to the valve stem model 20, the torque value according to the rotation is measured. Then, the interference protrusion 23 is paused in the state interfered with the interference hole 62, and then rotates while pushing the interference hole 62 by the driving force of the drive motor 40, the interference hole 62 is When the first elastic member 63 is contracted for a moment and the interference of the interference protrusion 23 is released, the first elastic member 63 protrudes out of the through hole 61a again by the elastic force of the first elastic member 63. The interference hole 62 may be adjusted in a pressurized state by the adjusting bolt 64c. When the fixing bolt 64c is slightly removed and the fixing plate 64b is separated from the body 61, the pressing force of the first elastic member 63 may be adjusted. By this reduction, the interference hole 62 is easily reversed. Therefore, by adjusting the pressurization state of the interference hole 62 by tightening and loosening the adjusting bolt 64c, the fixed sensor S1 and the detachable sensor S2 are measured during rotation of the valve stem model 20. The pressing force value can be used to more accurately test the performance of the sensors S1 and S2. On the other hand, the fixing plate 64b alone is sufficient to prevent the first elastic member 63 from being separated from the through-hole 61a of the body 61, but the correct support of the first elastic member 63 and the first elastic member In order to adjust the pressing force of the 63, the support 64a for supporting the first elastic member 63 in a state of being bound through the center of the fixing plate 64b is preferably provided.

Next, the pressing force generating unit 70 is installed in a state spaced apart from the distal end of the moving tube 50 on the base member 10, when the moving tube 50 enters during rotation of the valve stem model 20 is interfered with the pressing force ( That is, the tension force due to the thrust) is generated. 6 shows an embodiment of the pressing force generating unit 70, a pair of fixtures 71 are spaced apart from each other in a direction perpendicular to the axial direction of the valve stem model 20 on the base member 10. And a pair of interference plates 72 spaced apart from each other so as to allow the mobile tube 50 to enter and exit from each other, and to adjust an interval between the interference plates 72. Tightening bolts 73 for coupling the interference plates 72 to the fixture 71, and the interference plate 72 is connected to the fixture 71 and the interference plate 72 elastically so that the interference plate 72 It is composed of a second elastic member 74 to allow the elastic movement relative to. In the pressing force measurement by the pressing force generating unit 70, the valve stem model housing 30 can be freely rotated by allowing the valve stem model 20 to rotate freely with the interference hole 62 of the rotation resistance generating unit 60 removed. The moving tube 50 wrapped in the pressure to the pressure generating unit 70 to move. An end portion of the moving tube 50 moved to the pressing force generating unit 70 interferes with the pair of interference plates 72. When the pressing force is further generated in the valve stem model 20, the interference plate 72 is pushed out while pushing the interference plate 72. It is inserted between the (72), this pressure is pushed by the fixed sensor (S1) and the removable sensor (S2) will be measured. On the other hand, as shown in Figure 7, the end of the interference plate 72, and the end of the moving tube 50 is opposite to each other so that the moving tube 50 can enter accurately between the interference plate 72, It is preferable that the inclined surface is formed, and in this specification, these inclined surfaces will be referred to by being divided into a first inclined surface 72a and a second inclined surface 52, respectively.

The test apparatus of the present invention configured as described above measures the performance of the fixed sensor S1 and the detachable sensor S2 mounted on the valve stem model 20 by using the rotation and the pressing force of the valve stem model 20. These sensors S1 and S2 are connected to a system device (not shown), such as a computer, in which a plurality of programs are separately installed so as to compare the measured data with each other and evaluate the performance of the sensors S1 and S2 based thereon. It is obvious to those skilled in the art.

Next, a test procedure using the test apparatus of the present invention configured as described above will be described.

First, the fixed sensor S1 and the detachable sensor S2 to be tested are mounted on the sensor mounting part 22 of the valve stem model 20, and then the spiral part 21 of the valve stem model 20 is moved to the moving tube 50. ), And fix the end portion of the sensor mounting portion 22 side of the valve stem model 20 to the rotation shaft 90 coupled to the drive shaft 41 of the drive motor 40.

Subsequently, the adjusting bolt 64c of the rotation resistance generating unit 60 is operated to adjust the pressurization state of the interference hole 62 by the first elastic member 63, and the tightening bolt 73 of the pressing force generating unit 70. ) To adjust the mutual spacing of the interference plate 72 according to the width of the moving tube (50).

When the valve stem model 20 is rotated by operating the drive motor 40 in the above state, the interference protrusion 23 of the valve stem model 20 rotates while the interference hole of the rotation resistance generator 60 ( 62, the interference projection 23 is rotated while pushing the interference hole (62). At this time, the interference protrusion 23 is temporarily applied to the load (that is, pressure) according to the rotation, this rotation pressure is measured by the fixed sensor (S1) and removable sensor (S2), the measured value is Sent to the system unit. Therefore, it is possible to know how accurately the load applied when the valve stem model 20 is rotated by the values measured by the sensors S1 and S2, and also the performance of the sensors S1 and S2. I can figure it out.

On the other hand, after the measurement of the pressure according to the rotation of the valve stem model 20 generates a tensile force, that is, a pressing force by the thrust to test the performance of the sensors (S1, S2). In this case, the valve stem model 20 is free to rotate by removing the interference port 62 of the rotation resistance generator 60 so that the moving tube 50 is pressed from the valve stem model housing 30. 70) to the side.

The moving tube 50 is moved across the interference plate 72 while moving toward the pressing force generating unit 70, at which time the valve stem model 20 rotates to further push the moving tube 50, thereby reducing the movement of the moving tube 50. The end is inserted between the interference plates 72 while opening the interference plate 72. In addition, the fixed sensor S1 and the detachable sensor S2 measure the pressure generated in this process, and the measured data is transmitted to the system apparatus and processed like the rotation force measurement data described above.

As such, the test apparatus of the present invention generates the rotational force and the pressing force of the valve stem model 20 to test the performance of the fixed sensor S1 and the detachable sensor S2 mounted on the valve stem model 20. By using the sensors S1 and S2 whose performance has been verified by the test, the valves can be accurately measured whether the valves are sound.

In the above described the present invention based on the preferred embodiment, the present invention is not limited to the above embodiment, various modifications by those skilled in the art within the scope of the technical idea of the present invention This is possible.

1 is a side view and a partially enlarged view of a partial cross section of the sensor performance test apparatus for measuring the force of the valve stem according to an embodiment of the present invention.

2 is a plan view of the embodiment of FIG.

3 is a perspective view showing an embodiment of a valve stem model constituting the present invention.

4 is a perspective view showing an embodiment of a valve stem model housing and a moving tube of the present invention.

5 is a plan view of a partial cross-sectional view showing an embodiment of the rotation resistance generating portion constituting the present invention.

6 is a plan view of a partial cross-sectional view showing an embodiment of the pressing force generating portion constituting the present invention.

FIG. 7 is a view illustrating an entry state of a moving tube with respect to the pressing force generating part of FIG. 6.

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

10: base member 20: valve stem model

21: spiral part 22: sensor mounting part

23: interference protrusion 30: valve stem model housing

31: guide protrusion 40: drive motor

41: drive shaft 50: moving tube

51: movement guide groove 52: second slope

60: rotation resistance generating unit 61: the body

61a: through hole 62: interference hole

63: first elastic member 64: stopper member

64a: support 64b: fixed plate

64c: adjusting bolt 70: pressing force generating part

71: fixture 72: interference plate

72a: first slope 73: tightening bolt

74: second elastic member 80: coupling

90: rotating shaft S1: fixed sensor

S2: Removable Sensor

Claims (6)

A valve stem model having a threaded spiral portion, a sensor mounting portion formed of a smooth surface to mount a sensor for measuring an action force of rotation and pressure, and an interference protrusion protruding between the spiral portion and the sensor mounting portion; A base member on which the valve stem model is installed; A valve stem model housing installed on the base member to surround a portion of the valve stem model; A drive motor coupled to the valve stem model to rotate the valve stem model; A moving tube which has an inner circumferential surface helically coupled to a spiral portion of the valve stem model to slide into and out of the valve stem model housing while sliding when the valve stem model is rotated; A rotational resistance generator installed on the base member spaced apart from an outer circumferential surface of the valve stem model to generate a rotational resistance while the interference protrusion interferes with the rotation of the valve stem model; And Sensor performance test for measuring the force force of the valve stem is installed on the base member spaced apart from the distal end of the moving tube including a pressing force generating unit for generating interference when the moving tube enters when rotating the valve stem model Device. The method of claim 1, wherein the rotation resistance generating unit, A body mounted on the base member and having a through hole formed at a center thereof toward an outer circumferential surface of the valve stem model; An interference hole protruding from the through hole while being inserted into the through hole of the body so that the interference protrusion of the valve stem model may be interfered with; A first elastic member installed in the through hole of the body to press the interference hole toward the interference protrusion; And And a stopper member for closing the rear end of the through hole so that the first elastic member is not separated from the through hole of the body. The method of claim 2, wherein the stopper member, A support for supporting the first elastic member in the through hole; Fixing plate is fixed to the support is coupled to the rear end of the body; And Sensor fixing test for measuring the force force of the valve stem characterized in that it comprises a control bolt for adjusting the pressing force of the interference hole by the first elastic member by coupling the fixed plate to the rear end of the body to enable adjustment Device. The pressing force generating unit according to any one of claims 1 to 3, wherein A pair of fixtures spaced apart from each other on the base member in a direction orthogonal to the axial direction of the valve stem model; A pair of interference plates spaced apart from each other to face each other so that the moving tube can enter and exit; A tightening bolt for coupling the interference plates to the fixing body so as to adjust a gap between the interference plates; And And a second elastic member for elastically connecting the fixing body and the interference plate to allow the interference plate to elastically move relative to the fixing body. The method of claim 4, wherein An end portion of the interference plate into which the moving tube enters is formed of a first inclined surface, and the end of the moving tube facing the first inclined surface is formed of a second inclined surface. The method of claim 1, A movement guide groove is formed at an upper end of the movement pipe, and a movement guide protrusion is inserted into the movement guide groove to guide the movement of the movement pipe above the inner circumferential surface of the valve stem model housing. And a moving tube moves in and out of the valve stem model housing in a straight line to enter and exit the valve stem model housing.

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