KR20010048159A - Method for measuring load of sling rod using natural frequency measurement - Google Patents

Abstract

PURPOSE: A method for measuring sling rod load using natural frequency measurement is provided to reduce a measuring period of time and a measuring cost and easily measure entire load of the sling rod by measuring natural frequency of the sling rod. CONSTITUTION: A method for measuring sling rod load using natural frequency measurement includes the steps of measuring load of a standard sling rod of a number of sling rods using a hydraulic jack, generating vibration at a side of the sling rod for measuring natural frequency of the measured sling rod, detecting natural frequency of the sling rod according to vibration of a vibrator, and making load of the sling rod measured through the hydraulic jack and a detecting part and data of natural frequency into table in a data obtaining system and a data analyzer.

Description

Sling rod load measurement method using natural frequency measurement {METHOD FOR MEASURING LOAD OF SLING ROD USING NATURAL FREQUENCY MEASUREMENT}

The present invention relates to a sling rod load measuring method, and in particular, by using the natural frequency of the sling rod is changed according to the load change on the sling rod to provide a data that can quickly determine whether the load check carried out sling rod, The present invention relates to a sling rod load measuring method using a natural frequency measurement to easily measure and adjust the load of a sling rod using this.

As is well known, the present invention relates to a technique for measuring and analyzing a load of a sling rod supporting a main structure of a boiler in a fossil fired power plant. The principle is to calculate the load applied to each sling rod by measuring the natural frequency of each sling rod. By using this method, the load condition of the entire boiler can be inspected and adjusted. Estimation Of Sling Rod Integrity) ".

Conventionally, the sling rod load measuring device is manufactured by assembling a flange boss jig (a) according to the specifications of each sling rod and tightening at least 20 mounts to a bolt (d) formed on the upper part of the sling rod. do.

Subsequently, a dial gauge (b) is installed on the upper surface of the flange boss jig to measure the displacement of the sling rod, and the hydraulic jack (c) is connected to a hydraulic hose (not shown), a hydraulic pump, and a pressure gauge. Operate the pump to lift the sling rod to measure pressure and displacement.

At this time, the measured pressure and displacement, as shown in Figure 2, using a graph paper or a graphical tool (for example, Excel) to create a graph of pressure (x-axis), displacement (y-axis), at this time to the sling rod The applied pressure increases the pressure at intervals of 200 to 1000 psi according to the specifications of the sling rod, and a curve is made with the scale of the dial gauge (b) corresponding to the pressure.

On the other hand, the load calculation of the sling rod extrapolates the measurement data of the section in which the slope changes in FIG. 2 to find the point where it meets the pressure axis, and then multiplies the pressure by the pressure at the point where it meets the pressure axis and the cylinder area of the used hydraulic jack (c). Calculate and measure the actual load the rod is carrying by applying the above procedure for each sling rod.

However, the conventional sling rod load measuring device as described above requires a lot of equipment (hydraulic jack set, gauge, hydraulic hose, etc.) necessary for load measurement, and takes a lot of measurement time and cost because each load of each sling rod is individually measured. do.

In addition, if the load state of the rod is to be known due to damage or any need of the sling rod, there is a problem that the overall load should be measured, and there is a risk of damage to the sling rod or damage to related members due to excessive hydraulic jack operation. There was a problem with nesting.

Accordingly, the present invention is to solve the conventional problems as described above, an object of the present invention by measuring the natural frequency of the sling rod to measure the load of the sling rod, while reducing the measurement time and cost, It is to provide a sling rod load measuring method using the natural frequency measurement to easily measure the total load.

In order to achieve the above object, a sling rod load measuring method using the natural frequency measurement of the present invention includes an iron structure supporting a load of the entire boiler including an auxiliary facility, and a load of the auxiliary facilities through a nut. Sling rods to be transmitted to, and auxiliary equipment such as pipes, headers and tubes that are fastened to the sling rods, respectively, through which fluid flows, and a vibrator coupled to one side of the sling rods to vibrate, the other side of the sling rods. A sensing unit coupled to the sensing unit to detect the natural frequency of the sling rod by the vibration applied by the vibrator; A sling that is taken as a reference among a number of sling rods by measuring the load of the sling rod using a data analyzer Load measuring step for measuring the load of the de using the yuapjaek; A vibration generating step of generating vibration by being coupled to one side of the sling rod to measure the natural frequency of the sling rod measuring the load by using the hydraulic jack in the vibrator; A natural frequency detection step of detecting a natural frequency of the sling rod according to the vibration of the vibrator coupled to the other side of the sling rod in the detector; And a data table for tabulating the load of the sling rod measured by the hydraulic jack and the sensing unit and the corresponding natural frequency data in the data acquisition system and the data analyzer.

1 is a configuration diagram showing a conventional sling rod load measuring device,

2 is a view showing a graph method for calculating a conventional sling rod load,

3 is a block diagram showing an apparatus for implementing a sling rod load measuring method using a natural frequency measurement according to an embodiment of the present invention,

4 is a flowchart illustrating a sling rod load measuring method using a natural frequency measurement according to an embodiment of the present invention.

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

100: steel structure 200: sling rod

300: Additional facilities 400: Exciter

500: detector

600: data acquisition system and data analyzer

Hereinafter, a sling rod load measuring method using natural frequency measurement according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a block diagram showing a device for implementing a sling rod load measuring method using a natural frequency measurement, Figure 4 is a flow chart showing a sling rod load measuring method using a natural frequency measurement.

As shown in Figure 3, the present invention, the steel structure 100, the sling rod 200, the auxiliary equipment 300, the exciter 400, the detector 500, the data acquisition system and the data analyzer 600 Consists of, the steel structure 100 serves to support the load of the entire boiler including the auxiliary equipment 300, the sling rod 200 is the auxiliary equipment such as pipes, headers and tubes ( It performs a function of transmitting the load of the 300 to the steel structure 100 through a nut.

In addition, the auxiliary equipment 300 is fastened to the lower portion of the sling rod 200 so that the fluid flows therein, respectively, in the vibrator 400 is coupled to one side of the sling rod 200 to apply a vibration Role.

Subsequently, the detection unit 500 is coupled to the other side of the sling rod 200 and serves to detect and output the natural frequency of the sling rod 200 by the vibration applied by the exciter 400. The data acquisition system and the data analyzer 600 receive a sensing signal output from the sensing unit 500 and measure a load and a natural frequency applied to the sling rod 200.

Hereinafter, the operation of the sling rod load measuring method using the natural frequency measurement configured as described above is as follows.

The sling rod 200 transmits the load of the auxiliary equipment 300 consisting of a pipe, a header and a tube through the nut of the steel structure 100.

At this time, if the operator wants to measure the load of the sling rod 200 installed in the thermal power plant configured as described above, as shown in Figure 3 of the sling rod 200 is caught as a reference among the plurality of sling rods 200 The load is measured using the hydraulic jack (c) (S100), the sling rod 200 measured the load using the hydraulic jack (c) in the exciter 400 is coupled to one side of the sling rod (200) To generate a vibration to measure the natural frequency of the (S200).

Then, the sensing unit 500 coupled to the other side of the sling rod 200 detects the natural frequency generated in the sling rod 200 by the vibration of the exciter 400 (S300), and acquires data. In the system and data analyzer 600, the load of the sling rod 200 and the natural frequency data measured according to the hydraulic jack (c) and the sensing unit 500 are received and tabled (S400).

Subsequently, when the natural frequency according to the load of the sling rod 200 is tabulated in the data table step 400, when the operator wants to measure the load of the sling rod 200 desired, the exciter 400 and The sensing unit 500 detects the natural frequency of the sling rod 200 and then compares the loads according to the natural frequencies listed in the data acquisition system and the data analyzer 600 to load the sling rod 200. Can be measured easily.

As described above, in the sling rod load measuring method using the natural frequency measurement according to the present invention, after the load of the sling rod is tabled according to the natural frequency, the operator measures the natural frequency of the sling rod to measure the load of the sling rod. By measuring the load, since the equipment for measuring the load of the sling rod is not required separately, cost and measurement time are reduced accordingly, and the load of the plurality of sling rods can be easily measured.

Claims (1)

Steel structures that support the loads of the auxiliary equipments, sling rods that transfer the loads of the auxiliary equipments to the steel structures through nuts, and pipes, headers and tubes, etc., which are respectively fastened to the sling rods and allow steam to flow therein. Equipment, a vibration coupled to one side of the sling rod to apply vibration, a sensing unit for detecting the natural frequency of the sling rod by the vibration coupled to the other side of the sling rod applied by the excitation, and the detection unit It measures the load of the sling rod by using the data acquisition system and data analyzer to measure the load and natural frequency applied to the sling rod by receiving the detection signal output from A load measuring step of measuring by using a hydraulic jack; A vibration generating step of generating vibration by being coupled to one side of the sling rod to measure the natural frequency of the sling rod measuring the load by using the hydraulic jack in the vibrator; A natural frequency detection step of detecting a natural frequency of the sling rod according to the vibration of the vibrator coupled to the other side of the sling rod in the detector; Sling rod load using the natural frequency measurement, characterized in that the data acquisition system and the data analyzer comprises a data table for tabulating the load of the sling rod measured through the hydraulic jack and the sensing unit and the resulting natural frequency data How to measure.