KR101281707B1 - System for shaft alignment using mobile and method therefor - Google Patents

Abstract

The present invention relates to a portable axis alignment system that is equipped with a mobile app that can calculate the axis alignment adjustment value in the portable terminal to improve the efficiency and reliability of maintenance without mistakes of the operator.
The present invention relates to a portable shaft alignment system, comprising: display means for displaying a frame for inputting and outputting data for shaft alignment of a motor and a pump, input means for receiving input command signals from the outside and inputting shaft alignment data through the frame; It characterized in that it comprises a data processing means and a control means for calculating the vertical direction adjustment value and the horizontal direction adjustment value from the rim face data or reverse rim data of the axis alignment data input through.

Description

System for shaft alignment using mobile and method therefor}

It is equipped with a mobile app that can calculate the axis alignment adjustment value in the portable terminal to provide a portable axis alignment system that improves the efficiency and reliability of maintenance without mistakes.

In general, in order to solve problems such as vibration and noise in the rotating body, measurement of the roundness, deviation, deformation, etc. of the rotating body and axial alignment are essential.

Until now, most of these measurements have been performed by recording the data of a measuring instrument such as dial gauge and acquiring the data by calculation or wired communication. The conventional axis alignment method uses a dial gauge and a calculator. Measure the value, calculate it using the formula, and then apply it again and repeat the measurement again to see if it is correct.

In this case, the operator must calculate the measured value with a calculator using a calculation formula. At this time, the operator often makes a mistake. Therefore, the work time is doubled than when the correct value is applied. This resulted in less efficient and less reliable customers.

There is a problem that the work process is cumbersome, such as calculating and applying the movement amount of the motor and pump based on the data measured by the maintenance staff for the shaft alignment, and calculating and verifying whether the shaft alignment is corrected again.

As a prior art document, the axis alignment data is acquired with a small linear variable differential transformer (LVDT), the axis alignment data is transferred to a netbook through Bluetooth communication, and the axis alignment is performed in a simulation, thereby ensuring a highly reliable axis. Provide sorting.

Looking at the configuration, the LVDT displacement measuring sensor for measuring the respective displacements of the rotary shaft are respectively installed through a special jig to the coupling connecting the rotary shaft and the rotary shaft; Blue data transceivers installed on the rotating shaft and connected to the LVDT displacement measurement sensors, respectively, to receive and simulate the LVDT displacement value of the LVDT displacement measurement sensor, and receive and simulate the LVDT displacement data from the wireless data transceiver. It is characterized by consisting of a netbook having a ts adapter.

An object of the present invention is to provide a portable axis alignment system that is equipped with a mobile app that can calculate the axis alignment adjustment value in the portable terminal to solve the above problems and improve the efficiency and reliability of maintenance without mistakes of the operator.

The present invention provides a portable shaft alignment system comprising: display means (100) for displaying a frame for inputting and outputting data for shaft alignment of a motor and a pump; Input means for receiving an input command signal from the outside and receiving axis alignment data through the frame; Data processing means (300) for calculating a vertical direction adjustment value and a horizontal direction adjustment value using rim face data or reverse rim data among the axis alignment data inputted through the frame; And control means 400 for controlling the display means, input means, and data processing means.

On the other hand, an axis alignment method using a portable axis alignment system, comprising: (a) displaying, by a control means of a portable axis alignment system, a frame for inputting and outputting data for shaft alignment of a motor and a pump; (b) the control means receiving an input command signal from an external device through an input means and receiving axis alignment data into the frame; And (c) the control means calculating, by the data processing means, the vertical direction adjustment value and the horizontal direction adjustment value as rim face data or reverse rim data among the axis alignment data inputted through the frame. It is done.

According to the present invention, the mobile terminal is equipped with a mobile app that can calculate the axis alignment adjustment value has the effect of improving the efficiency and reliability of maintenance without mistakes of the operator.

Looking at the basic tool screen, the basic tool screen displays basic tools for aligning the axes so that the operator can easily identify and prepare the necessary tools. The reference screen attaches necessary data to align the axes. There is an effect that you can easily refer to.

1 is a block diagram of a portable axis alignment system according to an embodiment of the present invention.
Figure 2 is an illustration of a portable axis alignment system according to an embodiment of the present invention.
3 is a main screen of a display means according to an embodiment of the present invention.
4 is an exemplary view showing a rim face input frame according to an embodiment of the present invention.
5 is an exemplary view showing a rim face result frame according to an embodiment of the present invention.
6 is an exemplary view showing a reverse rim input frame according to an embodiment of the present invention.
7 is an exemplary view showing a reverse rim result frame according to an embodiment of the present invention.
8 is a flow chart illustrating an axis alignment method according to an embodiment of the present invention.
9 is a detailed flowchart of the display step according to an embodiment of the present invention.
10 is a detailed flowchart of a data processing step according to an embodiment of the present invention.

Portable axis alignment system according to an embodiment of the present invention is equipped with a mobile app (app) that can calculate the axis alignment adjustment value in the portable terminal to improve the efficiency and reliability of maintenance without mistakes of the operator, shown in Figure 1 As shown, it comprises a display means 100, input means 200, data processing means 300, the control means 400. Figure 2 shows a portable axis alignment system according to an embodiment of the present invention.

Display means (100)

First, as shown in FIG. 3, the display means 100 displays categories of basic tools, reference materials, rim face methods, and rimbus rim methods for axial alignment.

Here, the display means is a basic tool frame 110 for displaying the basic tool for the alignment of the axis so that the operator can easily identify and prepare the necessary tool, and when the axis alignment, attached to the necessary data, the operator easily Reference frame 120 for reference, a rim face input frame 130 for inputting the basic data required for axis alignment by the rim face method, a rim face result frame 140 processing the input data, It includes a reverse rim input frame 150 for inputting basic data required for axis alignment by the reverse rim method, and a reverse rim result frame 160 for processing the input data.

At this time, as shown in Figure 4, the rim face input frame 130, the rim measurement value (R), the face measurement value (F), the coupling diameter value (diameter value that the indicator rotates for the face measurement) (D ), The distance from the coupling of the moving machine (motor) to the center of the forefoot bolt (L1), the distance from the coupling of the moving machine (motor) to the center of the forefoot bolt (L2), the vertical displacement of the motor forefoot (S1, shim) ), A data input screen for receiving basic data of the rim face method including the vertical movement amount (S2, shim) of the rear foot of the motor.

As shown in Figure 6, the reverse rim input frame 150 is a dial indicator of the moving amount of the front foot of the moving machine (S1), the moving amount of the rear foot of the moving machine (S2), the coupling of the moving machine (motor) and the fixed machine (pump) Distance value (CD, Coupling Distance) between spindle centers, indicator of moving machine (motor) coupling Distance from spindle center to bolt center of front foot (L1), indicator of moving machine (motor) coupling Fundamentals of the reverse rim method, including distance to center (L2), rim measurement of mobile machine coupling (MR), fixed rim measurement of fixed machine (pump) coupling (FR) Displays a data input screen for receiving data.

The rim face result frame 140 and the reverse rim result frame 160 display the vertical direction adjustment value and the horizontal direction adjustment value which are the result of processing the previously input data in the rim face method or the reverse rim method, respectively.

Here, the rim face result frame displays the rim face vertical adjustment value and the horizontal adjustment value, which are the up, down, left and right adjustment values, and after adjusting the motor with the adjustment value, confirms the adjustment result using the dial gauge. .

In the reverse rim result frame, the vertical and horizontal adjustment values of the horizontal rim and the horizontal adjustment value are displayed. After adjusting the motor with the adjustment values, the adjustment results are confirmed using the dial gauge.

Input means 200

The input means 200 receives a command from the outside to input data. Here, the input means according to the present embodiment is set as a touch method for detecting a touch signal according to a user's operation, but the present invention is not limited thereto.

For reference, the input means moves the rim measurement value (R), the face measurement value (F), the coupling diameter value (diameter value at which the indicator rotates for face measurement) (D), on the rim face input frame in the display means. Distance from machine (motor) coupling to forefoot bolt center (L1), distance from moving machine (motor) coupling to center of forefoot bolt (L2), vertical displacement of motor forefoot (S1, shim), motor The basic data of the rim face method including the vertical movement amount of the rear foot (S2, shim) is input.

Then, on the reverse rim input frame, the moving amount of the front foot of the moving machine (S1), the moving amount of the rear foot of the moving machine (S2), and the distance value (CD, Coupling Distance) between the center of the dial of the dial of the coupling of the moving machine (motor) and the fixed machine (pump) ), The distance value (L1) from the center of the indicator spindle of the moving machine (motor) coupling to the bolt center of the forefoot, the distance value (L2) from the center of the indicator spindle of the moving machine (motor) coupling to the bolt center of the rear foot, the moving machine The basic data of the reverse rim method including the rim measurement value of the coupling (MR) and the rim measurement value (FR) of the fixed machine (pump) coupling are input.

Data processing means 300

The data processing means 300 includes a rim face processing unit 310 for processing data input through the rim face input frame from the input means, and a reverse rim processing unit 320 for processing data input through the reverse rim input frame. It is composed.

Here, the rim face processing unit 310 of the data input through the rim face input frame from the input means, the rim measurement value (R), the face measurement value (F), the coupling diameter value (the indicator is rotated for the face measurement) Diameter value (D), the distance from the moving machine (motor) coupling to the center of the forefoot bolt (L1), the distance from the moving machine (motor) coupling to the center of the rear foot bolt (L2), and the amount of vertical movement of the motor forefoot (S1) ), Including a rim face vertical direction calculating module 311 for calculating the vertical direction adjustment value using the vertical movement amount S2 of the motor rear foot, and a rim face horizontal direction calculating module 312 calculating the horizontal direction adjustment value. It is composed.

In this case, the rim face vertical direction calculation module 311 calculates a vertical direction adjustment value by using Equation 1 below.

As illustrated in FIG. 5, when the vertical adjustment value is described, the rim measurement value R _v1 and the face measurement value F _v2 near 0 degree, the rim measurement value R _v2 and the face measurement value near 180 degrees ( F _v1 ) is calculated.

And the rim face horizontal direction calculation module 312 calculates a horizontal direction adjustment value using the following equation (2).

As illustrated in FIG. 5, when the horizontal adjustment value is described, the rim measurement value R _H1 and the face measurement value F _H1 near 270 degrees, the rim measurement value R _H2 near the 90 degree value, and the face measurement value ( F _H2 ) is calculated.

And, the reverse rim processing unit 320 of the data input through the reverse rim input frame from the input means, the movement amount (S1) of the front foot of the mobile machine, the movement amount (S2) of the rear foot of the mobile machine, the dial of the mobile machine and the fixed machine coupling Distance value between indicator spindle center (CD, Coupling Distance), distance from indicator spindle center of moving machine (motor) coupling to bolt center of forefoot (L1), indicator spindle center of rear foot from moving machine (motor) coupling The vertical adjustment value is calculated using the distance value to the center of the bolt (L2), the rim measurement value of the moving machine coupling (MR), and the rim measurement value of the fixed machine coupling (FR). It includes a reverse rim vertical direction calculation module 321 and a reverse rim horizontal direction calculation module 322 for calculating a horizontal direction adjustment value.

At this time, the reverse rim vertical direction calculation module 321 calculates the vertical direction adjustment value using the following equation (3).

(MV: Motor Vertical, PV: Pump Vertical)

As illustrated in FIG. 7, when the vertical adjustment value of the reverse rim method is described, the rim measurement value MR _MV1 near 0 degrees of the moving machine (motor), the rim measurement value MR _MV2 near 180 degrees, and the fixed machine The rim measurement value FR _PV1 near 0 degree of the (pump) and the rim measurement value FR _PV2 near 180 degrees are calculated.

The reverse rim horizontal direction calculation module 322 calculates a horizontal direction adjustment value by using Equation 4 below.

(MH: Motor Horizontal, PH: Pump Horizontal)

As illustrated in FIG. 7, when the horizontal rim adjustment value of the reverse rim method is described, a 270 degree rim measurement value MR _MH1 near a moving machine (motor), a rim measurement value MR _MH2 near 90 degrees, and a fixed machine The 270 degree rim measurement value FR _PH1 and the 90 degree rim measurement value FR _PH2 of (pump) are calculated.

Control means 400

The control means performs a function of controlling the display means 100, the input means 200, and the data processing means 300. Here, the control means determines the input command signal received through the input means from the outside in the rim face mode or reverse rim mode to control each component.

Meanwhile, an axis alignment data calculation method (hereinafter, referred to as an axis alignment method) using a portable axis alignment system according to an embodiment of the present invention will be described with reference to FIG. 8.

First, the control means of the portable shaft alignment system displays a frame for inputting and outputting data for shaft-aligning the motor and the pump (S2).

Next, the control means receives the input command signal from the outside through the input means and receives the axis alignment data in the frame (S4).

The control means calculates a vertical direction adjustment value and a horizontal direction adjustment value as data processing means as rim face data or reverse rim data among the axis alignment data input through the frame (S6).

Looking at the frame display step (S2) according to an embodiment of the present invention with reference to Figure 9, the control means determines the input command signal received through the input means from the outside (S10), when determined in the rim face mode method Measured using the coupling diameter of the motor, the distance from the coupling to the center of the first bolt of the motor, the distance from the center of the first bolt of the motor to the center of the second bolt, and the dial gauge. A data input screen for receiving a rim value and a face value is displayed (S12).

When the control means determines the input command signal received through the input means from the outside in the reverse rim mode, the distance value between the coupling of the pump and the motor, the distance value from the coupling to the center of the first bolt of the motor, A data input screen for receiving a distance value from the center of the first bolt to the center of the second bolt and the rim value measured using the dial gauge is displayed (S14).

Here, the control means may be set to display the basic tool frame and axis reference reference frame for the axis alignment according to the input command signal received through the input means from the outside.

Looking at the data processing step (S6) according to an embodiment of the present invention with reference to FIG. 10, the control means determines the input command signal received through the input means from the outside (S20), when determined in the rim face mode method Of the axis alignment data input through the rim face input frame, the rim measurement data (R _v1 ) and the face measurement value (F _v2 ) near the machine (motor) and the rim measurement data (F _v2 ) and the rim measurement value near 180 degrees ( R _v2 ) and the face measurement value F _v1 are calculated as vertical adjustment values (S22).

Next, the control means uses rim face data to measure the rim near the 270 degree (R _H1 ) and face (F _H1 ), and the rim near the 90 degree (R _H2 ) and face (F) measurements of the mobile machine (motor). _H2 ) is calculated as the horizontal adjustment value (S24).

Here, the rim face data includes the rim measurement value R, the face measurement value F, the coupling diameter value of the moving machine (motor) (diameter value at which the indicator rotates for face measurement) (D), and the moving machine (motor). ) Distance from coupling to center of forefoot bolt (L1), moving machine (motor) Distance from coupling to center of forefoot bolt (L2), vertical movement amount of front foot of moving machine (motor) (S1), moving machine (motor) It includes the vertical movement amount S2 of the hind feet.

In addition, when the control means determines the input command signal received through the input means from the outside in the reverse rim mode, the rim measurement of the moving machine (motor) near the rim data of the axis alignment data input through the frame is performed. Value (MR _MV1 ), rim measurement value near 180 degrees (MR _MV2 ), rim measurement value near zero degrees (FR _PV1 ) of fixed machine (pump), rim measurement value near 180 degrees (FR _PV2 ) as vertical adjustment value It calculates (S32).

The control means uses reverse rim data to measure the rim near the 270 degree (MR _MH1 ) of the mobile machine (motor), the rim measurement near the 90 degree (MR _MH2 ), and the rim measurement near the 270 degree of the fixed machine (pump) (FR). _PH1 ), the rim measurement value FR _PH2 around 90 degrees is calculated as the horizontal adjustment value (S34).

The portable shaft alignment system according to the present embodiment can be used for shaft alignment of a pump and a motor, and when used, the portable shaft alignment system can reduce work time and reduce human errors.

The portable axis alignment system according to an embodiment of the present invention is to be applied to a mobile app to calculate the axis alignment adjustment value quickly and easily using a mobile terminal (cell phone).

The portable axis alignment system displays a basic screen by clicking on the icon on the main screen. These basic screens allow you to select the basic tool, reference material, rim face method and reverse rim method.

Looking at the basic tool screen, the basic tool screen displays the basic tools for aligning the axis so that the operator can easily identify and prepare the necessary tools.

The portable axis alignment system according to the present embodiment can be attached to the picture even beginners can easily check the shape of the tool.

The reference screen is attached to the data needed for axis alignment so that the operator can easily refer to it.

100: display means 110: basic tool frame
120: reference frame 130: rim face input frame
140: rim face result frame 150: reverse rim input frame
160: reverse rim result frame 200: input means
300: data processing means 310: rim face processing unit
311: rimface vertical direction calculation module 312: rimface horizontal direction calculation module
320: reverse rim processing unit 321: reverse rim vertical calculation module
322: reverse rim horizontal calculation module 400: control means

Claims (16)

In a portable axis alignment system,
Display means (100) for displaying a frame for inputting and outputting data for aligning a motor and a pump;
Input means for receiving an input command signal from the outside and receiving axis alignment data through the frame;
Data processing means (300) for calculating a vertical direction adjustment value and a horizontal direction adjustment value using rim face data or reverse rim data among the axis alignment data inputted through the frame; And
And control means (400) for controlling the display means, input means, and data processing means.
The display means 100,
A basic tool frame displaying basic tools for axial alignment; And
And a reference frame for displaying reference information related to the axis alignment. The method of claim 1,
The display means 100,
Measured using the coupling diameter of the motor, the distance from the coupling to the center of the first bolt of the motor, the distance from the center of the first bolt of the motor to the center of the second bolt, and the dial gauge. A rim face input frame displaying a data input screen for receiving a rim value and a face value; And
And a rim face result frame configured to display the data input through the rim face input frame as a result of data processing through the data processing means. The method of claim 1,
The display means 100,
The distance between the pump and the coupling of the motor, the distance from the coupling to the center of the first bolt of the motor, the distance from the center of the first bolt of the motor to the center of the second bolt, and the rim measured using the dial gauge A reverse rim input frame displaying a data input screen for receiving an input; And
And a reverse rim result frame for displaying the data inputted through the reverse rim input frame as a result of data processing through the data processing means. delete The method of claim 1,
The input means 200,
Portable axis alignment system, characterized in that the touch method for detecting a touch signal according to the user's operation. The method of claim 1,
The data processing means 300,
A rimface processing unit 310 for processing data input through the rim face input frame from the input means; And
And a reverse rim processing unit (320) for processing the data input through the reverse rim input frame. The method of claim 1,
The data processing means 300,
Of the alignment data entered through the frame, the rim 0 degrees near the rim measured value of the mobile machine (motor) in the face data (R _v1) and the face measure (F _v2), 180 also near the rim measure (R _v2) Rim face vertical calculation module 311 for calculating the phase and face measurement value F _v1 as a vertical adjustment value, and rim measurement value R _H1 and face near 270 degrees of the moving machine (motor) with the rim face data. And a rim face horizontal direction calculation module 312 for calculating the measured value F _H1 , the near rim measurement value R _H2 , and the face measurement value F _H2 as horizontal adjustment values. Axis alignment system. The method of claim 1,
The data processing means 300,
Among the data input through the rim face input frame from the input means, the rim face data is the rim measurement value (R), the face measurement value (F), and the coupling diameter value of the moving machine (motor) (the indicator rotates for face measurement). Diameter value (D), the distance from the moving machine (motor) coupling to the first bolt center (L1), the distance from the moving machine (motor) coupling to the second bolt center (L2), and the moving machine (motor) Portable shaft alignment system comprising a vertical movement amount (S1) of the front foot, the vertical movement amount (S2) of the rear foot of the moving machine (motor). The method of claim 1,
The data processing means 300,
Among the axis alignment data input through the frame, the reverse rim data is used as the reverse rim data, and the rim measurement value MR _MV1 near 0 degrees of the moving machine (motor), the 180 degree rim measurement value (MR _MV2 ) and 0 of the fixed machine (pump) A reverse rim vertical calculation module 321 for calculating the near-rim rim measurement value FR _PV1 and the 180-degree rim measurement value FR _PV2 as a vertical adjustment value, and the reverse rim data for the mobile machine (motor). 270 degrees near rim measurement (MR _MH1 ), 90 degrees near rim measurement (MR _MH2 ), fixed machine (pump) 270 degrees near rim measurement (FR _PH1 ), 90 degrees near rim measurement (FR _PH2 ) A portable axis alignment system comprising a reverse rim horizontal direction calculation module (322) for calculating a horizontal direction adjustment value. The method of claim 1,
The data processing means 300,
Among the data inputted through the reverse rim input frame from the input means, the reverse rim data includes the movement amount of the front foot of the moving machine (S1), the movement amount of the rear foot of the moving machine (S2), and the dial indicator of the coupling of the mobile machine and the fixed machine (pump). Distance value between center (CD, Coupling Distance), indicator center of moving machine (motor) coupling to bolt center of forefoot Distance value (L1), indicator center of moving machine (motor) coupling, bolt center of rear foot Characterized in that it comprises a distance value (L2), a rim measurement value (MR) of the moving machine (motor) coupling, and a rim measurement value (FR, Fixed Coupling RIM) of the fixed machine (pump) coupling. Portable axis alignment system. In the axis alignment method using a portable axis alignment system,
(a) displaying, by the control means of the portable shaft alignment system, a frame for inputting and outputting data for shaft-aligning the motor and the pump;
(b) the control means receiving an input command signal from an external device through an input means and receiving axis alignment data into the frame; And
(c) the control means calculating, by the data processing means, the vertical direction adjustment value and the horizontal direction adjustment value as rim face data or reverse rim data among the axial alignment data inputted through the frame.
In the step (a)
And displaying, by the control means, a basic tool frame and an axis reference frame for axis alignment. The method of claim 11,
In the step (a)
The control means includes a coupling diameter value of the motor, a distance value from the coupling to the center of the first bolt of the motor, a distance value from the center of the first bolt to the center of the second bolt of the motor, and a dial gauge. And displaying a data input screen for receiving a rim value and a face value measured by using the same. The method of claim 11,
In the step (a)
The control means measures using the distance value between the pump and the coupling of the motor, the distance value from the coupling to the center of the first bolt of the motor, the distance value from the center of the first bolt of the motor to the center of the second bolt, the dial gauge And displaying a data input screen for receiving a rim value. delete The method of claim 11,
The step (c)
(c-1) The rim measurement data (R _v1 ) and the face measurement value (F _v2 ), 180 of the axis alignment data inputted through the frame by the control means, to the rim face data, 180 A rim face vertical calculation step of calculating a near rim measurement value R _v2 and a face measurement value F _v1 as vertical adjustment values; And
(c-2) The control means uses the rim face data as the rim measurement value (R _H1 ), the face measurement value (F _H1 ), and the rim measurement value (R _H2 ) near 90 degrees of the moving machine (motor). And a rim face horizontal direction calculating step of calculating a face measurement value F _H2 as a horizontal direction adjustment value. The method of claim 11,
The step (c)
(c-1 ') The rim measurement value MR _MV1 near zero degree of the moving machine (motor) and the rim measurement value MR near 180 degrees among the axis alignment data inputted through the frame by the control means. _MV2 ), a reverse rim vertical calculation step of calculating the rim measurement value FR _PV1 near 0 degrees and the rim measurement value FR _PV2 near 180 degrees as vertical adjustment values of the fixed machine (pump); And
(c-2 ') The control means uses the reverse rim data to measure the rim near the 270 degree of the moving machine (motor) (MR _MH1 ), the rim measurement near the 90 degree (MR _MH2 ), and the 270 of the fixed machine (pump). And a reverse rim horizontal direction calculating step of calculating a near-rim rim measurement value FR _PH1 and a 90-degree rim measurement value FR _PH2 as a horizontal adjustment value.

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