KR101361619B1 - A/h rotor weight condition analyzer - Google Patents

Abstract

The present invention relates to a rotor weight condition analyzer for an air preheater. The rotor weight condition analyzer comprises: a rotor having an element and an element cage for receiving the element; a rotating part for supporting the rotor to be rotated; sector dividing sensors circumferentially coupled to the rotor at regular angles to divide the rotor into multiple sectors; a proximity sensor separated from the rotor to detect the sector dividing sensors when the rotor rotates; and a control part for detecting the rotation speed of the sectors based on the measured time of the sectors detected by the proximity sensor and analyzing the weight condition of the sectors through the rotation speed.

Description

Rotor Weight Analyzer for Air Preheater {A / H ROTOR WEIGHT CONDITION ANALYZER}

The present invention relates to a weight state analyzer for a preheater for air preheater, and more specifically, a weight for the air preheater for automatically analyzing the weight state of the body by analyzing the rotational speed after dividing the body into a plurality of sectors. It is about a health analyzer.

Power plants use air preheaters with element elements to recover the waste heat of the waste gases from the boilers. Air preheaters have been disclosed in Registered Room No. 20-0250755.

There are two general types of air preheaters. That is, there is a form arranged horizontally with respect to the axis and a form arranged vertically with respect to the axis. At this time, the air preheater arranged vertically with respect to the axis may cause excessive load on the driving unit when weight fluctuation occurs during rotation, causing damage to the rotating driving unit such as gears and stopping power generation. Therefore, maintaining the weight evenly throughout the air preheater is an important control guide.

Accordingly, the operator analyzes the weight of the air preheater. In order to analyze the weight of the conventional air preheater, the operator measured manually using a stopwatch. This is because air preheaters are more affected by gravity than centrifugal force due to weight imbalance, making it difficult to use specialized equipment.

However, when the weight is analyzed manually in the related art, since the measurement is repeated several times in order to increase the accuracy of the data, a lot of time and manpower is required for data acquisition.

In addition, since the workers are arranged in different positions of the bulky air preheater, the work is performed by a verbal signal in a place where the workers are not visible to each other, causing a safety accident.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problem, and separates the rotor into a plurality of sectors, and automatically measures the rotational speed of each sector in a non-contact manner to analyze the weight of each sector. To provide a full weight analyzer.

It is another object of the present invention to provide a rotor weight condition analyzer for an air preheater that can calculate together a place to attach additional weights based on the measured rotational speeds of each sector.

Still another object of the present invention is to provide a rotor weight state analyzer for an air preheater capable of measuring continuous rotation time for each sector by recognizing a measurement start signal and a measurement end signal input through an input unit.

It is another object of the present invention to provide a rotor weight state analyzer for an air preheater that can improve the reliability of weight analysis by analyzing the weight through stable center data except for unstable initial data and late data among repeated measured data. .

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

The object of the present invention can be achieved by a rotor weight condition analyzer for an air preheater. Here, the rotating body includes an element and an element cage for accommodating the element therein, and a rotation driving unit rotatably supporting the rotating body; A sector classification sensor coupled to the predetermined angle along the circumferential direction of the rotating body to divide the rotating body into a plurality of sectors; A proximity sensor disposed to be spaced apart from the rotor to sense the sector classification sensor when the rotor is rotated; And a control unit for detecting a rotational speed for each sector based on the measurement time for each sector detected by the proximity sensor, and analyzing the weight state for each sector based on the rotational speed.

According to an embodiment of the present disclosure, the controller analyzes the sector position to which the additional weight is to be attached to equalize the weight of the entire rotating body based on the analyzed weight state of each sector.

According to an embodiment, the apparatus may further include an input unit configured to receive a sector number of each sector to which the sector classification sensor is attached from a user, and to receive a measurement start signal and a measurement end signal.

The display apparatus may further include a display unit configured to display the weight state analyzed by the controller for each sector, and to display a position to which the additional weight is to be attached.

According to one embodiment, the sector classification sensor and the proximity sensor are formed to detect the position by the transmission and reception of the laser light.

According to an embodiment of the present disclosure, the control unit repeatedly receives the measurement time data of each sector from the proximity sensor for a predetermined time a plurality of times, and the intermediate measurement time except for the initial measurement time data and the late measurement time data among the received data. Based on the data, the weight state of the rotating body is analyzed.

The rotating body weight state analyzer for an air heater according to the present invention is an automatic measuring method using a proximity sensor and a sector classification sensor to prevent an error caused by manual measurement of an operator and to secure data reliability.

Therefore, the vibration state of the rotating body can be corrected by accurately correcting the weight state of the rotating body.

In addition, since the proximity sensor is a non-contact method, the operator can ensure safety when working.

In addition, it is possible to increase the convenience of maintenance work of the rotating body since the calculated state of the weight after the additional weight is calculated and displayed.

1 is a schematic diagram schematically showing the configuration of a rotating body weight analyzer according to the present invention,
Figure 2 is a block diagram showing the configuration of a rotating body weight analyzer according to the present invention,
Figure 3 is a perspective view showing the configuration of the analysis body of the rotating body weight state analyzer according to the present invention,
4 to 6 are exemplary views showing a process of analyzing the weight through a rotating body weight state analyzer rule according to the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

1 is a schematic diagram showing the configuration of the rotor weight state analyzer 1 according to the present invention, Figure 2 is a block diagram showing the configuration of the rotor weight state analyzer 1 according to the present invention, Figure 3 Is a perspective view showing an enlarged configuration of the analysis body 10 of the rotating body weight state analyzer 1 according to the present invention.

As shown, the rotating body weight state analyzer 1 according to the present invention includes an input unit 300 receiving an input signal from a user, a display unit 400 displaying a result of the weight state analysis, and a plurality of rotating bodies 100. Sector classification sensor 500 for dividing into four sectors, and is spaced apart from the rotating body 100 by a predetermined interval to detect the position of each sector by detecting the sector classification sensor 500 when the rotating body 100 is rotated Proximity sensor 600, and the control unit 800 for analyzing the weight of each sector of the rotating body 100 by the detection position for each sector measured by the proximity sensor 600.

 Here, the input unit 300, the display unit 400, the control unit 800 is provided integrally inside the analysis body (10). Accordingly, the worker can carry out the weight analysis work only carrying the analysis body 10 and the proximity sensor 600.

The rotating body 100 may be used for air preheaters of various power plants. The rotating body 100 includes an element 120 and an element cage 110 for receiving and supporting the element 120 therein.

The rotation driving unit 200 is provided at the lower portion of the element cage 110 to provide a driving force to rotate the rotating body 100. The rotary driving unit 200 may include a driving source (not shown) such as a motor, and a support plate 210 that rotates by a driving force of the driving source (not shown) and supports the rotating body 100.

The analysis body 10 is formed in a bag-like shape to facilitate carrying by the operator. As shown in FIG. 3, the analysis body 10 is formed of a lower casing 11 and an upper casing 13 opened and closed by the lower casing 11. The lower casing 11 includes an input unit 300, a display unit 400, and a controller 800. The input unit 300 and the display unit 400 are provided to be exposed to the outside when the upper casing 13 is opened, and the controller 800 is provided inside the lower casing 11.

In addition, a timer 700 is built in the analysis body 10 to measure the time after the start of work so that the rotational speed is calculated.

The input unit 300 receives a work start signal from a worker, receives a job end signal, and receives a number of the sector classification sensor 500. The input unit 300 may be formed of a plurality of buttons or switches, and in some cases, may be formed in the form of a touch panel on the display unit 400.

The display unit 400 displays a state in which the rotating body weight state analyzer 1 operates under the control of the controller 800 and an analysis result. The display unit 400 displays setting values for setting the respective components before the operation of the rotor weight state analyzer 1, and displays the measurement time for each sector acquired from the proximity sensor 600 during the operation operation. After the operation is completed, the position at which the additional weight is to be attached is displayed based on the measurement time and the rotational speed of each sector.

The sector classification sensor 500 is attached to the outside of the element cage 110 to divide the rotating body 100 into a plurality of sectors. Sector classification sensor 500 is provided in a form that can recognize the laser signal. The sector classification sensor 500 is attached to the outside of the element cage 110 at regular angle intervals.

The proximity sensor 600 is disposed to be spaced apart from the rotating body 100 by a predetermined interval to recognize the sector classification sensor 500. The proximity sensor 600 recognizes the sector classification sensor 500 attached to the outer circumference of the rotating body 100 when the rotating body 100 is rotated by the rotating driving unit 200, and thus each sector is rotated once. Obtain the measurement time data that is recognized.

The proximity sensor 600 according to the present invention recognizes the sector classification sensor 500 using a laser. That is, the position of the sector classification sensor 500 is recognized by the laser light emitted from the proximity sensor 600 being reflected from the sector classification sensor 500 and received.

The number of uses of the sector classification sensor 500 can be selected by the operator according to the size of the rotating body (100). That is, when the rotor 100 is divided into 12 sectors, 12 sector classification sensors 500 are used. When the rotor 100 is divided into 24 sectors, 24 sector classification sensors 500 are used.

The position of each section of the rotating body 100 divided by the sector classification sensor 500 to be used is input by the operator through the input unit 300 as a sequential number.

The proximity sensor 600 recognizes the sector classification sensor 500 in a non-contact manner. To this end, the proximity sensor 600 is fixed to the position of the sensor support 610 as shown in FIG. The proximity sensor 600 transmits the measurement time data obtained by being electrically connected to the analysis body 10 to the controller 800 of the analysis body 10.

Proximity sensor 600 may be provided in plurality for the reliability of the measurement results. In addition, a plurality of sensors may be used to prepare for a case in which one sensor malfunctions or malfunctions.

The analysis body 10 is provided with a selection button 620 for selecting a plurality of proximity sensors 600. The plurality of selection buttons 620 are connected to different proximity sensors 600, respectively, and the proximity sensor 600 corresponding to the selection button 620 selected by the operator detects the position of the sector. In some cases, the plurality of proximity sensors 600 may detect the position of the sector together.

The controller 800 analyzes the rotational speed of each sector based on the measurement time when the proximity sensor 600 detects the position of each sector. Then, by analyzing the rotational speed of each sector to analyze the weight of the entire rotating body, to analyze the position to attach the additional weight to solve the unevenness of the weight.

The controller 800 analyzes the rotational speed of each sector based on the control board (not shown) having various control panels and wires for power supply, and the position data received from the proximity sensor 600, and attaches additional weights. And a storage unit 810 in which software for analyzing the data is stored.

The controller 800 discards the unstable initial data and the late data among the measurement time data received from the proximity sensor 600 a plurality of times, and analyzes the weight using the middle stable data.

For example, when the total number of rotation bodies 100 is rotated and the measurement time of the sector is measured, the controller 800 discards the first and sixth measurement time data, and averages the four measurement time data measured in the middle. Calculate the rotation speed with the value and analyze the weight.

The controller 800 calculates the rotational variation rate for each sector based on the measurement time, and calculates a position to attach the additional weight. The attachment position of the additional weight is selected as the time point of acceleration by comparing the rotational speed of each sector. This is because the position where the acceleration is attached rotates differently from other sectors due to the weight unbalance with the opposite section.

The weight of the weight is a value that can solve the weight unbalance, and is calculated by referring to the weight condition table. The weight size is selected by finding the intersection of the spot steel plate thickness and the upper limit of the steel weight profile. Among the values selected by the intersection point, the weight is selected to be mountable in the field.

The weight analysis process through the rotor weight state analyzer 1 according to the present invention having such a configuration will be described with reference to FIGS. 1 to 6.

First, the operator checks whether the rotary drive unit 200 is driven to rotate the rotary body 100. When it is confirmed that the rotation driving unit 200 is smoothly driven, the proximity sensor 600 and the analysis body 10 are installed on one side of the rotating body 100. Proximity sensor 600 is installed to be supported by the sensor support 610, the analysis body 10 is installed to be electrically connected to the proximity sensor 600.

Check whether the proximity sensor 600 and the sector classification sensor 500 are operating properly. That is, the laser beam is stably transmitted from the proximity sensor 600 and the laser beam is reflected by the sector classification sensor 500 to confirm whether the mechanism received by the proximity sensor 600 is stably implemented.

If such work is preceded, the operator divides the rotor 100 into a plurality of sectors. The number of sectors is selected, and the sector classification sensor 500 is attached to the positions of the selected sectors.

The operator inputs the position where the proximity sensor 600 is disposed and the number of the sector classification sensor 500 through the input unit 300 as shown in FIG. 4. That is, the total number of sector classification sensors 500 are input, and the numbers of the sector classification sensors 500 are sequentially input.

When the input of the sector classification sensor 500 is completed, the operation is started by clicking the start button. When the operation is started, the rotation driving unit 200 is rotated, the timer 700 measures the time. As the rotation driving unit 200 rotates, the proximity sensor 600 continuously generates the laser light, and the sector classification sensor 500 attached to the outside of the rotating body 100 reflects the laser light.

The proximity sensor 600 detects that the laser light is reflected and is received, and transmits a measurement time at which the detection signal is received to the controller 800. The proximity sensor 600 sequentially transmits the detected time of the plurality of sectors arranged along the circumferential direction to the controller 800, and the controller 800 stores the measured measurement time.

The display unit 400 displays a measurement screen as shown in FIG. 5. The controller 800 may display the measurement time of each sector measured five times on the display unit 400. The controller 800 calculates the rotation speed of each sector based on the detected measurement time. At this time, the initial and late unstable data are deleted, and the average is calculated using the stable data. Based on the calculated average measurement time, a sector having a relatively large change in rotational speed is determined. At this time, the number of revolutions (rpm) of the rotary drive unit 200 and the time measured by the timer are displayed together on the display screen.

Accordingly, the weight state of the entire rotating body 100 is analyzed, and as shown in FIG. 6, the point to which the additional weight is to be attached is displayed. That is, as shown in FIG. 6, the display unit 400 indicates that an additional weight of 89.97 kg should be attached to the sector # 5. At this time, the position of the proximity sensor 600 is also displayed.

As described above, the rotating body weight state analyzer according to the present invention can prevent errors caused by manual measurement by an operator by using an automatic measuring method using a proximity sensor and a sector classification sensor, and ensure reliability of data.

Therefore, the vibration state of the rotating body can be corrected by accurately correcting the weight state of the rotating body.

In addition, since the proximity sensor is a non-contact method, it is possible to ensure the safety of the operator.

In addition, it is possible to increase the convenience of the maintenance work of the rotating body since the calculated state of the weight after calculation and display to the attachment position of the weight.

The embodiment of the rotating body weight analyzer of the present invention described above is merely exemplary, and those skilled in the art to which the present invention pertains can make various modifications and other equivalent embodiments therefrom. You can see well. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

1: Weight analysis state of the rotating body 10: Analysis body
100: rotating body 200: rotating drive part
300: input unit 400: display unit
500: Sector classification sensor 600: Proximity sensor
700: Timer 800: Control Unit
810: storage unit

Claims (6)

In the weight analyzer of the rotor for air preheater,
The rotating body includes an element and an element cage accommodating the element therein;
A rotation driving unit rotatably supporting the rotating body;
A sector classification sensor coupled to the predetermined angle along the circumferential direction of the rotating body to divide the rotating body into a plurality of sectors;
A proximity sensor disposed to be spaced apart from the rotor to sense the sector classification sensor when the rotor is rotated;
A controller for detecting a rotation speed for each sector based on the measurement time for each sector detected by the proximity sensor, and analyzing the weight state for each sector based on the rotation speed; And
And an input unit receiving a sector number of each sector to which the sector classification sensor is attached from a user, and receiving a measurement start signal and a measurement end signal.
The method of claim 1,
And the controller analyzes a sector position to which an additional weight is attached in order to equalize the weight of the entire rotating body based on the analyzed weight state for each sector.
delete The method of claim 1,
And a display unit for displaying the weight state analyzed by the control unit for each sector, and displaying a position to which the additional weight is to be attached.
5. The method of claim 4,
And the sector classification sensor and the proximity sensor are configured to detect a position by transmitting and receiving laser light.
The method of claim 1,
The control unit repeatedly receives the measurement time data of each sector from the proximity sensor a plurality of times repeatedly for a predetermined time, and based on the intermediate measurement time data excluding the initial measurement time data and the later measurement time data among the received data. Rotor weight condition analyzer for air preheater, characterized in that for analyzing the weight state of the whole.

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