KR200404111Y1 - Dynamic Analysis Simulator For Rotary Machines - Google Patents

Abstract

The present invention relates to a simulation apparatus for analyzing the causes and operating results of abnormal dynamic characteristics of a rotating machine.

The disclosed apparatus includes a base having a cover for moving and protecting each component, a driving unit provided on the base and having two driving shafts for controlling rotational speed and torque, and rotating around the driving shaft. It is characterized by consisting of a rotating part.

In particular, for the simulation of the rotation axis center shift phenomenon, the dynamic characteristics analysis of the rotor comprising a first bearing portion and a second bearing portion for enabling simultaneous simultaneous movement control of the position of the rotation axis center in the horizontal and vertical directions It relates to a simulation device.

Through the device of the present invention as described above, by simulating the cause and effect of the abnormal vibration and rotational motion characteristics of various rotating machines in the industrial site, it helps to acquire the abnormal diagnosis technology of the rotating body, as well as In this way, it is possible to reduce the risk of diagnosing on-site facilities and to analyze the cause of defects quickly and accurately.

Description

Simulation device for analyzing the dynamic characteristics of a rotary machine {Dynamic Analysis Simulator For Rotary Machines}

The present invention relates to a simulation device for analyzing the characteristics of the rotary motion of the rotary machine.

As much of modern industrial equipment and equipment consists of rotors and power transmission systems, the need for and the use of diagnostic techniques for the characteristics of rotating machinery are very high in actual industrial sites.

In the light industry sectors such as automobiles, there is a direct impact on the performance and quality of the products, and in the case of power generation or steel industry, for large installations such as large turbines and pumps, due to their risks and importance, prompt troubleshooting by skilled technicians need.

On the other hand, abnormal vibrations and abnormal noises accompanying rotational movements are caused by various complex causes such as assembly failures of the rotor and its power transmission system, coupling and bearing failures, gear failures, axial displacement, eccentricity, and wear. do. These abnormal vibrations of the rotor reduce the performance of the product, increase the fatigue of the entire installation, reduce durability, and increase the risk of operation of the facility.

However, the abnormal dynamics of the rotational motion are abnormalities caused by a complex cause when a machine or a facility are operating, and it is difficult to identify the cause and requires a lot of time and effort to acquire the diagnosis technique.

Therefore, the present invention was devised in view of the above-described problems, and the first object of the present invention is to intentionally give a cause of abnormal vibration and abnormal noise accompanying the rotational movement, and to compare and analyze the cause and effect. To provide a simulation device for analyzing the dynamic characteristics of a rotating machine.

The second object of the present invention, in giving the cause causing the abnormal vibration and abnormal noise, by the objective and quantitative method can be assigned to the cause, the cause can be adjusted, and the different causes are combined The present invention provides a simulation apparatus for analyzing the dynamic characteristics of a rotating machine.

The third object of the present invention is to simulate the dynamic characteristics of a rotating machine that can be used to experiment with a variety of causes in a variety of fields using the same device, it is possible to easily learn the diagnostic technology of the rotating machine by repeating the contents To provide. The various causes of the above are as follows.

First, the axis shift

Second, eccentricity such as axial weight eccentricity, double-sided weight eccentricity

Third, vibration phenomenon due to tension of power transmission belt

Fourth, vibration and noise phenomena due to gear bite abnormality and gear wear

In order to achieve the above objects, the present invention provides a base portion 100 equipped with a cover 100-a for enabling to mount and protect each component, and is installed on the base portion to generate a rotational force and rotate It provides a simulation device for analyzing the dynamic characteristics of the rotor, characterized in that the drive unit is provided with a drive shaft in both directions for controlling the speed and torque, and a rotating unit rotating around the drive shaft.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

1 and 2 are a front view and a plan view of a simulation device for analyzing the dynamic characteristics of a rotating machine according to an embodiment of the present invention.

1 and 2, the driving unit includes a motor 111 provided with drive shafts in both directions for generating an intended rotational force, and a controller 112 for controlling the rotational speed and torque by controlling the motor. .

The rotating part is coupled to one axis of the drive unit by coupling the first bearing unit 120, the eccentric induction rotary disk connecting the first bearing portion and the second bearing portion 130 by coupling at both ends The third bearing part 160 and the gear part 165 which are provided in connection with the other shaft of the drive part motor 111 are provided, and 140 and 150 are provided.

The first bearing part includes a bearing 121 in contact with the rotating shaft 170, an engagement coupling between the rack gear 122 and the worm 123 integrally processed with the structure 120 including the bearing, and a bearing. It consists of a pair of linear movement guide structure (124-a, 124-b) that serves to support and support the horizontal movement of the structure (120). The horizontal movement dial gauge 125 is installed in the worm 123 meshed with the rack gear 122, so that the structure 120 including a bearing supporting the rotating shaft 170 as the dial gauge rotates in both directions. This will move horizontally.

In order to induce the cause of the shaft center shift of the rotating shaft, by adjusting the dial gauge 125 of the first bearing portion to a quantitative value, it is possible to accurately adjust the movement of the rotating shaft center in the horizontal direction.

The second bearing part includes a bearing 131 in contact with the rotating shaft 170, an engagement coupling between the rack gear 132 and the worm 133 integrally processed with the structure 130 including the bearing, and a bearing. It consists of a pair of linear movement guide structure (134-a, 134-b) that serves to support and support the vertical movement of the structure (130). The vertical movement dial gauge 135 is installed on a worm 133 that is engaged with the rack gear 132 so that the structure 130 includes a bearing for supporting the rotation shaft 170 as the dial gauge is rotated in both directions. This will move vertically.

In order to induce the cause of the shaft center shift of the rotating shaft, by adjusting the dial gauge 135 of the second bearing portion to a quantitative value, the movement of the rotating shaft center in the vertical direction can be precisely adjusted.

Referring to FIG. 7, the rack gear 702 is rotated by rotating the dial gauges 125 and 135 provided in the worm 703 in both directions by a special gear coupling 700 that can change the rotational motion into a linear motion. ) Enables horizontal and vertical movement of structures 120 and 130, including the machined and installed bearings.

This simple and effective gear coupling 700 not only can not affect the linear movement of the 702 rotational movement, but also compensates for the disadvantages of using a normal worm gear or a general rack and pinion gear and provides user convenience. can do.

The plurality of eccentric induction rotary disks (140,150) has a plurality of circumference along the circumference to selectively mount bolts and nuts that serve as quantitative weight test pieces made in advance in the intended position in order to induce eccentricity during rotation The hole 140-a is provided.

The plurality of holes 140-a are installed to provide various causes of weight eccentricity by installing their positions differently according to their inner diameters.

The third bearing part comprises a bearing 161 in contact with a rotating shaft, a belt means 164 and a gear box 165.

In order to induce the dynamic characteristics of the normal rotational movement, the drive shaft in both directions is directly connected to the other shaft of the drive unit motor 111 is installed, and corrected and installed.

This is to compare the dynamic characteristics of the normal rotational motion with the vibration characteristics caused by the abnormal rotational motion.

In the structure 160 including the bearing of the third bearing part, the dynamic characteristics of the normal rotational motion may be measured.

The tension of the belt means 164 may be adjusted to induce a vibration phenomenon due to an abnormal belt.

By replacing and installing various gear test specimens intended for the gear box 165, the wear of the gears and the cause of gear abnormalities can be induced.

Hereinafter, with reference to the accompanying drawings, it will be described in detail a preferred embodiment according to the present invention.

In the preferred embodiment 1, as shown in Figs. 1 and 2, by simultaneously adjusting the horizontal movement dial gauge 125 of the first bearing portion and the vertical movement dial gauge 135 of the second bearing portion at the same time. In addition, it is possible to induce the cause of the axis shift of the axis of rotation in the three-dimensional space as in reality.

In addition, by adjusting the rotational speed and torque of the motor 111 of the drive unit to the intended quantitative value, the first term of the second and third objects of the present invention can be achieved.

In the preferred embodiment 2, as shown in Figures 1 and 6, in the holes provided in the plurality of eccentric rotational disks (140,150), consisting of bolts and nuts and made of the desired weight Branch weight specimens can be quantitatively mounted and rotated to give eccentricity as much as the weight of the specimen, or to rotate in a state in which the weights of both sides are different from each other, so that the eccentricity of the rotation axis can be induced as it is.

In addition, by adjusting the rotational speed and torque of the motor 111 of the drive unit to the intended quantitative value, the second term of the second and third objects of the present invention can be achieved.

In the description of the preferred embodiment 3, as shown in Figs. 1 and 3, the tension of the power transmission belt 164, which is well calibrated, is adjusted to prevent vibration of the belt from defects and installation errors. The cause can be induced as if it were real. In addition, by adjusting the rotational speed and torque of the motor 111 of the drive unit to the intended quantitative value, the third term in the second and third objects of the present invention can be achieved.

In the description of the preferred embodiment 4, as shown in Figures 1 and 3, by testing the defective specimens of various gears intentionally manufactured, it is possible to induce the causes of vibration and noise due to the gear defects in reality. Can be. In addition, by adjusting the rotational speed and torque of the motor 111 of the drive unit to the intended quantitative value, the fourth term in the second and third objects of the present invention can be achieved.

In implementing the above-described preferred embodiments 1, 2, 3, and 4, the dynamic characteristics and abnormal vibration characteristics of the normal rotational motion well-corrected in the structure 160 including the bearing of the third bearing part are compared with each other. By doing so, it is possible to provide a simulation device for analyzing the dynamic characteristics of the rotor capable of comparing and analyzing the cause and effect of the abnormality.

As described above, the present invention acquires an error diagnosis technique of a rotating body and a power transmission system by simulating causes and effects in advance on abnormal vibration and rotational motion characteristics of various rotating machines used in various industrial fields. In addition to helping to improve the quality and performance of products in the development of a variety of products using rotary machines in the light industry, as well as reducing the risk of on-site facility diagnosis in the heavy industry, The cause can be analyzed quickly and accurately.

1 is a front view of the device of the present invention

2 is a plan view of the device of the present invention

3 is a side view and a third bearing portion of the device of the present invention

4 is a detailed cross-sectional view of the first bearing portion

5 is a detailed cross-sectional view of the second bearing portion

6 is a detailed view of a rotating disc for eccentric induction

7 is a side cross-sectional view of the gear portion

8 is a front view of the gear unit

* Description of the symbols used in the main parts of the drawings *

100: foundation part

100-a: protective transparent cover

111: driving motor

112: 111's controller

120: structure of the first bearing portion

121: bearing of the first bearing portion

122: rack gear of the first bearing portion

123: worm of the first bearing portion

124-a: Right horizontal movement guide of the first bearing portion

124-b: left horizontal movement guide of the first bearing portion

125: rotary dial gauge of the first bearing portion

126: basic mounting base of the first bearing part

127-a: right coupling of the first bearing part

127-b: left coupling of the first bearing portion

130: structure of the second bearing portion

131: bearing of the second bearing part

132: rack gear of the second bearing part

133: worm of the second bearing portion

134-a: right vertical movement guide of the second bearing part

134-b: left vertical movement guide of the second bearing part

135: rotary dial gauge of the second bearing portion

136: basic mounting base of the second bearing

137-a: right coupling of second bearing part

137-b: left coupling of second bearing part

140: rotating disc for first eccentric induction

140-a: Hole for installing bolts and nuts for weight specimens

150: rotational disc for induction second eccentric

160: structure of the third bearing portion

161: bearing of the third bearing part

162: wheel for connecting the first belt

163: wheel for connecting the second belt

164: Belt

165: gearbox

170: axis of rotation

702: Balanced gear in gear

703: Worm of gear part

Claims (2)

It is installed on the foundation 100 equipped with the cover 100-a for enabling the mounting and protecting of each component, and the dynamic characteristics of the well-calibrated normal rotational motion of one axis and the abnormal vibration characteristic of the other axis are mutually different. By comparing, in order to be able to compare and analyze the cause and effect of the abnormality, the drive unit 111 is provided with a drive shaft in both directions; It is connected to the other shaft of the drive unit 111 by a coupling (127-b), By rotating the quantitative numerical values in both directions of the dial gauges 125 and 135 installed in the rotary gear means 123 and 133, The horizontal and vertical movement of the structure 120, including the bearing supporting the rotating shaft 170, of the machined or installed balanced gear means 122. 132 in engagement with the rotary gear means 123, 133, A first bearing part and a second bearing part to move and adjust an axis center of the rotation shaft 170 in horizontal and vertical directions; A rotating part provided with a plurality of eccentric guiding rotary disks 140 and 150 connected to the coupling means 127-a and 137-b of the first bearing part and the second bearing part; A gear box which is connected to the other shaft of the driving unit 111 and rotated by the belt means 164 of the third bearing unit and the third bearing unit, which is well calibrated and installed to measure the dynamic characteristics of the normal rotational motion. Sudan (165) Simulation device for analyzing the dynamic characteristics of the rotor, characterized in that consisting of. A gear device capable of converting rotational motion into linear motion by engaging engagement of teeth of the rotary gear means 703 and the balanced gear means 702.