阅读说明：本技术 一种带转子故障检测装置的高速电机 (High-speed motor with rotor fault detection device ) 是由 王家堡 于 2019-12-07 设计创作，主要内容包括：本发明公开了一种带转子故障检测装置的高速电机,包括前端盖(1)和后端盖(11)、机座(2)、定子铁芯(3)、转子支承(4),所述转子支承(4)包括转子铁芯(41)、转轴(42)、前后接触式轴承(43)以及故障监控装置(44),所述故障监控装置(44)由弹力元件(441)、传输线(442)和控制器(443)组成,所述转子铁芯(41)、前后接触式轴承(43)压装在转轴(42)上,所述故障监控装置(44)的弹力元件(441)端部设有电阻应变片,所述电阻应变片固定在前端盖(1)或后端盖(11)的轴承室的凹槽内,所述电阻应变片与控制器通过传输线(442)实现电性连接,所述控制器内设有滤波器、放大器、转换器。本发明具有成本低、结构简单、使用方便的特点。(The invention discloses a high-speed motor with a rotor fault detection device, which comprises a front end cover (1), a rear end cover (11), a machine base (2), a stator core (3) and a rotor support (4), wherein the rotor support (4) comprises a rotor core (41), a rotating shaft (42), a front-back contact type bearing (43) and a fault monitoring device (44), the fault monitoring device (44) consists of an elastic element (441), a transmission line (442) and a controller (443), the rotor core (41) and the front-back contact type bearing (43) are pressed on the rotating shaft (42), a resistance strain gauge is arranged at the end part of the elastic element (441) of the fault monitoring device (44), the resistance strain gauge is fixed in a groove of a bearing chamber of the front end cover (1) or the rear end cover (11), and is electrically connected with the controller through the transmission line (442), and a filter, an amplifier and a converter are arranged in the controller. The invention has the characteristics of low cost, simple structure and convenient use.)

1. The utility model provides a take rotor fault detection device's high-speed motor, includes front end housing (1) and rear end housing (11), frame (2), stator core (3), rotor support (4), its characterized in that: the rotor support (4) comprises a rotor iron core (41), a rotating shaft (42), a front-back contact type bearing (43) and a fault monitoring device (44), the fault monitoring device (44) consists of an elastic element (441), a transmission line (442) and a controller (443), the rotor iron core (41) and the front-back contact type bearing (43) are pressed on the rotating shaft (42), a resistance strain gauge is arranged at the end part of the elastic element (441) of the fault monitoring device (44), the resistance strain gauge is fixed in a groove of a bearing chamber of a front end cover (1) or a rear end cover (11), the resistance strain gauge is electrically connected with the controller through the transmission line (442), a filter, an amplifier and an A/D converter are further arranged in the controller, the resistance strain gauge is connected with the filter and the amplifier, and the filter and the amplifier are connected with the A/D converter, the A/D converter is embedded with a microchip.

2. The high-speed motor with the rotor fault detection device according to claim 1, characterized in that: still be equipped with display, siren and processing module in the controller, processing module is the PLC module, processing module passes through transmission line (442) and is connected with the resistance foil gage of elastic element (441), processing module's output is connected with display and siren respectively.

3. The high-speed motor with the rotor fault detection device according to claim 1, characterized in that: the filter is a low-pass filter consisting of an operational amplifier LF356, a resistor and a capacitor, and the micro chip embedded in the A/D converter consists of an 8098 single chip microcomputer chip.

Technical Field

The invention belongs to the technical field of high-speed driving motor design, and particularly relates to a high-speed motor with a rotor fault detection device.

Background

Generally, the motor is defined as a high-speed motor when the rotating speed is 10kr/min or the linear speed of the surface of a rotor is more than 100m/s, and mainly comprises a high-speed asynchronous motor, a high-speed brushless direct current motor, a high-speed permanent magnet synchronous motor and a high-speed reluctance motor. The high-speed motor has the advantages of high rotating speed, high efficiency and the like, is widely applied to a plurality of industrial fields, and is required to be driven by the high-speed motor in the fields of sewage treatment, natural gas transportation and the like, flywheel energy storage, turbocharging systems and the like; in the field of high-precision machining, the machining precision and the yield can be effectively improved by adopting the high-speed motorized spindle, and the market demand and the economic benefit are huge. In order to avoid the mechanical stress of the material of the rotor from being greater than the maximum value of the specified allowable stress, the rotor of the motor is usually designed to be slender to reduce the linear velocity of the outer surface of the rotor, or a sheath component is added on the outer surface of the rotor to improve the allowable stress, so that the stability and reliability are increased, but the high-speed motor occasionally has an overload or overspeed operation condition, so that the problems of excessive mechanical stress, excessive temperature rise, material failure and the like exist, the outer surface of the rotor rotating at high speed and the inner diameter of the stator are rubbed with each other, and the performance of the motor is deteriorated or burnt. Because the rotor that high speed operation is in the inside of motor, whether its damage, or the damage degree is difficult to observe from the motor outside, in addition, some damage because the damaged area is little, the surface is difficult to observe, consequently is difficult to perceive, can't judge that the rotor has had trouble hidden danger or has broken down. The rotor supporting system of the high-speed motor can stably, safely and reliably operate for a long time and can not be practically applied. The bearings widely adopted in various high-speed motors at present can be divided into two types, namely a contact type bearing and a non-contact type bearing, wherein the former is mainly a high-speed ball bearing, and the latter comprises an air bearing and a magnetic suspension bearing, wherein the contact type ball bearing is the most widely applied bearing type in the field of motors and has the advantages of strong robustness, low cost, small size and the like. At present, relevant documents and reports do not exist in online real-time detection of high-speed motor rotor faults, or the online real-time detection is still in a research stage.

Disclosure of Invention

The invention aims to solve the problem that the contact type ball bearing supports the rotor running at a high speed, the running state of the high-speed rotor is difficult to observe online in real time when a high-speed motor runs, if the rotor has structural faults such as deformation, mutual friction and the like, the structural faults cannot be found in time, and measures are taken, so that severe safety accidents can be caused. The utility model provides a take rotor fault detection device's high-speed electric machine carries out effectual, real-time monitoring to the rotor of high-speed operation, carries out effectual control when guaranteeing that the rotor structural failure appears, overcomes prior art's shortcoming and not enough.

The invention adopts the following technical scheme:

the utility model provides a take rotor fault detection device's high-speed motor, includes front end housing (1) and rear end housing (11), frame (2), stator core (3), rotor support (4), its characterized in that: the rotor support (4) comprises a rotor iron core (41), a rotating shaft (42), a front-back contact type bearing (43) and a fault monitoring device (44), the fault monitoring device (44) consists of an elastic element (441), a transmission line (442) and a controller (443), the rotor iron core (41) and the front-back contact type bearing (43) are pressed on the rotating shaft (42), a resistance strain gauge is arranged at the end part of the elastic element (441) of the fault monitoring device (44), the resistance strain gauge is fixed in a groove of a bearing chamber of a front end cover (1) or a rear end cover (11), the resistance strain gauge is electrically connected with the controller through the transmission line (442), a filter, an amplifier and an A/D converter are further arranged in the controller, the resistance strain gauge is connected with the filter and the amplifier, and the filter and the amplifier are connected with the A/D converter, the A/D converter is embedded with a microchip.

Furthermore, still be equipped with display, siren and processing module in the controller, processing module is the PLC module, processing module passes through transmission line (442) and is connected with the resistance strain gauge of elastic element (441), processing module's output is connected with display and siren respectively.

Still further, the filter is a low-pass filter composed of an operational amplifier LF356, a resistor and a capacitor, and the micro chip embedded in the A/D converter is composed of an 8098 single chip microcomputer chip.

The invention has the beneficial effects that:

1. the invention realizes that the fault monitoring of the motor can be realized by adding a groove for fixing the elastic resistance strain gauge in the bearing chamber of the end cover and matching with a fault monitoring device on the premise that the running performance, the external installation size and the internal structure of the high-speed motor are not changed.

2. The detection signal and the control system form closed-loop control, real-time on-line detection without shutdown can be realized, the signal of the stress change is tested and fed back in real time according to the resistance strain gauge, the unattended state is realized, and the safe and reliable operation of the system is ensured.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic diagram illustrating the deformation of the elastic element under stress when the motor of the present invention fails;

FIG. 3 is a schematic diagram of the fault monitoring apparatus of the present invention;

FIG. 4 is a schematic diagram of the fault monitoring apparatus of the present invention;

fig. 5 is a schematic diagram of the operation of the fault monitoring device of the present invention.

In the figure: 1-front end cover, 11-rear end cover, 2-base, 3-stator core, 4-rotor support, 41-rotor core, 42-rotating shaft, 43-front and rear contact type bearing, 44-fault monitoring device, 441-elastic element, 442-transmission line and 443-control line.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 4, the present invention provides a high-speed motor with a rotor fault detection device, which includes: the motor comprises a front end cover 1, a rear end cover 11, a machine base 2, a stator core 3 and a rotor support 4, wherein the front end cover 1 and the rear end cover 11 are respectively installed at two ends of the machine base 2, the stator core 3 is fixedly installed at two ends of the machine base 2, the rotor support 4 comprises a rotor core 41, a rotating shaft 42, a front-back contact type bearing 43 and a fault monitoring device 44, the fault monitoring device 44 consists of an elastic element 441, a transmission line 442 and a controller 443, the rotor core 41 and the front-back contact type bearing 43 are pressed on the rotating shaft 42, a resistance strain gauge is arranged at the end part of the elastic element 441 of the fault monitoring device 44, the resistance strain gauge is fixed in a groove of a bearing chamber of the front end cover 1 or the rear end cover 11 and is electrically connected with the controller 43 through the transmission line 442, and a filter, an amplifier and an A/D converter are arranged in, resistance strain gauge is connected with filtering, the amplifier in controller 43, the output and the AD converter of filtering, amplifier are connected, the inside microchip that has inlayed of AD converter still sets up display, siren and processing module in the controller 43, processing module is the PLC module, processing module passes through the resistance strain gauge of transmission line 442 and elastic element 441 and is connected, processing module's output is connected with display and siren respectively.

Specifically, the filter in the invention is a low-pass filter composed of an operational amplifier LF356, a resistor and a capacitor, and the embedded microchip in the A/D converter is composed of an 8098 singlechip chip.

The working principle of the invention is as follows: when the rotor core 41 running at high speed is deformed, the outer ring of the contact bearing 43 is stressed unevenly at different positions, uneven acting force acts on the elastic element 441 at the moment, the magnitude of the stress deformation of the elastic element 441 is different, a resistance strain gauge arranged on the elastic element 441 measures a signal of the stress change, the unbalanced strain force is converted into a weak electric signal through an external strain bridge, the weak electric signal penetrates through the front end cover 1 or the rear end cover 11 through a transmission line 442 and is led out, the weak electric signal and an analog signal arranged in the controller 43 are filtered, amplified, sampled and kept and then are transmitted to an A/D (analog/digital) for conversion, a digital signal obtained after the conversion is output to a processing module in the controller 443 for analysis, the digital signal is processed and then displayed on line, an alarm signal is generated, so that a countermeasure can be taken in time, and the rotor fault running at high speed can be pre-judged and detected in real time, the safe and reliable operation of the system is ensured.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.