RU2144728C1 - Stator test technique and facility - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: stator testing for performance characteristics such as resistance, extra current, sense of rotation, and breakdown voltage conducted before its connection with rotor consists in placing it positioning and locking unit, applying control voltage to it for resistance measurements followed by display or measurement results, and also applying extra current to stator for measuring and displaying this characteristic; then specified voltage is applied for detecting sense of rotation of standard rotor and displaying results obtained; specified voltage is also applied to stator to measure its breakdown value and displaying results. Facility implementing this technique has control unit that receives start- of-test instruction from key input unit and functions to control resistance measurement unit, extra current testing unit, breakdown voltage measuring unit, and sense-of-rotation detecting unit for determining sense of rotation of standard rotor which is set in rotary motion due to current supplied to stator under test; facility also has stator positioning and locking unit and display unit. EFFECT: reduced number of motor troubles caused by stator; reduced troubleshooting time. 6 cl, 7 dwg

Description

 The present invention relates to the creation of a device for testing the stator and method of its implementation, and more specifically, relates to the creation of a device for testing the stator and method of its implementation, in which a variety of tests, such as testing the characteristics of the resistance, characteristics of the extracurrent, direction of rotation and withstand voltage of the stator previously connecting the fully fabricated stator to the rotor is carried out, so that the number of defective motors as a result of a mismatch can be reduced stator and the time required to detect a stator defect.

 Recently, a variety of engines have been used as a drive for various electronic household appliances such as washing machines and air conditioners. In its most general form, the motor includes a stator, which forms a magnetic field, and a rotor, which is driven by the magnetic field of the stator. Such a general purpose engine is shown in FIG. 1 and 2.

 In FIG. 2 shows a stator 3 of a motor 1 comprising a plate core 3f having a plurality of magnetic pole pieces 3c, the main windings (coils) 3a and the auxiliary windings (coils) 3b being wound around the magnetic pole pieces 3c. In addition, the insulator 3e isolates from the plate core 2 of the respective windings 3a and 3b having three output terminals 3d, the main windings 3a being wound around the magnetic pole pieces 3c, and the auxiliary windings 3b wound between the respective main windings 3a.

 Three output terminals 3d, coming from the corresponding coils 3a and 3b, are connected to the terminals of the network wires, with the main, auxiliary and zero conclusions marked in red, blue and white, respectively.

 As shown in FIG. 1, the rotor 2, which includes the axis 2a, the first bearing 2b, the plate core of the rotor 2c and the second bearing 2d, is placed in the cavity formed in the Central part of the stator 3. After installing the rotor, connect the upper 1a and lower 1b half of the housing to form a single the housing of the stator 3 and rotor 2, which completes the manufacturing process of the motor 1.

 When power is supplied from an external three-phase AC source (not shown) to the motor terminals, a predetermined magnetic field is formed between the main windings 3a and the auxiliary stator windings 3b.

 In this case, the current induced by the magnetic field flows through the surface of the core of the rotor 2c and causes the rotor 2 to rotate. Due to the alternating excitation of the magnetic field in the respective windings 3a and 3b of the stator 3, the rotor 2 is driven into continuous rotation.

 After the engine has been completely assembled, said engine 1 undergoes various tests, for example, tests of the resistance characteristics, characteristics of the extracurrent, rotation direction and withstand voltage of the stator. Typically, several operators manually test engine 1, moreover, to test the quality of engine 1, these various tests are carried out individually.

 After that, the engine manufactured in this way is subjected to tests of drive characteristics; if the engine passes these tests, then its quality is good and it is put on the market; if not, then his quality is poor and he is getting married.

 However, the reasons why the engine mismatch is detected may be due to defects in the stator or rotor. Thus, if a completely manufactured motor is defective due to a technical defect associated with the stator, then a good rotor, which is installed in an engine with a poor stator, also goes into marriage, which leads to unjustified economic losses.

 Moreover, if a defective motor is disassembled to reduce economic losses, in order to replace a defective stator with a good one and use it with an existing rotor of good quality, then in this case, the completely assembled motor is disassembled and then reassembled. This increases the manufacturing time of the engine and there is a problem of increasing operator labor.

 As the closest analogue / prototype / to the present invention, a solution is known, known from the laid out application JP 58-133145.

 In accordance with the present invention, it is proposed to overcome the above problems of the prior art. The first objective of the present invention is to provide a device for testing the stator, which makes it possible to avoid sending the engine to the marriage due to a stator defect, as it allows to evaluate the quality of the stator using various test methods before the final assembly of the engine.

 Another object of the present invention is to provide a method for testing a stator using said stator testing device.

 To solve the first problem of the present invention, the stator testing device includes a control unit for receiving a start-up (test) command from a key input unit, as well as a resistance measuring unit controlled from the control unit and allowing to measure the resistance value of the tested stator. The stator test device also includes an extra-current characteristic test unit controlled from the control unit and allowing to measure the extra-current characteristic of the test stator, an withstand voltage measurement unit controlled from the control unit and allowing to measure the withstand voltage characteristic of the tested stator, and a rotation direction detection unit controlled from the control unit and allowing to determine the direction of rotation of the reference rotor, which rotates due to current, by applying emogo subject to the stator. Additionally, the locking unit in a certain position allows the test stator to be mounted to carry out the corresponding tests, and the display unit allows the results of the corresponding tests to be displayed using the control unit.

 To solve the second problem of the present invention, the stator test method includes a first operation of installing the test stator in the fixation unit in a specific position, a second operation of applying a control voltage to the test stator installed in a certain position in the fixation unit by performing the first operation to measure the value resistance and indication of the result. After that, the third operation of the method is carried out by applying an extracurrent to the test stator, installed in a certain position in the fixation unit, to measure the characteristics of the extracurrent and indicate the result. Then, the fourth operation of the method is carried out by applying a predetermined voltage to the test stator installed in a certain position in the fixation unit to measure the direction of rotation of the reference rotor and indicate the result. After this, the fifth operation of the method is carried out by applying a predetermined voltage to the test stator, installed in a certain position in the fixing unit, to measure the characteristics of the withstand voltage and indicate the result.

 The above and other characteristics of the invention will be more apparent from the following detailed description of the preferred options for its implementation, given with reference to the accompanying drawings.

 In FIG. Figure 1 shows a perspective view of a general-purpose engine in a disassembled state, where you can see its design.

 In FIG. 2 is a perspective view of the stator of FIG. 1.

 In FIG. 3 is a block diagram of an advantageous embodiment of a stator test apparatus in accordance with the present invention.

 In FIG. 4 is a circuit diagram of a resistance measuring unit in accordance with the present invention.

 In FIG. 5 is a side view of a unit for measuring the direction of rotation and a fixing unit in a specific stator position in accordance with the present invention.

 In FIG. 6 schematically shows an indication unit in accordance with the present invention.

 In FIG. 7 is a flowchart illustrating a stator test method in accordance with the present invention.

 Next will be described in detail the preferred embodiment of the device for testing the stator in accordance with the present invention and the method of its implementation, with reference to the accompanying drawings, in which the same reference numbers denote similar nodes.

 As shown in FIG. 3, the control unit 20 receives a command to start work from the key input unit 10, included by the tester. In this case, the control unit 20 is a general purpose programmable logic chip (PLC).

 The resistance measuring unit 30 is controlled by a control signal supplied from the control unit 20 to measure the resistance value of the tested stator 3, and the extracurrent 40 characteristic is measured by the control signal supplied by the control unit 20 from the control unit 20 to measure the characteristics of the tested stator extracurrent 3.

 The withstand voltage measuring unit 50 is controlled by a control signal supplied from the control unit 20 to measure the withstand voltage characteristics of the tested stator 3, and the rotation direction measuring unit 60 is controlled by a control signal supplied from the control unit 20 to measure the direction of rotation a reference rotor 61 driven into rotation by a current supplied to the test stator 3.

 The fixation unit in a certain position 70 allows the test stator 3 to be fixed on the upper surface of the working table 72 to carry out the tests described above, and the display unit 80 allows the results of the corresponding tests to be displayed using the control unit 20.

 In FIG. 4 is a circuit diagram of a resistance measuring unit in accordance with the present invention.

 As shown in FIG. 4, the first and second electronic switches 32 and 33, which can be turned on / off by the control unit 20, are connected in series to the main terminal M of the tested stator 3, and the third and fourth electronic switches 34 and 35, which can be turned on / off when using the control unit 20, are connected in series to the auxiliary terminal S of the tested stator 3. The fifth and sixth electronic switches 36 and 37, which can be turned on / off by the control unit 20, are connected in series to the common terminal C of the tested stator 3.

 In addition, a voltmeter 31 is provided, which can be connected to the main and auxiliary terminals M and S, connected in parallel with the electronic switches 32 and 35, and which can be connected to a common terminal C connected to the electronic switches 36 and 37 separately from the main and auxiliary conclusions M and S.

 In FIG. 5 is a side view of a unit for detecting a direction of rotation and a fixing unit in a specific stator position in accordance with the present invention.

 As shown in FIG. 5, the locking unit 70 in a certain position allows mounting using the mandrel 71 of the test stator 3 on the upper surface of the working table 72 to carry out the corresponding tests.

 The unit for detecting the direction of rotation 60 is equipped with a reference rotor 61 located in the lower part of the working table 72 with a stator 3 mounted on it and a cylinder 65 connected to the lower part of the reference rotor 61 for moving it up / down to enter the rotor 61 into the test stator 3 and the conclusion from it.

 In addition, the bracket 64 is mounted on a shaft 62 extending from the bottom of the reference rotor 61, and a rotation direction detection sensor 63 is provided near the bracket 64 to measure the rotation direction of the bracket 64.

 In FIG. 6 schematically shows an indication unit 80 in accordance with the present invention, which provides for connection to respective test units 30, 40, 50, and 60, the control unit 20 formed by the computer system 21 controlling the operation of the respective test units 30, 40, 50, and 60 and allows you to display the test results in the display unit 80.

 Advantageously, the display unit 80 has an alarm lamp 81, which flashes red when a defective element (stator) is detected or green when a good element is detected, and also displays on the front panel the total number (TN) of products remaining to check the number (RN) products and the number of defective (DN) products counted by the control unit 20.

 In FIG. 7 is a flowchart illustrating a stator test method in accordance with the present invention. Next, the operation of the device in accordance with the present invention will be described in detail with reference to FIG. 7.

 First of all, after installing the stator 3 in the mandrel 71 on the upper surface of the working table 72, the tester turns on the key input unit 10 and gives the command to start work (testing) from the block 10 to the control unit 20, which allows you to start the operation of the device for testing the stator in accordance with the present invention. At the first stage, the resistance measuring unit 30 measures the voltage across the tested stator 3 in order to measure the resistance value of the tested stator 3 (operations S 101 and S 102).

 After that, the control unit 20 displays the resistance value measured by the resistance measuring unit 30 using the display unit 80, which allows the tester to judge whether the resistance value is normal or not (step S 103).

 If we describe the above operations in more detail, as shown in FIG. 4, the control unit 20 supplies control signals to the first and second electronic switches 32 and 33, as well as to the fifth and sixth electronic switches 36 and 37, and turns on the corresponding electronic switches 32, 33, 35 and 36.

 After that, the control unit 20 supplies a current, for example, 1A (amperes) to the test stator 3, while the current 1A flows through the circuit formed by the fifth and sixth electronic switches 36 and 37 and the first and second electronic switches 32 and 33, through the main terminal M and the common terminal C of the tested stator 3. In this case, the voltmeter 31 measures the voltage occurring on the tested stator 3 when current 1A flows.

 In this case, the digital voltage value corresponds to the value of the total resistance of the main winding of the tested stator 3, namely, V = R, since the current is 1 A and from Ohm's law V = 1 x R. The voltage value measured by voltmeter 31 on command from the control unit 20 it is indicated in the display unit 80, which allows the tester to judge whether the resistance value of the tested stator 3 is normal or not, analyzing the displayed digital value.

 Additionally, the control unit 20 removes the control signal supplied to the first and second electronic switches 32 and 33, which leads to their shutdown, and supplies the enable control signal to the third and fourth electronic switches 34 and 35, which allows measurement of the resistance value between the auxiliary output S and the common terminal C of the tested stator 3. The resistance value measured at this time is displayed on the display unit 80 as described previously.

 After the measurement of the resistance value described above between the auxiliary terminal S and the common terminal C of the test stator 3, the control unit 20 supplies the switching control signal to the first and second electronic switches 32 and 33, as well as to the third and fourth electronic switches 34 and 35, which allows measurement of the resistance value between the main terminal M and the auxiliary terminal S of the tested stator 3. The resistance value measured at this time is indicated on the display unit 80 using the control unit 20 en similar to that described previously, which allows the tester to judge whether the resistance value of the tested stator 3 is normal or not.

 In the second stage of the tests, the control unit 20 supplies a control signal to the test unit for measuring the characteristics of the extracurrent 40. The extract in this case is the overload current or pulse current periodically supplied to the test object by a given pulse signal. At the same time, the test unit for measuring the characteristics of the extracurrent 40 supplies a predetermined pulse signal to the test stator 3, which is installed in the fixation unit at a certain position 70, to indicate the impulse response of the test stator 3 in the display unit 80.

 As a result, the tester can judge whether the test stator 3 is normal or not by analyzing the pulse shape of the test stator 3 in the display unit 80 (steps S 104 and S 105).

 After that, the control signal from the control unit 20 is supplied to the rotation direction detection unit 60, while the rotation direction detection unit 60 sets the reference rotor 61 inside it into the cavity existing inside the test stator 3.

 When a predetermined voltage is applied to the test stator 3, the reference rotor 61 starts to rotate due to the magnetic field created by the tested stator 3. At this time, the direction of rotation of the reference rotor 61 is checked.

 In other words, when after the tester installs the test stator 3 in the mandrel 71 on the upper surface of the working table 72, the tester includes a key input unit 10, a control signal is supplied to the cylinder 65 from the control unit 20 to raise the reference rotor 61 due to the operation of the cylinder 65. B As a result, the reference rotor 61 is inserted into the cavity of the test stator 3.

 After that, using the control unit 20, the three-phase voltage is applied to the output terminals 3d of the test stator 3 and the reference rotor 61 starts to rotate with the magnetic field of the windings 3a and 3b of the test stator 3 created by the AC power source. When the reference rotor 61 is rotated, the bracket 64 mounted on the shaft 62 at the bottom of the reference rotor 61 is also rotated from the reference rotor 61.

 In this case, the rotation direction detection sensor 63, installed close to the bracket 64, determines the rotation direction of the bracket 64 and provides a corresponding signal to the control unit 20. In turn, the control unit 20, upon receipt of a signal from the rotation direction detection sensor 63, determines whether the direction of rotation of the reference rotor 61 in the forward direction.

 The corresponding signal of the direction of rotation of the reference rotor 61 from the control unit 20 is supplied to the display unit 80 or to the output sound signaling unit (not shown) available in the unit 80, which allows the tester to judge whether the rotation characteristics in the forward or reverse directions of the tested stator 3 are good or not (operations S106 and S 107).

 Then, from the control unit 20, a control signal is supplied to the test unit 50 withstand voltage characteristics to carry out the test of the withstand voltage of the tested stator 3. And in this case, since the test results are displayed in the display unit 80, the tester can easily determine the cause of the defect of the tested stator 3 (operations S 108 and S 110).

 As a result, when after the tester installs the test stator 3 in the fixation unit at a certain position 70, the tester turns on the test setup, the impedance, the characteristics of the extracurrent, the reverse rotation characteristics and the withstand voltage of the tested stator 3 are sequentially measured using the control voltage supplied from the control unit 20.

 All tests of the manufactured stator 3 are carried out after its installation in the fixation unit in a certain position 70, which simplifies the testing process and reduces the testing time of the tested stator 3.

 As described above, all tests of the manufactured stator 3 are carried out before the final assembly of the engine using the stator test device and the method of its implementation in accordance with the present invention, therefore, the economic losses caused by the sending of the finished engine to the marriage due to a defective stator are reduced.

 Moreover, since the corresponding tests of the fabricated stator 3 are carried out sequentially after its installation in the fixing unit at a certain position 70, the cause of the defect can easily be found, while the required test time is reduced.

 Despite the fact that the preferred embodiment of the invention has been described, it is completely clear that it will be modified and supplemented by those skilled in the art that do not, however, go beyond the scope of the following claims.

Claims (6)

 1. The method of testing the stator, which consists in installing the test stator in the fixation unit in a certain position, applying a control voltage to the test stator to measure the resistance value, followed by an indication of the result, characterized in that an extra is supplied to the test stator to measure the characteristics of the extra current and indication of the result, apply the specified voltage to the test stator to measure the direction of rotation of the reference rotor and indicate the result, and the applied voltage is applied to the test stator to measure the characteristics of the withstand voltage and indicate the result.  2. A stator test device comprising a control unit for receiving a test start command from a key input unit, a resistance measurement unit controlled from a control unit and allowing to measure a resistance value of a test stator, a fixation unit in a certain position of a test stator for performing corresponding tests, and a unit indications for indicating test results associated with the control unit, characterized in that it further includes an ex-characteristic test unit a circuit controlled from the control unit and allowing to measure the characteristic of the extracurrent of the tested stator, and a resistive voltage measurement unit controlled from the control unit and allowing to measure the characteristic of the withstand voltage of the tested stator, a rotation direction detection unit controlled from the control unit and allowing to determine the rotation direction of the reference rotor, which rotates due to the current supplied to the test stator.  3. The device for testing the stator according to claim 2, characterized in that the control unit is a computer system.  4. The device for testing the stator according to claim 2, characterized in that the control unit is made in the form of a programmable logic chip.  5. The device for testing the stator according to claim 2, characterized in that the resistance measurement unit includes first and second electronic switches controlled by the control unit and connected in series to the main terminal of the tested stator, third and fourth electronic switches, controlled control units and connected sequentially to the auxiliary output of the test stator, the fifth and sixth electronic switches controlled by the control unit and connected in series to the general output of the test about the stator, and a voltmeter connected to the primary and secondary terminals, connected in parallel said respective electronic switches, and which is connected to a common terminal connected to said corresponding electronic switches connected in parallel, separately from the main and auxiliary pin.  6. The stator testing device according to claim 2, characterized in that the rotation direction detection unit includes a reference rotor located in the lower part of the working table with a stator mounted on it, a cylinder connected to the lower part of the reference rotor for moving it up / down to enter the rotor into the test stator and withdraw the rotor from it, a bracket mounted on a shaft extending from the bottom of the reference rotor, and a rotation direction detection sensor located close to the bracket for measuring the direction of rotation bracket bracket.

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