CN108414202A - A kind of high speed rotation shafting dynamic radial load stiffness test method and device - Google Patents

Abstract

The invention discloses a kind of high speed rotation shafting dynamic radial load stiffness test method and devices, method includes to electromagnetism winding output driving current, record the radial displacement of driving current and displacement sensor output, the radial displacement for determining live spindle, the Radial magnetic force applied to live spindle, the ratio between the radial displacement of Radial magnetic force, live spindle that calculating applies to live spindle is as the ratio between the Fourier transformation result of the first dynamic stiffness and/or aforementioned the two of calculating as the second dynamic stiffness；Device includes stator holder and rotor clamper, stator holder is equipped with two electromagnetism windings that accommodating hole, displacement sensor and relative rotor fixture are arranged symmetrically, rotor clamper is arranged in accommodating hole, the outer wall of rotor clamper is equipped with servo-motor silicon steel sheet rotor, and servo-motor silicon steel sheet rotor is arranged between two electromagnetism windings.The present invention has the advantages that high certainty of measurement, strong applicability, measurement is convenient, low energy consumption, can realize regulated linear load.

Description

A kind of high speed rotation shafting dynamic radial load stiffness test method and device

Technical field

The present invention relates to the dynamic stiffness measuring technologies of high-speed machine tool main shaft, high-speed electric main shaft and high-speed electric expreess locomotive, and in particular to A kind of high speed rotation shafting dynamic radial load stiffness test method and device, for completing high-speed electric main shaft and high-speed electric expreess locomotive Radial non-contact load and dynamic stiffness test.

Background technology

High-speed machine tool main shaft is the core functional components of modern machine, and effect is band cutter (grinding wheel) or workpiece rotation Turn, realizes high-speed ＆ precise progressive die.With the continuous improvement that modern industry requires machine finish and processing efficiency, lathe pair The requirement of main shaft performance is also higher and higher.Rigidity is to weigh one of the important indicator of high-speed machine tool main shaft performance.Main axis stiffness packet Include the Static stiffness under stationary state and dynamic stiffness when running at high speed.Stiffness excitations that are feasible in engineering at present and being widely adopted Method is Static stiffness test method.But Static stiffness is under the conditions of can not really reflect that main shaft bears chip-load when running at high speed The dynamic bearer properties of the ability of resistance to deformation, only dynamic stiffness ability science reflection main shaft.And the use in engineering at present Dynamic stiffness test method is since there are various limitations, it is difficult to promote the use of.

At present there is dynamic stiffness test method in engineering：

1, non-contact air-bearing loaded type measuring device, the advantage is that, contactless with main shaft, be conducive in high speed rotation It is loaded under state.Its shortcoming is that：A. the rigidity of air-bearing is smaller, and loading force is limited；B. air supporting loaded type measuring device accounts for It is also big with space, it is restricted by main shaft external part space；C. it is difficult to remain air supporting state, the thickness of air film in loading procedure Only micron dimension, in loading procedure, be easy because load biasing occur gas bearings and main shaft tested surface touch mill accident.

2, contactless liquid suspension loaded type measuring device, load capability are loaded higher than air supporting, but complicated, are held Liquid leakage easily occurs, is restricted by load space, is only applicable in specifically testing main shaft.

3, " belt-type " contact measurement device, its advantage is that it is easy to operate, to main shaft space without particular/special requirement.Its deficiency is " belt " and main shaft direct friction, fever is serious and easy to wear, is not suitable for using when main shaft high speed.

4, it hangs weight and loads measuring device, i.e., be set with rolling bearing in axle stretch end, weight is hung on rolling bearing.This method It is disadvantageous in that：(1) rigidity of vertical direction can only be measured；(2) when major axis size is larger, bearing size is big, vibrated Limitation, is only suitable for using in the case of the speed of mainshaft is relatively low.

5, rolling bearing type loads measuring device, i.e., the outer circle of main shaft projecting end is directly acted on rolling bearing outer circle. This method is disadvantageous in that：(1) for load bearings with main shaft high speed rotation, noise is big, and vibration is big, and load bearings are easy fever And it damages；(2) bearing is that smooth normal direction contacts with main shaft outer circle, and the position for loading contact point is easy to happen offset, causes to test As a result inaccurate.

6, unidirectional electromagnetism loaded type measuring device, disadvantage is that, (1) electromagnetic force is with axle journal displacement at nonlinear dependence System, it is difficult to which accurate calibration, test result are easy to happen error；(2) when measured surface is non-magnetic, measurement method is not applicable；(3) axis It is that smooth normal direction contacts to hold with main shaft outer circle, and the position for loading contact point is easy to happen offset, causes test result inaccurate； (4) when magnetic bearing stator and closer rotor surface distance, since electromagnetic attraction increases sharply, it is easy to stick together, in master In the state of axis high speed rotation, it is easy to frictional heating occur and burn even safety accident.

Invention content

The technical problem to be solved in the present invention：For the above problem of the prior art, a kind of high certainty of measurement is provided, is applicable in Property it is strong, measure the high speed rotation shafting dynamic radial load stiffness test method that convenient, low energy consumption, can realize regulated linear load And device.

In order to solve the above-mentioned technical problem, the technical solution adopted by the present invention is：

A kind of high speed rotation shafting dynamic radial load stiffness test method, implementation steps include：

1) in advance in the live spindle of tested high speed rotation shafting installation rotor, on flange installation for passing through rotor Apply two electromagnetism windings of Radial magnetic force and at least one for detecting live spindle radial displacement to live spindle Displacement sensor, two electromagnetism winding relative rotors are arranged symmetrically；The driving exported to an electromagnetism winding when being tested Electric current is i₀+i_x, to another electromagnetism winding export driving current be i₀-i_x, wherein i₀On the basis of electric current, i_xIt is electric in order to control Stream, records the radial displacement of change with time driving current and displacement sensor output, and redirects and execute next step；

2) radial displacement exported according to displacement sensor determines the radial displacement of live spindle；

3) Radial magnetic force applied to live spindle is determined according to the radial displacement of driving current, live spindle；

4) ratio between the radial displacement of calculating applies to live spindle Radial magnetic force, live spindle is as test Obtained the first dynamic stiffness output；And/or calculate the Fourier transformation result of the Radial magnetic force applied to live spindle, rotation The second dynamic stiffness output that ratio between the Fourier transformation result of the radial displacement of main shaft is obtained as test.

Preferably, shown in the function expression such as formula (1) that the Radial magnetic force applied to live spindle is determined in step 3)：

In formula (1), f_x(t) it is the Radial magnetic force applied to live spindle, k_iElectric current ratio between two electromagnetism windings Example coefficient, k_sFor the displacement scale coefficient between two electromagnetism windings, i_xElectric current in order to control, x are the radial displacement of live spindle, k For the proportionality coefficient of electromagnetism winding, i₀On the basis of electric current, s₀For the benchmark event of live spindle.

Preferably, the quantity of displacement sensor is two or more in step 1), is exported according to displacement sensor in step 2) Radial displacement determine and specifically refer to be made even by the radial displacement that each displacement sensor exports when the radial displacement of live spindle It is worth to.

A kind of test device for the aforementioned high speed rotation shafting dynamic radial load stiffness test method of the application present invention, Including stator holder and rotor clamper, the stator holder is equipped with accommodating hole, displacement sensor and relative rotor folder Have two electromagnetism windings being arranged symmetrically, the rotor clamper is arranged in accommodating hole, and the outer wall of the rotor clamper is equipped with Servo-motor silicon steel sheet rotor, the servo-motor silicon steel sheet rotor are arranged between two electromagnetism windings.

Preferably, there is described two electromagnetism windings public driving unit, the driving unit to include add circuit, subtract Method circuit, the first amplifying circuit and the second amplifying circuit, the add circuit, subtraction circuit both an input terminal with for Reference current is connected, another input degree is connected with control electric current, and the output end of the add circuit passes through the first amplifying circuit It is connected with an electromagnetism winding, the output end of the subtraction circuit is connected by the second amplifying circuit with another electromagnetism winding.

Preferably, interior magnetism-isolating loop is equipped with positioned at the inside of servo-motor silicon steel sheet rotor, be located at silicon steel on the outer wall of the rotor clamper The outside of piece rotor is equipped with outer magnetism-isolating loop, and the servo-motor silicon steel sheet rotor is arranged between interior magnetism-isolating loop, outer magnetism-isolating loop.

Preferably, the stator holder is equipped with inner end cap and outer end cap, and the electromagnetism winding is clamped respectively to be arranged in Between inner end cap and outer end cap, and the interior magnetism-isolating loop and inner end cap is adjacent and gap is arranged, the outer magnetism-isolating loop and outer end cap Adjacent and gap is arranged.

Preferably, the inner end of the stator holder is equipped with mounting base, and the stator holder is installed to by mounting base On the high-speed electric expreess locomotive flange of tested high speed rotation shafting.

Preferably, the rotor clamper is circular ring shape, and the outside of the rotor clamper is equipped with for locking rotor clamper Rotor clamper is locked and is clamped to the high-speed electric expreess locomotive rotation master of tested high speed rotation shafting by locking nut, the locking nut On axis.

Preferably, two electromagnetism windings are vertically arranged on same straight line up and down.

High speed rotation shafting dynamic radial load stiffness test method of the present invention has following advantageous effects：

1, the present invention in the live spindle of tested high speed rotation shafting installation rotor, on flange installation for by turning Son applies two electromagnetism windings of Radial magnetic force and at least one for detecting live spindle radial displacement to live spindle Displacement sensor, two electromagnetism winding relative rotors are arranged symmetrically, and rotor clamper is arranged in accommodating hole, rotor clamper it is outer Wall is equipped with servo-motor silicon steel sheet rotor, and servo-motor silicon steel sheet rotor is arranged between two electromagnetism windings, the driving exported to an electromagnetism winding Electric current is i₀+i_x, to another electromagnetism winding export driving current be i₀-i_x, by controlling two electromagnetism winding current summations It is constant, when the load of electromagnetism winding, trunnion offset, ensure that the variable quantity of two electromagnetism winding currents is equal in magnitude, according to magnetic The active force of the action principle of suction, two electromagnetism windings synthesis just keeps linearly proportional with the increment of electric current, such as This can eliminate the non-linear of single side electromagnetism loaded ribbon, realize stable linear loading.

2, the present invention in the live spindle of tested high speed rotation shafting installation rotor, on flange installation for by turning Son applies two electromagnetism windings of Radial magnetic force and at least one for detecting live spindle radial displacement to live spindle Displacement sensor, rotor clamper is arranged in accommodating hole, and the outer wall of rotor clamper is equipped with servo-motor silicon steel sheet rotor, servo-motor silicon steel sheet rotor It is arranged between two electromagnetism windings, using the contactless load test form of this kind of stator and rotor, exists between the two Gap, avoidable stator rotor touch mill safety accident.

3, high speed rotation shafting dynamic radial of the present invention loads stiffness test method low noise, and vibrations are small, and test environment is good； Controlled current flow, it is easy to accomplish automation is easy to implement the digitlization and automation of test；Fever is few, and energy consumption is very low, overcomes liquid The high energy consumption of body gas bearing load.

High speed rotation shafting dynamic radial load device for testing stiffness of the present invention has following advantageous effects：

1, the present invention includes stator holder and rotor clamper, and stator holder is equipped with accommodating hole, and accommodating hole is equipped with Two electromagnetism windings that displacement sensor and relative rotor fixture are arranged symmetrically, rotor clamper are arranged in accommodating hole, rotor The outer wall of fixture is equipped with servo-motor silicon steel sheet rotor, and servo-motor silicon steel sheet rotor is arranged between two electromagnetism windings, can be by controlling two electricity Magnetic winding current summation is constant, when the load of electromagnetism winding, trunnion offset, ensures that the variable quantity of two electromagnetism winding currents is big Small equal, according to the action principle of magnetic attraction, the active force of two electromagnetism windings synthesis is just kept with the increment of electric current into line Sex ratio relationship can so eliminate the non-linear of single side electromagnetism loaded ribbon, realize stable linear loading.

2, stator holder of the present invention is equipped with accommodating hole, and accommodating hole is equipped with displacement sensor and relative rotor fixture Two electromagnetism windings being arranged symmetrically, displacement sensor are an entirety, servo-motor silicon steel sheet rotor with electromagnetism winding and stator assembly It is corresponding with displacement sensor tested surface, electromagnetism winding load when, can measure simultaneously measured surface generation displacement with Calculate dynamic stiffness.

3, stator holder of the present invention is equipped with accommodating hole, and displacement sensor and electromagnetism winding and stator holder are direct Flange coupling with high-speed electric main shaft or high-speed electric expreess locomotive is integrated, and rigidity is good, it is easy to accomplish load avoids individually designed test Rack and the error fixed the trouble of magnetic bearing stator module and thus brought.

4, stator holder of the present invention is equipped with accommodating hole, and rotor clamper and servo-motor silicon steel sheet rotor can make standardised series The test original paper of change makes different standard components according to different electro spindles or motor overhanging end interface；Equally, stator is fixed Seat, electromagnetism winding and displacement sensor may be alternatively configured the test component of standardised series, according to electro spindle or motor flange Different structure makes different standard components, is conducive to promote and apply, strong applicability.

5, the present invention in the live spindle of tested high speed rotation shafting installation rotor, on flange installation for by turning Son applies two electromagnetism windings of Radial magnetic force and at least one for detecting live spindle radial displacement to live spindle Displacement sensor, rotor clamper is arranged in accommodating hole, and the outer wall of rotor clamper is equipped with servo-motor silicon steel sheet rotor, servo-motor silicon steel sheet rotor It is arranged between two electromagnetism windings, using the contactless load test form of this kind of stator and rotor, exists between the two Gap, avoidable stator rotor touch mill safety accident.

6, apparatus of the present invention low noise, vibrations are small, and test environment is good；Controlled current flow, it is easy to accomplish automation is easy to implement The digitlization and automation of test；Fever is few, and energy consumption is very low, overcomes the high energy consumption of liquefied gas bearing load.

Description of the drawings

Fig. 1 is the schematic cross-sectional view of device of the embodiment of the present invention.

Fig. 2 is the circuit theory schematic diagram of driving unit in the embodiment of the present invention.

Marginal data：1, stator holder；10, accommodating hole；11, inner end cap；12, outer end cap；13, mounting base；2, rotor Fixture；3, electromagnetism winding；31, add circuit；32, subtraction circuit；33, the first amplifying circuit；34, the second amplifying circuit；4, position Displacement sensor；5, servo-motor silicon steel sheet rotor；6, interior magnetism-isolating loop；7, outer magnetism-isolating loop；8, locking nut.

Specific implementation mode

Embodiment one：

The present embodiment high speed rotation shafting dynamic radial load stiffness test method implementation steps include：

1) in advance in the live spindle of tested high speed rotation shafting installation rotor, on flange installation for passing through rotor Apply two electromagnetism windings of Radial magnetic force and at least one for detecting live spindle radial displacement to live spindle Displacement sensor, two electromagnetism winding relative rotors are arranged symmetrically；The driving exported to an electromagnetism winding when being tested Electric current is i₀+i_x, to another electromagnetism winding export driving current be i₀-i_x, wherein i₀On the basis of electric current, i_xIt is electric in order to control Stream, records the radial displacement of change with time driving current and displacement sensor output, and redirects and execute next step；

2) radial displacement exported according to displacement sensor determines the radial displacement of live spindle；

3) Radial magnetic force applied to live spindle is determined according to the radial displacement of driving current, live spindle；

4) ratio between the radial displacement of calculating applies to live spindle Radial magnetic force, live spindle is as test Obtained the first dynamic stiffness output.

In the present embodiment, the function expression such as formula (1) of the Radial magnetic force applied to live spindle is determined in step 3) It is shown：

In formula (1), f_x(t) it is the Radial magnetic force applied to live spindle, k_iElectric current ratio between two electromagnetism windings Example coefficient, k_sFor the displacement scale coefficient between two electromagnetism windings, i_xElectric current in order to control, x are the radial displacement of live spindle, k For the proportionality coefficient of electromagnetism winding, i₀On the basis of electric current, s₀For the benchmark event of live spindle.

For single electromagnetism winding, shown in the expression formula such as formula (1-1) of the magnetic attraction generated；

In formula (1-1), F_cFor the magnetic attraction that electromagnetism winding generates, μ₀For the magnetic conductivity of electromagnetism winding core material, N is electricity The coil turn of magnetic winding, A be magnetic circuit cross-sectional area, i be electromagnetism winding size of current, δ be electromagnetism winding magnetic pole with The distance between rotor end-face, k are the proportionality coefficient of electromagnetism winding.From formula (1-1) as can be seen that the magnetic that electromagnetism winding generates Power F_cIt is square directly proportional to the size of current i's of electromagnetism winding, the distance between the magnetic pole of electromagnetism winding and rotor end-face δ's It square is inversely proportional；Therefore, the magnetic attraction F that electromagnetism winding generates_cWith the size of current i of electromagnetism winding, electromagnetism winding magnetic pole with Nonlinear relationship is presented in the distance between rotor end-face δ, is unfavorable for the adjusting and control of loaded load in operation. In view of the above technical problems, installation applies the two of Radial magnetic force to live spindle for passing through rotor on flange in the present embodiment A electromagnetism winding, two electromagnetism winding relative rotors are arranged symmetrically, and are further used as shown in formula (1-2), and mode realizes magnetic Linearisation (the i.e. plus load of magnetic attraction and the size of current i of electromagnetism winding, the magnetic pole and rotor end-face of electromagnetism winding of suction The distance between δ it is linearly proportional) so that the function table of Radial magnetic force applied to live spindle is determined in step 3) Up to shown in formula such as formula (1)；

In formula (1-2), f₁(t) Radial magnetic force applied to live spindle for an electromagnetism winding, f₂(t) it is another The Radial magnetic force that electromagnetism winding applies to live spindle, each parameter connotation is identical as formula (1), and details are not described herein.

In the present embodiment, the quantity of displacement sensor is two in step 1), is exported according to displacement sensor in step 2) Radial displacement determine and specifically refer to be made even by the radial displacement that each displacement sensor exports when the radial displacement of live spindle It is worth to.

As shown in Figure 1, the test dress for Application Example high speed rotation shafting dynamic radial load stiffness test method It sets including stator holder 1 and rotor clamper 2, stator holder 1 is equipped with accommodating hole 10, displacement sensor 4 and turns relatively Two electromagnetism windings 3 that sub-folder tool 2 is arranged symmetrically, rotor clamper 2 are arranged in accommodating hole 10, are set on the outer wall of rotor clamper 2 There are servo-motor silicon steel sheet rotor 5, servo-motor silicon steel sheet rotor 5 to be arranged between two electromagnetism windings 3.In the present embodiment, 5 interference of servo-motor silicon steel sheet rotor connects Female connector rotates on rotor clamper 2 with the high-speed electric expreess locomotive live spindle of tested high speed rotation shafting (measurand)；It holds By added radial load, the high-speed electric expreess locomotive live spindle of tested high speed rotation shafting (measurand) is transferred load to； Set two displacement sensors 4 in the present embodiment altogether, the outside of each electromagnetism winding 3 sets that there are one displacement sensors 4, uses respectively In top displacement and lower section displacement of the measurement rotor under the action of radial load.

In the present embodiment, two electromagnetism windings 3 have public driving unit, as shown in Fig. 2, driving unit includes addition Circuit 31, subtraction circuit 32, the first amplifying circuit 33 and the second amplifying circuit 34, both add circuit 31, subtraction circuit 32 Uniform a input terminal electric current on the basis of is connected, another input degree is connected with control electric current, and the output end of add circuit 31 is logical The first amplifying circuit 33 is crossed with an electromagnetism winding 3 to be connected, the output end of subtraction circuit 32 by the second amplifying circuit 34 with it is another One electromagnetism winding 3 is connected.

In the present embodiment, interior magnetism-isolating loop 6 is equipped with positioned at the inside of servo-motor silicon steel sheet rotor 5 on the outer wall of rotor clamper 2, is located at silicon The outside of steel disc rotor 5 is equipped with outer magnetism-isolating loop 7, and servo-motor silicon steel sheet rotor 5 is arranged between interior magnetism-isolating loop 6, outer magnetism-isolating loop 7.It is interior every magnetic 6 interference connector sleeve of ring rotates on rotor clamper 2 with high-speed electric expreess locomotive live spindle；Added radial load is born, will be carried Lotus passes to high-speed electric expreess locomotive live spindle；7 interference connector sleeve of outer magnetism-isolating loop is on rotor clamper 2, with high-speed electric expreess locomotive live spindle It rotates together；Added radial load is born, high-speed electric expreess locomotive live spindle is transferred load to.

In the present embodiment, stator holder 1 is equipped with inner end cap 11 and outer end cap 12, and arrangement is clamped in electromagnetism winding 3 respectively Between inner end cap 11 and outer end cap 12, and interior magnetism-isolating loop 6 and inner end cap 11 is adjacent and gap is arranged, outer magnetism-isolating loop 7 and outer end Lid 12 is adjacent and gap is arranged.Inner end cap 11 is connected as an entirety with stator holder 1, while as upper displacement sensor Support construction；Support construction of the stator holder 1 as upper and lower two electromagnetism windings 3, at the same with tested high speed rotation shafting The flange of (measurand) is connected as an entirety by bolt etc..

In the present embodiment, the inner end of stator holder 1 is equipped with mounting base 13, and stator holder 1 is installed by mounting base 13 Onto the high-speed electric expreess locomotive flange of tested high speed rotation shafting (measurand).Tested high speed rotation shafting (measurand) Connected support structure of the high-speed electric expreess locomotive flange as stator holder 1 is considered as fixed structure in the course of work；Electromagnetism around When group 3 is powered to the generation magnetic attraction load of rotor clamper 2, it is (tested that electromagnetism winding 3 can react on tested high speed rotation shafting Object) flange.

In the present embodiment, rotor clamper 2 is circular ring shape, and the outside of rotor clamper 2 is equipped with the lock for locking rotor clamper 2 Rotor clamper 2 is locked and is clamped to the high speed electricity of tested high speed rotation shafting (measurand) by tight nut 8, locking nut 8 In machine live spindle, form an entirety.For tested high speed rotation shafting (measurand), high-speed electric expreess locomotive rotation master High speed rotation when axis works, is subject to the part of loaded load, radial displacement is also by the parameter of sensor test.Rotor presss from both sides Tool 2 is clamped in high-speed electric expreess locomotive live spindle and with high-speed electric expreess locomotive live spindle high speed rotation, bears added load, Transfer load to high-speed electric expreess locomotive live spindle；Since itself and high-speed electric expreess locomotive live spindle are connected as one, displacement sensor is surveyed Its radial displacement of examination namely the radial displacement of high-speed electric expreess locomotive live spindle.

In the present embodiment, two electromagnetism windings 3 are vertically arranged on same straight line up and down, referring to Fig. 2, this reality It applies and is respectively labeled as winding 3#2, f under electromagnetically winding 3#1 and electromagnetism in example_xFor the Radial magnetic force applied to live spindle, x For the radial displacement of live spindle.Electromagnetically after winding 3#1 galvanizations, electric current induction generates magnetic field, is generated to servo-motor silicon steel sheet rotor 5 The size of upward magnetic attraction, electric current changes, and magnetic attraction can accordingly change；Under electromagnetism after winding 3#2 galvanizations, electric current induction production Magnetisation field generates servo-motor silicon steel sheet rotor 5 downward magnetic attraction；The size of electric current changes, and magnetic attraction can accordingly change.

Embodiment two：

The present embodiment and embodiment one are essentially identical, and main distinction point is only to calculate to apply to live spindle in step 4) Ratio between the Fourier transformation result of the radial displacement of the Fourier transformation result, live spindle of the Radial magnetic force added is made To test the second obtained dynamic stiffness output.Shown in the function expression such as formula (2) for calculating the second dynamic stiffness：

In formula (2), K (ω) is the second dynamic stiffness (amount with frequency change), and F (ω) is the radial direction applied to live spindle The Fourier transformation of magnetic attraction f (t) is as a result, X (ω) is the Fourier transformation of the radial displacement x (t) of live spindle as a result, f (t) For the Radial magnetic force applied to live spindle, x (t) is the radial displacement of live spindle, and t is the time.

Embodiment three：

The present embodiment and embodiment one are essentially identical, and main distinction point is not only to calculate to apply to live spindle in step 1) The first dynamic stiffness output that ratio between the radial displacement of the Radial magnetic force, live spindle that add is obtained as test, simultaneously The Fourier for also calculating the radial displacement of the Fourier transformation result, live spindle of the Radial magnetic force applied to live spindle becomes The second dynamic stiffness output that the ratio changed between result is obtained as test, for details, reference can be made to embodiments for the calculating of the second dynamic stiffness Two.

Example IV：

The present embodiment and embodiment one are essentially identical, and main distinction point is that the quantity of displacement sensor in step 1) is single It is a, thus in step 2) according to displacement sensor export radial displacement determine the radial displacement of live spindle when, displacement sensing The radial displacement of device output is the radial displacement of live spindle.In addition it is also possible to which the substantially increase in embodiment one is more (>2) displacement sensor determines the radial displacement of live spindle in step 2) according to the radial displacement of displacement sensor output When, can also equally the radial displacement exported by each displacement sensor be used to be averaged to obtain the radial position of live spindle It moves.

Although the present invention has been disclosed as a preferred embodiment, however, it is not intended to limit the invention.It is any to be familiar with ability The technical staff in domain, without deviating from the scope of the technical scheme of the present invention, all using the technology contents pair of the disclosure above Technical solution of the present invention makes many possible changes and modifications, or is revised as the equivalent embodiment of equivalent variations.Therefore, every Without departing from the content of technical solution of the present invention, according to the present invention technical spirit any simple modification made to the above embodiment, Equivalent variations and modification, all shall fall within the protection scope of the technical scheme of the invention.

Claims (10)

1. a kind of high speed rotation shafting dynamic radial loads stiffness test method, it is characterised in that implementation steps include：

1) in advance in the live spindle of tested high speed rotation shafting installation rotor, on flange installation for by rotor to rotation Turn main shaft and applies two electromagnetism windings of Radial magnetic force and at least one displacement for detecting live spindle radial displacement Sensor, two electromagnetism winding relative rotors are arranged symmetrically；The driving current exported to an electromagnetism winding when being tested For i₀+i_x, to another electromagnetism winding export driving current be i₀-i_x, wherein i₀On the basis of electric current, i_xElectric current in order to control, note The radial displacement of change with time driving current and displacement sensor output is recorded, and redirects and executes next step；

2) radial displacement exported according to displacement sensor determines the radial displacement of live spindle；

3) Radial magnetic force applied to live spindle is determined according to the radial displacement of driving current, live spindle；

4) ratio between the radial displacement of calculating applies to live spindle Radial magnetic force, live spindle is obtained as test The first dynamic stiffness output；And/or calculate Fourier transformation result, the live spindle of the Radial magnetic force applied to live spindle Radial displacement Fourier transformation result between ratio as test obtain the second dynamic stiffness output.

2. high speed rotation shafting dynamic radial according to claim 1 loads stiffness test method, which is characterized in that step 3) shown in the function expression such as formula (1) for determining the Radial magnetic force applied to live spindle in：

In formula (1), f_x(t) it is the Radial magnetic force applied to live spindle, k_iFor the current ratio system between two electromagnetism windings Number, k_sFor the displacement scale coefficient between two electromagnetism windings, i_xElectric current in order to control, x are the radial displacement of live spindle, and k is electricity The proportionality coefficient of magnetic winding, i₀On the basis of electric current, s₀For the benchmark event of live spindle.

3. high speed rotation shafting dynamic radial according to claim 1 loads stiffness test method, which is characterized in that step 1) quantity of displacement sensor is two or more in, is determined according to the radial displacement of displacement sensor output in step 2) and rotates master It specifically refers to be averaged to obtain by the radial displacement that each displacement sensor exports when the radial displacement of axis.

4. a kind of for using any one of claims 1 to 3 high speed rotation shafting dynamic radial load stiffness test method Test device, it is characterised in that：Including stator holder (1) and rotor clamper (2), the stator holder (1), which is equipped with, holds Set two electromagnetism windings (3) that hole (10), displacement sensor (4) and relative rotor fixture (2) are arranged symmetrically, the rotor folder Tool (2) is arranged in accommodating hole (10), and the outer wall of the rotor clamper (2) is equipped with servo-motor silicon steel sheet rotor (5), and the silicon steel sheet turns Sub (5) are arranged between two electromagnetism windings (3).

5. high speed rotation shafting dynamic radial according to claim 4 loads device for testing stiffness, it is characterised in that：It is described Two electromagnetism windings (3) have a public driving unit, the driving unit include add circuit (31), subtraction circuit (32), First amplifying circuit (33) and the second amplifying circuit (34), the add circuit (31), subtraction circuit (32) both one Input terminal and i₀On the basis of electric current be connected, another input degree with control electric current i_xIt is connected, the output end of the add circuit (31) It is connected with an electromagnetism winding (3) by the first amplifying circuit (33), the output end of the subtraction circuit (32) is put by second Big circuit (34) is connected with another electromagnetism winding (3).

6. high speed rotation shafting dynamic radial according to claim 5 loads device for testing stiffness, it is characterised in that：It is described Interior magnetism-isolating loop (6) is equipped with positioned at the inside of servo-motor silicon steel sheet rotor (5), be located at servo-motor silicon steel sheet rotor (5) on the outer wall of rotor clamper (2) Outside is equipped with outer magnetism-isolating loop (7), and the servo-motor silicon steel sheet rotor (5) is arranged between interior magnetism-isolating loop (6), outer magnetism-isolating loop (7).

7. high speed rotation shafting dynamic radial according to claim 6 loads device for testing stiffness, it is characterised in that：It is described Stator holder (1) is equipped with inner end cap (11) and outer end cap (12), and the electromagnetism winding (3) is clamped is arranged in inner end cap respectively (11) between outer end cap (12), and the interior magnetism-isolating loop (6) and inner end cap (11) is adjacent and gap is arranged, the outer magnetism-isolating loop (7) and outer end cap (12) is adjacent and gap is arranged.

8. high speed rotation shafting dynamic radial according to claim 4 loads device for testing stiffness, it is characterised in that：It is described The inner end of stator holder (1) is equipped with mounting base (13), and the stator holder (1) is installed to tested by mounting base (13) On the high-speed electric expreess locomotive flange of high speed rotation shafting.

9. high speed rotation shafting dynamic radial according to claim 4 loads device for testing stiffness, it is characterised in that：It is described Rotor clamper (2) is circular ring shape, and the outside of the rotor clamper (2) is equipped with the locking nut for locking rotor clamper (2) (8), rotor clamper (2) is locked and is clamped to the high-speed electric expreess locomotive rotation of tested high speed rotation shafting by the locking nut (8) On main shaft.

10. high speed rotation shafting dynamic radial according to claim 4 loads device for testing stiffness, it is characterised in that：Two A electromagnetism winding (3) is vertically arranged on same straight line up and down.