Patent Description:
When a balancing machine detects unbalance of a rotor, the measured unbalance is vector sum of the unbalance of the rotor and unbalance of the balancing machine itself. The unbalance of balancing machine includes zero-point error of balancing machine, electrical compensation unbalance possibly being applied in measuring unit of balancing machine, as well as the unbalance of balance tooling and drive component that being connected mechanically with the rotor being measured.

When balancing machine measures unbalance of a rotor, it is necessary to support the rotor to form rotating axis of the rotor, and to drive the rotor to reach a certain rotating speed. Balancing machines supporting and driving the rotor are classified as two cases:
The first case, when balancing machine support and drive rotor, no mechanical part on balancing machine is rigidly connected with the rotor being measured into one body and rotates together, that is, non-rigid connection, common examples are, horizontal balancing machine use rollers to support the journal of the rotor and use the rollers or belt to drive the rotor to rotate; vertical air bearing machine, the balancing machine support and drive rotor by compressed air.

The second case, when balancing machine support and drive rotor, some mechanical component on balancing machine is rigidly connected with the rotor being measured into one body and is rotating together, common examples are, horizonal balancing machine use drive shaft to drive rotor rotating; vertical balancing machine use tooling to clamp rotor and rotate together.

This invention is only related to the first case. For the first case, the unbalance of balancing machine refers to zero-point error of the balancing machine and electrical compensation unbalance possibly being applied in measuring unit of the balancing machine; But there is no unbalance of tooling and drive component that being connected mechanically with the rotor.

Corresponding to the first case, current existing technology for acquiring the unbalance of rotor and balancing machine is by changing angle reference point on the rotor, or by setting more than one angle reference points on the rotor. The problem of this technology is that, when changing angle reference point on the rotor, since the material being used for reference point always has a certain mass, changing angle reference point will influence the unbalance of the rotor, additionally, because changing angle reference point needs to be done during measuring process, it is not easy to make the angle accurate. When setting more than one reference points on rotor, misusage of reference points can happen.

<CIT> provides a method for acquiring the unbalance of a rotor. It is used for decoupling the unbalance of the rotor and the unbalance of the balancing machine itself, including: setting set at least two reference points of the unbalance on the rotor, on the plane perpendicular to the rotating axis of the rotor, there is an angle between the lines connecting the projection of each reference point to the projection of the rotating axis; measure the unbalance of the rotor in sequence by using each reference point as angle reference; through vector calculation of the unbalance corresponding to two arbitrarily selected reference points, the unbalance of the rotor is obtained. However, the method disclosed by <CIT> requires that the angle sensor is put always in a fixed angle, commonly, at <NUM> o'clock above the rotor's rotational axis, but with different heights above the rotational axis of the rotor in order to scan different reference points made on the rotor. The angle sensor RF is firstly at a higher position Po1 to scan the reference point F3, which is at a bigger radius of the rotor; then the angle sensor RF is moved to a lower position Po2 to scan the reference point F4, which is at a smaller radius of the rotor.

<CIT> discloses a method to measure and determine the unbalance of a rotor, by decoupling the unbalance of the balancing machine and the unbalance of the rotor, which includes the following procedures make the zero angle reference on the rotor or on the balancing machine, select two planes on the rotor, and use a balancing machine to measure the unbalances of the rotor in the two planes, these balances are designated as first nominal unbalances. However, the method disclosed by <CIT> requires that the angle sensor is put always in a fixed angle, commonly, at <NUM> o'clock above the rotor's rotational axis and keep this fixed position, then changing the reference point (mark) on the rotor, the first reference point p1 is made at a position on the rotor, then removes the first reference point and makes a new reference point p2 in <NUM> degree position relative to the first reference point. By respectively scanning reference mark p1 and p2 to de-compose the unbalance of the rotor and the unbalance of a balancing machine.

<CIT> (<NUM>-<NUM>-<NUM>) discloses an example of a rotor assembly wherein an unbalance of the rotor is determined based on measuring the amount of unbalance of the rotor assembly.

In view of above mentioned technical problem, the purpose of this invention is to provide a method by using only one angle reference point made on rotor to acquire the unbalance of rotor and unbalance of balancing machine.

In implementation <NUM> of this invention, a method in accordance with claim <NUM> for acquiring the unbalance of a rotor is given for decomposing the unbalance of the rotor and balancing machine itself. The specific method is that, setting angle reference point on the rotor, angle sensor is installed on the balancing machine, its position on the balancing machine is first position, when the angle sensor is on the first position, a plane being formed by it and rotating axis of the rotor is first position plane. Use the balancing machine to measure unbalance of the rotor, the measured unbalance is represented as first unbalance in measuring plane <NUM> which is perpendicular to the rotating axis; Change the position of the angle sensor from the first position to second position on balancing machine, when the angle sensor at the second position, a plane being formed by it and the rotating axis is second position plane, an angle α is formed between the second position plane and the first position plane. Measure the unbalance of the rotor again, the measured unbalance is second unbalance in the measuring plane <NUM>. During the above mentioned two unbalance measurements, the unbalance amount of the rotor has no change, however, the unbalance angle of the rotor is changed by an angle α relative to the angle reference point on rotor. Moreover, during above mentioned two measurements, the unbalance amount and angle of the balancing machine itself has no change. Accordingly, obtain the unbalance of the rotor by using vector calculation.

Implementation <NUM> can be used for the rotor with a relatively small ratio of length to diameter, selecting one measuring plane to represent its unbalance.

Implementation <NUM> is a method based on Implementation <NUM>, the specific method is that, when angle sensor is in the first position plane, using the balancing machine to measure the unbalance of the rotor, the measured unbalance is represented by two planes perpendicular to the rotating axis, that is, by first unbalance in measuring plane <NUM> and first unbalance in measuring plane <NUM>; when angle sensor is in the second position plane, using the balancing machine to measure the unbalance of the rotor again, the measured unbalance is represented by second unbalance in the measuring plane <NUM> and second unbalance in the measuring plane <NUM>. Accordingly, obtain the unbalance of the rotor in two measuring planes by using vector calculation.

Implementation <NUM> is to select two measuring planes to represent the unbalance of a rotor. For most rotors, selecting two measuring planes can represent its unbalance more accurately.

Implementation <NUM> is a method based on Implementation <NUM> or Implementation <NUM>, after measuring and calculating to obtain the unbalance of a rotor, make correction for the unbalance of rotor so that the unbalance of rotor equals to zero or is less than a setup value. In this way, a rotor with zero unbalance or with unbalance less than a setup value is acquired.

Implementation <NUM> provides a method to acquire the unbalance of a balancing machine, for decomposing the unbalance of a rotor and a balancing machine, select one measuring plane, the method is that, set angle reference point on the rotor, angle sensor is installed on the balancing machine, its position on the balancing machine is first position, when the angle sensor is on the first position, a plane being formed by it and the rotating axis of the rotor is first position plane; use the balancing machine to measure the unbalance of the rotor, the measured unbalance is represented by first unbalance in measuring plane <NUM> which is perpendicular to the rotating axis; move the angle sensor from the first position to second position on balancing machine, when the angle sensor is on the second position, a plane being formed by it and the rotating axis of the rotor is second position plane, an angle α is formed between the second position plane and the first position plane; measure the unbalance of the rotor again, the measured unbalance is second unbalance in the measuring plane <NUM>; during above mentioned two unbalance measurements, the unbalance amount of the rotor has no change, however the unbalance angle of the rotor is changed by angle α relative to the angle reference point on the rotor. Moreover, during above two measurements, the unbalance amount and angle of the balancing machine itself has no change. Accordingly, obtain the unbalance of the balancing machine by using vector calculation.

Implementation <NUM> is a method based on Implementation <NUM>, but select two measuring planes for unbalance measuring, respectively measuring plane <NUM> and measuring plane <NUM>. The method is that: when angle sensor is on the first position plane, use the balancing machine to measure the unbalance of the rotor, the measured unbalance is represented by two planes, that is, first unbalance in measuring plane <NUM> and first unbalance in measuring plane <NUM>; When angle sensor is on the second position plane, use the balancing machine to measure the unbalance of the rotor again, the measured unbalance is represented by second unbalance in the measuring plane <NUM> and second unbalance in the measuring plane <NUM>. By using vector calculation, obtain the unbalance of the balancing machine in two measuring planes.

Implementation <NUM> is a method based on Implementation <NUM> or <NUM>, after obtaining the unbalance of the balancing machine, make electrical compensation to the unbalance of the balancing machine so that the unbalance of the balancing machine is zero. Accordingly, the balancing machine with zero unbalance is acquired.

Implementation <NUM> is a method based on Implementation <NUM>, when the second unbalance in the measuring plane <NUM> and the first unbalance in the measuring plane <NUM> has the same amount and an angle difference α, it is judged that the unbalance of balancing machine is zero in the measuring plane <NUM>; when the second unbalance in the measuring plane <NUM> and the first unbalance in the measuring plane <NUM> has the same amount and an angle difference α, it is judged that the unbalance of balancing machine is zero in the measuring plane <NUM>.

This invention only needs to set one angle reference point on rotor, by changing angle sensor position on balancing machine to obtain the unbalance of rotor and balancing machine. The installation position of angle sensor can be made precisely in advance, so that changing the angle of angle sensor can be done precisely and can be implemented easily.

A sample implementation of this invention is prescribed in this section with the help of the drawings. For easier explanation, the implementation procedures are basically in the order of the realization of this invention, but some sections are not sequential, and the prescribed procedure is not unique. The procedure as below is for illustrative purpose, not all the steps are necessary, as long as that the invention can be realized. The method and procedure prescribed in this section do not in any way limit the protection area of this invention.

(A) <FIG> shows a main view of a vertical balancing machine measuring a turbocharger compressor wheel (abbreviated as compressor wheel hereafter). Compressor wheel is sometimes also called as rotor <NUM> in the following section. Balancing machine is equipped with radial air bearing <NUM> to support rotor <NUM>, the air bearing has two rows of small holes <NUM> being arranged horizontally; balancing machine is equipped with end air bearing <NUM> on which a circle of small holes <NUM> is arranged vertically. When entering compressed air <NUM>, end air bearing <NUM> blows out air through a circle of small holes <NUM> to make rotor <NUM> floating, two rows of holes <NUM> on radial air bearing <NUM> blow air outward to support the inner hole of rotor <NUM>, forming the rotating axis A1-A2 of rotor <NUM>. Air bearing <NUM> and air bearing <NUM> is mounted on vertically arranged balancing machine pedestal <NUM>, and balancing machine pedestal <NUM> connects with two vibration sensors <NUM> that are for measuring vibration signal.

<FIG> shows top view of the vertical machine measuring a compressor wheel. Compressed air <NUM> drives rotor <NUM> rotating through injecting nozzle <NUM> which is mounted on balancing machine, angular velocity speed is ω, rotating direction is shown by an arrow, that is counter-clockwise direction. Set angle increasing direction of the unbalance of rotor <NUM> as clockwise, as the marked angle on rotor <NUM> increases in clockwise direction. When balancing machine measures the unbalance of rotor <NUM>, normally the speed is relatively stable, in this implementation, it is assumed that the speed (or angular velocity ω) of rotor <NUM> is constant.

Set unbalance angle reference point <NUM> on rotor <NUM>. Angle sensor <NUM> is installed on balancing machine. When starting the measurement, angle sensor <NUM> is on first position Po1. When angle sensor <NUM> is on first position Po1 of balancing machine, a plane being formed by it and the rotating axis A1-A2 of rotor <NUM> is noted as first position plane PM1 of angle sensor <NUM>. When reference point <NUM> on rotor <NUM> passes through first position plane PM1 of angle sensor <NUM>, angle sensor <NUM> detects angle reference point <NUM> on rotor <NUM> and generates an angle referencing signal. Angle referencing signal is an impulse time signal. For easily explanation, in this implementation, the position of reference point <NUM> on rotor <NUM> is defined as the position where unbalance angle of rotor is zero. Such angle definition can be realized by the calibration of balancing machine.

(B) Referring to <FIG>, select two planes on rotor <NUM> perpendicular to the rotating axis A1-A2 for measuring the unbalance, respectively called measuring plane <NUM> PL1 and measuring plane <NUM> PL2. Use balancing machine to measure the unbalance of rotor <NUM>. The measured unbalance is represented by first unbalance U11 in measuring plane <NUM> PL1 and first unbalance U21 in measuring plane <NUM> PL2. The unbalance has amount and angle.

Plot the unbalance U11 and U21 onto the plane coordinate, as shown in <FIG>. The origin of the coordinate is zero point for the amount of the measured unbalance, zero degree of the coordinate is zero degree for the angle of the rotor unbalance, that is, the angle of reference point <NUM>.

The measured unbalance U11 and U21 is vector sum of the unbalance of rotor <NUM> and the unbalance of balancing machine.

(C) Move angle sensor <NUM> on balancing machine from first position Po1 to second position Po2. When angle sensor <NUM> is on second position Po2 of balancing machine, a plane being formed by it and the rotating axis A1-A2 of rotor <NUM> is noted as second position plane PM2 of angle sensor <NUM>. When reference point <NUM> on rotor <NUM> passes through second position plane PM2 of angle sensor <NUM>, angle sensor <NUM> detects angle reference point <NUM> on rotor <NUM> and generates an angle referencing signal.

An included angle between second position plane PM2 and first position plane PM1 of angle sensor <NUM> can be any angle α. As an example, in this implementation, the included angle between two planes is selected as <NUM> degrees, that is, the included angle between second position plane PM2 and first position plane PM1 is <NUM> degree, and second position plane PM2 relative to first position plane is in the opposite direction of rotor rotating.

(D) Measure the unbalance of rotor <NUM> again, the measured unbalance is represented by second unbalance U12 in measuring plane <NUM> PL1 and second unbalance U22 in measuring plane <NUM> PL2. Plot unbalance U12 in measuring plane <NUM> PL1 and second unbalance U22 in measuring plane <NUM> PL2 into the plane coordinate, as shown in Figure.

(E) During above two unbalance measurements, the unbalance amount of rotor <NUM> has no change, but the unbalance angle is changed, that is, the unbalance angle relative to angle reference point <NUM> on rotor is changed. Referring to <FIG>, use the angle change of the rotor unbalance in measuring plane <NUM> for illustration. In <FIG>, horizontal axis is time t, vertical axis is amplitude of vibration voltage signal detected by vibration sensor <NUM> due to the unbalance of rotor. The vibration amplitude signal is a sine wave. Every time rotor <NUM> rotates one circle (<NUM> degree), vibration voltage signal being measured by vibration sensor <NUM> is a complete sine wave, the period of sine wave is noted as T. The positive maximum vibration amplitude P1 in sine wave is corresponding to the measured unbalance vector of rotor which includes the amount and the angle. The unbalance amount is determined by the magnitude of vibration amplitude P1. Every time rotor rotates one circle (<NUM> degree), angle sensor <NUM> on balance machine scans reference point <NUM> on rotor <NUM> once and gives an impulse time referencing signal. The angle of the rotor unbalance is determined by the relative relationship between the time point of impulse signal being generated when angle sensor <NUM> detects reference point <NUM> on rotor and the time point corresponding to maximum amplitude P1 of sine wave signal. In a sine wave along time axis, when angle sensor <NUM> on balancing machine is on first position Po1 and angle sensor <NUM> detects reference point <NUM> on rotor <NUM>, this time point is recorded as T1, the time point along time axis corresponding to maximum amplitude of vibration signal is recorded as T3, time interval between time point T1 and T3 is recorded as T<NUM>; To divide T<NUM> by the time for rotor rotating one round, that is sine wave period T, and further to multiply <NUM> degree, then it is the angle of the measured unbalance relative to angle reference point <NUM> on rotor, it is recorded as β, β=T<NUM>/T*<NUM>, or T<NUM>=β/<NUM>*T.

After moving angle sensor <NUM> from first position Po1 on balancing machine to second position Po2, the time point when angle sensor <NUM> detects angle reference point <NUM> on rotor during rotor <NUM> rotating is recorded as T2. Since second position Po2 of angle sensor <NUM> is <NUM> degree relative to first position Po1 of angle sensor <NUM> in the opposite of rotor rotating direction, when considering the time sequence, the time when angle sensor <NUM> on second position Po2 detects angle reference point <NUM> of rotor is earlier than the time when angle sensor <NUM> on first position Po1 detects angle reference point <NUM> of rotor, that is, the point T2 is earlier than the point T1, the earlier (advanced) time interval is recorded T<NUM>. This advanced time difference is caused by angle sensor <NUM> on balancing machine being moved <NUM> degrees opposite to the rotating direction of rotor <NUM>, that is, caused by rotor <NUM> rotating <NUM> degree less in one round, T<NUM>=<NUM>/<NUM>*T. After moving angle sensor <NUM> to second position Po2 on balancing machine, the unbalance angle of rotor is the angle corresponding to the time between the time point T2 and T3. The time between T2 and T3 is the sum of T<NUM> and T<NUM>, that is: T<NUM>+ T<NUM> = β/<NUM>*T + <NUM>/<NUM>*T = (β+<NUM>)/<NUM>*T.

The angle corresponding to the time between T2 and T3 is: <MAT>.

That is, after moving angle sensor <NUM> on balancing machine to second position Po2, the measured unbalance angle of rotor is changed to (<NUM>+β) degree.

(F) In <FIG>, if moving angle sensor <NUM> on balancing machine with <NUM> degrees in the rotating direction of rotor <NUM>, the time when angle sensor <NUM> on this position detects angle reference point <NUM> on rotor <NUM> is later than the time when angle sensor <NUM> on first position Po1 detects angle reference point <NUM> on Rotor <NUM>, according to the above analysis, it can be known that the unbalance angle of rotor at this case is changed to β-<NUM> degree.

The above analysis is obtained under the condition that rotor <NUM> rotating direction is opposite to the angle increasing direction of rotor unbalance. If rotor <NUM> rotating direction is the same with angle increasing direction of rotor unbalance, when moving angle sensor <NUM> on balancing machine a certain angle opposite to rotor rotating direction, angle of rotor unbalance is changed by reducing this certain angle, when moving angle sensor <NUM> on balancing machine a certain angle in rotor rotating direction, angle of rotor unbalance is changed by increasing this certain angle.

(G)When the position of angle sensor <NUM> on balancing machine changes, the unbalance of balancing machine itself, including possible electrical compensation or zero point calibration error, both amount and angle of the unbalance of the balancing machine have no change. This is because the unbalance of balancing machine itself is not the unbalance caused by the mechanical unbalance which generates sine vibration signal, but is only the electrical analogue amount (or digital amount), its amount has no change, its angle only relates to angle reference point <NUM> on rotor <NUM> and does not relate to vibration voltage signal of vibration sensor, thus, unbalance angle of balancing machine itself has no relationship with the position change of angle sensor <NUM>.

(H) Based on above mentioned unbalance angle change of rotor <NUM>, as per vector calculating method shown in <FIG>, the unbalance of rotor <NUM> and the unbalance of balancing machine are calculated. Taking an example of measuring plane <NUM> PL1, the specific calculating method is that, name the vector end point of the unbalance U11 as B1 and the vector end point of the unbalance U12 as B2, making an isosceles triangle by using the connecting line of B1 and B2 as the bottom side, top point is B3, top angle is <NUM> degrees, and when vector B3B1 rotates to vector B3B2, it is angle increasing direction in the coordinates (in the figure, clockwise is unbalance angle increasing direction). Vector O1B3 is the unbalance amount and angle of the balancing machine, Vector B3B1 is the unbalance amount and angle of rotor <NUM> when angle sensor <NUM> on first position Po1, vector B3B2 is the unbalance amount and angle of rotor <NUM> when angle sensor <NUM> on second position Po2. Vector B3B2 and Vector B3B1 equals in amount, while angle difference is positive <NUM> degrees, that is, angle of vector B3B2 is increased by <NUM> degrees comparing to angle of vector B3B1.

(I) When the unbalance of balancing machine is zero, vector O1B3 in measuring plane <NUM> PL1 is zero, under the condition shown in <FIG>, when angle sensor <NUM> is moved <NUM> degree opposite to rotor rotating direction, the unbalance amount of rotor <NUM> is no change, but the direction is changed by increasing <NUM> degree positively, as shown in <FIG>. Based on this principle, a simple method can be used to detect whether the unbalance of balancing machine is zero, that is, moving angle sensor a certain degree opposite to rotor rotation, if before and after the angle sensor position changes, the measured unbalance amount equals, but the measured angle is positively increased by the moved angle of angle sensor, it is proved that the unbalance of balancing machine is zero.

(J) <FIG> shows a sketch of a horizontal balancing machine measuring the unbalance of a rotor, rotor <NUM> in <FIG> is supported by rollers of balancing machine on journal <NUM> and <NUM> at two ends of rotor, and meanwhile rollers of balancing machine also drive rotor <NUM> rotating, rotating direction is shown by the arrow in (b) of <FIG>, that is, counterclockwise direction.

The types for horizontal balancing machine supporting rotor can be bearing sleeves, rollers, V blocks etc., the methods for horizontal balancing machine to drive rotor can be roller drive, belt drive, or air drive etc. but should satisfy the following conditions: when balancing machine supports and drives rotor, no mechanical part on balancing machine is mechanically connected with rotor into one body and rotates together.

Angle reference point <NUM> is set on rotor <NUM>, angle sensor <NUM> is installed on balancing machine and its initial position is recorded as first position Po1. As per the same method mentioned above, move angle sensor <NUM> on balancing machine and measure the unbalance before and after this move, obtain the unbalance of rotor and balancing machine by above mentioned vector calculation.

The above mentioned implementation to acquire the unbalance of rotor and balancing machine is to select two measuring planes of rotor. For rotor with a relatively small ratio of length to diameter, normally it is called as disc type rotor, one plane can be used to measure the unbalance of rotor. The implementation of this invention is also suitable for selecting one measuring plane, to acquire the unbalance of rotor and balancing machine.

After using above mentioned method to measure and acquire the unbalance of balancing machine itself, electrical compensation can be proceeded for balancing machine, so that to make the zero point of balancing machine accurate for it to measure the unbalance of rotor, after the balancing machine being compensated in such way, the unbalance of balancing machine itself is zero, and the unbalance that it measures is the unbalance of rotor.

(M) After using above mentioned method to acquire the unbalance of rotor, make the unbalance correction for rotor, so that the unbalance of rotor is zero or less than a setup value. In this way, a rotor with zero unbalance or with unbalance less than a setup value is obtained.

Claim 1:
A method to acquire unbalance of a rotor (<NUM>), for decomposing the unbalance of the rotor (<NUM>) and unbalance of a balancing machine; wherein when the balancing machine supports and drives the rotor (<NUM>), the balancing machine and the rotor (<NUM>) being measured is in non-rigid connection;
the method comprising the following steps
setting an angle reference point (<NUM>) on the rotor (<NUM>), wherein an angle sensor (<NUM>) is installed on the balancing machine; when the angle sensor (<NUM>) is on a first position (Po1), a plane being formed by the angle sensor and a rotating axis (A1-A2) of the rotor (<NUM>) is defined as a first position plane (PM1);
using the balancing machine to obtain a first measured unbalance (U11) of the rotor (<NUM>), the first measured unbalance is represented in a measuring plane <NUM> (PL1) perpendicular to the rotating axis (A1-A2);
the method is characterized by further comprising the following steps:
moving the angle sensor (<NUM>) from the first position (Po1) to a second position (Po2) on the balancing machine; when the angle sensor (<NUM>) is on the second position (Po2), a plane being formed by the angle sensor and the rotating axis (A1-A2) of the rotor (<NUM>) is defined as a second position plane (PM2); an included angle (α) is formed between the second position plane (PM2) and the first position plane (PM1), and the second position plane (PM2) is in an opposite direction of rotor rotation relative to the first position plane (PM1);
using the balancing machine to obtain a second measured unbalance (U12) of the rotor (<NUM>) in the measuring plane <NUM> (PL1);
using the first measured unbalance and the second measured unbalance, acquiring, by vector calculation, a calculated unbalance of the rotor (<NUM>); the vector calculation comprises:
forming an isosceles triangle by taking a line connecting a vector end of the first measured unbalance and a vector end of the second measured unbalance as a base side, and the included angle α as a vertex angle; wherein, from isosceles side of the vertex to the vector end of the first measured balance to isosceles side of the vertex to the vector end of the second measured balance is clockwise, the vector from the vertex of the isosceles triangle to the vector end of the first measured unbalance is the calculated unbalance of the rotor (<NUM>).