CN113370573A - System and method for restraining clearance impact of mechanical transmission system of servo press - Google Patents

Abstract

The invention discloses a clearance impact suppression system of a mechanical transmission system of a servo press, which comprises a control system, a motor and a servo motor, wherein the control system is connected with the motor through a power cable; an output shaft of the motor is mechanically connected with the speed reducer and is provided with an encoder, and a signal output end of the encoder is electrically connected with the control system; the speed reducer is connected with the sliding block through a crank connecting rod mechanism, and the corresponding method is to judge whether the transmission system is in a clearance state in real time in the servo control process. If the sliding block is in the clearance state, the motor is commanded to output smaller torque, so that the rotating speed difference between the driving side and the load side is limited, and the impact can be reduced, and the sliding block is driven by the crank-link mechanism to move up and down along the guide rail.

Description

System and method for restraining clearance impact of mechanical transmission system of servo press

Technical Field

The invention relates to the field of servo press control, in particular to a system and a method for restraining clearance impact of a mechanical transmission system of a servo press.

Background

The servo press machine adopts a servo motor to generate power, and pushes a sliding block to reciprocate through a mechanical transmission mechanism such as a gear, a crank, a connecting rod or a threaded screw rod to generate pressure, so that the material is extruded and formed. Because the mechanical transmission system has a gap, when the servo motor rotates in a certain angle range, the load keeps still, the transmission system is in a gap state at the moment, the load is separated from the motor, and the motor is in an idle state. If the motor rotates at a fast speed, the driving-side components connected to the motor shaft will quickly hit the load-side components, thereby causing an impact. Not only is accompanied by huge noise, but also equipment is easy to damage, the abrasion is accelerated, and the service life of the equipment is shortened.

At present, the high-precision parts are generally adopted in the industry to reduce the clearance of a transmission system as much as possible, so that the impact is reduced. However, this method requires precision machining of the parts, which results in expensive equipment. And wear is inevitable as the use time is prolonged, and the gap is increased, thereby generating impact.

With the progress of automatic control technology, a technology for suppressing backlash strike by a control method has now appeared. A chinese patent document entitled control method, apparatus, system for eliminating gear backlash and new energy automobile discloses a solution to the impact generated during the starting process of an electric automobile, which applies a small torque to a motor when the automobile is stationary, which is insufficient to cause the automobile to move, thereby eliminating backlash in a transmission system. It can be seen that this method only works when the vehicle is started and does not prevent the impact of mechanical play, both during operation and during stopping of the vehicle. The application of the method disclosed in the chinese patent document, named speed control algorithm for solving the problem of jitter caused by mechanical backlash, is limited to a control process starting from zero speed, accelerating, uniform speed, decelerating, and finally ending at zero speed. The method has poor adaptability to load change and complex motion modes in the numerical control machine tool and is difficult to avoid impact and jitter.

Disclosure of Invention

The invention provides a clearance impact suppression system and method for a mechanical transmission system of a servo press, aiming at overcoming the defects of the prior art.

The invention is realized by the following technical scheme:

a clearance impact suppression system of a mechanical transmission system of a servo press comprises a control system, wherein the control system is connected with a motor through a power cable; an output shaft of the motor is mechanically connected with the speed reducer and is provided with an encoder, and a signal output end of the encoder is electrically connected with the control system; the speed reducer is connected with the sliding block through a crank connecting rod mechanism.

The slider pressure sensor is electrically connected with the control system.

A method for restraining the clearance impact of a mechanical transmission system of a servo press comprises the following steps:

s1 extracting data including driving side moment of inertia

The inertia of the load-side component is converted into the rotational inertia of the motor shaft

Motor driving torque

Actual measurement motor speed of current control period

And the measured motor speed of the previous control period

；

S2 calculating angular acceleration of gap state motor

;

S3 calculating the actual angle of the motorSpeed of rotation

Wherein, in the step (A),

is the control cycle time;

s4, judging whether the transmission system is in a clearance state: if the actually measured angular acceleration of the motor is obviously smaller than that in the clearance state, that is to say

Judging that the transmission system is in a contact state; otherwise, judging that the transmission system is in a clearance state;

s5 output control: when the transmission system is judged to be in a clearance state, the control system limits the driving torque of the motor by limiting the maximum current output to the motor; and when the transmission system is judged to be in the contact state, the control system normally controls.

The step S4 of determining whether the driveline is in the lash state includes S4-1 setting a threshold

(ii) a S4-2, judging the state of the transmission system, and when the measured angular acceleration is smaller than the threshold value

Then reliably obtain

To conclude that the transmission is in contact; otherwise, the transmission system is judged to be in a clearance state.

Threshold value in the step S4-1

Is determined by first calculating the angular acceleration of the motor when the drive train is in contact

Then by the formula

And (6) obtaining.

The data extracted in the step S1 further comprises the conversion of the pressure F into the load torque on the motor shaft

(ii) a Threshold value in the step S4-1

Is determined by first calculating the angular acceleration of the motor when the drive train is in contact

Then by the formula

And (6) obtaining.

The specific process of the output control in step S5 is to first define the maximum value of the angular acceleration of the lash state as

Calculating the maximum torque

If the motor torque command obtained by the control system according to the gapless control algorithm is larger than the maximum value

Then command the motor to output only

Otherwise, the torque command is output as calculated.

The invention has the following beneficial effects:

1. the technical scheme utilizes the characteristics and the basic control principle of a transmission system of the servo press to realize the automatic identification of the clearance state of the transmission system, and limits the maximum angular acceleration of the servo motor in the clearance state to reduce the relative speed of a driving side and a load side, thereby inhibiting the impact.

2. The method has the advantages of simple principle, small calculation amount, low requirements on software and hardware of the control system and easy use.

3. The method requires only a few parameters of the mechanical system to be known and the parameters are readily available and therefore easy to implement.

4. The method aims at the general problem of the transmission system clearance, is not limited by the operation mode and the use occasion of the equipment, has strong universality and can be applied to a servo press or other similar processing equipment.

5. The method can be used on the basis of the condition of the existing servo control equipment, any new hardware can be omitted, and only algorithm software needs to be added, so that the material cost is not brought to the upgrading and reconstruction of the existing equipment, and the method is simple, convenient and easy to implement.

7. The method greatly reduces the impact of the equipment, is particularly suitable for frequent acceleration and deceleration application occasions, can greatly reduce the field noise, reduces the abrasion of the equipment and prolongs the service life of the equipment.

Drawings

The invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic structural diagram of a mechanical transmission system gap impact suppression system of a servo press using a slide pressure sensor according to the present invention.

FIG. 2 is a schematic diagram of a mechanical drive train lash impact suppression system for a servo press of the present invention without the use of a ram pressure sensor.

FIG. 3 is a flow chart of a method for damping lash of a mechanical drive train of a servo press according to the present invention.

Detailed Description

The following description is given of an embodiment of the present invention, and it should be noted that the scope of the present invention is not limited to the following embodiment, and any changes or substitutions that can be easily made by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention.

Fig. 1 to 3 show an embodiment of the present invention. The embodiment provides a system and a method for restraining clearance impact of a mechanical transmission system of a servo press.

Fig. 1 shows a first embodiment of the system part of the present invention, which includes a motor connected to a control system through a power cable, the motor is a servo motor, and the control system supplies a required current to the motor through the power cable to drive the motor to generate a torque for rotation. The output shaft of the motor is mechanically connected with the speed reducer and is provided with an encoder, and the signal output end of the encoder is connected with the control system. The control system uses the encoder signals to calculate the rotational speed and angular acceleration of the motor. The speed reducer drives the sliding block to move up and down along the guide rail through the crank connecting rod mechanism, pressure is generated on a workpiece below the sliding block, and the pressure of the sliding block is measured through the sliding block pressure sensor and sent to the control system.

The method provided by the invention has the idea that whether the transmission system is in a clearance state or not is judged in real time in the servo control process. If the sliding block is in the clearance state, the motor is commanded to output smaller torque, so that the rotating speed difference between the driving side and the load side is limited, and the impact can be reduced, and the sliding block is driven by the crank-link mechanism to move up and down along the guide rail.

And the side close to the motor is a driving side, and the side close to the sliding block is a load side. Drive side moment of inertia of

The inertia of the load-side component is converted into the rotational inertia of the motor shaft

. The motor generates a driving torque of

. The total sum of external forces (including forming force and friction) applied to the slide during operation is F, and the sum is measured by a pressure sensor on the press. The pressure F is converted into a load torque on the motor shaft

. Parameter(s)

And

determined by the mechanical system as a known parameter. Parameter(s)

The servo motor control algorithm is obtained through calculation according to a motor control model and current and belongs to servo control process variables.

And calculating according to the measured value of the slide pressure. Therefore, the above parameters are all known quantities.

Because the crank connecting rod of the press is a nonlinear transmission mechanism, when the inertia and the stress of the slide block, namely the inertia and the pressure of a load-side part are converted onto a motor shaft, the size of the slide block can be periodically changed along with the change of a crank angle. The method of the invention takes the minimum value of the equivalent moment of inertia and the equivalent load torque under each crank angle. How to convert the load side inertia and the external force to the rotational inertia and the load torque on the motor shaft respectively is an industry basic method, and is not described herein.

First extracting the driving side moment of inertia

The inertia of the load-side component is converted into the rotational inertia of the motor shaft

Motor driving torque

The pressure F is converted into a load torque on the motor shaft

The way of extracting the variables has been described above.

Calculating the angular acceleration of the motor in a clearance state, namely when the gear of the speed reducer is in the clearance state:

(ii) a Because of the fact that

And

are known, so can be calculated at any time

。

Calculating the actual angular acceleration of the motor:

，

wherein the content of the first and second substances,

is the measured motor angular velocity of the current control period,

is the measured motor angular velocity of the last control period,

is the control cycle time.

And

measured by the encoder.

Judging whether the transmission system is in a clearance state: if the actually measured angular acceleration of the motor is obviously smaller than the clearanceAngular acceleration of the motor in the state, i.e.

If so, judging that the transmission system is in a contact state; otherwise, judging that the transmission system is in a clearance state; wherein

Is alpha _ m<alpha_T。

Further, in order to accurately judge the contact and clearance states, the angular acceleration of the motor when the transmission system is in the contact state, that is, the gears of the speed reducer are in the contact state, is calculated:

(ii) a The motor drives all the components and external loads on the driving side and the load side.

Because of the fact that

Is positive and located on a molecule, and

is positive number and is positioned in the denominator, and the combined action of the two inevitably leads the angular acceleration under the contact state to be smaller than the angular acceleration under the clearance state, namely

；

Setting a threshold value

So that when the actual angular acceleration is less than the threshold value

Can reliably derive

To conclude that the transmission is in contact; otherwise, judging the transmission systemIn a clearance state; wherein

。

And (3) output control:

when it is determined that the transmission system is in the lash state, the control system limits the drive torque of the motor by limiting the maximum current output to the motor. Specifically, first, the maximum value of the angular acceleration of the clearance state is defined as

Calculating the maximum torque

If the motor torque command obtained by the control system according to the gapless control algorithm is larger than the maximum value

Then command the motor to output only

Otherwise, the torque command is output as calculated. By limiting the maximum output torque, the angular acceleration of the motor can be suppressed, so that the drive-side component does not reach a high relative speed when crossing the gap, and the impact at the moment of contact can be reduced.

And when the transmission system is judged to be in the contact state, the control system normally controls.

Fig. 2 shows a second embodiment of the system of the present invention, which is different from the first embodiment only in that the present embodiment does not have a slider pressure sensor, and accordingly, since the force applied to the slider is unknown, the angular acceleration of the motor in the contact state cannot be accurately calculated. However, if the load-side equivalent moment of inertia is large (accounting for 30% or more of the total) with respect to the drive side, the angular accelerations calculated in the two states can be made significantly different even without taking the load torque into consideration, so that the lash state can be reliably determined. At this time, the threshold formula of the angular acceleration is modified as follows:

wherein

The method comprises the following specific steps.

First extracting the driving side moment of inertia

The inertia of the load-side component is converted into the rotational inertia of the motor shaft

And motor drive torque

；

Calculating the angular acceleration of the motor in a clearance state, namely when the gear of the speed reducer is in the clearance state:

(ii) a Because of the fact that

And

are known, so can be calculated at any time

。

Calculating the actual angular acceleration of the motor:

，

wherein the content of the first and second substances,

is the measured motor angular velocity of the current control period,

is the measured motor angular velocity of the last control period,

is the control cycle time.

And

measured by the encoder.

Judging whether the transmission system is in a clearance state: if the actually measured angular acceleration of the motor is obviously smaller than that in the clearance state, that is to say

If not, the transmission system is judged to be in a clearance state; wherein

Is alpha _ m<alpha_T。

Further, the angular acceleration of the motor is calculated when the transmission system is in a contact state, i.e. the gears of the reducer are in a contact state:

and the motor pushes all parts on the driving side and the load side and the external load to move.

Setting a threshold value

So that when the actual angular acceleration is less than the threshold value

Can reliably derive

To conclude that the transmission is in contact; otherwise, judging that the transmission system is in a clearance state; wherein

；

And (3) output control: when it is determined that the transmission system is in the lash state, the control system limits the drive torque of the motor by limiting the maximum current output to the motor. Specifically, first, the maximum value of the angular acceleration of the clearance state is defined as

Calculating the maximum torque

If the motor torque command obtained by the control system according to the gapless control algorithm is larger than the maximum value

Then command the motor to output only

Otherwise, the torque command is output as calculated.

And when the transmission system is judged to be in the contact state, the control system normally controls.

After the device is assembled in the manner shown in fig. 1 or fig. 2, the control software in the control system executes the control program according to the flow cycle shown in fig. 3. Each cycle period is fixed in time. At each control cycle, the algorithm first reads in measured data from sensors internal and external to the control system, including motor current, motor encoder speed, and slider pressure. The motor angular acceleration in the gap state and the contact state is then calculated according to the aforementioned formula and known constants,

and

(or

) And calculating a gap state judgment threshold value

Simultaneously calculating the actual angular acceleration of the motor

. Finally, will

And

and comparing to judge whether the gap is in a clearance state. And if the motor torque command is judged to be in the clearance state, carrying out maximum value limitation on the motor torque command output by the control system, and otherwise, directly outputting the original torque command. After that, the control algorithm waits for the control period to end, and enters the next loop to repeatedly execute the above operations.

Claims (7)

1. A mechanical transmission system clearance impact suppression system of a servo press comprises a control system and is characterized in that: the control system is connected with the motor through a power cable; an output shaft of the motor is mechanically connected with the speed reducer and is provided with an encoder, and a signal output end of the encoder is electrically connected with the control system; the speed reducer is connected with the sliding block through a crank connecting rod mechanism.

2. The mechanical drive train lash impact suppression system of a servo press as claimed in claim 1, wherein: the slider pressure sensor is electrically connected with the control system.

3. A method for restraining the clearance impact of a mechanical transmission system of a servo press is characterized by comprising the following steps:

s1 providesFetching data including drive side moment of inertia

The inertia of the load-side component is converted into the rotational inertia of the motor shaft

Motor driving torque

Actual measurement motor speed of current control period

And the measured motor speed of the previous control period

；

S2 calculating angular acceleration of gap state motor

;

S3 calculating actual angular acceleration of motor

Wherein, in the step (A),

is the control cycle time;

s4, judging whether the transmission system is in a clearance state: if it is

Judging that the transmission system is in a contact state; otherwise, judging that the transmission system is in a clearance state;

s5 output control: when the transmission system is judged to be in a clearance state, the control system limits the driving torque of the motor by limiting the maximum current output to the motor; and when the transmission system is judged to be in the contact state, the control system normally controls.

4. A method of damping lash impact of a mechanical drive train of a servo press as claimed in claim 3, wherein: the step S4 of determining whether the driveline is in the lash state includes S4-1 setting a threshold

(ii) a S4-2, judging the state of the transmission system, and when the actually measured angular acceleration of the motor is smaller than the threshold value

Then reliably obtain

To conclude that the transmission is in contact; otherwise, the transmission system is judged to be in a clearance state.

5. The method for suppressing lash impact of a mechanical transmission system of a servo press as set forth in claim 4, wherein: threshold value in the step S4-1

Is determined by first calculating the angular acceleration of the motor when the drive train is in contact

Then by the formula

And (6) obtaining.

6. The method for suppressing lash impact of a mechanical transmission system of a servo press as set forth in claim 4, wherein: the data extracted in the step S1 further comprises the conversion of the pressure F into the load torque on the motor shaft

(ii) a Threshold value in the step S4-1

Is determined by first calculating the angular acceleration of the motor when the drive train is in contact

Then by the formula

And (6) obtaining.

7. The method for suppressing lash impact of a mechanical transmission system of a servo press as claimed in any one of claims 3 to 6, wherein: the specific process of the output control in step S5 is to first define the maximum value of the angular acceleration of the lash state as

Calculating the maximum torque

If the motor torque command obtained by the control system according to the gapless control algorithm is larger than the maximum value

Then command the motor to output only

Otherwise, the torque command is output as calculated.

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