前苏联专利SU1308185A3 Control system for stopping spindle in specific angular position

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专利摘要:
A control system for stopping a spindle 202 at a predetermined rotational position, for driving a spindle 202 in such a manner that a positional deviation signal between the present rotational position of a specified point on the spindle 202 and a predetermined rotational position at which the specified point is to be stopped, is reduced to zero, thereby to stop the specified point on the spindle at the predetermined rotational position. First and second rotational position sensors 204, 205 are attached to the spindle 202 at first and second specified points thereof, the position at which at least the first rotational position sensor 204 is attached being adjustable. Further provided are changeover means 209 and an orientation control circuit 210. The first position sensor 204 produces a rotational position deviation signal when a tool is inserted into and withdrawn from a workpiece at the time of a boring operation, and the second position sensor 205 produces a rotational position deviation signal when tools are changed. These deviation signals are applied to the orientation control circuit 210 selectively by the changeover means 209. As a result, the orientation control circuit 210 controls the rotation of the spindle 202 so as to reduce to zero the difference between an average speed signal, which conforms to the actual rotational speed of the spindle 202, and each of the deviation signals, whereby a specified point on the spindle 202 is stopped at a predetermined rotational position.
公开号:SU1308185A3
申请号:SU803222704
申请日:1980-12-31
公开日:1987-04-30
发明作者:Фудзиока Есики
申请人:Фудзицу Фанук Лимитед (Фирма)；
IPC主号:

专利说明:

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The invention relates to a spindle stopping system at a predetermined angular position, in particular to a system for stopping a certain point on a spindle at any of two predetermined angular positions.
The aim of the invention is the expansion of technological capabilities.
The goal is achieved by providing a single control circuit with separate sensors for orientation in the tool change position and tool insertion into the bore of the part.
FIG. 1 is a diagram of a control system for stopping a spindle at a certain angular position; Fig. 2 is a block diagram of the control circuit.
stop spindle; in fig. 3 and 4 are diagrams of signals in the circuit shown in FIG. 2 in FIG. 5 is a diagram of the magnetic sensor in FIG. 6 is a diagram of the magnetic and sensitive elements j in FIG. 7 — a schematic diagram of the reactor (of the reactor in question; FIG. 8 — signals received from sensitive circuits; FIGS. 9 and 11 — reactor diagrams; FIG. 10. 12 and 13 are diagrams Fig. 14 is a block diagram of the generation of a positional deflection signal, Fig. 15 is a timing diagram of the signals in the circuit of Fig. 14.
The device contains the first 1 and second 2 position sensors, which are magnetic sensors consisting, for example, of magnets 3 and 4 and sensitive elements 5 and 6. Magnets 3 and 4 are fixed on spindle 7 entering the spindle mechanism 8, and sensitive elements 5 and 6 are fixed on the mechanically fixed part 9 of the machine tool. The first position sensor 1 is used when the spindle 7 stops at a specific angle during the boring operation, and the second sensor 2 during the execution of the automatic tool change operation. Since the angular position at which the spindle stops during an automatic tool change is fixed, the magnet 4 of the second position sensor 2 is attached to a certain point of the spindle stationary. When performing a boring operation, the angular position in which it should stop

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with the spindle, depends on the shape and location of the slot for the tool in the workpiece. Therefore, the magnet 3 of the first position sensor 1 is mounted on the spindle 7 so as to move to any desired position. To amplify the signals produced by the sensors 1 and 2, amplifiers 10 and 11 are provided. A control circuit 12 is also provided, at the command of which the switch 13 switches between the outputs of the amplifiers 10 and 11, and the selected output signal is fed to the orientation control unit 14. When a cutter for a bore is introduced into or out of the workpiece, switch 13 is connected to terminal a, transmitting the amplified output signal of the first position sensor to orientation control unit 14, which performs an orientation compensation in accordance with
with received signal. The orientation control operation stops the spindle 7, at which time the magnet 3 attached to the spindle faces the sensing element 5. When a tool change is required, the switch 13 is connected to the contact b, transmitting the amplified output signal of the second position sensor 2 to the orientation control circuit 14, Another control operation, the orientation in accordance with the received signal for stopping the spindle 7 in such a position when the magnet 4 attached to it is opposite the sensitive element 6.
FIG. Figure 2 shows the block diagram of the control circuit for stopping the spindle at a certain angular position.
The speed command block 15 generates the CV speed command, and the 16 orientation team blogs the ORCM orientation command. The speed control unit 17 contains an adder 18, a phase compensation circuit 19 connected to the cyMiviaTopa output, a voltage-to-voltage converter 20 connected to the output of the phase compensation circuit 19, and a thyristor converter-21 at the output of the converter 20.
SAT-1mator 18 determines the voltage difference corresponding to the difference between the command speed CV and the actual AV speed of the DC motor when performing a speed control operation. It also determines the differential voltage between the deviation of the angular position RPD and the actual velocity AV when performing the position control operation. Phase compensation circuit 19 phase-compensates the output voltage by shifting the phase forward or backward. The voltage converter 20 — the phase controls the phase of operation of each thyristor in the thyristor converter 21 in accordance with the output voltage of the phase compensation circuit 19, the thyristor converter 21 operates in accordance with 20
25
The cash is positive on one side of the zero point and negative on the other, i.e. crosses the zero level. ASV signal voltage is obtained by adding a signal
DV.
DV,
It is controlled with controlled -5 phases with the center line of the magnet 3. Thyristor flashes, changing the value of the voltage applied to the direct current motor 22, as a result of which the rotation speed of the latter changes. When the DC motor 22 rotates, the tachometer 23 generates a voltage corresponding to the motor speed. The rotational movement of the direct current motor 22 is transmitted through gear or belt transmission 24 to the spindle 7. The spindle 7 is connected to the spindle mechanism 25, in which the tool 26 is attached.
. and a signal derived from by a 180 ° phase shift.
A sensitive circuit corresponding to one of saturable reactors 31 is shown in FIG. 9. The sensitive circuit, included in block 27, contains a pulse generator 41, generating a high-frequency pulse signal of 100 kHz HFP,
Magnetic sensor 1 (2) has a magnet.- ЗО rzdzshayushchy transformer 42 and Nm element 3 (4), a sensitive element of a semi-rectifier 43. Saturation 5 (6) and an electrical unit 27
The reactor 31 is excited by a high-frequency pulse signal transmitted through the isolation transformer 42. As a result, the output voltage DV shown in FIG. 8 will be removed from the output contacts a, b of block 27, (the voltage is approximately proportional to the external magnetic field Hg ,,., The intensity of which varies in accordance with the angular position of the magnetic element 3).
(Fig. 5).
The magnetic element 3 (Fig. 6) consists of magnets 28 and 29 having a triangular cross section and installed in the housing 30 in such a way that the magnetic field voltage varies from the pole S to the pole N in the direction of rotation of the spindle, i.e. along the arrow . The sensing element 5 is mounted on the non-piercing part of the machine opposite the magnetic element 3 and contains three pinned reactors 31-33 in the housing 34, oriented in the direction of rotation of the spindle (Fig. 6). Coils 36 and 37 are wound on the core 35 of each of the saturable reactors. These coils are wound so that their polarities are opposite. The coils on each of the cores have a common contact 38, to which a high-frequency signal is applied, and the signals determining the angular position of the magnetic element 3 are removed from the contacts 39 and 40 of the respective coils.

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FIG. 8 shows the signals received from sensitive circuits. Saturated reactors 31-33 are supplied with these signals. These signals occur when the magnetic 3 and sensing 5 elements are in such a relative position as shown in FIG. 6
DV,. DV.
ten
,, uv, DV, are signals from sensitive circuits corresponding to reactors 31, 32, and 33. Each of these signals has a zero value when the center line of the corresponding saturated reactor coincides
The cash is positive on one side of the zero point and negative on the other, i.e. crosses the zero level. ASV signal voltage is obtained by adding a signal
with the center line of the magnet 3. Sig-
DV.
DV,
with the center line of the magnet 3. Sig-
. and a signal derived from by a 180 ° phase shift.
A sensitive circuit corresponding to one of saturable reactors 31 is shown in FIG. 9. The sensitive circuit, included in block 27, contains a pulse generator 41, generating a high-frequency pulse signal of 100 kHz HFP,
rdzvshayushchy transformer 42 and half-period rectifiers 43. Saturation
rdzvshayushchy transformer 42 and half-period rectifiers 43. Saturation
The reactor 31 is excited by a high-frequency pulse signal transmitted through the isolation transformer 42. As a result, the output voltage DV shown in FIG. 8 will be removed from the output contacts a, b of block 27, (the voltage is approximately proportional to the external magnetic field Hg ,,., The intensity of which varies in accordance with the angular position of the magnetic element 3).
The conversion of the DV signal taken from the contacts of block 27 is described using the example of operation of the reactor 31.
When magnetic element 3 is far from the stationary reactor 31 (the external magnetic field affecting this reactor is zero), the high-frequency impulse signal HFP has a relatively good vertical H-H curve of the reactor, as shown in fig. 10. As a result, the flow of power lines, intersected by coils 36 and 37, are equal to the output voltages taken from the contacts .U and –tO, equal to
amplitude, but out of phase by 180. Since these voltages are rectified by the corresponding half-period rectifiers 43, the potentials at the contacts a and b of block 27 are equal, therefore, the voltage between a and b is zero.
As the magnetic element 3 approaches the saturated reactor 31, the external magnetic field Hgj (created by the magnetic element begins to affect the reactor. If the field created by the high-frequency pulse signal HFP is designated as hp, then the coil 36 will cross the flow corresponding to hg + Hgj (as shown in Fig. 12. Coil 37 will intersect the flow corresponding to hg + Hg. If this is expressed using the BBI curve, then the high-frequency pulse signal HFP will act relative to the line - Hgj as relatively zero (dp coil 36), as shown in Fig. 12, and relative to the Hg line (for coil 37), as shown in Fig. 13. Therefore, a negatively directed flow crossing coil 36 causes the core to become full, resulting in variations in the mills t is less than. A negatively directed flow crossing coil 37 does not lead to saturation, so the variations remain large. Due to the fact that the induced voltage E is accepted
d, em value -t-- (where N is the number
turns), the potential at contact b becomes greater than the potential at contact a, which leads to the appearance of a potential difference between the contacts. This potential difference changes as shown in FIG. 8 (curve DV) as the magnet 3 continues to rotate.
The position switch 13 is switched by a command of the control circuit 12.
The orientation control unit 14 includes an angular position deviation signal generation circuit 44 which produces an angular position deviation signal RPD, the voltage of which varies in accordance with the deviation of the angular position. The ORDEV signal of the termination of the orientation and the VZR signal are also produced.
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left speed, which takes the value 1 when the rotational speed of the spindle drops to zero. Feedback switching circuit 45 triggers feedback switch 46 based on the zero speed signal VZR, upon receipt of a command. ORCM orientation from command chain 16 orientation.
The angular position deviation signal generation circuit 44 receives the voltage DV2 (which is used as an accurate, as opposed to coarse, angular position deviation signal when the spindle is near the predetermined angular position) received at the center of the sensor 1 or 2, as well as an approximation ASV signal obtained by adding the voltage DV of the reactor 31 and the voltage corresponding to the phase rotation of the signal DV of the reactor 33 by 180. The signal ASV indicates that the spindle is reachable The region is adjacent to a certain angular position. The signal AV, indicating the actual speed of the engine, enters a circuit 44 generating a deviation signal from the angular position 23 and is integrated with an integrating circuit (not shown). The output (equivalent to the rotation of the spindle) of the integrating circuit is subtracted from the set-. Whose initial voltage 1 sv. Thus, the AV signal is converted to a coarse angular position CPD signal. The magnitude of the V-voltage ISV is chosen equal to the voltage deviation of the angular position corresponding to one rotation (360 °) of the spins of the cases. deviation angular position.
When the speed command CV drops to zero, in accordance with the orientation OR CM command originating from the orientation command 16, the spindle rotational speed eventually decreases (at time t) of the pad-i em to zero (the zero-speed signal VZR takes the value one). Circuit 44 generating a signal deflection angle 713
This position produces a predetermined ISV voltage starting from the moment when the signal of zero speed takes the value 1 to time t2, when the spindle for the first time reaches a certain angular position. Thereafter, as the spindle continues to rotate and the magnetic element 3 (target point on the spindle) approaches a certain angular position a second time, a coarse positional deviation signal CPD is produced as long as the magnet 3 approaches closer to the NCP region (located between the points - 0 and + 0) within a given angular position, i.e. until it comes to a point - Also, until the above-mentioned NCP area is reached, a bias BIS signal is generated. A precise deviation signal DV is generated after magnet 3 enters the NCP region within a predetermined angular position. As a result of these operations, the RPD signal of the angular position shown in FIG. 3. The BIS offset signal can be eliminated from the RPD signal by setting 02 equal b, ..
Assuming that switch 13 is connected to contacts, day 44 of generating the angle deviation signal receives the output of the second magnetic sensor 2, which is used when changing the -tool in the manner described above.
During the rotation of the spindle, the switch 13 is connected to the side and as a result a feedback circuit is formed that controls the speed. More specifically, the adder 18 of the contact d receives the command CV speed signal coming from the speed command circuit 15 and the average speed signal coming from tachometer 23, and produces in response a voltage deviation (deviation) of angular velocity. The voltage converter 20 is the phase of control of the angle (phase) of starting the thyristors in the thyristor converter 21 in accordance with the voltage deviation voltage. As a result. the thyristor converter 21 regulates the voltage applied to the DC motor 22. Thus, the actual speed of the AV engine 22 is adjusted according to
58
CV command speed. Subsequently, the speed control loop adjusts the speed of the engine so that the speed deviation tends to zero and the spindle rotates while maintaining a constant speed deviation.
When processing is completed, the digital control device sends a signal to the orientation command circuit 16 to send an orientation command ORCM to the switching circuit 45 at time t. At the same time, the ORCM orientation command enters the speed command circuit 15, and the speed CV command drops to zero. As a result, the actual speed AV decreases and at time t becomes zero} o. At this time, a zero speed signal VZR is generated in circuit 44 of generating the position-deflection signal, leading to circuit 45 shifting switch 46 to the side of contact B; Now the circuit is aimed at controlling the position instead of controlling the speed. In response to the zero speed signal VZR, the circuit 44 of generating the position deviation signal first produces the initial voltage ISV of V. In response to this signal, the spindle begins to rotate again, and the AV signal corresponding to the actual speed tends to take the value V. As the magnetic element 4 of the second magnetic sensor 2 continues to rotate and reaches a certain angular position for the first time (time tj), the angular position signal generation circuit 44 begins to produce a rough
position variation CPD signal. The spindle continues to rotate, and the magnet 4 approaches the N CP region (Fig. 3) within a certain angular position (time tj), and the circuit 44 of generating the position deviation signal generates the bias signal BIS. When the magnetic element 4 falls into the NCP area (moment t), the generation of an accurate position-deflection signal V begins. After the DV2 signal drops to zero, i.e. When the magnetic element 4, located on a given part of the spindle, is located directly in front of the saturated reactor 32, the spindle stops rotation. On this za15
25
Spindle position control is complete.
If during the boring operation, a cutting tool needs to be introduced into the workpiece or withdrawn from 5 of it, then the switch 46 switches -. c to position B via a control signal from control circuit 12. Thereafter, an orientation operation is performed, identical to that described above, resulting in the spindle stopping in a certain angular position, allowing insertion or removal of the tool.
A circuit for generating a signal for deflecting the angular position of the circuit 44 is shown in FIG. 14, and the graphs of the signals arising in it are shown in FIG. 15.
FIG. 14 shows a block 47 for generating an ISV voltage and an RIS offset signal for integrating the actual speed AV signal and For subtracting the output voltage. The resulting integration from the initial ISV voltage. Switch 48 switches to contact + 15V or to contact -15B in accordance with the direction of rotation of the spindle. If the spindle rotates in the forward direction, a connection is made to -15V. This voltage is divided by resistors g, Gl, and capacitor C is charged by a signal passing through amplifier 35 49, resistor g and switch 50, and the voltage to which the capacitor is charged tends to V. the initial voltage of the ISV. If the actual speed signal AV enters block 47 through switch 51 or 52 after the switch 50 is open, capacitor C is discharged from RC time constant, because the voltage value of the signal of actual speed AV is less than V. .. and gross the CPR deviation signal of the position obtained by subtracting the output voltage in-... resulting from the integration of the AV signal of the actual speed, from the initial ISV voltage, appears at the output of amplifier 49. Amplifier 49, resistor R and capacitor C form an integrating c ep If the switches 50 and 53 after the voltage of the SRV signal reaches the specified value V-, then the block 47 acts 30
45
50
55
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45
50
55
as an amplifier, and at the output of amplifier 49 a bias RIS signal appears, having a predetermined level V., i.e. switching on and synchronizing the closure and opening of the switches 50-53 first provide the transfer of the initial ISV voltage, then the transfer of the gross deviation signal of the SRV and finally the bias signal of the BIS.
Circuits 54 and 55 are used to switch the gain in accordance with the gear ratio. These circuits increase the gain of the position control circuit when the transmission between the DC motor 22 and the spindle 7 is small (the reduction ratio is large), and reduces the gain for large gears (the reduction ratio is small), i.e. reduce the gain compared to gain at a high reduction ratio. When the reduction ratio is large, the switches 51 and 56 close, increasing the gain, and when the reduction ratio is small, the switches 52 and 57 close, reducing the gain. This prevents the buildup and the emergence of sharp jolts when the spindle stops at a certain angular position and provides the ability to stop the spindle in a shorter time, regardless of the size of the reduction ratio.
The absolute magnitude determination unit 58 calculates the absolute value of the signal from circuit 47. Comparator 59 determines whether the coarse position deviation signal does not decrease below a predetermined level, and generates an IVRPS signal that indicates that the determined portion (magnetic element 3 (4) of the sensors 1 (2) approached the area (from –in to + l of Fig. 3) within a certain angular stop position. At the NRPS signal, the switches 50 and 53 are closed.
The gain control circuit 60 adjusts the gain in accordance with the gap between the magnets 3 or 4 and the corresponding sensitive elements, cops 5 or 6, and absorbs the BVji registration signal (an accurate position deviation signal) with a given slope. The threshold circuit 61 cuts off the approaching signal ASV at a certain level and produces the signal LS, which indicates that
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Some of the magnets reached the NCP area (Fig. 3) within a certain angular position. On the LS signal, the switches 62 and 63 open and the switch 64 closes. As a result, an exact angular deviation signal is generated, which serves. signal deviation.
The forward and reverse switching circuit 65 has a switch 62 which, in the closed state, passes the output signal of the absolute value block 58 if the spindle is to rotate in the forward direction. If the spindle is to rotate in the opposite direction, the switch 63 closes, skips the output signal of the absolute value block 58, inverted in the amplifier 66, the INPOS signal generation circuit 67 containing the comparator, processes the exact signal DVj of the position deviation and generates an INPOS signal when the spindle is in within a given angular position. The INFOS signal is applied to the orientation termination signal generation circuit.
Comparators 68 and 69 process

The DV signal is a position deviation and generates NEG and ROS signals, indicating from which side the spindle approaches a certain angular position: when the spindle rotates in the opposite direction, the NEG signal is 1, and when the spindle rotates in the forward direction, the ROZ signal takes the value, 1. One of the switches 62, 63 is closed, and the second is opened by the signals VZR and L3, depending on which of the signals (NEG or ROZ) is 1. The signal synthesis circuit 70 passes a precise or coarse signal of the deviation of the angular position in accordance with the state switches 64, 62 and 63. The speed detection circuit 71 receives an AV voltage indicating the actual spindle speed and produces a zero speed VZR signal when AV drops to zero. An orientation termination signal generation circuit 72 receives an INP03 signal, a zero speed signal V2R, and an orientation command signal ORCM and calculates the logical product of these signals, resulting in an orientation termination signal ORDEN when all INP03, VZR and ORCM signals are 1.
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So, if the ORCM orientation command takes the value 1 at time point to, the command speed CV drops to zero, resulting in the actual AV speed decreasing to zero and the zero speed signal VZR takes the value 1. When this happens, the switch 46 in the feedback circuit switches to position b, one
o
of the switches 56, 57 is closed in accordance with a small or large gear ratio, and one of the switches 62, 63 is closed depending on the direction (direct
5 or reverse) spindle rotation. In this way, a position control loop is formed, in which the initial voltage of the ISV is supplied through switch 46. Switch 50 is closed and switches 51-53 are open. DC motor 22 (FIG. 2) begins to rotate again, the spindle rotates and for the first time reaches a certain angular position (i.e.
5, L3 and INP03 signals are 1). Therefore, at time t2, the switch 50 is opened, and one of the switches 51, 52 is closed in accordance with the gear ratio. As a result, the coarse CPD deviation signal of the CHiiMaeTCH with switch 46. After the actual speed and deviation deviation decreases and the spindle approaches the zone in the region of a certain angular position (time t), the comparator 59 generates a NRPS signal equal to 1, as a result switches 50 and 53 are closed. Thus, the BIS offset signal of a predetermined level is removed from switch 46. As the spindle continues to rotate at a lower speed and reaches the NCP region within a certain
5 angular position (at time t),
the LS signal goes to state 1.5; the switches 62 and 63 open and the switch 64 closes. Therefore, a precise position deviation signal DVj passes through the switch 46. When the magnetic element 3 or 4 (the set point on the spindle) comes close to a certain angular position, an INPOS signal is generated. Following this, the actual spindle speed drops to zero, with the result that the bullet velocity signal VZR returns to the value 1. This completes the up5 operation.
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stopping the spindle at a certain angular position, and the chain 72 generating a signal for verification. orientation generates an orientation completion signal ORDEN.
The switch 46 switches to position b when the actual spindle speed becomes zero. However, this switch can be performed when the actual spindle speed becomes equal to the target speed.
In accordance with the invention, a single control circuit is provided for stopping the spindle at a certain angular position and two position sensors; for tool change and for bore orientation, are mounted on the spindle. By switching from one sensor to another, the spindle can be stopped with high accuracy at a certain angular position, when the tool needs to be changed, and at another certain angular position, when boring is performed. The device is simplified, its cost decreases
due to the fact that a single control system is used to stop the spindle in a certain angular position, both for tool replacement and for boring operations.

权利要求:
Claims (1)
[1]
Invention Formula
A control system for stopping the spindle B at a certain angular position, comprising a position sensor mounted on the spindle, the output of which is connected to the spindle orientation control unit, characterized in that, in order to expand the technological possibilities, the control system is equipped with an additional position sensor mounted on the spindle with the possibility of adjusting its position, and successively connected by a control circuit and a switch, with the outputs of the sensors being connected through a switch to the orientation block.
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Editor L. Veselovska
Compiled by V. Zhiganov
Tehred M. Khodanych
Order 1644/58 Circulation 787 Subscription
VNIIPI USSR State Committee for Inventions and Discoveries 4/5, Moscow, Zh-35, Raushsk nab. 113035
Production and printing company, Uzhgorod, st. Project, 4
CPU v.15
Proofreader E.Roshko

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同族专利:

公开号 | 公开日

DE3071608D1|1986-06-19|

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JPS56102451A|1981-08-15|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

JP54172685A|JPS6140497B2|1979-12-31|1979-12-31|

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