JP4558968B2 - Electronic component mounting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The picking nozzle of the mounting head picks up the electronic component, the mounting head moves, the electronic component picked up by the picking nozzle is picked up by the imaging camera , and the image picked up by the camera by the picking nozzle of the mounting head moved The electronic component mounting apparatus mounts the electronic component on a printed circuit board by correcting the rotation of the suction nozzle by a rotational displacement amount based on the recognition result of the rotation.
[0002]
[Prior art]
When the operation of the rotary drive motor is stopped, the rotational torque is lowered to a low current value for the purpose of suppressing heat generation and the overall current value, so that the holding torque of the rotor decreases while the motor is stopped. .
[0003]
[Problems to be solved by the invention]
Accordingly, the rotor is vibrated by, for example , the turning acceleration of the rotary table on which the mounting head is provided due to this decrease. There is a problem in that the accuracy of the position recognition of the electronic component is not good with the increase in the speed of the mounting device.
[0004]
Therefore, the present invention increases the current value for a certain period at the timing of suction / recognition / mounting of the electronic component in the electronic component mounting apparatus even if the rotation drive motor for rotating the suction nozzle is stopped, and rotates by disturbance. It aims at suppressing the vibration of the rotor of a drive motor.
[0005]
[Means for Solving the Problems]
Therefore, in the first invention, the mounting head stops moving, the suction nozzle of the mounting head takes out the electronic component, the mounting head moves onto the imaging camera, and is sucked by the suction nozzle by the imaging camera. Rotation of the suction nozzle by the rotational drive motor based on the recognition result of the image picked up by the imaging camera. In the electronic component mounting apparatus in which the suction nozzle of the mounting head that has been corrected and moved onto the printed circuit board stops mounting the electronic component on the printed circuit board, the rotation drive motor is stopped when the mounting head stops moving The drive circuit of the rotary drive motor is given a current value increase command for raising the current value to be higher than the drive current at the time of rotation of the rotary drive motor. Characterized in that it consists of a control device for.
[0006]
According to a second aspect of the present invention, the rotation of the mounting head from before the mounting head stops moving until the mounting head starts moving after the electronic camera picked up by the suction nozzle is stopped after the stop. The control device performs control so as to give the current value increase command to the drive circuit of the rotary drive motor while the drive motor is stopped .
[0007]
In a third aspect of the invention, the rotation drive motor is used when the suction nozzle of the mounting head sucks and takes out an electronic component, or when the electronic component sucked by the suction nozzle of the mounting head is mounted on the printed circuit board. The control device controls so that the current value increase command is given to the drive circuit of the rotary drive motor while the mounting head is stopped. The suction nozzle picks up the electronic component, the mounting head moves onto the imaging camera , the electronic camera picks up the electronic component sucked by the suction nozzle, and the electron picked up by the suction nozzle of the mounting head Based on the recognition result of the image obtained by picking up the part with the imaging camera, the rotational drive motor performs rotation correction by the amount of deviation in the rotation direction of the suction nozzle, and the print base In the electronic component mounting apparatus in which the suction nozzle of the mounting head that has moved and stopped on the plate is lowered to mount an electronic component on a printed circuit board, the rotational drive motor that extends from before the mounting head stops moving to when it stops moving. And a control device that controls the drive circuit of the rotary drive motor to give a current value increase command for raising the drive value to a current value higher than the drive current during rotation of the rotary drive motor.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In FIG. 1 and FIG. 2, 1 is a Y table that moves in the Y direction by driving the Y axis motor 2, and 3 is a result of moving in the X direction on the Y table 1 by driving the X axis motor 4. An XY table that moves in the XY direction, and a printed circuit board 6 on which a chip-like electronic component 5 (hereinafter referred to as an electronic component or a component) is mounted is fixed and mounted on a fixing means (not shown).
[0009]
Reference numeral 7 denotes a supply stand, on which a number of component supply devices 8 for supplying the electronic components 5 are arranged. Reference numeral 9 denotes a supply table drive motor. When the ball screw 10 is rotated, the supply table 7 is guided to the linear guide 12 via the nut 11 fitted and fixed to the supply table 7, and X Move in the direction. Reference numeral 13 denotes a rotary table that rotates intermittently, and mounting heads 15 having a plurality of suction nozzles 14 as take-out nozzles are arranged at equal intervals according to the intermittent pitch on the outer edge of the table 13.
[0010]
Next, the main stop station by stopping the intermittent rotation of the rotary table 13 will be described. The stop position of the rotary table 13 of the mounting head 15 where the suction nozzle 14 picks up and picks up the component 5 from the supply device 8 (in FIG. 1). The upper black circle position) is the suction station I, and when the mounting head 15 is lowered at the suction station I, the suction nozzle 14 sucks the component 5.
[0011]
II is an imaging station in which the mounting head 15 that sucks the component 5 is stopped by intermittent rotation of the rotary table 13, and an image of the component 5 is picked up by the imaging camera 16, and the positional deviation of the component 5 with respect to the suction nozzle 14 is recognized.
[0012]
Reference numeral III denotes a mounting station (a position indicated by a black circle in the lower part of FIG. 1) where the mounting head 15 stops in order to mount the component 5 held by the suction nozzle 14 on the printed circuit board 6. The component 5 is mounted on the printed circuit board 6 stopped at a predetermined position by the movement of the XY table 3 by lowering.
[0013]
Reference numeral 18 denotes a power line 18A for transmitting a current from a drive circuit 82 (see FIG. 4) stored in a rotary table 13 for driving a pulse motor 31 as a current drive load to be described later, a current drive load to be described later. A cable including a power line 18 </ b> B for transmitting current to the vacuum valve 44, and an electric wire that transmits current to other current-driven loads and the like, and is connected to each mounting head 15. The cable 18 is provided with communication lines 18C and 18D to an origin detection element 43 described later. A vacuum tube 19 communicates with a vacuum source (not shown) to suck the electronic component 5 from the suction nozzle 14.
[0014]
The mounting head 15 is attached to the linear guide 22 via the head block 21 and is movable up and down with respect to the rotary table 13.
[0015]
The mounting head 15 will be described below with reference to FIG. In the mounting head 15, a pulse motor 31 for rotating the suction nozzle 14 is incorporated and formed.
[0016]
A rotor 32 is a rotating body of the motor 31 and is rotatable in the θ direction within the stator 30 serving as a housing portion. The θ direction is a direction that rotates about an axis extending vertically (vertical axis). Reference numeral 33 denotes a permanent magnet embedded around the entire circumference of the rotor 32, and an iron core 34 magnetized by the magnet 33 is repeatedly provided on the upper and lower sides thereof in a circumferential direction. Reference numeral 35 denotes an iron core attached to the inner wall of the stator 30 over the entire circumference. Plural portions of the iron core 35 in the circumferential direction of the stator 30 are protrusions, and a coil 36 is wound around the protrusions. ing.
[0017]
A pulsed current from the cable 18 is passed through the coil 36, and the rotor 32 rotates by a predetermined angle according to the number of pulses due to the repulsive force with the protrusion of the iron core 34 magnetized by the permanent magnet 33. A bearing 38 rotatably supports the rotor 32 with respect to the stator 30.
[0018]
Each of the suction nozzles 14 is provided so as to be vertically movable through the rotor 32 in the vertical direction, and a vacuum suction hole 40 is formed from the tip of the nozzle 14. The vacuum suction hole 40 opens toward the rotor 32 in the middle of the side surface of the nozzle 14 and communicates with a vacuum chamber 39 extending in the axial direction of the rotor 32 through a communication hole 37 formed in the rotor 32. An engaging body 42 is formed on the upper portion of the nozzle 14 and is urged downward by a pressing spring 50. Above the rotor 32, a lever 46 that engages with the engaging body 42 of each suction nozzle 14 and holds the suction nozzle 14 in the raised state against the spring 50 swings in the axial direction of the rotor 32. It is urged and attached to the spring 47. When the lever 46 is swung so that its lower end is opened against the spring 47 by a lever rotating device (not shown), the suction nozzle 14 held by the lever 46 as shown on the left side of FIG. Thus, the component 5 is brought into use so that the component 5 is sucked. In the state on the left side of FIG. 3 in which the engagement body 42 is held and accommodated by the lever 46 without using the nozzle 14, the opening of the body portion of the nozzle 14 does not communicate with the communication hole, and the communication hole 37 is the side surface of the nozzle 14. Sealed so that the vacuum does not leak.
[0019]
The vacuum chamber 39 communicates with the vacuum tube 19 via a rotary joint 49 that can rotate at the top of the rotor 32. The rotary joint 49 includes a rotary end 51 having a hollow portion (not shown) and a fixed end 52 having a hollow portion (not shown) provided on the rotary end 51 so as to be relatively rotatable by a ball bearing (not shown).
[0020]
In FIG. 2, 57 is an index unit, and the rotation of the output shaft of a motor (not shown) is decelerated by the speed reducer 58 and input to the unit 57, and the output shaft of the unit 57 intermittently rotates at a predetermined angle. The intermittent rotation of the rotary table 13 connected to the output shaft is driven. An index input shaft (not shown) that is an output shaft of the speed reducer 59 is provided through the housing 59 of the index unit 57.
[0021]
Reference numeral 26 denotes an elevating lever that moves up and down to swing the swing lever 27 of the component supply device 8. The lever 27 is swung to feed a tape (not shown) wound in a tape reel 28 into the tape. The stored electronic component 5 is supplied to the suction position of the nozzle 14.
[0022]
The rotary table 13 is rotatably attached to a base 29, and the supply base 7 and the XY table 3 are also moved relative to the base 29.
[0023]
The lower end 48 of the rotor 32 has a disk shape, and a magnet 41 is embedded at one place on the circumference of the lower end 48. The stator 30 is provided with an origin detection element 43 (Hall IC) as a current drive load for origin detection, and an origin detection signal is output when the magnet 41 faces the origin detection element by the rotation of the rotor 32. The signal current flows through the communication line 18D in the cable 18 and is input to the microcomputer 78 in the rotary table 13.
[0024]
The head block 21 is equipped with a vacuum valve 44 as a current-driven load, and a vacuum passage in the rotary table 13 for supplying a negative pressure into the vacuum chamber 39 of the head 15 via the vacuum tube 19. There is a function of switching to communicate with a vacuum source (not shown) via 45 or switching the vacuum chamber 39 to an open state. The vacuum valve 44 is an electromagnetic valve and is driven by a control from a microcomputer 78 (described later) in the rotary table 13 by a current flowing through the power line 18B in the cable 18.
[0025]
As shown in FIG. 3, the cable 18 is detachably connected to the mounting head 15 by a connector 54 as a head side connecting member. The connector 54 is configured by a drive side connector 55 fixed to the cable 18 and a driven side connector 56 fixed to the head 15, and the drive side connector 55 is attached to and detached from the driven side connector 56. A power line 18A for supplying a driving current for the motor 31 to each terminal of the driven connector 56, communication lines 18C and 18D for supplying a signal current from the origin detection element 43, a power line 18B for supplying a current for driving the vacuum valve 44, and the like. It is fixed by soldering or the like. The cable 18 is detachably connected to the rotary table 13 by a table side connecting member 53 (see FIG. 4) which is an integrated connector.
[0026]
The control block of the electronic component automatic mounting apparatus will be described with reference to FIG. A host CPU 74 controls various operations related to the mounting of the electronic component 5 according to programs stored in the ROM 76 based on various data stored in the RAM 75. Reference numeral 77 denotes a bus line for connecting the RAM 75 and the like to the CPU 74.
[0027]
In the RAM 75, mounting data (not shown) is stored for each type of the printed circuit board 6, and the component 5 is taken out from the component supply device 8 at the position on the supply table 7 indicated by the reel number in the order of the step number of the data. Thus, it is mounted at the coordinate position of the printed circuit board 6 at the angular position indicated by the mounting angle data. When the suction nozzle 14 is rotated by the mounting angle data by the rotation of the rotor 32, the electronic component 5 taken out from the component supply device 8 is at an angular position to be mounted if the sucked posture is correct.
[0028]
Based on the mounting data, the host CPU 74 sends data representing the distance to which the XY table 3 should move to the drive circuits 60 and 61 for driving the Y-axis motor 2 and the X-axis motor 4 in the X direction and the Y direction, respectively. The control data signal is sent to the microcomputer 78, which will be described later, based on the mounting angle data.
[0029]
A serial interface 79 for controlling the pulse motor 31 is further connected to the bus line 77. The pulse motor 31 is mounted on the mounting head 15 of the rotary table 13 that rotates with respect to the base 29, and is connected to the host line. Since the CPU 74 is mounted in the base 29, the wiring between the pulse motor 31 and the CPU 74 cannot be connected by soldering lead wires at this portion. For this reason, a microcomputer 78 is connected as control means for driving each pulse motor 31 via the slip ring 80. A serial interface (not shown) is incorporated in the microcomputer 78, and as many wires as the number corresponding to the pulse motor 31 are connected to the interface (not shown) in a multi-drop communication form of a current loop. A computer 78 is connected. Each microcomputer 78 is connected to a drive circuit 82 that drives the pulse motor 31 by passing a current.
[0030]
When the angle amount that the pulse motor 31 should rotate is given from the host CPU 74, the microcomputer 78 calculates and generates a velocity waveform according to the angle, and the drive circuit 82 controls the pulse motor 31 based on the data based on the waveform. A current to be driven is passed through the cable 18.
[0031]
The vacuum valve 44 is connected to the drive circuit 82 via the cable 18. When the corresponding mounting head 15 reaches the suction station I, the vacuum valve 44 turns on the vacuum and vacuum-sucks the component 5 from the suction nozzle 14. The head 15 reaches the mounting station III and the head 15 When the part 5 is lowered and the component 5 is mounted, the vacuum is turned off to switch to the atmospheric pressure. For this purpose, the drive circuit 82 supplies a drive current for switching, and the microcomputer 78 performs the control based on a command from the host CPU 74. The origin detection element 43 is connected to the microcomputer 78 via the cable 18, and a detection signal is transmitted to the computer 78.
[0032]
A rotation angle detector 65 such as an optical encoder or a resolver is provided on the output shaft of the index unit 57 and detects the rotation angle of the rotary table 13. Based on the angle information from the rotation angle detector 65 through the interface 66, the host CPU 74 gives a current value increase command to the drive circuit 82 of the pulse motor 31 through the serial interface 79 and the microcomputer 78. The increased current flows to the power line 18A and is given to the pulse motor 31.
[0033]
That is, when the operation of the pulse motor 31 is stopped, the current value is generally lowered for the purpose of suppressing heat generation and the overall current value. As a result, the rotor 32 is vibrated due to the turning acceleration of the rotary table 13 due to the decrease. For this reason, based on the angle information from the rotation angle detector 65, that is, for example, from the end of the stop of the station immediately before the imaging station II to the end of the stop of the imaging station II, the current flows to the pulse motor 31 as described above. The current value (hereinafter referred to as “current value”) is increased (the current value is increased to 130% of the driving current at the time of rotation, and the current value and the increasing period are stored in the RAM 75), and due to disturbance The vibration of the rotor 32 of the pulse motor 31 is suppressed.
[0034]
As a result, when the image pickup station that picks up the electronic component 5 sucked by the suction nozzle 14 is vibrated, the image becomes blurred, and the position of the electronic component cannot be recognized as the mounting device increases in speed. However, this problem can be solved.
[0035]
The operation will be described below with the above configuration. First, the operation of automatic operation for mounting the electronic component 5 of the electronic component automatic mounting apparatus on the printed circuit board 6 will be described. When the apparatus is turned on, the origin position of the rotation angle of the suction nozzle 14 of each mounting head 15 (that is, the rotation angle of the rotor 32) is detected. That is, the rotor 32 is rotated at a low speed, a detection signal is output at a position where the origin detection element 43 faces the magnet 41, the signal current is transmitted via the cable 18 and detected by the microcomputer 78, and the origin position is stored. Is done.
[0036]
Next, when the automatic operation is started, when the mounting head 15 is stopped at the suction station I due to the intermittent rotation by the index unit 57 of the rotary table 13, the supply is driven by the supply table drive motor 9. The component supply device 8 for storing the electronic component 5 to be supplied is stopped at the suction position of the suction nozzle 14 of the mounting head 15 of the suction station I, and the electronic component 5 is lowered by the lowering of the nozzle 14. It is taken out.
[0037]
At this time, a driving current is supplied to the vacuum valve 44 through the cable 18 under the control of the microcomputer 78, and the vacuum valve 44 is switched so that the negative pressure is applied to the vacuum suction hole 40 of the suction nozzle 14 at an appropriate timing when the head 15 is lowered. The pressure is generated, the component 5 is sucked, and the bent cable 18 is extended when the mounting head 15 is lowered, and is bent again when the cable 18 is raised.
[0038]
Next, the rotary table 13 is indexed by the index unit 57, performs intermittent rotation, and eventually moves to the imaging station II. In this case, since the rotation angle of the rotary table 13 is known by the rotation angle detector 65, the host CPU 74 does not stop until the stop of the imaging station II until the stop of the imaging station II as shown in FIG. A command for increasing the current value corresponding to 130% of the driving current at the time of rotation is given to the driving circuit 82 of the pulse motor 31 via the serial interface 79 and the microcomputer 78, and the increased current flows from the driving circuit 82 to the power line 18A. It is given to the pulse motor 31. Accordingly, since the holding torque of the rotor 32 does not decrease, the rotor 32 is prevented from being vibrated due to the turning acceleration of the rotary table 13.
[0039]
Therefore, when the image pickup station that picks up the electronic component 5 picked up by the conventional suction nozzle 14 is vibrated, the image becomes blurred, and the accuracy of the position recognition of the electronic component is improved as the mounting device speeds up. There was a problem that there was no situation, but this problem can be solved.
[0040]
In a state where the vibration is prevented, the electronic component 5 picked up by the pickup nozzle 14 is picked up by the pickup camera 16 while the rotary table is stopped. After that, after this stop, the host CPU 74 sends a current value decrease command (about 50% of the driving current at the time of rotation) to the driving circuit 82 of the pulse motor 31 via the serial interface 79 and the microcomputer 78. ), And the current descending from the drive circuit 82 flows to the power line 18A and is applied to the pulse motor 31.
[0041]
Then, recognition processing is performed, and the positional deviation of the component 5 with respect to the suction nozzle 14 is recognized. When the recognition is completed, the CPU 74 calculates an angle amount obtained by adding the amount (deviation amount) to be corrected based on the recognition result to the mounting angle data of the mounting data. Next, the calculated angular amount is output to the microcomputer 78 of the mounting head 15 via the slip ring 80 or the like, and the angle positioning is performed by driving the pulse motor 31 at a station immediately before the mounting station III.
[0042]
Further, the rotary table 13 performs intermittent rotation to reach the mounting station III, and the coordinates indicated by the mounting data by moving the XY table 3 (including the amount of displacement in the XY direction) of the electronic component 5 whose angular positioning has been completed. It is mounted on the printed circuit board 6 positioned at the position. Also in this case, the mounting head 15 moves up and down in a short time, and the cable 18 is bent. Further, a driving current is output to the vacuum valve 44 via the power line 18B in the cable 18, and the suction nozzle 14 is switched at an appropriate timing to turn off the negative pressure of the suction hole 40 and to be released to atmospheric pressure. .
[0043]
Next, when the mounting head 15 passes through the mounting station III, the CPU 74 commands the origin detection operation, the origin detection element 43 detects the origin and outputs a detection signal, and the next component suction operation is performed. Preparations are made.
[0044]
As described above, in this embodiment, control is performed so that a current value increase command is given to the drive circuit 82 of the pulse motor 31 from the end of the stop of the station immediately before the image pickup station II to the end of the stop of the image pickup station II. However, the present invention is not limited to this, and at the timing of electronic component suction / recognition / mounting in the electronic component mounting apparatus, even during the stop of the pulse motor 31 due to intermittent rotation of the rotary table, the current value is only specified. The vibration of the rotor of the rotary drive motor due to the disturbance may be suppressed. That is, for example, it is raised only during the stoppage at the suction nozzle switching (selection) station from the mounting station to the suction station, and the switching mechanism does not work well when the suction nozzle is switched (it is not fixed at the original position). You may do it.
[0045]
In this case, the reason is limited to a specific period because, as described above, if the entire period during which the pulse motor 31 is stopped is increased, heat generation occurs and the overall current value cannot be suppressed. is there.
[0046]
Further, by increasing the current value while the pulse motor 31 is stopped at the suction station and the mounting station, vibration of the rotor of the rotary drive motor due to the turning acceleration of the rotary table 13 can be suppressed. Accuracy can be ensured.
[0047]
Although the embodiments of the present invention have been described above, various alternatives, modifications, and variations can be made by those skilled in the art based on the above description, and the present invention is not limited to the various alternatives described above without departing from the spirit of the present invention. It includes modifications or variations.
[0048]
【The invention's effect】
According to the present invention, at the timing when the mounting head stops moving in the electronic component mounting apparatus, even when the rotation drive motor for rotating the suction nozzle is stopped, the current value is increased and the rotor of the rotation drive motor due to disturbance is increased. Can be suppressed. Therefore, various effects due to the vibration of the rotor can be suppressed.
In particular, even at the timing when the electronic component picked up by the suction nozzle is imaged by the camera, even if the rotary drive motor for rotating the suction nozzle is stopped, the current value is increased only for a certain period, and Since the vibration of the rotor can be suppressed, the captured image is prevented from blurring and the recognition process can be performed satisfactorily.
In addition, at the timing of suction / mounting of electronic components, even if the rotary drive motor for rotating the suction nozzle is stopped, the current value is increased for a certain period to suppress the vibration of the rotor of the rotary drive motor due to disturbance. Can do. Therefore, it is possible to suppress the influence at the timing at which the rotor vibrates and causes various influences.
In addition, during the stop of the rotation drive motor from before the stop of movement of the mounting head to the stop of the movement, a current value increase command is given to the drive circuit of the rotation drive motor to increase the current value higher than the drive current at the time of rotation of the rotation drive motor. Therefore, even when the rotation drive motor for rotating the suction nozzle is stopped, vibration of the rotor of the rotation drive motor due to disturbance can be suppressed. Therefore, various effects due to the vibration of the rotor can be suppressed.
[Brief description of the drawings]
FIG. 1 is a plan view of an electronic component mounting apparatus.
FIG. 2 is a side view of the electronic component mounting apparatus.
FIG. 3 is a side view in which the mounting head is partially broken.
FIG. 4 is a control block diagram of the electronic component mounting apparatus.
FIG. 5 is a timing chart of current application of a pulse motor.
[Explanation of symbols]
13 Rotary Table 14 Suction Nozzle 15 Mounting Head 16 Imaging Camera 31 Pulse Motor 32 Rotor 65 Rotation Angle Detector 74 Host CPU
75 RAM
82 Drive circuit

Claims (4)

The mounting head stops moving, the suction nozzle of the mounting head takes out the electronic component, the mounting head moves onto the imaging camera, the electronic camera picks up the electronic component sucked by the suction nozzle, and Based on the recognition result of the image picked up by the image pickup camera of the electronic component picked up by the pick-up nozzle of the mounting head, the rotation correction is performed by the rotational drive motor by the amount of deviation in the rotation direction of the pick-up nozzle and onto the printed circuit board. In the electronic component mounting apparatus in which the suction nozzle of the mounting head moved and stopped mounts an electronic component on a printed circuit board, the drive circuit of the rotational drive motor is stopped while the rotational drive motor is stopped when the mounting head stops moving And a control device that controls to give a current value increase command for increasing the current value to a value higher than the drive current during rotation of the rotary drive motor. An electronic component mounting apparatus characterized by. The electronic component sucked by the suction nozzle after the stop before the mounting head stops moving is imaged by the imaging camera and the mounting head starts to move while the rotary drive motor is stopped. 2. The electronic component mounting apparatus according to claim 1, wherein the control device performs control so as to give the current value increase command to a drive circuit of the rotary drive motor.   The control device when the rotation drive motor is stopped when the suction nozzle of the mounting head sucks and takes out the electronic component or when the electronic component sucked by the suction nozzle of the mounting head is mounted on the printed circuit board 2. The electronic component mounting apparatus according to claim 1, wherein control is performed so as to give the current value increase command to a drive circuit of the rotary drive motor. The mounting head stops moving, the suction nozzle of the mounting head takes out the electronic component, the mounting head moves onto the imaging camera , the electronic camera picks up the electronic component sucked by the suction nozzle, and Based on the recognition result of the image picked up by the image pickup camera of the electronic component picked up by the pick-up nozzle of the mounting head, the rotation correction is performed by the rotational drive motor for the amount of deviation in the rotation direction of the pick-up nozzle and onto the printed circuit board. In the electronic component mounting apparatus in which the suction nozzle of the mounting head that has moved and stopped descends and mounts an electronic component on a printed circuit board, the rotation drive motor is stopped from before the mounting head stops moving to when it stops moving. A current value increase command for increasing the current value higher than the drive current at the time of rotation of the rotary drive motor is given to the drive circuit of the rotary drive motor. An electronic component mounting apparatus characterized by comprising a control device for controlling.

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