JP7213411B2 - Parts mounting device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a component mounting apparatus that mounts a component at a mounting position on a board.

A component mounting apparatus used to mount components on a board in the manufacturing process of a component mounting board absorbs fluctuations in the mounting height position caused by warping and deformation of the board during the mounting operation, and also adjusts the component to the mounting position of the board. It is necessary to control the mounting load to be pressed to an appropriate value according to the target part.

In order to realize such a function, there has been conventionally known a configuration in which a loading nozzle that holds a component and mounts it on a substrate incorporates a spring for absorbing the load (see, for example, Patent Document 1). In the prior art disclosed in this patent document, in a configuration in which an elastic body such as a coil spring is used to urge the suction nozzle, a load sensor is used to measure the correlation between the pressing amount of the suction nozzle and the pressing load. , an example of performing load control during the mounting operation is described.

JP 2008-227140 A

However, the prior art described above has the following problems. That is, in recent years, with the miniaturization of electronic devices, the size and thickness of mounted components have progressed. Since the load capacity of these types of parts is small, damage such as part cracks may occur if the mounting load is not properly set. Therefore, it is necessary to control the mounting load in the low load range. be. However, in the configuration in which the suction nozzle is urged by an elastic body, including the above-mentioned prior art, the mounting load is set in a low load range for small parts due to fluctuations in the sliding state of the mechanism that holds the suction nozzle. It was difficult to control stably with high accuracy.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a component mounting apparatus capable of stably controlling a mounting load in a low load range with high accuracy.

A component mounting apparatus according to the present invention is a component mounting apparatus for mounting a component on a board, comprising: a component holding section that holds a component by means of negative pressure; a shaft mounted in a state of being urged downward by a , a servomotor for causing the component holding portion to move up and down by moving the shaft up and down, and the servomotor being controlled based on a preset operation pattern. As a result, the component held by the component holding portion is landed on the mounting position of the substrate, and after the component holding portion presses the component against the substrate, the component holding portion is raised to mount the component on the mounting position. wherein the control unit is configured such that the load when the component holding unit presses the component against the substrate is smaller than the force that urges the component holding unit toward the shaft by the elastic body. to control the servo motor;

According to the present invention, the mounting load can be stably controlled with high accuracy in a low load region.

1 is a perspective view showing the overall configuration of a component mounting apparatus according to one embodiment of the present invention; FIG. 2 is a configuration explanatory diagram of a mounting head provided in a component mounting apparatus according to an embodiment of the present invention; 1 is a sectional side view of a mounting head provided in a component mounting apparatus according to an embodiment of the present invention; FIG. 1 is a cross-sectional front view of a mounting head provided in a component mounting apparatus according to an embodiment of the present invention; FIG. FIG. 2 is a configuration explanatory diagram of a nozzle unit in a mounting head provided in a component mounting apparatus according to an embodiment of the present invention; FIG. 2 is an explanatory diagram of the configuration of a component holding portion in the mounting head provided in the component mounting apparatus according to the embodiment of the present invention; FIG. 4 is an operation explanatory view of the mounting operation of the component holding portion to the holder in the mounting head provided in the component mounting apparatus according to the embodiment of the present invention; 1 is a block diagram showing the configuration of a control system of a component mounting apparatus according to one embodiment of the present invention; FIG. FIG. 2 is an explanatory diagram of the arrangement state of the load detection section in the component mounting apparatus according to the embodiment of the present invention; FIG. 3 is an explanatory diagram showing the relationship between forces acting on the nozzle unit of the component mounting apparatus according to one embodiment of the present invention; Explanatory drawing of thrust-load correlation data showing the correlation between the thrust of the servomotor and the load by the component holding unit in the component mounting apparatus according to the embodiment of the present invention. FIG. 2 is an explanatory diagram of a substrate to be worked on by a component mounting apparatus according to an embodiment of the present invention and mounting data of the substrate; FIG. 4 is an explanatory diagram of a height parameter for controlling the lifting operation in the component mounting operation by the component mounting apparatus according to the embodiment of the present invention; FIG. 2 is an explanatory diagram of a basic example of component mounting operation by the component mounting apparatus according to one embodiment of the present invention; Explanatory drawing of the first example of the component mounting operation by the component mounting apparatus according to the embodiment of the present invention. Explanatory drawing of the second example of the component mounting operation by the component mounting apparatus according to the embodiment of the present invention. Explanatory drawing of the third example of the component mounting operation by the component mounting apparatus according to the embodiment of the present invention. FIG. 11 is an explanatory diagram showing correction target positions for deceleration height correction in the third example of the component mounting operation by the component mounting apparatus according to the embodiment of the present invention; FIG. 2 is a flowchart showing component mounting work by the component mounting apparatus according to one embodiment of the present invention;

Embodiments of the present invention will now be described with reference to the drawings. First, referring to FIG. 1, the configuration and functions of the component mounting apparatus 1 will be described. The component mounting apparatus 1 has a function of manufacturing a component-mounted substrate by mounting components on the substrate. In FIG. 1, a substrate transfer section 2 is arranged in the X direction (substrate transfer direction) on the upper surface of the base 1a. The board transfer unit 2 receives the board 3 to be mounted with components from an upstream apparatus (not shown), conveys the board 3 to a mounting position in the component mounting apparatus 1, and positions and holds the board. That is, the substrate transfer section 2 functions as a substrate holding section that holds the substrate 3 . A component supply unit 5 is arranged on both sides of the substrate transport unit 2, and a plurality of tape feeders 6 are arranged in parallel with each component supply unit 5. As shown in FIG. The tape feeder 6 has a function of conveying a carrier tape containing components P (see FIGS. 12 and 13) to a component pickup position by a mounting head 11 described below.

Y-axis moving tables 8 driven by linear motors are arranged in the Y direction on the upper surfaces of a pair of frame members 7 arranged at both ends in the X direction in the component mounting apparatus 1 . Between the Y-axis moving tables 8, an X-axis moving table 9 similarly driven by a linear motor is installed so as to be movable in the Y direction. A mounting head 11 is mounted on the X-axis moving table 9 so as to be freely movable in the X direction.

The Y-axis moving table 8 and the X-axis moving table 9 constitute an XY table 10. By driving the XY table 10, the mounting head 11 moves in the XY directions. As a result, the mounting head 11 picks up the component P from the tape feeder 6 by the component holder 31 (see FIG. 2) and mounts it on the substrate 3 . Therefore, the XY table 10 serves as a mounting head moving mechanism that moves the mounting head 11 with respect to the substrate holding portion that holds the substrate 3 and the component supply portion 5 that supplies the component P. As shown in FIG.

A component recognition camera 12 is arranged in the movement path of the mounting head 11 between the substrate transport unit 2 and the component supply unit 5, with the imaging direction facing upward. The component recognition camera 12 images the component P held by the mounting head 11 from below. Identification and position detection of the component P held by the mounting head 11 are performed by recognizing the imaging result. A mounting head controller 13 is built in the mounting head 11, and a body controller 14 is built in the base 1a.

The mounting head control section 13 has a function of controlling the up-and-down operation of the component holding section 31 (see FIG. 2) that holds the component P in the mounting head 11 . Further, the body control section 14 has a function of controlling the apparatus body section and issuing a work command to the mounting head control section 13 . The mounting head control section 13 and the body control section 14 constitute a control section 15 that controls each section of the component mounting apparatus 1 .

In this embodiment, the mounting head 11 can be attached to and detached from an X-axis moving table 9 of an XY table 10, which is a mounting head moving mechanism. FIG. 2(a) shows a cross section of the X-axis moving table 9 with the mounting head 11 mounted on the X-axis moving table 9. FIG. A back surface member 23 is provided on the back surface of the mounting head 11 having a component holding portion 31 for holding a component at the lower end portion. As shown in FIG. 2(b), the back member 23 is detachably attached to the moving base 22 provided on the X-axis moving table 9 (arrow a).

The moving base 22 is coupled to the X-axis moving table 9 via a pair of slide guides 21 so as to be freely movable in the X direction. A moving base 22 is driven in the X direction with respect to the X-axis moving table 9 by a linear motor 20 . The linear motor 20 has a structure in which a mover 20b coupled to a move base 22 faces a stator 20a arranged on the X-axis move table 9 in the X direction. A board recognition camera 16 is arranged at the lower end of the moving base 22 with its imaging direction facing downward. The board recognition camera 16 moves integrally with the mounting head 11 to pick up an image of the board 3 positioned below.

A connector holder 25 is coupled to the upper end of the moving base 22 via a horizontal coupling member 24 . The upper portion of the mounting head 11 and the connector holding portion 25 are connected via a piping connector 26 and a wiring connector 27 . The piping connector 26 has a function of supplying air pressure or vacuum pressure to the mounting head 11 from the apparatus main body. The wiring connector 27 has a function of supplying power and transmitting/receiving an electric signal from the device main body to the mounting head 11 . As a result, the mounting head controller 13 built in the mounting head 11 and the body controller 14 built in the base 1a are connected.

As shown in FIG. 2(b), when the back member 23 is removed from the moving base 22, the head side connection portions 26a and 27a provided on the mounting head 11 in the pipe connector 26 and the wiring connector 27 are connected to the connector holding portions. 25 is detached from the main body side connecting portions 26b and 27b. When mounting the mounting head 11 on another component mounting device, the rear member 23 is fixedly coupled to the moving base 22 of the other device, and the head-side connecting portions 27a and 26a are provided to the connector holding portion 25 of the other device. are fitted to the main body side connecting portions 26b and 27b.

Next, the configuration of the mounting head 11 will be described with reference to FIGS. 3 and 4. FIG. As shown in FIGS. 3 and 4, the mounting head 11 has a plurality of nozzles (here, 12 nozzles arranged in two rows in the Y direction, six nozzles arranged in the X direction) on the front surface of the vertical back member 23 . It has a configuration in which the nozzle unit 30 is arranged. These nozzle units 30 are held by a shaft holding portion 23a and a servo motor mounting portion 23b fixed to the back member 23, and the outer surface side is closed by a cover member 11a.

As shown in FIG. 3, the nozzle unit 30 has a configuration in which a shaft 35 having an upper portion 36 and a lower portion 32 is raised and lowered by a servomotor 41, thereby raising and lowering the component holding portion 31. As shown in FIG. The shaft 35 is supported by the shaft holding portion 23a, and the servomotor 41 is attached to the servomotor attachment portion 23b. A moving rod 42 vertically moved by a servomotor 41 is coupled to the upper portion 36 via a rotating member 40 . Rotating member 40 is rotatably attached to moving rod 42 and couples upper portion 36 to moving rod 42 in a manner that allows relative rotation.

By driving the servomotor 41, the component holding portion 31 mounted on the lower portion 32 of the shaft 35 is raised and lowered, whereby the component P held by the component holding portion 31 is moved up and down to be mounted on the board 3. will be The mounting head control section 13 for moving the component holding section 31 up and down is attached to the back surface member 23 and connected to the head-side connection section 27a. It can be detachably connected to the body control unit 14 .

As shown in FIG. 4 , a pulley 37 is attached to each upper portion 36 so as to allow the upper portion 36 to move up and down while allowing rotation to be transmitted to the upper portion 36 . A belt 37a stretched around a pulley 37 is driven by a .theta.-axis motor 38, which rotates each upper part 36 to allow .theta.-rotation to rotate the component holder 31 around the nozzle axis. These multiple component holding portions 31 have a function of holding the component P by means of negative pressure introduced into the suction holes 31d (see FIG. 6).

That is, the mounting head 11 in the component mounting apparatus 1 shown in the present embodiment includes a plurality of component holding portions 31 that hold the components P by means of negative pressure introduced into the suction holes 31d, and a plurality of components that lift and lower the plurality of component holding portions 31. By controlling the servomotor 41 and the servomotor based on a preset operation pattern, the component holding unit 31 is moved up and down to mount the component P held by the component holding unit 31 on the substrate 3. It is configured to have a mounting head control unit 13 that allows

Next, referring to FIG. 5, the configuration and function of the nozzle unit 30 will be described. In FIG. 5, a shaft 35 having an upper portion 36 and a lower portion 32 is held by a shaft holding portion 23a. A component holding portion 31 having a nozzle 31a and a nozzle holding portion 31b is attached to a holder portion 32a (see FIG. 6) provided in the lower portion 32 so as to be vertically displaceable. Between the lower portion 32 and the nozzle holding portion 31b of the component holding portion 31, a biasing member 33 using a compression spring, which is an elastic body, is mounted. The biasing member 33 constantly presses the component holding portion 31 downward with a predetermined biasing force set in advance as a pressure value.

A return spring 39 that is a compression spring is mounted between the pulley 37 attached to the upper portion 36 and the rotating member 40 . The return spring 39 applies an upward reaction force to the rotating member 40 . That is, when the component holding portion 31 is lowered, the downward thrust of the servomotor 41 causes the upper portion 36 to descend against the reaction force of the return spring 39 . When the component holding portion 31 is lifted, the upper portion 36 is lifted by the upward thrust of the servo motor 41 and the upward reaction force of the return spring 39 .

The shaft 35 is provided with an air joint portion 34 positioned above the lower portion 32 . The air joint portion 34 communicates the suction hole 31d provided in the component holding portion 31 with an external negative pressure source (not shown). When the component holding portion 31 is lifted and lowered, the air joint portion 34 is lifted and lowered together with the shaft 35 by being guided by an elevation guide member 34a provided downwardly extending from the shaft holding portion 23a.

A servomotor 41 for raising and lowering the shaft 35 includes a linear motor section 41a for raising and lowering a moving rod 42 inserted vertically, and an encoder 44 for outputting a pulse signal as the moving rod 42 moves. The encoder 44 has a linear scale 44a provided on the moving rod 42, and a movement detector 44b provided on the vertical member 43 to face the linear scale 44a and detecting movement of the linear scale 44a. The movement detector 44b outputs encoder pulses indicating the movement distance and direction of the linear scale 44a as position signals to the position detector 53 (see FIG. 8).

Next, with reference to FIGS. 6 and 7, a detailed configuration of the component holding portion 31 and a mounting operation for mounting and holding the component holding portion 31 to the lower portion 32 will be described. FIG. 6 shows side surfaces in a state where the component holding portion 31 is held by the lower portion 32, and FIGS. 6(a) and 6(b) show side surfaces in two orthogonal directions.

As shown in FIG. 6A, the lower portion 32 is provided with a holder portion 32a for holding the component holding portion 31. As shown in FIG. A cylindrical sliding portion 31c provided on the component holding portion 31 is engaged with a fitting portion 32b provided in the shape of a hollow circular hole in the holder portion 32a so as to be displaceable in the vertical direction. A nozzle holding portion 31b is provided below the slide portion 31c, and the nozzle holding portion 31b holds a nozzle 31a provided with a suction portion 31f for sucking a component.

A pin 31e for fixing the position of the component holding portion 31 to the holder portion 32a is provided at the upper end portion of the slide portion 31c so as to protrude to both sides in the radial direction. A guide groove for guiding the pin 31e to a fixed position is provided in the holder portion 32a in a configuration described below. That is, as shown in FIG. 6A, an insertion portion 32c extending vertically upward from the lower end surface of the holder portion 32a is provided on the side surface of the holder portion 32a.

A horizontal portion 32d is provided at the upper end portion of the insertion portion 32c in a range that encircles the holder portion 32a by half a turn. Furthermore, as shown in FIG. 6(b), the terminal end of the horizontal portion 32d is connected to a guide portion 32e extending vertically downward to the middle of the height of the holder portion 32a. When the component holding portion 31 is held by the holder portion 32a, the pin 31e is positioned at the lower end portion of the guide portion 32e, whereby the component holding portion 31 is held by the holder portion 32a. At this time, a predetermined clearance is ensured between the upper end of the slide portion 31c and the ceiling surface of the fitting portion 32b, and the pin 31e can move vertically in the guide portion 32e. As a result, the component holding portion 31 can be vertically displaced with respect to the lower portion 32 .

The suction portion 31f communicates with a suction hole 31d formed inside the component holding portion 31. When the component holding portion 31 is held by the holder portion 32a, the suction hole 31d communicates with the suction hole 31d formed in the lower portion 32. 32f and communication state. The suction hole 32f is connected to an external negative pressure generating source via an air joint portion 34 (see FIG. 5), whereby the component P is held by the nozzle 31a in the component holding portion 31 under negative pressure.

In the above configuration, the nozzle 31a, the nozzle holding portion 31b, the slide portion 31c, the suction hole 31d, and the pin 31e are attached to the lower portion 32 of the shaft 35 so as to be displaceable in the vertical direction. A component holding portion 31 having a suction hole 31d is configured. A biasing member 33, which is an elastic body, is fitted to the outer periphery of the slide portion 31c between the lower end surface of the holder portion 32a and the nozzle holding portion 31b. The biasing member 33 biases the component holding portion 31 downward against the lower portion 32 of the shaft 35 .

Next, referring to FIG. 7, an operation procedure for holding the component holding portion 31 in the holder portion 32a of the lower portion 32 will be described. First, as shown in FIG. 7A, the pin 31e provided on the slide portion 31c of the component holding portion 31 is aligned with the insertion portion 32c of the holder portion 32a. Then, in this state, the component holding portion 31 is brought closer to the holder portion 32a so that the sliding portion 31c is fitted into the fitting portion 32b (arrow b).

Next, as shown in FIG. 7B, the component holding portion 31 is lifted while guiding the pin 31e by the insertion portion 32c (arrow c), and when the pin 31e reaches the horizontal portion 32d, the pin 31e is The component holder 31 is rotated around the axis while being guided by 32d. As a result, as shown in FIG. 7(c), the pin 31e reaches the terminal end of the horizontal portion 32d. Thereafter, as shown in FIG. 7(d), the component holding portion 31 is pulled down while guiding the pin 31e by the guide portion 32e (arrow e). As a result, the pin 31e is positioned at the lower end of the guide portion 32e, and the component holding portion 31 is held by the holder portion 32a of the lower portion 32. As shown in FIG.

Here, the relationship between the forces acting on the nozzle unit 30 having the above configuration will be described with reference to FIG. 10 . In FIG. 10, the thrust T is the thrust generated by the servomotor 41 and acts in the direction of pushing down the shaft 35 coupled via the rotating member 40 . The weight W is the total weight of the moving rod 42, the rotating member 40, the upper portion 36, the air joint portion 34, the lower portion 32, the component holding portion 31, and the like. Similarly, it acts in the direction of pushing down the shaft 35 .

The reaction force F<b>1 is the reaction force of the return spring 39 and acts in the direction of pushing up the shaft 35 via the rotating member 40 . The resistance F2 is an external resistance force of the slide guide portion that slidably holds the movable portion described above, and acts upward on the shaft 35 that is driven in the downward direction. The load LF indicates the load when the component holding portion 31 descends and contacts the abutting portion, for example, the component P held by the component holding portion 31, when it is pressed against the substrate.

In FIG. 10, in order to obtain the thrust-load correlation data (see FIG. 11), the component holder 31 is pressed against the load detector 45 (see FIGS. 8 and 9) having a function of measuring the load LF. state. A biasing force FP shown in FIG. 10 is the pressure value of the biasing member 33 interposed between the component holding portion 31 and the lower portion 32, and indicates the pressing force exerted on the component holding portion 31 and the lower portion 32. FIG.

In the state where the force is applied as described above, the load LF is represented by the relationship shown in Equation (1) in the figure, that is, LF=T+W-F1-F2. Here, since the weight W, the reaction force F1, and the resistance F2 can be regarded as fixed values for the same nozzle unit 30, the load LF uniquely depends on the thrust force T. In the component mounting apparatus 1 according to the present embodiment, the thrust T is set so that the biasing force FP and the load LF satisfy the inequality (2), that is, the load LF is smaller than the biasing force FP. I have to.

Setting the thrust T so that the load LF is smaller than the biasing force FP has the following technical significance. That is, in the prior art, the urging member 33 has a role of elastically supporting the component holding portion 31, and when the component held in the component holding portion 31 is mounted, the urging member 33 is pushed. The component was pressed against the substrate by the generated reaction force.

On the other hand, in the component mounting apparatus 1 shown in the present embodiment, first, the limit value of the load LF that makes the load LF that pushes down the component holding portion 31 smaller than the biasing force FP of the biasing member 33 is defined as the limit load LFL. do. Then, the thrust force T of the servo motor 41 corresponding to such a limit load LFL is obtained as a thrust force limit value TL and stored in the mounting head controller 13 . When the servomotor 41 is driven in the actual component mounting operation, the servomotor 41 is controlled so that the thrust T does not exceed the thrust limit value TL.

By controlling the thrust force T of the servomotor 41 in the nozzle unit 30 in this manner, the component is mounted on the substrate by the pressing force of the load LF itself without compressing the biasing member 33 during the downward movement of the component holding portion 31. be able to. As a result, even if there is variation in the height of the board depending on the component mounting position, the component can be pressed against the board by the load LF that can be controlled with high precision.

In order to enable such control of the thrust T, in the present embodiment, the value of the thrust T of the servo motor 41 is limited by the mounting head control section 13 that controls the operation of the nozzle unit 30 of the mounting head 11. A thrust force limit value TL is set for each servo motor 41, and the servo motors 41 are controlled based on the set thrust force limit value TL. The thrust limit value TL is set by referring to the thrust-load correlation data (see FIG. 11) prepared in advance and the limit load LFL included in the command from the main body control unit 14 provided in the main body of the component mounting apparatus 1. performed by A configuration provided in the control section 15 including the mounting head control section 13 and the main body control section 14 for executing such control processing in the component mounting apparatus 1 will be described below with reference to FIG.

In FIG. 8, a control unit 15 for controlling the entire component mounting apparatus 1 is composed of a body control unit 14 and a mounting head control unit 13 connected to the body control unit 14 via a wiring connector 27 . The body control unit 14 controls operations such as transporting the board 3 in the component mounting apparatus 1 and picking up components from the component supply unit 5 by the mounting head 11 , and also transmits control commands to the mounting head control unit 13 . have a function.

That is, the body control unit 14 controls at least the XY table 10 (mounting head moving mechanism) that moves the mounting head 11 , and transmits a command to the mounting head control unit 13 to move the component holder 31 up and down. In other words, the control unit 15 controls the servomotor 41 for raising and lowering the shaft 35 of the nozzle unit 30 based on the operation pattern preset and stored in the second storage unit 58 as the "standard operation pattern" 58d. As a result, the component holding section 31 is caused to move up and down for mounting the component held by the component holding section 31 on the board 3 .

The mounting head control unit 13 includes servo motors for controlling the servo motors 41 (#1 to #12) of the nozzle units 30 for each of the plurality of nozzle units 30 (twelve units in this case) arranged in the mounting head 11. A control unit 50 (#1 to #12) is provided. Each servo motor control section 50 includes a motor driver 51, a thrust detection section 52, a position detection section 53, a landing detection section 54, a timer 55, a thrust limit section 56, a first storage section 57 and a second storage section 58. I have.

Here, as described above, the mounting head 11 is detachably attached to the XY table 10, which is the mounting head moving mechanism, and the first storage section 57 is a non-volatile storage section. With this configuration, even when the mounting head 11 is removed from the X-axis moving table 9 of the XY table 10 and becomes a single unit, the stored contents can be retained. As a result, even when the mounting head 11 removed from one component mounting apparatus 1 is transferred to another component mounting apparatus 1, each nozzle unit 30 of the mounting head 11 is stored in the first storage unit 57. It is possible to operate correctly by referring to the correlation data.

The motor driver 51 is a drive control device for the servomotor 41 and drives the servomotor 41 by supplying electric power (arrow f) to the servomotor 41 based on a preset operation pattern. A pulse signal sent from the encoder 44 of the servomotor 41 detects the deviation from the target position and the target speed determined by the operation pattern (arrow g), and the servomotor 41 is driven by servo control that feeds back the detected deviation. do.

The thrust detection unit 52 has a function of detecting the thrust of the servomotor 41 . That is, the thrust generated in the servomotor 41 is detected from the current supplied from the motor driver 51 to the servomotor 41 (arrow f) or the current value notified from the motor driver 51 (arrow h). In this embodiment, the thrust force of the servomotor 41 is limited by the function of the thrust limiter 56 based on the aforementioned thrust force limit value TL.

The thrust limiter 56 refers to the limit load LFL included in the control command from the body control unit 14 with the thrust-load correlation data stored in the first storage unit 57, which is the correlation data storage unit, to determine the thrust limit value. TL is obtained and stored in the first storage unit 57 as a "thrust limit value" 57a. Then, a process of setting the obtained thrust limit value TL in the motor driver 51 is executed (arrow i).

That is, when the component holding portion 31 descends and reaches the thrust limit height TLh (see FIG. 13) set in advance and stored in the second storage portion 58 as the "thrust limit height" 58c, the first is set in the motor driver 51 to the thrust limit value TL stored as the "thrust limit value" 57a. When the component holding portion 31 rises and moves to a position higher than the thrust limit height TLh, the setting of the thrust limit value TL in the motor driver 51 is canceled.

In this configuration, the thrust limiter 56 and the motor driver 51 limit the thrust of the servomotor 41 based on the thrust-load correlation data and information on the limit load LFL included in the control command from the main body control unit 14. A value TL is set, and a thrust limiter is configured to limit the thrust of the servomotor 41 to the thrust limit value TL or less when the component holder 31 is lowered toward the substrate 3 . Here, the thrust force limit value TL is defined as the load acting on the parts from the component holding portion 31 when the servomotor 41 is driven with the same thrust force as the thrust force limit value TL. is set within a range smaller than the biasing force FP that biases the .

In the thrust limiter configured as described above, the load LF acting on the component from the component holder 31 when the servomotor 41 is driven is smaller than the biasing force FP with which the biasing member 33 biases the component holder 31. A thrust limit value TL that limits the thrust of the servomotor 41 is set within a certain range, and the thrust of the servomotor 41 is limited to the thrust limit value TL or less. Specifically, in driving the servomotor 41 by the motor driver 51, the current supplied to the servomotor 41 is limited so that the thrust becomes equal to or less than the thrust limit value TL.

The position detector 53 counts encoder pulses from the encoder 44 of the servomotor 41 . This count value serves as position information indicating the position of the component holding portion 31 in the height direction. That is, the position detection section 53 has a height position measurement function of detecting the position of the component holding section 31 in the height direction based on the position signal from the servomotor 41 . Mounting position height measurement, which will be described later, is performed using the height position measurement function of the position detection unit 53 .

The landing detection section 54 detects that the component held by the component holding section 31 has landed on the board 3 . This landing detection is performed by one of the following two methods. First, as one method, while the thrust force limit value TL is set and the thrust force T is limited by the above-described thrust force limiter, the thrust force detection unit 52 detects that the thrust force T of the servo motor 41 has reached the set thrust force limit value TL. is detected, it is detected that the component has landed on the substrate 3. As an alternative to this method, it may be possible to detect that the component has landed on the substrate 3 by detecting that the encoder pulse output from the encoder 44 of the servomotor 41 is stagnant.

The timer 55 has a function of measuring the elapsed time after the landing detection unit 54 detects the landing. When the measured elapsed time reaches a "target time" 58e that is set in advance as an appropriate static time and stored in the second storage unit 58, the component holding unit 31 starts to rise. In the present embodiment, the mounting head control unit 13 of the control unit 15 determines that the elapsed time " When the target time 58e is reached, the servomotor 41 is controlled to raise the part holding portion 31. As shown in FIG.

The first storage unit 57 is a correlation data storage unit that stores correlation data (thrust-load correlation data) indicating the relationship between the thrust force T of the servomotor 41 and the load LF generated at the tip of the component holding unit 31 in a plurality of storage units. Stored for each servo motor. Note that the first storage unit 57 is a non-volatile storage unit, and can retain stored contents even when the mounting head 11 is removed from the XY table 10 .

The contents of the thrust-load correlation data will be described with reference to FIG. FIG. 11 is a graph in which the thrust force T of the servomotor 41 is plotted on the horizontal axis and the load LF generated at the tip of the component holding portion 31 is plotted on the vertical axis. In the nozzle unit 30 having the configuration shown in FIG. 10, the thrust T and the load LF are in a linear relationship in a practical target section, and in the graph of FIG. L].

This characteristic straight line [L] is obtained as follows. First, the load A and the load B generated at the tip of the part holding portion 31 when the servomotor 41 is driven by two thrusts A and B having different magnitudes are measured by the load detection portion 45 shown in FIG. . In FIG. 11, a straight line connecting two data points (PA) and (PB) defined by (thrust A, load A) and (thrust B, load B) is defined as a characteristic straight line [L].

When the control command sent from the main body control unit 14 designates the limit load LFL during the execution of the component mounting operation, the thrust force corresponding to this limit load LFL on the characteristic line [L] is set to the thrust force limit value TL. Ask as That is, in order to limit the thrust force T generated by the servomotor 41 using the limit load LFL applied to the component P by the component holding unit 31 when mounting the component P on the substrate 3 and the thrust-load correlation data shown in FIG. The thrust limit value TL of is calculated. The obtained thrust limit value TL is stored for each of the plurality of servo motors as a "thrust limit value" 57a in the first storage unit 57, which is a correlation data storage unit.

In driving the servomotor 41 in the component mounting operation, the thrust limit value TL thus stored is set in the motor driver 51 at a predetermined timing so that the thrust of the servomotor 41 is equal to or less than the thrust limit value TL. Thrust is controlled. With such a configuration, in the component mounting apparatus 1 including a plurality of component holding portions 31 and servo motors 41 , variations in load caused by variations in the characteristics of the servo motors 41 can be reduced.

In the thrust-load correlation data described above, the thrust A is the first thrust, and the load A is the first load generated when the servomotor 41 is driven with the first thrust. A thrust force B is a second thrust force different in magnitude from the first thrust force, and a load B is a second load generated when the servomotor 41 is driven by the second thrust force. The thrust-load correlation data are stored in the first storage unit 57 as digital values indicating "thrust limit value" 57a, "thrust A" 57b, "load A" 57c, "thrust B" 57d, and "load B" 57e. is stored in the form of

Note that the load A as the first load and the load B as the second load are set to be smaller than the biasing force FP with which the biasing member 33, which is an elastic body, biases the component holding portion 31. . As a result, in the load measurement using the load detection unit 45, the load LF can be measured without compressing the biasing member 33, and the thrust-load correlation can be obtained correctly.

The second storage unit 58 stores work execution data transmitted from the main body control unit 14 to the mounting head control unit 13, such as a height parameter and an operation pattern for controlling the lifting operation in the mounting operation. These work execution data are created by the mounting work execution unit 60 of the main body control unit 14 based on the mounting data for each board type shown in FIG.

FIG. 12(a) shows a component-mounted board 3* manufactured by mounting components on the board 3 by a component-mounting system including the component-mounting apparatus 1 shown in the present embodiment. A component mounting range 3b to be mounted by the component mounting apparatus 1 is set on the component mounting surface of the substrate 3 on which the recognition mark 3a is formed. A component P is mounted by the component mounting apparatus 1 within the component mounting range 3b. A component P* is mounted outside the component mounting range 3b by another component mounting apparatus.

FIG. 12(b) shows the mounting data 70 referred to when the component mounting apparatus 1 mounts the component P within the component mounting range 3b. The wearing data 70 is stored in the wearing data storage section 64 of the body control section 14 . The mounting data 70 includes "mounting position No." 70a indicating the mounting position number of the component P on the board 3 by MP1, MP2, . Mounting position coordinates (X, Y, Θ)” 70b, “mounting position height (Z)” 70c indicating the mounting position height of the component P at each of the “mounting position No” 70a, and the name of the component P to be mounted "part name" 70d shown in FIG.

Next, the height parameter for controlling the lifting operation included in these work execution data will be described with reference to FIG. FIG. 13 schematically illustrates the positional relationship of height parameters for control when the shaft 35 (see FIG. 5) on which the component holding portion 31 holding the component P is mounted is lowered by the servomotor 41. . In FIG. 13, the horizontal line drawn upward indicates the standby height Z0, which is the position before the start of operation of the component holder 31 .

A first example EX1 shown on the lower left side shows the mounted state of the component P in an ideal state. That is, here, the substrate 3 in an ideal state without deformation is set on the substrate holding portion held at the correct height, and the component holding portion 31 holding the component P is lowered with respect to the substrate 3. there is The upper surface of the substrate 3 in this state indicates the mounting height Z1 in the ideal state. On the way from the standby height Z0 to the mounting height Z1, a thrust limit height TLh, which is the height at which the thrust limit value TL is applied to limit the thrust of the servo motor 41, is set. , are stored in advance in the second storage unit 58 of the mounting head control unit 13 .

The height above the mounting height Z1 by the mounting thickness dimension d (here, the thickness dimension obtained by adding the thickness of the component P, the thickness of the land 3c, and the thickness of the solder S for bonding) is A landing height ZC indicates the height of the component holding portion 31 when the held component P contacts the joining solder. A position above the landing height ZC by a predetermined deceleration height offset OFD is a deceleration height Dh that defines a deceleration position at which the descending speed of the component holder 31 is reduced from high to low. A position below the landing height ZC by a target height offset OFT in consideration of whiff prevention is a target height Th at which the component holding portion 31 is lowered.

Here, from the viewpoint of shortening the lowering time of the component holding portion 31 and improving productivity, the deceleration height Dh is set by making the deceleration height offset OFD as small as possible and setting the deceleration height Dh to a height close to the landing height ZC. It is desirable to set However, when the mounting height Z1 of the board 3 to be worked varies, the following inconvenience occurs depending on the setting position of the deceleration height Dh.

That is, if the deceleration height Dh is too low, there is a possibility that the component P held by the component holding portion 31 will land without being decelerated, resulting in mounting failure. Conversely, if the deceleration height Dh is too high, the lowering speed is decelerated earlier than necessary, resulting in a delay in the operating time. In order to prevent such an inconvenience, in the component mounting apparatus 1 shown in the present embodiment, an appropriate mounting height is detected based on the actual mounting height detected by the function of the position detection section 53 in the process of executing the component mounting work. The deceleration height is set dynamically.

In the second example EX2 and the third example EX3 shown on the right side of the first example EX1, the height position of the substrate 3 is displaced from the substrate 3 in the ideal state by an upward variation Δ1 and a downward variation Δ2, respectively. 1 shows the mounted state of the part P of . The upper surface of the substrate 3 in the second example EX2 shows the mounting height Z11 in this state. The landing height ZC1 is a height above the mounting height Z11 by the mounting thickness dimension d, and the deceleration height Dh1 is a position above the landing height ZC1 by a predetermined deceleration height offset OFD.

The upper surface of the substrate 3 in the third example EX3 indicates the mounting height Z12 in this state. The height above the mounting height Z12 by the mounting thickness dimension d is the landing height ZC2, and the position below the landing height ZC1 by the target height offset OFT1 is the target for lowering the component holding portion 31. becomes the target height Th1. Here, the height is set so as not to cause whiff even if the height of the assumed mounting position is the lowest. Note that the illustration of the target height is omitted for the second example EX2, and the illustration of the deceleration height is omitted for the third example EX3.

These height parameters are stored in the second storage unit 58 . Here, the target height Th and the deceleration height Dh are set for each operation of the nozzle unit 30 in the mounting head 11 . A "target height" 58a that is a target lowering height for lowering the component holding unit 31 in the component mounting operation, and a height that defines the timing for reducing the speed of lowering the component holding unit 31 from high speed to low speed. is updated and stored as "deceleration height" 58b. The thrust limit height TLh is also stored as a "thrust limit height" 58c.

The "standard operation pattern" 58d is an operation pattern of the mounting operation in component mounting by the mounting head 11 on the board 3 as the object. This operation pattern includes a deceleration height at which the speed at which the component holder 31 is lowered from a high speed to a low speed and a target height, which is a target lowering height of the component holder 31 .

The “target time” 58 e is a settling time during which the component holding unit 31 holding the component P descends and maintains the settling state while pressing the component P against the substrate 3 . In this embodiment, when the elapsed time measured by the landing detection unit 54 after the landing detection unit 54 detects the landing reaches the target time Ts stored as the "target time" 58e, the part holding unit 31 is detached from the part P and lifted.

The XY table 10 , the board transfer section 2 , the component supply section 5 , the touch panel 68 , the board recognition camera 16 , the component recognition camera 12 , the notification section 69 and the load detection section 45 are connected to the body control section 14 . The body control unit 14 includes a mounting work execution unit 60, a miss swing detection unit 61, a mounting position height measurement unit 62, a deceleration height calculation unit 63, a mounting data storage unit 64, and a part information storage unit 65 as internal processing function units. , mounting height storage unit 66 and thrust-load correlation data acquisition unit 67 .

Based on the mounting data (see FIG. 12B) stored in the mounting data storage unit 64, the mounting work executing unit 60 controls the XY table 10, the board transfer unit 2, the component supply unit 5, the mounting head 11, and the component recognition camera. 12. Control the board recognition camera 16; As a result, a series of operations (see the flow shown in FIG. 19) for mounting the component P on the board 3 are executed. The touch panel 68 is an operation input unit that displays an input operation and an operation screen at the time of the input operation, and performs an input operation required for executing the series of work described above. The notification unit 69 is notification means such as a signal tower or display screen that operates in a predetermined situation, and notifies when an abnormal state is detected in the component mounting operation by the mounting head 11 .

The load detector 45 is a detection unit having a function of detecting the load LF shown in FIG. As shown in FIG. 9, the load detector 45 has a load detector 45a such as a load cell on its upper surface. can be measured. The load detector 45 can be detachably connected to the body controller 14 via a connector device 45b. When load measurement is required, it is placed on the base 1a of the mounting head 11 as shown in FIG.

After the thrust limiter configured as described above limits the thrust of the servomotor 41, the miss-swing detection unit 61 detects that the thrust detected by the thrust force detector 52 does not reach the rising start timing determined by the operation pattern set in advance. It detects that the set thrust limit value TL has not been reached, in other words, that the component held by the component holding part 31 has not reached the upper surface of the substrate and the mounting operation has become "missing".

Then, when the miss-swing detection unit 61 detects a miss-swing, the notification unit 69 is operated to notify that effect. As described above, in this embodiment, it is possible to immediately detect "missing", which is highly likely to be a mounting defect, and to inform the user of the fact, thereby predicting the occurrence of defects and correcting the target height of the component. It is possible to respond quickly and stabilize quality.

The mounting position height measuring unit 62 measures the height of the component holding unit 31 detected by the position detecting unit 53 at a predetermined timing from when the component lands on the mounting position of the substrate 3 to immediately before the component holding unit 31 starts to rise. Based on the position in the height direction and the dimension of the component P mounted by the component holding portion 31, the mounting height indicating the height at the mounting position where the component P is mounted is measured. A plurality of measured mounting heights of the plurality of mounting completion positions are stored in the mounting height storage unit 66 .

The deceleration height calculation unit 63 utilizes at least one mounting height stored in the mounting height storage unit 66 to determine when the component is to be mounted at the non-mounting position, which is the mounting position to which the component has not yet been mounted. A deceleration height (see deceleration height Dh2 shown in FIG. 17(b)) is calculated. That is, in the present embodiment, based on the mounting height detected by the position detection unit 53 for the mounting completion position where mounting has already been performed on the same board 3, the deceleration height for the non-mounting position to be the work target thereafter is calculated. is corrected by calculation.

Here, an execution example of the deceleration height correction by the deceleration height calculation unit 63 will be described with reference to FIG. 18 . FIG. 18 shows correction target positions for deceleration height correction. In FIGS. 18A and 18B, a plurality of mounting positions MP1 to MP7 are set on the upper surface of the board 3 to mount components. Among these mounting positions, the mounting positions surrounded by rectangular frames indicate the mounting completed position, which is the mounting position where the component P is mounted.

In FIG. 18A, the mounting positions MP1, MP2, and MP3 are the mounting completed positions, and the mounting position MP4 is the non-mounting position to be subjected to the next mounting operation. For the mounting position MP4, which is the non-mounting position, when setting a new deceleration height by calculation in place of the already set deceleration height, a range ( Here, it is determined whether or not the mounting completion position exists within a circular range C having a radius R centered on the mounting position MP4.

Then, if there is an installation completion position, the deceleration height for the non-installation position (here, installation position MP4) is determined based on the installation height measured for that installation completion position (here, installation position MP2). Calculate. That is, in this case, the deceleration height calculation unit 63 calculates the deceleration height based on the mounting height of the mounting completion position existing within a preset range from the non-mounting position. The deceleration height calculator 63 calculates the mounting height of the mounting position MP4 from the mounting height of the mounting position MP2. As an example, if the mounting height of the mounting position MP2 is different from the initially assumed mounting height, it is assumed that the mounting height of the mounting position MP4 existing in the vicinity of it is also different. Calculate Z11 (see FIG. 17(b)). Then, the deceleration height calculation unit 63 calculates the deceleration height Dh2 at the mounting position MP4 using the mounting height Z11, the mounting thickness dimension d at the mounting position MP4, and the deceleration height offset OFD.

It is also possible to determine whether or not the deceleration height can be calculated on the condition that there are a predetermined number or more of mounting completed positions in the vicinity of the non-mounting position targeted for the mounting operation. In the example shown in FIG. 18B, the mounting positions MP1, MP2, MP3, MP4, and MP5 are the mounting completed positions, and the mounting position MP6 is the unmounted position to be subjected to the next mounting operation. For the mounting position MP6, which is the non-mounting position, when setting a new deceleration height by calculation in place of the already set deceleration height, a range ( Here, it is determined whether or not there are a preset number (here, 3) of mounting completion positions within a circular range C with a radius R centered on the mounting position MP6.

When there are a preset number or more of the mounting completion positions, the non-mounting position is determined based on the plurality of mounting heights measured for the plurality of mounting completion positions (here, mounting positions MP3, MP4, and MP5). A deceleration height is calculated for the position (here, mounting position MP6). That is, in this case, the deceleration height calculation unit 63 calculates the deceleration height of the unmounted positions based on the mounting heights of the predetermined number of mounting completed positions. In this calculation, for example, the mounting height Z11 of the mounting position MP6 is calculated from the average value of a plurality of mounting heights. Then, the deceleration height calculation unit 63 calculates the deceleration height Dh2 at the mounting position MP6 using the mounting height Z11, the mounting thickness dimension d at the mounting position MP6, and the deceleration height offset OFD.

The mounting data storage unit 64 stores the mounting data (see FIG. 12) such as mounting position coordinates and mounting position coordinates of the component P on the substrate 3 to be mounted by the component mounting apparatus 1 . The component information storage unit 65 stores component information indicating the model numbers and dimensions of the components P mounted on the board 3 . The mounting height storage unit 66 stores a plurality of mounting heights of a plurality of mounting completion positions measured by the mounting position height measuring unit 62 .

The thrust-load correlation data acquisition unit 67 performs processing for acquiring the thrust-load correlation data shown in FIG. That is, as shown in FIG. 9, the mounting head 11 is made to access the load detection unit 45 prepared at a predetermined position on the base 1a, and the servomotor 41 of the nozzle unit 30 to be measured is driven with a prescribed thrust. The component holding portion 31 is pressed against the load detector 45a of the load detection portion 45, and the load LF corresponding to the thrust at this time is measured. The measurement result is transmitted to the mounting head control section 13 as thrust-load correlation data and stored in the first storage section 57 as a correlation data storage section.

Thus, in this embodiment, the mounting head control section 13 is provided with the first storage section 57 as a correlation data storage section and the aforementioned thrust limiting section. Here, the first storage unit 57 stores correlation data indicating the relationship between the thrust force of the servomotor 41 and the load LF generated at the tip of the component holding unit 31 for each of the plurality of servomotors. The thrust limiter sets a thrust limit value TL for limiting the thrust generated by the servomotor 41 based on the correlation data stored in the first storage unit 57 and load information included in the command from the main body control unit 14. It has a function of limiting the thrust of the servomotor 41 to a thrust force limit value TL or less when the component holding portion 31 is lowered toward the substrate 3 . By having the mounting head control unit 13 having such a configuration, it is possible to control the mounting load stably with high accuracy in the configuration in which the servo motor 41 is provided for each of the plurality of component holding units 31 . .

Here, the thrust-load correlation data shown in FIG. 11 is created, and the parts are mounted on the substrate 3 by using the mounting head 11 having the servo motor 41 for moving up and down the component holder 31, thereby manufacturing the component mounting substrate. I will explain how. In this component mounting method, first, as shown in FIG. Next, the servomotor 41 is driven with a predetermined thrust to press the lower end of the component holding portion 31 (the nozzle 31a or a load measuring jig attached in place of the nozzle 31a) against the load detecting portion 45, and the servomotor 41 Measure the correlation data of the thrust T and the load LF (see FIG. 10). As a result, the characteristic line [L] shown in FIG. 11 is obtained, and the measured correlation data is stored in the first storage section 57, which is a correlation data storage section.

Next, using the limiting load LFL applied to the component by the component holding unit 31 when mounting the component P on the substrate 3 and the correlation data described above, a thrust limit value TL for limiting the thrust generated by the servomotor 41 is calculated. Calculate The limit load LFL is included in the control command transmitted from the body control section 14 to the mounting head control section 13 . When the component mounting operation is started, the component holder 31 holding the component P is lowered toward the mounting position of the board 3 .

In this lowering operation of the component holding portion 31, the thrust T of the servomotor 41 is limited to the thrust limit value TL or less before the component P lands on the mounting position. After the component P lands on the mounting position, the component holding part 31 is lifted and separated from the component P that has landed on the mounting position, thereby completing one component mounting operation in the component mounting method. By using such a method, the thrust limit value TL for limiting the thrust of the servomotor 41 according to the limit load LFL can be set in a simple manner.

Next, referring to FIG. 19, the component mounting process executed by the component mounting apparatus 1 having the above configuration will be described. Prior to the start of the process shown in FIG. 19, the substrate 3 to be worked is carried into the substrate transfer section 2, positioned and held, and substrate recognition by the substrate recognition camera 16 is executed. When the component mounting process is started, first, the mounting head 11 is moved to the component supply section 5, the component holding section 31 is lowered, and the component P to be mounted is held by the component holding section 31 (ST1). Next, the mounting head 11 holding the component P by the component holding unit 31 is moved above the component recognition camera 12, and the component P is imaged by the component recognition camera 12 for component recognition (ST2).

Next, the component holder 31 is moved to the mounting position (ST3). That is, the mounting work execution unit 60 of the main body control unit 14 controls the XY table 10 based on the mounting data 70 shown in FIG. positioned above the Next, the deceleration height Dh (see FIG. 13) in the component mounting operation targeting the mounting position is calculated (ST4). This deceleration height calculation is executed only when the mounting height of the mounting completion position in the vicinity of the mounting position has already been measured as described above. When the conditions for calculating the deceleration height described above are not satisfied, such as when a newly carried substrate 3 is to be processed, this process is skipped and the pre-stored default deceleration height is applied as it is. .

Next, a component mounting command is transmitted from the body control section 14 to the mounting head control section 13 (ST5). That is, a control command is sent to the mounting head control unit 13, including the mounting operation parameters such as the number specifying the component holding unit 31 in the mounting head 11 to be worked on, the target height Th, the deceleration height Dh, and the limit load LFL. do. These mounting operation parameters are stored in the first storage unit 57 and the second storage unit 58 for execution of the mounting operation in the mounting head 11 .

After that, the component mounting operation by the nozzle unit 30 of the mounting head 11 is executed by the control processing function of the mounting head control section 13 . In this component mounting operation, the servo motor 41 is driven by the servo motor control section 50 (ST6), thereby raising and lowering the component holding section 31 holding the component P with respect to the board 3 mounting position. After the substrate 3 has landed on the mounting position and a predetermined static time has passed, the component holding portion 31 is lifted to complete the component mounting operation (ST7).

With the completion of this operation, the thrust detection result detected by the thrust detection unit 52 of the servo motor control unit 50 in the component mounting operation and the mounting height of the component holding unit 31 when the component P detected by the position detection unit 53 is mounted are It is transmitted to the main body control section 14 (ST8). After that, it is determined whether or not a missed swing has occurred in the component mounting operation described above (ST9). That is, when the thrust detected by the thrust detection unit 52 does not reach the set thrust force limit value TL during the downward movement of the component holding unit 31, the component P held by the component holding unit 31 is removed from the substrate. The controller 69 notifies the player of this fact by the notification unit 69 and stops the apparatus (ST10).

If it is determined in (ST9) that no whiff has occurred, the mounting height of the component holding portion 31 received by the body control section 14 is stored in the mounting height storage section 66 (ST11). As a result, the component mounting operation for the component holding portion 31 of one nozzle unit 30 is completed, and then the presence or absence of the unfinished component holding portion 31 is checked (ST12). If there is a component holding unit 31 for which the work has not been completed, the process returns to (ST3) and repeats the subsequent processes. On the other hand, if there is no component holding portion 31 for which the work has not been completed, the completion of mounting of all components is confirmed (ST13). If the mounting has not been completed, the process returns to (ST1) and repeats the subsequent processes. Then, in (ST13), the completion of mounting of all the components is confirmed, and the component mounting processing by the component mounting apparatus 1 ends.

Next, a method of mounting a component by the component mounting apparatus 1 having the above configuration will be described with reference to FIGS. 14 to 17. FIG. A plurality of component mounting methods shown with reference to these drawings respectively control the servomotor 41 based on a preset operation pattern so that the component P held by the component holding portion 31 is mounted on the board 3. This is performed by the component mounting apparatus 1 having the control unit 15 that causes the component holding unit 31 to perform the up-and-down operation for mounting on the position. Each operation shown in this component mounting method is executed by controlling each unit shown in FIG. A mounting substrate 3* (see FIG. 12) is manufactured.

14 to 17 schematically show the vertical movement of the component holder 31 during the mounting operation of the component. there is 14 to 17, TR1 indicated by a thick dashed line indicates a set trajectory TR1 along which the lower end portion of the component holding portion 31 moves in a preset operation pattern. A thick solid line TR2 indicates an actual locus TR2 along which the lower end portion of the component holding portion 31 moves in the actual mounting operation shown in each figure.

In each figure, timing ta is the timing of starting the operation, and shows a state in which the component holding section 31 is moved above the mounting position of the substrate 3 to stand by at the stand-by height Z0. The thrust limit height TLh indicates a thrust limit start height for limiting the thrust of the servomotor 41 to the thrust limit value TL or less when the component holder 31 is lowered. The landing height ZC indicates the height of the component holding portion 31 when the terminal of the held component P contacts the solder portion supplied to the substrate 3 and the component P lands. The target height Th1 is the target height for the lowering operation of the component holding portion 31, and is set lower than the height at which the component P actually lands, taking into account variations in mounting height of the board 3. there is

First, with reference to FIG. 14, a basic embodiment M0 of a component mounting operation according to this component mounting method will be described. FIG. 14(a) shows a high-speed mounting mode M0-1 in which the component holder 31 is lowered only at high speed in order to shorten the work operation time in the basic embodiment M0. FIG. 14(b) shows a low-impact mounting mode M0-2 in which the impact when the part P held by the part holding portion 31 lands is minimized in the basic embodiment M0.

The high-speed mounting mode M0-1 will be described with reference to FIG. 14(a). The component holding part 31 holding the component P moves above the mounting position of the substrate 3, and is positioned at the standby height Z0 at the timing ta and is in the standby state. Next, a thrust limit value TL for limiting the thrust of the servomotor 41 is set by the function of the thrust limiter 56 provided in the servomotor control unit 50 . Here, when the servomotor 41 is driven with the same thrust force as the thrust limit value TL, the load acting on the component P from the component holding portion 31 is applied to the component holding portion 31 by the urging member 33 which is an elastic body. A thrust limit value TL is set within a range smaller than the biasing force FP.

Next, by controlling the servomotor 41 based on a preset operation pattern, the component holder 31 is lowered toward the mounting position of the board 3 by the target height Th1. During this descent, at the timing when the height of the component holding part 31 reaches the thrust limit height TLh, the thrust of the servo motor 41 is limited to the thrust limit value TL or less before the component P lands at the mounting position. .

The thrust limit value TL is set by the thrust limiter 56 provided in the servomotor control unit 50, the thrust of the servomotor 41 is limited at the timing when the thrust limit height TLh is reached during the descent of the component holding unit 31, Landing detection for detecting that the part P has landed on the board 3 is similarly applied to the first, second and third embodiments shown in FIGS.

After that, when the component holding portion 31 is further lowered, the component holding portion 31 reaches the landing height ZC, and the terminal of the held component P comes into contact with the solder portion supplied to the substrate 3, and the component P lands. Become. The impact at the time of landing is absorbed by the biasing member 33, and after absorbing the impact, the biasing member 33 returns to its normal length before landing. Thereafter, the component holding unit 31 maintains the pressed state for a target time Ts for stabilizing the landing state of the component P from the pressing start timing set in advance in the operation pattern. Then, at the rising start timing when the target time Ts expires, the component holding section 31 starts to rise, the component holding section 31 rises to the standby height Z0, and the mounting operation ends.

In the pressing state described above, since the thrust limit value TL is set within a range smaller than the biasing force FP before the component P lands on the mounting position, the servomotor 41 moves the component with a thrust smaller than the biasing force FP. Press P against the substrate 3 . Therefore, compared with the conventional method in which the component P is pressed against the substrate 3 by the elastic force of the biasing member 33 that is pushed in after landing and elastically deformed, it is possible to control the mounting load stably with high accuracy in a low load region. It has become.

In the low-impact mounting mode M0-2 shown in FIG. 14(b), unlike the high-speed mounting mode M0-1, the deceleration height Dh1 is set between the thrust limit height TLh and the landing height ZC. ing. That is, in the low-impact mounting mode M0-2, when the component holding portion 31 holding the component P reaches the deceleration height Dh1 in the process of descending from the standby height Z0, the descending speed is switched from high to low. As a result, the component holding portion 31 descends to the landing height ZC and the impact when the component P lands can be reduced.

In addition, in the process of the mounting operation described above, the thrust detection unit 52 of the servo motor control unit 50 detects the thrust of the servo motor 41 . As a result, after limiting the thrust of the servomotor 41, the miss-swing detection unit 61 of the servomotor control unit 50 detects that the detected thrust does not reach the thrust force limit value TL during the period up to the rising start timing determined by the operation pattern. can be detected. In this way, the fact that the thrust force after the thrust limit does not reach the thrust limit value TL means that there is a possibility that the component P held by the component holding portion 31 does not land on the substrate 3, causing a “missing” state. are doing. When such a state occurs, the body control unit 14 notifies the thrust of the servomotor 41 through the notification unit 69 that the thrust of the servomotor 41 has not reached the thrust limit value TL.

Next, referring to FIG. 15, a first embodiment M1 of a component mounting operation according to this component mounting method will be described. In the basic embodiment M0 shown in FIG. 13, the component holder 31 is lifted according to the lift timing determined by the predetermined operation pattern. On the other hand, in the first embodiment M1, the elapsed time after the part P held by the part holding portion 31 has landed is measured, and the rising timing of the part holding portion 31 is determined.

The technical significance of applying the first embodiment M1 will be described. That is, when the height of the mounting position varies due to deformation of the board, the landing height at which the component P contacts the solder portion of the board also varies. In such a case, the timing at which the part P lands on the ground during the mounting operation is not constant. For this reason, it is difficult to properly secure the time for pressing the component P against the solder portion, and it is difficult to secure proper solder joint quality. In particular, if the pressing time is too long, problems such as bridges connecting solder between adjacent lands and solder balls in which particles of solder are separated may occur. Even if the height of the mounting position varies in this way, by applying the first example M1 shown in the present embodiment, it is possible to properly secure the time for pressing the component P against the solder portion. can be done.

FIG. 15(a) shows a high-speed mounting mode M1-1 in which the component holder 31 is lowered only at high speed in order to shorten the work operation time in the first embodiment M1. FIG. 15(b) shows a low-impact mounting mode M1-2 in which the impact when the part P held by the part holding portion 31 lands is minimized in the first embodiment M1.

The high-speed mounting mode M1-1 will be described with reference to FIG. 15(a). The component holding part 31 holding the component P moves above the mounting position of the substrate 3, and is positioned at the standby height Z0 at the timing ta and is in the standby state. Next, by controlling the servomotor 41 based on a preset operation pattern, the component holder 31 is lowered toward the mounting position of the board 3 by the target height Th1.

Prior to this descent, a thrust limit value TL for limiting the thrust of the servomotor 41 is set as in the basic embodiment M0 shown in FIG. In the middle of the descent of the component holding portion 31, the thrust of the servomotor 41 is limited to the thrust limit value TL or less before the component P lands at the mounting position, as in the basic embodiment M0 shown in FIG. By this thrust limitation, the same effect as described in the basic embodiment M0 shown in FIG. 14 is obtained.

After that, when the component holding portion 31 is further lowered, the component holding portion 31 reaches the landing height ZC. As a result, the terminal of the held component P comes into contact with the solder portion supplied to the board 3 and the component P lands on the board 3 . This landing is detected by the function of the landing detection section 54 provided in the servomotor control section 50 by one of the following methods.

One method is to monitor the thrust of the servomotor 41 by the thrust detector 52 in the servomotor controller 50 . That is, it detects that the part P has landed on the substrate 3 when the thrust of the servo motor 41, which is being limited to the thrust limit value TL or less, reaches the set thrust limit value TL. Another method of landing detection is a method using a position signal from the servomotor 41 . That is, when the encoder pulse output from the encoder 44 of the servomotor 41 is stagnant, it is detected that the component has landed on the substrate 3 .

When the landing of the part P is detected by any of the above-described methods, the timer 55 measures the elapsed time from the timing t1 when the landing is detected. Then, when the elapsed time measured by the timer 55 reaches the target time Ts before the rising start timing determined by the operation pattern indicated by the set locus TR1, the servomotor 41 is controlled at this timing t2 to move the component holding portion. Raise 31.

As a result, even when the substrate 3 whose landing height ZC varies due to deformation or the like is used, the component P can always be pressed against the solder portion in an appropriate target time Ts, and the variation in the pressing time can be minimized. It is possible to prevent the resulting solder joint failure. Furthermore, it is possible to prevent the delay of the mounting operation time due to the pressing time being unnecessarily long, thereby improving the productivity.

In the low-impact mounting mode M1-2 shown in FIG. 15(b), unlike the high-speed mounting mode M1-1, the deceleration height Dh1 is set between the thrust limit height TLh and the landing height ZC. ing. That is, in the low-impact mounting mode M1-2, when the component holding portion 31 holding the component P reaches the deceleration height Dh1 in the process of descending from the standby height Z0, the descending speed is switched from high to low. As a result, the component holding portion 31 descends to the landing height ZC and the impact when the component P lands can be reduced.

Next, with reference to FIG. 16, a second embodiment M2 of the component mounting operation according to this component mounting method will be described. In the second embodiment M2, the mounting position height measuring unit 62 measures the mounting height at the mounting position during the mounting operation of landing and mounting the component P held by the component holding unit 31. In this way, by measuring the mounting height at the mounting position during the mounting operation, board height information can be obtained by a simple method without performing a separate measurement operation for measuring the board height. .

FIG. 16(a) shows a high-speed mounting mode M2-1 in which the component holder 31 is lowered only at high speed in order to shorten the work operation time in the second embodiment M2. FIG. 16(b) shows a low-impact mounting mode M2-2 in which the impact when the component P held by the component holding portion 31 lands is minimized in the second embodiment M2.

The high-speed mounting mode M2-1 will be described with reference to FIG. 16(a). The component holding portion 31 holding the component P moves above the mounting position of the substrate 3 and is positioned at the standby height Z0 at the timing ta and is in the standby state. Next, by controlling the servomotor 41 based on a preset operation pattern, the component holder 31 is lowered toward the mounting position of the board 3 by the target height Th1.

Prior to this descent, a thrust limit value TL for limiting the thrust of the servomotor 41 is set as in the basic embodiment M0 shown in FIG. In the middle of the descent of the component holding portion 31, the thrust of the servomotor 41 is limited to the thrust limit value TL or less before the component P lands at the mounting position, as in the basic embodiment M0 shown in FIG. By this thrust limitation, the same effect as described in the basic embodiment M0 shown in FIG. 14 is obtained.

After that, when the component holding portion 31 is further lowered, the component holding portion 31 reaches the landing height ZC. As a result, the terminal of the held component P comes into contact with the solder portion supplied to the board 3 and the component P lands on the board 3 . This landing is detected by the function of the landing detection section 54 provided in the servo motor control section 50, and the elapsed time from the timing t1 at which the landing is detected is measured by the timing function of the timer 55. FIG. Then, when the elapsed time measured by the timer 55 reaches the target time Ts before the rising start timing determined by the operation pattern indicated by the set locus TR1, the servomotor 41 is controlled at this timing t2 to move the component holding portion. Raise 31.

That is, in the mounting operation described above, after the component P has landed on the mounting position of the board 3 , the component holding portion 31 is lifted to separate the component holding portion 31 from the component P that has landed on the mounting position of the board 3 . Then, the thrust of the servomotor 41 is limited at least during the period from when the component P lands on the mounting position of the board 3 until before the component holding portion 31 starts to rise. The pressing by the component holding portion 31 for mounting the component P is performed in a state where the thrust of the servomotor 41 is limited.

In the second example M2 shown in this embodiment, the mounting height is detected during the mounting operation described above. That is, at a predetermined timing from when the component P lands on the mounting position of the board 3 to immediately before the component holding portion 31 starts to rise, the mounting position height measuring portion 62 detects the position of the component holding portion 31 from the position detecting portion 53 . Get information. The position information of the component holding portion 31 acquired at this timing is the landing height ZC indicating the position of the component holding portion 31 in the height direction in FIG. Then, the mounting position height measuring unit 62 calculates the mounting height of the mounting position where the component P is mounted based on the acquired position information and the dimension of the mounted component P. That is, the mounting position height measuring section 62 obtains the mounting height Z1 based on the landing height ZC and the mounting thickness dimension d including the thickness of the component P of the component P. FIG.

The timing at which the mounting position height measuring unit 62 acquires the position information of the component holding unit 31 from the position detecting unit 53 is determined by the biasing member 33, which is an elastic body, absorbing the impact when the component P lands on the mounting position. After that, it is within a period until just before the component holding portion 31 starts to rise, and the time immediately before the start of the rise is most preferable. Since this positional information is acquired in the fully extended state of the biasing member 33 for cushioning, even if the biasing member 33 for cushioning is provided, the positional information of the position detection unit 53 is The height detection of the component holding portion 31 can be performed with high accuracy.

Further, since the load LF with which the component holding portion 31 presses the board 3 is a low load, the board 3 is hardly deformed. Therefore, even if the height of the mounting position is measured using the height position of the component holding portion 31, there is little error, and accurate height measurement can be performed. Accordingly, board height information including the height of the mounting position can be obtained by a simple method in parallel with execution of the component mounting operation without using a dedicated measuring device.

In the low-impact mounting mode M2-2 shown in FIG. 16(b), unlike the high-speed mounting mode M2-1, the deceleration height Dh1 is set between the thrust limit height TLh and the landing height ZC. ing. That is, in the low-impact mounting mode M2-2, when the component holding portion 31 holding the component P reaches the deceleration height Dh1 in the process of descending from the standby height Z0, the descending speed is switched from high to low. As a result, the component holding portion 31 descends to the landing height ZC and the impact when the component P lands can be reduced.

Next, with reference to FIG. 17, a third embodiment M3 of the component mounting operation according to this component mounting method will be described. In the third embodiment M3, during the mounting operation of landing and mounting the component P held by the component holding portion 31, the mounting height at the mounting completion position where the component is mounted is detected, and the detected mounting height is is used to calculate and correct the deceleration height when a part is mounted on the non-mounted position.

FIG. 17(a) shows a pre-correction mounting mode M3-1 in which the component mounting operation is performed in the state where the mounting completion position does not yet exist and the deceleration height is not corrected in the third embodiment M3. . FIG. 17B shows a post-correction mounting mode in which the mounting height at the mounting completion position is detected in the third embodiment M3, and components are mounted after correcting the deceleration height based on the detected mounting height. M3-2 is shown.

The pre-correction mounting mode M3-1 will be described with reference to FIG. 17(a). The component holding portion 31 holding the component P moves above the mounting position of the substrate 3 and is positioned at the standby height Z0 at the timing ta and is in the standby state. Next, by controlling the servomotor 41 based on a preset operation pattern, the component holder 31 is lowered toward the mounting position of the board 3 by the target height Th1. Here, the operation pattern includes a deceleration height Dh1 for reducing the speed of lowering the component holder 31 and a target height Th1 for the component holder 31 . The component holding portion 31 is lowered at a high speed up to the deceleration height Dh1 and at a low speed from the deceleration height Dh1. In the pre-correction mounting mode M3-1, the deceleration height Dh1 is set to a height Δh1 from the target height Th1.

Prior to this descent, a thrust limit value TL for limiting the thrust of the servomotor 41 is set as in the basic embodiment M0 shown in FIG. In the middle of the descent of the component holding portion 31, the thrust of the servomotor 41 is limited to the thrust limit value TL or less before the component P lands at the mounting position, as in the basic embodiment M0 shown in FIG. By this thrust limitation, the same effect as described in the basic embodiment M0 shown in FIG. 14 is obtained.

After that, when the component holding portion 31 is further lowered, the component holding portion 31 reaches the landing height ZC. As a result, the terminal of the held component P comes into contact with the solder portion supplied to the board 3 and the component P lands on the board 3 . This landing is detected by the function of the landing detection section 54 provided in the servo motor control section 50, and the elapsed time from the timing t1 at which the landing is detected is measured by the timing function of the timer 55. FIG. Then, when the elapsed time measured by the timer 55 reaches the target time Ts before the rising start timing determined by the operation pattern indicated by the set locus TR1, the servomotor 41 is controlled at this timing t2 to move the component holding portion. 31 is raised to separate the component holding portion 31 from the component P that has landed on the mounting position. Then, one mounting operation is completed at the timing tb when the component holding portion 31 rises to the standby height Z0. In the pre-correction mounting mode M3-1, one mounting operation requires working time WT1 from timing ta to timing tb.

In order to shorten this work time WT1 as much as possible and improve productivity, in the third embodiment M3 shown in this embodiment, detection of the mounting height for the purpose of correcting the deceleration height during the mounting operation described above is performed. I do. That is, at a predetermined timing from when the component P lands on the mounting position of the board 3 to immediately before the component holding portion 31 starts to rise, the mounting position height measuring portion 62 detects the position of the component holding portion 31 from the position detecting portion 53 . Acquire information (landing height ZC).

Then, based on the obtained landing height ZC and the dimension of the mounted component P, a mounting height measurement process for calculating the mounting height indicating the height at the mounting position where the component P is mounted, which is the mounting position. to run. This mounting height measurement process is executed by the mounting position height measurement section 62 of the main body control section 14 . That is, the mounting height Z1 is obtained based on the landing height ZC indicating the position of the component holding portion 31 in the height direction in FIG. 13 and the mounting thickness dimension d of the component P including the thickness of the component P.

Similar mounting height measurement processing is performed for a plurality of mounting completion positions, and the plurality of mounting heights are stored in the mounting height storage unit 66 of the main body control unit 14 . Next, by using at least one mounting height stored in the mounting height storage unit 66, the deceleration height for mounting the component at the non-mounting position, which is the mounting position where the component has not yet been mounted, is calculated. . This arithmetic processing is executed by the deceleration height arithmetic section 63 of the main body control section 14 .

This calculation processing of the deceleration height is shown as an execution example of the deceleration height correction by the deceleration height calculation unit 63 described with reference to FIG. That is, in the example shown in FIG. 18A, the deceleration height calculation unit 63 calculates the deceleration height based on the mounting height of the mounting completion position existing within a preset range from the non-mounting position. In the example shown in FIG. 18(b), the deceleration height calculation unit 63 calculates the deceleration height of the unmounted position based on the mounting heights of the predetermined number of mounting completed positions. As a result, instead of the uncorrected deceleration height Dh1, the post-correction deceleration height Dh2 calculated based on the mounting height at the mounting completion position is obtained.

FIG. 17(b) shows a post-correction mounting mode M3-2 in which the component P is mounted at the non-mounting position based on the post-correction deceleration height Dh1-1 thus calculated. In the example shown here, the corrected deceleration height Dh2 is set to a height Δh2 from the target height Th1. Since Δh2 is set based on the mounting height of the known mounting completion position, it can be set to an appropriate value smaller than Δh1.

Therefore, the corrected deceleration height Dh2 can be set to a height closer to the landing height ZC, and a delay in the descent time due to deceleration from an unnecessarily high position can be prevented. As a result, in the pre-correction mounting mode M3-1, the work time WT1 is required from the timing ta to the timing tb for one mounting operation, whereas in the post-correction mounting mode M3-2, the work time WT1 is required from the timing ta to the timing tb. The required time to tb is shortened to work time WT2, which is shorter than WT1. Even in the case of substrates with varying warpage deformation states, the productivity can be improved by appropriately setting the deceleration height based on the mounting height at the mounting completion position. .

In this embodiment, the mounting thickness dimension d used in the calculation of the mounting height Z1 by the mounting position height measuring unit 62 and in the calculation of the deceleration height Dh2 by the deceleration height calculation unit 63 is the thickness of the part P. , the thickness of the land 3c and the thickness of the solder S for bonding are added. d may be used. If both the thickness of the land 3c and the thickness of the joining solder S are ignored, the thickness of the component P may be used as the mounting thickness dimension d. In other words, the mounting thickness dimension d includes at least the thickness of the part P.

INDUSTRIAL APPLICABILITY The component mounting apparatus of the present invention has the effect of being able to stably control the mounting load in a low load region with high accuracy, and is useful in the field of mounting components at mounting positions on substrates.

1 component mounting device 3 substrate 3* component mounting substrate 11 mounting head 15 control unit 30 nozzle unit 31 component holding unit 31d suction hole 32 lower portion 33 biasing member 35 shaft 36 upper portion 41 servo motor 44 encoder 45 load detection unit 51 motor driver ( drive controller)
52 Thrust detection unit 54 Landing detection unit 56 Thrust limiter 57 First storage unit (storage unit)
61 Missing detection unit 69 Notification unit P Parts T Thrust LF Load FP Biasing force TLh Thrust limit height Z0 Standby height ZC, ZC1 Landing height Dh, Dh1, Dh2 Deceleration height Th, Th1 Target height

Claims (6)

A component mounting apparatus for mounting components on a substrate,
a component holding unit that holds the component by negative pressure;
a shaft on which the component holding portion is mounted in a state in which it can be displaced in the vertical direction and in a state in which it is urged downward by an elastic body;
a servomotor for causing the component holder to move up and down by moving the shaft up and down;
By controlling the servomotor based on a preset operation pattern, the component held by the component holding section is landed on the board mounting position, and after the component holding section presses the component against the board, the a control unit that raises the component holding unit and mounts the component at the mounting position;
The control unit controls the servomotor so that the load when the component holding unit presses the component against the substrate is smaller than the force that urges the component holding unit toward the shaft by the elastic body. on-board equipment. The control unit includes a drive control device that drives the servomotor, a storage unit that stores thrust-load correlation data that is a correlation between the thrust generated by the servomotor and the load, and a component that presses the component against the substrate. thrust limit for limiting the thrust force generated by the servomotor to a range smaller than the force urging the part holding portion against the shaft by the elastic body based on the limit load and the thrust-load correlation data when and a thrust limiter for setting a value to the drive control device, wherein the drive control device limits the thrust of the servomotor based on the thrust limit value when the thrust limit value is set by the thrust limiter. The component mounting apparatus according to claim 1, wherein The thrust limiter sets the thrust limit value to the drive control device before the component lands at the mounting position while the component holding unit holding the component is lowered toward the mounting position. 3. The component mounting apparatus according to claim 2. The control unit includes a thrust detection unit that detects the thrust of the servomotor, and if the thrust detection unit detects that the thrust of the servomotor has reached the thrust limit value while the thrust is being limited by the thrust limiter, 3. The component mounting apparatus according to claim 2, further comprising: a landing detection section for detecting that the component has landed on the mounting position. The control unit includes a thrust detection unit that detects the thrust of the servomotor, and the thrust detection unit during a period from when the thrust of the servomotor is limited by the thrust limiter to the rise start timing determined by the operation pattern. 3. The component mounting apparatus according to claim 2, further comprising a whiff detection section for detecting that the thrust detected in 1 does not reach the thrust limit value. 6. The component mounting apparatus according to claim 5, wherein said control unit has a notification unit for notifying that said whiff detection unit has detected a whiff.

Images