JP6746465B2 - Surface mounter - Google Patents

Description

The present invention relates to an apparatus for mounting electronic components on a board.

There is known a surface mounter that holds an electronic component supplied by a feeder with a holding head and mounts the electronic component on a substrate. Japanese Patent Application Laid-Open No. 2004-242242 discloses that the feeding time of a component by a feeder is measured and the holding head is lowered based on the measured feeding time.

JP, 2005-146336, A

In the above configuration, the feeding time of the component by the feeder is measured, and the holding head is lowered accordingly. Therefore, the timing when the feeder completes the feeding operation of the component and the timing when the holding head completes the lowering operation are accurate. You can match well. However, the feeding time of the feeder is not always constant during production, and differs, for example, when the number of remaining electronic components stored in the component supply tape is large and when it is small. Therefore, in order to accurately match the two timings, it is necessary to dynamically change the feed time of the electronic component during production, which leaves room for improvement.

The present invention has been completed based on the above circumstances, and an object thereof is to accurately match the timing at which the feeder completes the component feeding operation with the timing at which the holding head completes the lowering operation. To do.

The present invention is a surface mounter for mounting an electronic component on a substrate, a feeder for intermittently delivering the electronic component to a component supply position, and a head unit for supporting a holding head that holds the electronic component so that the holding head can be moved up and down. An elevation unit that raises and lowers the holding head with respect to the head unit; a drive unit that moves the head unit on a base; and a control unit that controls the movement of the head unit and the holding head. The controller controls the lowering operation of the holding head based on the feeding time of the electronic component by the feeder so that the end timing of the feeding operation of the electronic component by the feeder and the end timing of the lowering operation of the holding head coincide with each other. While controlling, the feeder has a measuring unit for measuring the feeding time of the electronic component, the control unit measures the data of the feeding time of the electronic component by the feeder by the measuring unit during the production of the substrate. Update based on the measured value. It should be noted that “during board production” means a period during which electronic parts are mounted on the board. With this configuration, since the accurate feeding time can be grasped, it is possible to accurately match the timing when the feeder completes the feeding operation of the electronic component and the timing when the holding head completes the lowering operation.

As one embodiment of the present invention, the control unit is configured to feed the electronic component by the feeder, and based on a descent time required for the holding head to descend from an initial height to a height of the electronic component, the feeder. The lowering start timing of the holding head is determined so that the end timing of the feeding operation of the electronic component and the end timing of the lowering operation of the holding head coincide with each other. In this configuration, by adjusting the lowering start timing of the holding head, it is possible to match the end timing of the feeding operation of the electronic component by the feeder with the end timing of the lowering operation of the holding head.

As one embodiment of the present invention, the control unit controls the holding time based on a first time obtained by subtracting a descent time of the holding head from a moving time for the head unit to move onto the feeder, and a feeding time of the feeder. Timing when the longer time of the first time and the second time elapses from the time when the movement of the head unit and the feeding of the feeder are started by comparing the second time after subtracting the head descent time Then, it is preferable to start the lowering of the holding head. With this configuration, the following effects can be obtained. When the first time is long, it is possible to suppress the holding head from interfering with the surroundings by starting the lowering of the holding head at the timing when the first time has elapsed. Further, when the second time is long, the holding head is started to descend at the timing when the second time has elapsed, so that a mistake in holding the electronic component by the holding head can be suppressed.

As one embodiment of the present invention, the measuring unit performs the measurement of the feeding time a plurality of times during the production of the substrate, and the control unit sets the feeding time data of the feeder to the measured feeding time. Of these, it is preferable to update to the worst value. With this configuration, a more accurate feed time can be grasped based on a plurality of measured values. Further, by updating the feeding time to the worst value, it is possible to more reliably suppress the mistake in holding the electronic component by the holding head.

As one embodiment of the present invention, the control unit notifies the abnormality of the feeder to the outside when the measurement value by the measurement unit is abnormal.

An object of the present invention is to accurately match the timing at which the feeder completes the component feeding operation with the timing at which the holding head completes the lowering operation.

Front view of a surface mounter applied to an embodiment of the present invention Plan view of surface mounter, Partially enlarged view showing the support structure of the head unit Perspective view of parts supply tape Front view of feeder Partially enlarged perspective view showing the front end of the feeder Diagram showing the feeder installed in the parts supply section Block diagram showing electrical configuration of surface mounter The figure which shows the data constitution of memory section Side view showing the lowering operation of the suction head The top view which shows the movement operation of a head unit. Diagram showing the relationship between XY movement time, feed time, and descent time Flowchart diagram showing the flow of electronic component suction processing Flowchart diagram showing the flow of update processing of the sending time A graph showing an approximate curve Lt of the feed time T2

An embodiment of the present invention will be described with reference to FIGS.
1. Overall Configuration of Surface Mounter Main Body FIG. 1 is a front view of the surface mounter, FIG. 2 is a plan view of the surface mounter, and FIG. 3 is a partially enlarged view showing a support structure of a head unit. As shown in FIGS. 1 and 2, the surface mounter 10 includes a surface mounter main body 10A that performs a mounting process of electronic components, and a plurality of feeders 100 that supply electronic components.

The surface mounter main body 10A includes a base 11 having a flat plate shape, a transfer conveyor 20, a head drive device 30, and a head unit 60. The transport conveyor 20 is arranged in the center of the base 11 and extends in the X direction (the left-right direction in FIG. 2). A work position (a position indicated by a chain double-dashed line in FIG. 2) is set at the center of the base 11 and on the path of the conveyor 20.

The conveyor 20 carries a printed circuit board (an example of the board of the present invention) P from the right side of FIG. 2, which is the entrance side of the surface mounter 10, to a work position, and temporarily stops the conveyance of the printed circuit board P at that position. .. Then, the component W is mounted on the printed circuit board P stopped at the working position by the head unit 60, and when the mounting of the electronic component W is completed, the transport conveyor 20 starts transporting again. As a result, the substrate P is transported to the left side in FIG. 2, which is the exit side of the surface mounting machine 10, and is eventually carried out of the machine. In this specification, producing a board means producing a mounting board in which electronic components are mounted on a printed board.

The head drive device 30 roughly includes a pair of support legs 41, a head support 51, a Y-axis ball screw 45, a Y-axis motor 47, an X-axis ball screw 55, and an X-axis motor 57. More specifically, as shown in FIG. 2, a pair of piers 41 are installed on the base 11. Both piers 41 are located on both sides of the component supply unit 15 described later, and both extend straight in the Y-axis direction (vertical direction in FIG. 2). Guide rails 42 are installed on the upper surfaces of the two piers 41. Both guide rails 42 provided on the left and right piers 41 extend in parallel to the Y-axis direction.

As shown in FIG. 3, both piers 41 support a head support 51. The head support 51 has a horizontally long shape extending in the X-axis direction (the left-right direction in FIG. 3), and both ends in the longitudinal direction are fitted to the left and right guide rails 42, respectively.

A Y-axis ball screw 45 extending along the Y-axis is attached to the right pier body 41 in FIG. 2, and a ball nut (not shown) is screwed onto the Y-axis ball screw 45. The Y-axis ball screw 45 and the ball nut constitute a Y-axis servo mechanism together with the Y-axis motor 47 which is a drive source. That is, when the Y-axis motor 47 is energized, the ball nut advances and retreats along the Y-axis ball screw 45. As a result, the head support 51 fixed to the ball nut, and thus the head unit 60 described below, is moved along the guide rail 42. Can be moved horizontally in the Y-axis direction.

As shown in FIG. 3, the head support 51 is provided with a rod-shaped guide member 53 extending in the X-axis direction, and the head unit 60 is movable relative to the guide member 53 along the axis of the guide member 53. Is attached to. An X-axis ball screw 55 extending along the X-axis is mounted on the head support 51, and a ball nut is screwed onto the X-axis ball screw 55.

The X-axis ball screw 55 and the ball nut form an X-axis servo mechanism together with the X-axis motor 57 as a drive source. That is, when the X-axis motor 57 is energized, the ball nut moves back and forth along the X-axis ball screw 55, and as a result, the head unit 60 fixed to the ball nut can be moved along the guide member 53 in the X-axis direction. I can.

Thus, the head unit 60 can be freely driven (moved) in the horizontal direction (X-Y direction) on the base 11 by compositely controlling the X-axis servo mechanism and the Y-axis servo mechanism. The X-axis motor 57 and the Y-axis motor 47 correspond to the "driving unit" of the present invention.

The head unit 60 is equipped with a suction head 63 that executes a mounting operation for mounting the electronic component W on the printed circuit board P. The suction head 63 projects downward from the lower surface of the head unit 60, and a suction nozzle 64 is provided at the tip. In this embodiment, eight suction heads 63 are mounted on the head unit 60 in a line. Further, the head unit 60 is equipped with a Z-axis motor 67 and an R-axis motor (not shown) corresponding to each suction head 63. Note that FIG. 3 shows a part of the plurality of Z-axis motors 67 provided corresponding to each suction head 63. The Z-axis motor 67 corresponds to the "elevating section" of the present invention.

Each suction head 63 is configured to be movable up and down in the Z-axis direction (vertical direction, height direction) with respect to the frame 61 of the head unit 60 by driving the Z-axis motor 67 (Z-axis servo mechanism). In addition, the rotation operation around the axis is possible by driving the R-axis motor. Further, each suction nozzle 64 is configured to be supplied with a negative pressure from a negative pressure means (not shown) so as to generate a suction force at the tip of the head.

With such a configuration, the electronic head W can be taken out by the suction head 63 and the electronic parts W can be mounted on the printed circuit board P. That is, by operating the X-axis servo mechanism and the Y-axis servo mechanism described above, the suction head 63 of the head unit 60 is horizontally moved to above the component supply position O described later, and the Z-axis servo mechanism is further activated. The suction head 63 is lowered from the rising end position L0.

Then, the suction head 63 supplies a negative pressure from a negative pressure means (not shown) at the timing when the suction head 63 descends to the component suction height L1 (the height at which the nozzle tip is the component upper surface) on the component supply position O. Thus, the suction head 63 can suck and hold the electronic component W supplied to the component supply position O by the feeder 100 described later. Then, following the suction operation, this time the Z-axis servo mechanism raises the suction head 63 to take out the component W from the component supply position O (component take-out operation). After the parts are taken out, the suction head 63 moves up to the rising end position L0, which is the initial height, and stops at that position.

Further, after the electronic component W is taken out, the X-axis servo mechanism and the Y-axis servo mechanism are operated to horizontally move the taken-out electronic component W to the component mounting position on the printed circuit board P by the suction head 63. While the Z-axis servo mechanism is driven to lower the suction head 63 from the ascending end position L0, the negative pressure supply from the negative pressure means (not shown) is stopped at the timing of the suction head 63. The component W can be mounted (component mounting operation).

Further, in the present embodiment, the component supply units 15 are provided at four locations on the base 11. The arrangement of the component supply unit 15 is as shown in FIG. 2, and two parts are provided on each of the upper side and the lower side of the work position. In each of these component supply units 15, a plurality of feeders 100 described below are arranged side by side in the X direction.

Reference numeral 17 shown in FIG. 2 is a component recognition camera. Two component recognition cameras 17 are installed on the base 11 substantially at the center in the X direction with the work position interposed therebetween. The component recognition camera 17 has a function of capturing a component image sucked by the suction head 63. The obtained component image is subjected to image analysis in an image processing unit 216, which will be described later, so that the suction position shift of the component W by the suction head 63 is detected.

2. Parts supply tape and parts supply device (hereinafter simply referred to as feeder)
FIG. 4 is a perspective view of the component supply tape, and FIG. 5 is a front view of the feeder. The component supply tape 70 includes a carrier tape 71 and a cover tape 73 attached to the carrier tape 71. The carrier tape 71 has hollow component storage portions 71a that open upward at regular intervals (feed pitch Lp), and each component storage portion 71a stores an electronic component W such as an IC.

Further, on one side of the carrier tape 71, engaging holes 71b are formed at regular intervals so as to penetrate vertically along the edge of the carrier tape 71. The component supply tape 70 is wound around and supported by a reel (not shown) at a rear position (on the left side in FIG. 5) of the feeder 100 described below.

The structure of the feeder 100 is as shown in FIG. 5, and comprises a feeding device 110, a take-up device 120, a main body 101 to which these devices are fixed, and the like.

The main body 101 has a long front and rear shape, and a container 140 made of a resin material is installed at the rear end. A passage 105 for passing the component supply tape 70 is provided in the main body 101 and the container 140. The passage 105 extends straight and horizontally from the lower rear end of the container 140 toward the front (right side in FIG. 5). Then, it is connected to the main body 101, and then goes to the upper part of the main body 101 by taking a path extending obliquely upward to the right in FIG. 5, and faces the upper surface of the main body 101 at the front part.

A delivery device 110 described below is arranged on the front side (right side in FIG. 5) of the main body 101 with the passage 105 as a boundary, and the take-up device 120 is provided on the opposite side (left side in FIG. 5) with the passage 105 as a boundary. It is provided.

The delivery device 110 includes a delivery motor 112, a plurality of gears 113, 114, 115A, and a sprocket 115 that is integrally provided with the gear 115A, and is installed on the front side of the device. Then, the engagement holes 71b of the carrier tape 71 are engaged with the teeth of the sprocket 115.

The take-up device 120 has a function of pulling the cover tape backward, and includes a take-up motor 122, a plurality of gears 123 and 124A, and a take-up roller 124 and a pinch roller 125 that are integrally provided with the gear 124A.

Reference numeral 130 shown in FIG. 6 is a tape holder. The tape holder 130 guides both sides of the component supply tape 70 to guide the conveyance of the tape, and presses the upper surface of the component supply tape 70 to maintain the engagement between the carrier tape 71 and the sprocket 115.

A slit 131 is formed in the tape holder 130 at a position slightly near the center of the tape holder 130. The slit 131 has a function of folding the cover tape 73 backward and separating it from the carrier tape 71.

Reference numeral 150 shown in FIG. 5 is a control box. The control box 150 accommodates a feeder control board 160 (on which a feeder control unit 251 described later is mounted) that controls and controls the entire feeder 100, and a connector 155 is arranged in front of the box 150.

The feeder 100 described above includes the locking device 170, and by operating the locking device 170, the feeder 100 can be fixed in a positioned state to the mounting portion 15a provided in the component supply unit 15 as shown in FIG. it can. In the fixed state, power supply and various control signals are transmitted from the mounting machine body 10A side through the connector 155.

When the feed motor 112 is driven to operate the feeder 100 configured as described above, the power of the feed motor 112 is transmitted to the sprocket 115 via the gears 113, 114, 115A.

As a result, the sprocket 115 rotates in the direction of the arrow A shown in FIG. 5 while pulling the locked carrier tape 71 horizontally, so that the component supply tape is directed toward the component supply position O at the front of the apparatus (the zenith portion of the sprocket 115). 70 is sent out. Then, the electronic component W can be sequentially supplied to the component supply position O by feeding the component supply tape by one pitch Lp.

3. Electric Configuration of Surface Mounter Main Body 10A and Feeder 100 As shown in FIG. 8, the controller 210 controls the entire surface mounter main body 10A. The controller 210 includes an arithmetic processing unit 211 including a CPU and the like, and also includes a storage unit 213, a motor control unit 215, an image processing unit 216, a first timer 217A, a second timer 217B, and an input/output unit 218. .. The arithmetic processing unit 211 is an example of the “control unit” in the present invention.

The arithmetic control unit 211 controls the position of the head unit 60 in the X-axis direction and the Y-axis direction by controlling the X-axis motor 57 and the Y-axis motor 47 via the motor control unit 211. Further, by controlling the Z-axis motor 57 and the R-axis motor, the position control of each suction head mounted on the head unit 60 in the Z-axis direction and the position control in the R-axis direction are performed. As shown in FIG. 9, the storage unit 213 stores a mounting program, data such as the feeding time T2 of the feeder 100, and the like. The mounting program is a control program for mounting the electronic component W on the printed circuit board P. Further, the storage unit 213 stores the data of the electronic component W mounted on the printed board P, the data of the feeder 100 that supplies the data, and the data of each suction head 63 mounted on the head unit 60. The data of the electronic component W includes data on the shape of the electronic component W such as the height, and the data of the feeder 100 includes the data of the mounting position of the feeder 100 on the base and the position of the component supply position O. Is included. Further, the data of the suction head 63 includes the pitch of the suction head 63 and the data of the rising end position L0 with the upper surface of the printed circuit board P as a reference.

Various motors are electrically connected to the motor control unit 215. The motor controller 215 drives various motors in response to a command from the arithmetic processing unit 211. Further, the component recognition camera 17 is electrically connected to the image processing unit 216, and the image pickup signals output from the camera 17 are respectively captured. Then, in the image processing unit 216, the component image analysis and the board image analysis are performed based on the captured image pickup signal.

The input/output unit 218 is a so-called interface and is configured to receive detection signals output from various sensors provided in the mounting machine body 10A.

The feeder 100 has a feeder control unit 251, a delivery motor 112, a take-up motor 122, a rotary encoder 253, and an input/output unit 258. The feeder control unit 251 controls the feeding motor 112 and the take-up motor 122. The rotary encoder 253 outputs a pulse signal according to the rotation state of the delivery motor 112, and detects the rotation speed and rotation amount of the delivery motor 112.

The input/output unit 258 is communicatively connected to the input/output unit 218 of the surface mounter main body 10A. Then, the feeder control unit 251 cooperates with the arithmetic processing unit 211 of the mounting machine main body 10A to control the delivery motor 112 and supply the electronic component W to the component supply position O.

4. Adsorption processing of electronic component When the electronic component W is adsorbed from the feeder 100, it is desirable to determine the lowering start timing of the adsorption head 63 in consideration of the XY movement time T1 of the head unit 60 and the feeding time T2 of the feeder 100. ..

Specifically, in relation to the feeding operation of the feeder 100, as shown in FIG. 10, before the electronic component W reaches the component supply position O, the suction nozzle 64 makes the component suction height at the component supply position O. When L1 is reached, a suction error occurs. Therefore, after the electronic component W reaches the component supply position O, the suction nozzle 64 suctions the component 100 based on the feed time T2 of the feeder 100 so that the suction nozzle 64 reaches the component suction height L1 on the component supply position O. It is preferable to set the descent start timing of the head 63. Further, when the feeding time T2 of the feeder 100 is set as a long time with a margin in consideration of variations in time and the like, in the feeder 100 having a short feeding time T2, the suction head 63 is not moved after the feeding operation is completed. It will be delayed to descend to the component suction height L1. Therefore, a waiting time is generated and the mounting of components is delayed. Therefore, it is preferable to shorten the waiting time.

Further, in relation to the movement operation of the head unit 60 in the XY directions, if the lowering start timing of the suction head 63 is earlier than the movement of the head unit 60 in the XY directions, the suction head 63 is positioned above the component supply position O in the XY directions. Since the suction nozzle 64 reaches the component suction height L1 before reaching, the suction nozzle 64 may interfere with the surroundings.

Therefore, in the present embodiment, the first time (T1−Td) obtained by subtracting the lowering time Td of the suction head 63 from the XY movement time T1 of the head unit 60 and the lowering time Td of the suction head 63 from the feeding time T2 of the feeder 100. A process of comparing the second time (T2-Td) after subtracting is performed (FIG. 13: S40).

The XY movement time T1 of the head unit 60 is the time required for the head unit 60 to move in the XY directions for component adsorption. For example, as shown in FIG. 11, when the electronic component W is sucked by moving from one feeder 100a to another feeder 100e, the XY movement time T1 is the time required for the head unit 60 to move from the feeder 100a to 100e. (Movement time of distance Dx).

Further, the feeding time T2 of the feeder 100 is the time from when the feeder 100 starts feeding the electronic component W until the component reaches the component supply position O (the time when the component supply tape advances one pitch Lp). .. Further, the descent time Td of the suction head 63 is the time during which the suction head 63 descends from the rising end position L0 (initial height) shown in FIG. 10 to the component suction height (height of the component upper surface) L1.

(T1-Td)>(T2-Td) (1)
(T1-Td)≦(T2-Td) (2)

When the first time (T1−Td) is longer than the second time (T2−Td) as shown in the equation (1), the head unit 60 is set as shown in (A) of FIG. At the time t1 when the first time (T1-Td) has elapsed from the time point t0 when the movement in the XY directions is started, the suction head 63 starts descending from the ascending end position L0 (FIG. 13: S50).

In this case, as shown in FIG. 12A, the suction head 63 reaches the component suction height L1 at time t3 when the head unit 60 completes the movement in the XY directions. From the above, the completion timing of the lowering operation of the suction head 63 can be matched with the timing when the head unit 60 completes the movement in the XY directions, and the suction nozzle 64 can be prevented from interfering with the surroundings.

At time t0, the head unit 60 starts moving in the XY directions, and at the same time, the feeder 100 starts the feeding operation of the electronic component W. Therefore, in this case, as shown in FIG. 12A, the feeding operation of the feeder 100 is completed first, and then the lowering operation of the suction head 63 is completed.

Further, as shown in the equation (2), when the second time (T2-Td) is the first time (T1-Td) or more, the feeder 100 feeds the component W as shown in (B) of FIG. At the time t2 when the second time (T2-Td) has elapsed from the time point t0 when the suction head 63 starts, the suction head 63 starts descending from the rising end position L0 (FIG. 13: S60).

In this case, the suction head 63 reaches the component suction height L1 at time t4 when the feeder 100 completes the feeding operation of the electronic component W, as shown in FIG. From the above, it is possible to match the completion timing of the lowering operation of the suction head 63 with the timing when the feeder 100 completes the feeding operation of the electronic component W. Therefore, it becomes possible to suppress the suction error of the electronic component W. In addition, it is possible to take out the electronic component W with the suction head 63 at the same time when the feeding operation of the feeder 100 is completed, and a waiting time occurs until the electronic component is taken out after the feeding operation is completed. Can be avoided as much as possible. Therefore, the parts can be mounted quickly and the production efficiency is good.

At time t0, the head unit 60 starts moving in the XY directions at the same time when the feeder 100 starts the feeding operation of the electronic component W. Therefore, in this case, as shown in FIG. 12B, the movement of the head unit 60 in the XY directions is completed first, and then the lowering operation of the suction head 63 is completed.

FIG. 13 is a flowchart of the suction process of the electronic component by the suction head 63. When the processing starts, first, the arithmetic processing unit 211 of the surface mounter main body 10A performs the processing of S10A to S35A and the processing of S10B to S30B in parallel.

More specifically, in S10A, the arithmetic processing unit 211 gives a command to the motor control unit 215 to start moving the head unit 60 from the initial position toward the target position. For example, as shown in FIG. 11, when the electronic component W is sucked by moving from one feeder 100a to another feeder 100e, the head unit 60 moves from above the feeder 100a at the initial position to the feeder 100e at the target position. The movement starts in the X direction toward the upper side.

In S20A, the arithmetic processing unit 211 starts counting by the first timer 217A. The first timer 217A is a timer for the head unit, and measures the elapsed time after the head unit 60 starts moving (time t0 shown in FIG. 12).

In S30A, the arithmetic processing unit 211 calculates the XY movement time T1 of the head unit 60. The XY movement time T1 is the time during which the head unit 60 moves in the XY directions for component adsorption. In the example of FIG. 11, the moving distance of the head unit 60 is “Dx”. Therefore, the arithmetic processing unit 211 calculates the XY movement time T1 of the head unit 60 from the movement distance Dx and the movement speed and acceleration data of the head unit 60.

In S35A, the arithmetic processing unit 211 calculates the descent time Td of the suction head 63. The descent time Td of the suction head 63 is the time required for the suction head 63 to descend from the rising end position L0 to the component suction height L1. The component suction height L1 is the height of the upper surface of the electronic component W with respect to the printed circuit board P, and varies depending on the type of electronic component. Therefore, in the present embodiment, the descending distance Dd from the rising end position L0 to the component suction height L1 is obtained for each electronic component W based on the height data of the electronic component W. Then, the descending time Td of the suction head 63 is calculated from the obtained descending distance Dd and the data of the descending speed and the acceleration of the suction head 63.

Further, in S10B, the arithmetic processing unit 211 gives a command to the feeder control unit 251 of the feeder 100, and at the same time when the head unit 60 starts moving in the XY directions, the feeding operation of the electronic component W by the feeder 100 is performed. Let it start. For example, in the example of FIG. 11, in the feeder 100e that is a component supply target, the delivery motor 112 starts driving and the feeding operation of the electronic component W is started.

In S20B, the arithmetic processing unit 211 starts counting by the second timer 217B. The second timer 217B is a timer for the feeder, and measures the elapsed time after the feeder 100e starts the feeding operation of the electronic component W (time t0 shown in FIG. 12).

In S30B, the arithmetic processing unit 211 accesses the storage unit 213 and acquires the feeding time T2 of the feeder 100e. The feeding time T2 is the time from when the feeder 100 starts feeding the electronic component W until the component reaches the component supply position O. Although the data evaluated in advance before the production is started is stored in advance in the storage unit 213 as the initial value of the feed time T2, the data is updated to the actually measured value after the production of the printed circuit board P is started. It is like this.

In S40, the determination processing 1 is executed by the arithmetic processing unit 211. Specifically, the first time (T1-Td) obtained by subtracting the lowering time Td of the suction head 63 calculated in S35A from the XY moving time T1 of the head unit 60 calculated in S30A, and the feeder 100 acquired in S30B. The process of comparing with the second time (T2−Td) obtained by subtracting the lowering time Td of the suction head 63 calculated in S35A from the feeding time T2 of FIG.

Then, when the first time (T1-Td) is longer than the second time (T2-Td), YES is determined in the determination process 1 of S40, and the process proceeds to S50. After shifting to S50, the arithmetic processing section 211 performs determination processing 2. Specifically, the process of determining whether the elapsed time of the first timer 217A has reached the first time (T1-Td) is performed.

When the elapsed time of the first timer 217A reaches the first time (T1-Td), YES is determined in S50 and the process proceeds to S70. In S70, the arithmetic processing unit 211 controls the Z-axis motor 67 to start the lowering operation of the suction head 63. Therefore, in the example of FIG. 11, the suction head 63b located second from the right starts to descend from the rising end position L0 at time t1 shown in FIG.

On the other hand, if the second time period (T2-Td) is equal to or longer than the first time period (T1-Td), NO is determined in the determination process 1 of S40, and the process proceeds to S60. After shifting to S60, the arithmetic processing section 211 performs determination processing 3. Specifically, the process of determining whether the elapsed time of the second timer 217B has reached the second time (T2-Td) is performed.

Then, when the elapsed time of the second timer 217B reaches (T2-Td), YES is determined in S60, and the process proceeds to S70. In S70, the arithmetic processing unit 211 controls the Z-axis motor 67 to start the lowering operation of the suction head 63. Therefore, in the example of FIG. 11, the suction head 63b located second from the right starts to descend from the rising end position L0 at time t2 shown in FIG.

Subsequently, in S80, the electronic component W is taken out by the suction head 63b. That is, when the descent is started at the time t1 shown in FIG. 12, the suction head 63b descends to the component suction height L1 at the time t3, and sucks and holds the electronic component W from the feeder 100e to take it out.

On the other hand, when the descent is started at time t2 shown in FIG. 12, the suction head 63b descends to the component suction height L1 at time t4, and suction-holds and takes out the electronic component W from the feeder 100e. This completes one suction operation.

After that, the feeder 100e executes a process of transferring the measured value of the feed time T2 to the surface mounter main body 10A and storing it in the storage unit 213. That is, in the present embodiment, when the feeding operation of the electronic component W is performed, the feeder control unit 251 measures the feeding time T2 of the electronic component W. Specifically, the feeder control unit 251 measures the time (feed time T2) from the output of the rotary encoder 253 until the delivery motor 112 starts rotating with the delivery of the electronic component W. .. Then, when one feeding operation is completed, the feeder 100 transmits the data of the measured value of the feeding time T2 to the surface mounter main body 10A, and the data is stored in the storage unit 213. The feeder control unit 251 and the rotary encoder 253 are examples of the “measuring unit” in the present invention.

Since the feeding time T2 is measured each time the feeding operation of the feeder 100 is performed, after the production of the printed circuit board P is started, the data of the measured value of the feeding time T2 of each feeder 100 is stored in the storage unit 213. Accumulated.

5. Update Processing of Sending Time T2 FIG. 14 is a flowchart showing the flow of update processing of the sending time T2.
The updating process of the feeding time T2 is executed for each feeder. Hereinafter, the feeder 100e will be described as an example.

When the updating process starts, the arithmetic processing unit 211 first determines in S100 whether the measured number N of the feed time T2 accumulated in the storage unit 213 of the feeder 100e is a predetermined number (10 as an example) or more.

If the number of measurements N of the feed time T2 is 10 or more, a YES determination is made, and then the process proceeds to S110. If the number of measurements N is less than 10, the process waits until the number of measurements N becomes 10 or more, and then the process proceeds to S110.

After shifting to S110, the arithmetic processing unit 211 determines whether or not the measured value of the feed time T2 is included in the normal range. Then, when all the measured values of the feed time T2 are within the normal range, the process proceeds to S120.

After shifting to S120, the arithmetic processing unit 211 updates the feeding time T2 of the feeder 100e. Specifically, the worst value is obtained by comparing N measurement values, and the feed time T2 of the feeder 100e stored in the storage unit 213 is updated to the worst value. The worst value is the longest feed time among the measured values.

The updating process of the feeding time T2 is repeatedly performed, for example, every time a fixed period has elapsed from the start of production of the printed circuit board P. Therefore, the feeding time T2 of each feeder 100 is updated to the latest value at regular intervals.

Then, when the feed time T2 is updated, in the component suction processing shown in FIG. 13, which is executed thereafter, the updated feed time T2 is applied, the determination processing of S40 to S60 is executed, and the suction head The descent start timing of 63 is determined. That is, when the second time period (T2-Td) is longer than the first time period (T1-Td), the timing at which the feeder 100 completes the feeding operation of the electronic component W and the suction head 63 moves down. The descent start timing of the suction head 63 is determined based on the updated feed time T2 so that the completion timings match. By doing so, for example, when the feeding time T2 of the feeder 100 becomes shorter than the initial time as the remaining number of the electronic components W in the component supply tape 70 decreases after the production of the printed circuit board P starts, Along with this, the lowering start timing of the suction head 63 becomes earlier. Therefore, even when the feeding time T2 changes, the timing of completing the feeding operation of the electronic component W and the timing of completing the lowering operation of the suction head 63 always match. As described above, it is possible to avoid waiting time as much as possible until the electronic component W is taken out after the feeding operation by the feeder 100 is completed. Therefore, the parts can be mounted quickly and the production efficiency is good.

If the measured value of the feed time T2 includes an abnormal value outside the normal range, the processing proceeds to S130, and the arithmetic processing unit 211 indicates that the target feeder 100 has an abnormality by the display/operation unit 219. A process of informing the outside is performed, for example, by displaying on. This allows the user to be notified of an abnormality in the feeder 100.

6. Description of Effect In the present embodiment, since the feed time T2 is measured and updated during the production of the printed circuit board P, the accurate feed time T2 can be grasped, and the feeder 100 completes the feed operation of the electronic component W. The timing and the timing at which the suction head 63 completes the lowering operation can be accurately matched.

<Other Embodiments>
The present invention is not limited to the embodiments described by the above description and the drawings, and the following embodiments are also included in the technical scope of the present invention.

(1) In the above embodiment, as an example of the head unit, the in-line type head unit 60 in which the suction heads 63 are arranged in a line in the X direction is illustrated. The head unit is not limited to the in-line type, but may be a rotary type in which the suction heads 63 are arranged at equal intervals in the circumferential direction. In the case of the rotary type, when the target suction head is moved above the feeder, the head unit not only moves in the X and Y directions but also rotates in the R direction. Therefore, the moving time of the head unit needs to be set in consideration of not only the movement in the X direction and the Y direction but also the rotation.

(2) In the above embodiment, the example in which the head unit 60 moves from above the feeder 100a to above the feeder 100e to adsorb the electronic component has been described. The initial position of the head unit 60 is not limited to above the feeder 100, and may be another position such as above the printed circuit board P. Further, the moving direction of the head unit 60 is not limited to the X direction, but may be two directions of the X direction and the Y direction.

(3) In the above-described embodiment, as an example of the component suction process, the process of performing the three determination processes of S40, S50, and S60 is shown. The determination process 1 in S40 and the determination process 2 in S50 are not necessarily required processes. For example, the completion timing of the feeding operation of the feeder 100 (the timing at which the electronic component reaches the component supply position O) and the XY direction of the head unit 60 are set. If the start timing of the movement operation of the head unit 60 in the XY directions is controlled so that the completion timing of the movement operation of the head unit 60 (timing at which the suction head 63 reaches the component supply position O) matches, S60. Only the determination process of (1) is performed so that the end timing of the feeding operation of the electronic component by the feeder 100 and the end timing of the lowering operation of the suction head 63 match based on the feeding time T2 of the feeder 100 and the lowering time Td of the suction head 63. Alternatively, the descending timing of the suction head 63 may be determined.

(4) In the above embodiment, the feed time T2 of the feeder 100 is measured a plurality of times, and the feed time T2 is updated based on the obtained measurement value. In addition to this, for example, as shown in FIG. 15, an approximate curve Lt of the transition of the feed time T2 is obtained from the measured values of the past several times, and the feed time T2 is estimated from the obtained approximate curve Lt and updated. You can

(5) In the above embodiment, an example in which the actual feed time T2 is measured by measuring the time from the start of the rotation of the feed motor 112 to the stop of the rotation with the feeding of the electronic component W showed that. In addition to this, for example, the rotation speed of the feed motor 112 is measured from the output of the rotary encoder 112, and the actual feed time T2 is obtained from the measured value of the rotation speed and the feed pitch Lp of the electronic component W. Good. Further, for example, the actual feed time T2 may be calculated by detecting the difference between the timing when the suction head 63 reaches the component suction height L1 and the timing when the feeder 100 completes the component feeding operation. ..

(6) In the above embodiment, by adjusting the lowering timing of the suction head 63, the timing at which the feeder 100 completes the feeding operation of the electronic component W and the timing at which the suction head 63 completes the lowering operation match. did. Besides this, for example, the two timings may be matched by adjusting the descending speed of the suction head 63. Specifically, when the actual feed time T2 is shorter than the reference feed time T2, the lowering speed of the suction head 63 is adjusted faster than the reference lowering speed, and when the actual feed time T2 is longer, the suction is performed. The descent speed of the head 63 may be adjusted to be slower than the reference descent speed.

(7) In the above embodiment, the suction head 63 that suction-holds the component by negative pressure is illustrated as an example of the holding head that holds the component. The holding head has only to be configured to hold and release the component, and the holding method is not limited to suction. For example, the structure may be such that the parts are held by being sandwiched or gripped.

(8) In the above embodiment, when the measured value of the feed time T2 includes an abnormal value outside the normal range, it is determined that the feeder 100 is abnormal. The criterion for determining whether or not there is an abnormality in the feeder 100 is not limited to the example of the embodiment. For example, when abnormal values outside the normal range continue, or when the cumulative number of abnormal values reaches a predetermined number. In some cases, the feeder 100 may be determined to be abnormal. Further, if there is an abnormal value, it may not be included in the measured value and the abnormality determination may not be performed.

(9) In the above embodiment, when an abnormality of the feeder 100 is determined, the configuration is notified to the outside, but the production may be stopped immediately at the same time that the abnormality is notified.

10...Surface mounter 10A...Surface mounter main body 30...Head drive device 47...Y-axis motor (corresponding to “drive unit” of the present invention)
57... X-axis motor (corresponding to the "driving unit" of the present invention)
67... Z-axis motor (corresponding to the "elevating part" of the present invention)
60...Head unit 63...Suction head 100...Feeder 110...Sending device 112...Sending motor 211...Calculation processing unit (corresponding to the “control unit” of the present invention)
213... Storage unit 217A... First timer 217B... Second timer 251... Feeder control unit (corresponding to "measuring unit" of the present invention)
253... Encoder (corresponding to the "measuring unit" of the present invention)

Claims (4)

A surface mounter for mounting electronic components on a board,
A feeder that intermittently sends electronic components to a component supply position,
A head unit that supports a holding head that holds electronic components so that the holding head can move up and down,
An elevating part for elevating the holding head with respect to the head unit,
A drive unit for moving the head unit on a base,
A control unit that controls the movement of the head unit and the holding head,
The control unit is
Based on the feeding time of the electronic component by the feeder, the lowering operation of the holding head is controlled so that the end timing of the feeding operation of the electronic component by the feeder and the end timing of the lowering operation of the holding head coincide with each other,
The feeder has a measuring unit for measuring the feeding time of electronic components,
The control unit updates the data of the feeding time of the electronic component by the feeder based on the measurement value measured by the measurement unit during the production of the substrate ,
The control unit has a first time obtained by subtracting a descent time of the holding head from a moving time for moving the head unit onto the feeder, and a first time obtained by subtracting a descent time of the holding head from a feeding time of the feeder. Compare with 2 hours,
From the time point when the movement of the head unit and the feeding of the feeder are started at the same time, the holding head starts to descend at the timing when the longer side of the first time and the second time elapses. Machine. The surface mounter according to claim 1,
The controller ends the feeding operation of the electronic component by the feeder based on the feeding time of the electronic component by the feeder and the descent time required for the holding head to descend from the initial height to the height of the electronic component. A surface mounter that determines the descent start timing of the holding head so that the timing coincides with the end timing of the descent operation of the holding head. A surface mounter for mounting electronic components on a board,
A feeder that intermittently sends electronic components to a component supply position,
A head unit that supports a holding head that holds electronic components so that the holding head can move up and down,
An elevating part for elevating the holding head with respect to the head unit,
A drive unit for moving the head unit on a base,
A control unit that controls the movement of the head unit and the holding head,
The control unit is
Based on the feeding time of the electronic component by the feeder, the lowering operation of the holding head is controlled so that the end timing of the feeding operation of the electronic component by the feeder and the end timing of the lowering operation of the holding head coincide with each other,
The feeder has a measuring unit for measuring the feeding time of electronic components,
The control unit updates the data of the feeding time of the electronic component by the feeder based on the measurement value measured by the measurement unit during the production of the substrate,
The measuring unit measures the feeding time a plurality of times during production of the substrate,
The surface mounter in which the control unit updates the data of the feeding time of the feeder to the worst value of a plurality of measured values by the measuring unit. The surface mounter according to any one of claims 1 to 3 ,
The surface mounter, wherein the control unit notifies the abnormality of the feeder to the outside when the measurement value of the measuring unit is abnormal.

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