JP3597630B2 - Surface mounting machine - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a surface mounter having a head unit movable between a component supply unit and a component mounting unit, and a component mounting nozzle member that moves up and down by being driven by an air cylinder.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a head unit movable between a component supply unit and a printed circuit board positioned at a predetermined work position is provided with a nozzle member for component suction so as to be able to move up and down and rotate, and is supplied to the nozzle member. 2. Description of the Related Art A surface mounter in which an electronic component is sucked by a negative pressure, a head unit is moved onto a printed circuit board after the component is sucked from a component supply unit, and the component is mounted is generally known. In this mounting machine, the nozzle member mounted on the head unit is moved up and down by the elevating drive means at the time of picking up components and mounting components.
[0003]
As the elevating drive means, there are a type in which a nozzle member is raised and lowered by a servo motor via a ball screw and the like, and a type in which a nozzle member is raised and lowered by an air cylinder. From a viewpoint, there are many mounting machines that constitute a driving system for raising and lowering a nozzle member using an air cylinder.
[0004]
In particular, in a mounting machine equipped with a large number of nozzle members in the head unit from the viewpoint of increasing mounting efficiency, it is difficult to provide a servo motor for each nozzle member in terms of space and so on. An air cylinder is effective as a driving means for driving the air cylinder.
[0005]
[Problems to be solved by the invention]
By the way, in the mounting machine in which the nozzle member is moved up and down by using the air cylinder as described above, since the speed at which the nozzle member is moved up and down by the air cylinder is substantially constant over the entire up-and-down stroke, the nozzle is designed to reduce the cycle time When an attempt is made to increase the elevating speed of the member, the impact force when the nozzle member reaches the lower end position or the upper end position increases accordingly. For this reason, the impact force applied to the component during suction or the like becomes large, and the component may be shifted with respect to the nozzle member or the component may fall off due to the impact when the nozzle member reaches the rising end position after component suction. There is therefore a possibility that mounting accuracy may be impaired by merely increasing the elevating speed of the nozzle member to shorten the cycle time.
[0006]
Therefore, in order to reduce the impact at the time of raising and lowering the nozzle member and to shorten the cycle time, for example, it is conceivable to provide a damper member at the rising end position of the nozzle member to reduce the impact force. In this case, it is necessary to provide a separate damper member, which may lead to an increase in the size and weight of the head unit.
[0007]
SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problem, and in a lifting / lowering driving means of a nozzle member using an air cylinder, a surface capable of effectively mitigating an impact when the nozzle member is raised / lowered with a compact configuration. The purpose is to provide a mounting machine.
[0008]
[Means for Solving the Problems]
The present invention relates to a surface mounter comprising: a head member movable between a component supply unit and a component mounting unit; a nozzle member for sucking an electronic component; and an air cylinder for driving the nozzle member up and down. A housing driven by a motor is provided, and the nozzle member and the air cylinder are mounted on the housing. The housing is moved up and down by the motor and the nozzle member is moved up and down by the air cylinder. The nozzle member is configured to move up and down,PreviousThe air cylinder includes a piston connected to the nozzle member, and a cylinder having a pair of pressure chambers above and below the piston, and a cylinder having an air supply / discharge port in each pressure chamber, and at least one of the cylinders In the pressure chamber, a narrow tube portion is formed on the moving end side of the piston, and the air supply / discharge port is opened in the narrow tube portion. On the other hand, the piston has a narrow tube portion at an axial end thereof. A small-diameter portion that can be inserted into the cylindrical portion is provided, and any one of the small-diameter portion of the cylinder and the small-diameter portion of the piston is provided between the small-diameter portion and the small-diameter portion when the small-diameter portion is inserted into the small-diameter portion. Sealing means for sealing are provided, and the sealing means is configured to achieve the sealing before reaching the moving end position of the piston.Further, the air supply / discharge system for the air cylinder is provided with an operation speed switching valve capable of switching the elevation drive speed of the nozzle member between a low speed and a high speed, while the operation sequence of the motor and the air cylinder and the nozzle elevation drive Control means for driving and controlling the motor and the operating speed switching valve to switch the speed in accordance with the type of electronic component sucked by the nozzle member is provided, and the control means, after lowering the housing, On the other hand, a first elevating mode in which the electronic component is sucked and mounted by moving the nozzle member at high speed, and the electronic component is sucked and mounted by lowering the housing at a low speed after lowering the housing. A second elevating mode in which the nozzle member is lowered at a low speed with respect to the housing, and then the housing is lowered. The electronic component吸装applied by Rukoto, then perform either mode selectively among the third lift mode to increase the nozzle member against the housing with raising the housing at a low speedIs configured as.
[0009]
According to this surface mounter, while air is supplied to one pressure chamber of the air cylinder, air is discharged from the other pressure chamber, whereby the piston is moved up and down, whereby the nozzle member is driven up and down. Is done. During the raising and lowering of the nozzle member, when the piston reaches the vicinity of the moving end position, the small diameter portion of the piston is inserted into the small cylindrical portion of the cylinder, and the space between the small cylindrical portion and the small diameter portion is sealed by the seal member, In this state, air is sealed between the small diameter portion of the piston and the inner wall of the cylinder. Therefore, until the piston reaches the moving end position from this position, the movement of the piston is decelerated by the cushioning action by the compression of the air sealed between the small-diameter portion of the piston and the inner wall of the cylinder. The impact at the rising end position or the falling end position of the member is reduced.Then, the operation order of the motor and the air cylinder and the nozzle elevating / lowering drive speed are switched according to the type of the electronic component to be sucked by the nozzle member, so as to be appropriate.It becomes possible to mount components quickly.
[0010]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described with reference to the drawings.
[0011]
FIG. 1 schematically shows an entire surface mounter (hereinafter abbreviated as a mounter) according to an embodiment of the present invention. In this figure, a conveyor 2 constituting a transport line is arranged on a base 1, and a printed circuit board 3 is transported on the conveyor 2 and stopped at a predetermined mounting work position. The conveyor 2 is composed of a pair of unit conveyors 2a and 2b arranged in parallel, and one (upper in FIG. 1) unit conveyor 2b is replaced by the other (lower in FIG. 1) unit by a width adjusting mechanism (not shown). 2a can be approached or separated. Thus, the configuration is such that the size of the printed board 3 can be changed.
[0012]
A component supply unit 4 is arranged on the side of the conveyor 2. The component supply unit 4 includes a plurality of rows of tape feeders 4a. Each of the tape feeders 4a stores and holds small chip-shaped chip components such as ICs, transistors, and capacitors at predetermined intervals. And a ratchet feeding mechanism is provided at the tape feed-out end, so that the tape is fed out intermittently as components are picked up by a head unit 5 described later.
[0013]
Above the base 1, a head unit 5 for mounting components is provided, and the head unit 5 is mounted in the X-axis direction (the direction of the conveyor 2) and the Y-axis direction (the direction orthogonal to the X axis on a horizontal plane). ) Can be moved.
[0014]
That is, a pair of fixed rails 7 extending in the Y-axis direction and a ball screw shaft 8 rotated and driven by a Y-axis servomotor 9 are disposed on the base 1, and a head unit is mounted on the fixed rail 7. A support member 11 is arranged, and a nut portion 12 provided on the support member 11 is screwed to the ball screw shaft 8. The support member 11 is provided with a guide member 13 extending in the X-axis direction and a ball screw shaft 14 (shown in FIG. 3) driven by an X-axis servomotor 15. The unit 5 is movably held, and a nut portion 16 (shown in FIG. 3) provided on the head unit 5 is screwed to the ball screw shaft 14. The ball screw shaft 8 is rotated by the operation of the Y-axis servo motor 9 to move the support member 11 in the Y-axis direction, and the ball screw shaft 14 is rotated by the operation of the X-axis servo motor 15, thereby causing the head unit to rotate. 5 moves in the X-axis direction with respect to the support member 11.
[0015]
A component recognition camera 17 is arranged at a predetermined position on the base 1. In the illustrated example, a component recognition camera 17 is arranged between the unit conveyor 2a on the fixed side and the component supply unit 4 on the side of the unit conveyor 2a. , And a component recognition state is determined by a component recognition process based on the image.
[0016]
2 to 5 show the structure of the head unit 5. In these figures, the head unit 5 is provided with a nozzle member 20 for sucking a component, and in this embodiment, eight nozzle members 20 are arranged in a state of being aligned in the X-axis direction. Further, the head unit 5 includes a lifting drive mechanism for raising and lowering each of the nozzle members 20, a rotation drive mechanism for rotating each of the nozzle members 20, and a negative pressure supply system for supplying a negative pressure for component suction to each of the nozzle members 20. Is provided.
[0017]
The elevation drive mechanism includes one overall vertical movement servomotor 21 that simultaneously moves the nozzle members 20 up and down, and a predetermined number (eight) of air cylinders 25 that individually elevate and lower each nozzle member 20 by a fixed stroke. The servo motor 21 and the air cylinder 25 are used in combination to raise and lower each nozzle member 20 over a predetermined raising position and lowering position. Further, the rotation drive mechanism has one rotation servomotor 60, and the servomotor 60 is configured to rotate each nozzle member 20 via power transmission means.
[0018]
More specifically, the structure of the head unit 5 will be described. A housing 22 for holding the nozzle member 20, the air cylinder 25, and the like is attached to the head unit main body 5a so as to be movable up and down. A moving servomotor 21 is mounted, and the housing 22 is moved up and down via a ball screw 23 by the servomotor 21.
[0019]
Each of the nozzle members 20 includes a hollow nozzle shaft 20a, a nozzle holder 20b attached thereto, and a nozzle 20c detachably attached to a lower end thereof. The housing 22 is attached to the housing 22 so as to be vertically movable and rotatable. That is, the nozzle guide 26 is rotatably attached to the housing 22, and the nozzle shaft 20a is fitted to the nozzle guide 26 so as to be vertically movable.
[0020]
The nozzle holder 20b is attached to the nozzle shaft 20a in a state in which the nozzle holder 20b can move at a constant stroke in the axial direction with respect to the nozzle shaft 20a and is urged toward the lower end by a spring 27. That is, by allowing the nozzle holder 20b to elastically move in the axial direction with respect to the nozzle shaft 20a, a collision between the nozzle tip and the component at the time of component suction mounting, or a suction component at the time of component mounting. The impact caused by the collision with the printed board 3 can be reduced.
[0021]
A bearing 28 is fixed to a substantially intermediate portion of the nozzle shaft 20a, and a spring 29 is attached to a lower portion thereof. The spring 29 urges the nozzle shaft 20a upward through the bearing 28. ing. As shown in FIG. 6, a washer 30 that is rotatable relative to the nozzle member 20 is interposed between the bearing 28 and the spring 29, and between the washer 30 and the inner ring of the bearing 28. A steel ball 31 is held so as to roll freely.
[0022]
The outer ring portion of the bearing 28 slides on a vertically extending guide portion 22a formed on the housing 22 when the nozzle shaft 20a moves up and down, thereby preventing the nozzle shaft 20a from swinging when ascending and descending. It has become so.
[0023]
Further, a lower end sensor 32 is attached to the housing 22 at a position facing the nozzle shaft 20a of each nozzle member 20, and the sensor 32 detects the bearing 28 as the nozzle shaft 20a lowers. This detects that the nozzle shaft 20a has reached the lower end position.
[0024]
The air cylinders 25 and the air supply / discharge system for the air cylinders 25 are provided above the nozzle member arrangement location on the front side of the housing 22. The upper ends of the nozzle shafts of the nozzle members 20 are respectively provided. It protrudes into the corresponding air cylinder 25. The air supply / discharge system has an air cylinder drive solenoid valve 44 for switching the supply / discharge of air to / from each air cylinder 25, and controls the air discharge speed by using speed control valves 49 and 50, as described in detail later. There is an elevating / lowering drive speed varying means capable of changing the elevating / lowering speed of the air cylinder 25 by adjusting the above. The solenoid valve 44 is connected to an air supply source (not shown).
[0025]
Each air cylinder 25 has a piston 33 therein, and has pressure chambers 34, 35 above and below the piston 33. These pressure chambers 34, 35 are supplied and exhausted with air through ports 36, 37. It is connected to the passage of the system. When the air is discharged from the lower pressure chamber 35 while the air is supplied to the upper pressure chamber 34, the piston 33 descends. Conversely, the air is supplied from the upper pressure chamber 34 to the lower pressure chamber 35 while the air is supplied to the lower pressure chamber 35. Is discharged, the piston 33 rises.
[0026]
At the lower end of the piston 33, a tubular sleeve 33a longer than the elevating stroke of the piston 33 is provided integrally, and the upper end of the nozzle shaft of the nozzle member 20 protruding into the air cylinder 25 is connected to the sleeve 33a. It is rotatably inserted into.
[0027]
The air cylinder 33 is provided with a cushion mechanism for reducing the moving speed of the piston 33 immediately before the rising end and immediately before the falling end when the piston 33 moves up and down. The cushion mechanism includes small diameter portions 38a and 38b provided at the upper and lower portions of the piston 33, seal members 39a and 39b respectively provided at upper and lower portions thereof, and upper end portions of the pressure chambers 34 and 35. And inner frame portions (small cylindrical portions) 40a and 40b provided near the lower end, respectively. The ports 36 and 37 are opened in the inner wall of each of the inner frame portions 40a and 40b, and each pressure Subports 41a and 41b, each of which is a very small passage communicating the chambers 34 and 35 with the ports 36 and 37, are opened at the lower end surface of the upper inner frame portion 40a and the upper end surface of the lower inner frame portion 40b.
[0028]
Then, in order to lower the nozzle member 20, the piston 33 in the air cylinder 25 is lowered from the state of being at the rising end position as shown in FIG. 7A, and reaches near the lowering end as shown in FIG. 7B. The seal member 39b provided on the lower small-diameter portion 38b slides on the lower inner frame portion 40b, and in this state, a cushion chamber 42 is defined between the small-diameter portion 38b of the piston 33 and the cylinder inner wall. . Then, during the time from when the piston 33 reaches this position to the lower end position shown in FIG. 7C, the air sealed in the cushion chamber 42 is compressed and gradually discharged through the subport 41b while being compressed. The action lowers the lowering of the piston 33.
[0029]
Conversely, when the piston 33 in the air cylinder 25 is raised from the state of the lower end position shown in FIG. 8A in order to raise the nozzle member 20, and reaches the vicinity of the upper end as shown in FIG. The seal member 39a provided on the upper small-diameter portion 38a is in sliding contact with the upper inner frame portion 40a, whereby a cushion chamber 43 is defined between the small-diameter portion 38a of the piston 33 and the cylinder inner wall. Then, until the piston 33 reaches the rising end position shown in FIG. 8C, the air sealed in the cushion chamber 42 is compressed and gradually discharged through the subport 41a while being compressed. The rise of the piston 33 is decelerated.
[0030]
FIG. 9 shows an air supply / discharge system for the air cylinder 25. As shown in the figure, between the solenoid valve 44 for driving the air cylinder and the air cylinder 25, an air passage 45 for the lower pressure chamber communicating with the lower pressure chamber 35 of the air cylinder 25, and an upper pressure chamber 34. And an upper pressure chamber air passage 46 communicating with the upper pressure chamber. The solenoid valve 44 is connected to the lower pressure chamber air flow path 45 to the air supply source 51 and opens the upper pressure chamber air flow path 46 to the atmosphere through an air exhaust flow path 47 and the like. (State shown) and a lower drive state in which the upper pressure chamber air passage 46 is connected to the air supply source 51 and the lower pressure chamber air passage 45 is opened to the atmosphere via the air exhaust passage 47 and the like. It can be switched to
[0031]
Further, as an ascending / descending drive speed varying means, an air exhaust passage 47 connected to the solenoid valve 44 is connected to the air exhaust passage 47 via an operation speed switching valve 52, and the other end is opened to the atmosphere. Speed control channel 48 is provided. The speed control flow path 48 includes a high-speed operation flow path 49 having a high-speed lifting / lowering throttle 49a and a low-speed operation flow path 50 having a low-speed lifting / lowering throttle 50a, and these flow paths 49, 50 are arranged in parallel. The throttle opening of the high-speed lifting / lowering throttle 49a is set to be relatively larger than the throttle opening of the low-speed lifting / lowering throttle 50a.
[0032]
Therefore, when the operation speed switching valve 52 is off (in the state shown in the drawing) when the solenoid valve 44 is switched from the upward drive state to the downward drive state and the piston 33 descends, the air in the lower pressure chamber 35 is exhausted. High-speed descent is performed by being discharged through the flow path 47 and the high-speed operation flow path 49, and when the operation speed switching valve 52 is on, the air in the lower pressure chamber 35 flows through the low-speed operation flow path 50. A low speed descent is performed by being discharged through. Further, when the operating speed switching valve 52 is off when the solenoid valve 44 switches from the downward drive state to the upward drive state and the piston 33 rises, the air in the upper pressure chamber 34 is discharged to the air exhaust passage 47 and the high-speed operation. When the operation speed switching valve 52 is turned on, the air in the upper pressure chamber 34 is discharged through the low-speed operation channel 50 so that the air is discharged through the low-speed operation channel 50. A slow climb is performed.
[0033]
Incidentally, the solenoid valve 44 and the operation speed switching valve 52 are controlled by a control unit 55 provided in the mounting machine. The control unit 55 raises and lowers the nozzle member 20 by using the control of the vertical movement servomotor 21 and the air cylinder 25 in combination with the suction of the component from the component supply unit 4 and the mounting of the component on the printed circuit board 3. The control of the servomotor 21 and the control of the air cylinder 25 by controlling the solenoid valve 44 and the operation speed switching valve 52 are performed. At this time, the operation sequence of the servo motor 21 and the air cylinder 25 and the elevating drive speed of the air cylinder 25 are selected according to the type of the electronic component adsorbed on the nozzle member 20. That is, information on various electronic components is stored in advance in the storage unit 56 in the control unit 55, and information on the component to be processed (the electronic component that is attracted to the nozzle component) is read from the storage unit 56, and Accordingly, a lifting control mode suitable for the component to be processed is selected from among various lifting control modes described below, and the servo motor 21 and the air cylinder 25 are controlled in accordance with the selection.
[0034]
As shown in FIG. 5, the housing 22 is further provided with a servomotor 60 for rotation and a drive shaft 64 interlocked with the servomotor 60 via a speed reduction mechanism including pulleys 61 and 62 and a belt 63, A rotation transmission belt 67 is wound around a pulley 65 provided on the drive shaft 64 and a pulley 66 provided on each nozzle member 20, and a speed reduction mechanism, a drive shaft 64, and a rotation transmission Each nozzle member 20 is rotationally driven via a belt 67.
[0035]
Further, the head unit 5 is provided with a vacuum generator 70 for supplying a negative pressure to each of the nozzle members 20, respectively, and is disposed above the head unit body 5a. Then, the negative pressure introducing portion at the upper end of the air cylinder 25 is connected to the vacuum generator 70 via a flexible pipe, a valve, and the like (not shown), so that the inside of the piston 33 of the air cylinder 25 passes. A negative pressure supply / discharge system is configured so that negative pressure is supplied to the nozzle member 20. Since the upper end of the nozzle shaft 20a is rotatably connected to the piston 33 between the piston 33 and the nozzle member 20, there is a concern about the sealing property between these members during negative pressure supply. If an O-ring is press-fitted to ensure the sealing performance, the rotational resistance of the nozzle shaft 20a increases, which is inconvenient. However, as described above, the sleeve 33a longer than the elevating stroke of the piston 26 is formed integrally with the piston 33, and the nozzle shaft 20a is connected to the piston 33 via the sleeve 33a. Is secured, and the rotational resistance is reduced.
[0036]
By the way, in the above mounting machine, as shown in FIG. 4, the upper component 71 constituting the upper end of the air cylinder 25 has the port 36, the upper inner frame portion 40a, the negative pressure introducing portion from the vacuum generator 70, and the like. The upper component member 71 is fitted into the cylinder portion of the air cylinder 25 and is fixed to the housing 22 with screws or the like, and the nozzle guide 26 for holding the nozzle member 20 is connected to the housing 22. Is inserted from below into the inside thereof, and is prevented from being removed by a plate member 72 attached with screws or the like. Thereby, maintenance of the nozzle member 20 and the air cylinder 25 is ensured.
[0037]
That is, in the above mounting machine, since only the nozzle shaft 20a is inserted into the sleeve 33a, the upper component member 71 is removed, the upper part of the air cylinder 25 is opened, and only the piston 33 is taken out by pulling the piston 33 upward. The nozzle guide 26 and the nozzle member 20 can be removed from the housing 22 for replacement or the like by removing the plate member 72. Therefore, the piston 33 and the nozzle member 20, which are relatively easy to wear and change with time, can be easily detached and replaced.
[0038]
Reference numeral 73 denotes a camera for recognizing a fiducial mark provided on the printed circuit board 3, which is attached to one side of the head unit main body 5a.
[0039]
Next, a mounting operation by the mounting machine will be described.
[0040]
When the mounting operation is started, first, the head unit 5 is arranged above the component supply unit 4, and while the air is supplied to the upper pressure chamber 34 in the air cylinder 25 corresponding to the nozzle member 20 to which the component is to be sucked. The air is discharged from the lower pressure chamber 35, and the negative pressure generated by the vacuum generator 70 is supplied into the nozzle member 20 at a predetermined timing. As a result, the piston 33 is lowered, and the sleeve 33a presses the bearing 28 downward via a retaining ring or the like, whereby the piston 33 and the nozzle shaft 20a are displaced integrally to the lower end position, and the components are sucked. Is Further, by operating the vertical movement servomotor 21 in addition to the operation of the air cylinder 25, the lower end position is adjusted.
[0041]
Thereafter, the supply and discharge of air to and from the air cylinder 25 are switched, and the air is discharged from the upper pressure chamber 34 while the air is supplied to the lower pressure chamber 35, so that the piston 33 is raised, and By the urging force of the spring 29, the nozzle shaft 20a follows the piston 33 and is raised to the rising end position.
[0042]
At this time, the rise near the rising end position of the nozzle member 20 is reduced by the air cushioning action of the cushion mechanism provided in the air cylinder 25, so that the impact when the nozzle member 20 reaches the rising end position is reduced. Is done. For this reason, the displacement or falling off of the suction component due to the impact at the time of reaching the rising end position is effectively prevented.
[0043]
Then, by performing the above-described component suction operation for each nozzle member 20, the component suction is sequentially performed by each nozzle member 20, and when possible, the component suction is performed simultaneously by the plurality of nozzle members 20. Done.
[0044]
When the removal of the component from the component supply unit is completed, the head unit 5 is moved above the printed circuit board 3, and the nozzle member 20 is activated by the operation of the vertical movement servomotor 21 and the air cylinder 25, as in the case of the component suction. At the same time as the nozzle member 20 is raised and lowered, the supply of the negative pressure to the nozzle member 20 is interrupted at the timing when the nozzle member 20 reaches the lower end, whereby the component is mounted on the printed circuit board 3. At this time, the nozzle member 20 is rotated by driving the rotation servomotor 60 before or after the nozzle member 20 descends, thereby positioning the component in the rotational direction.
[0045]
In the lowering operation of the nozzle member 20 for mounting components as well, the lowering of the nozzle member 20 near the lower end is reduced by the cushion mechanism of the air cylinder 25, and the impact at the lower end position of the nozzle member 20 is reduced. This prevents the suction component from shifting or falling off.
[0046]
When the nozzle member 20 is rotated in the state where the nozzle member 20 is lowered as described above in positioning in the rotation direction at the time of component mounting, the spring 29 is compressed, and the axial biasing force is applied to the bearing. Since it acts on the nozzle shaft 20 a via the nozzle member 28, there is a concern that this acts as a rotational resistance of the nozzle member 20. However, in the above-described mounting machine, as described above, the steel ball 31 is rotatably held between the upper end of the spring 29 and the bearing 28 via the washer 30, whereby the relative rotation between the bearing 28 and the spring 29 is reduced. Since it can be easily performed, even when the spring 29 is in a compressed state, the urging force is suppressed from acting as a rotational resistance of the nozzle member 20. Therefore, even when the nozzle member 20 is lowered, the rotation of the nozzle member 20 is performed smoothly, and the positioning in the rotation direction is performed with high accuracy.
[0047]
When a component is being sucked by each nozzle member 20 of the head unit 5, the movement of the head unit 5, the rotation of the nozzle member 20, and the elevation of the nozzle member 20 are continuously performed, so that each nozzle The component sucked by the member 20 is mounted on the printed circuit board 3.
[0048]
In the above-described component sucking / mounting operation, the nozzle member 20 is raised / lowered in a mode selected according to the type of component from among various lifting / lowering control modes as shown in FIGS.
[0049]
That is, FIG. 10 shows the elevation control mode when the target component is a standard chip component. At the time of picking up the components, the servomotor 21 is first driven so that the distance between the tip of the nozzle and the upper surface of the target component corresponds to the operating stroke of the air cylinder 25 as shown in FIG. The height position of the member is adjusted (step S11). Next, the lowering of the nozzle member 20 by the driving of the air cylinder 25 is performed at a high speed, that is, the air cylinder driving solenoid valve 44 is switched to the lowering driving state and the operation speed switching valve 52 is turned off. The piston 33 is operated at a high speed in the descending direction (Step S12). Then, when the nozzle member 20 reaches the lower end position and the tip of the nozzle comes into contact with the target component, the component is sucked by the negative pressure supplied to the nozzle member 20 (step S13). Then, the nozzle member 20 is raised at a high speed by driving the air cylinder 25, that is, the solenoid valve 44 is switched to the ascending drive state and the operation speed switching valve 52 is kept on, whereby the piston 33 is moved. It is moved at a high speed in the ascending direction (step S14).
[0050]
Also at the time of component mounting, first, the height position of the nozzle member 20 is adjusted by driving the servo motor 21 (step S16), as shown in FIG. 20 is lowered at a high speed (step S17). Then, when the nozzle member 20 reaches the lower end position, the supply of the negative pressure is stopped and the component is mounted on the printed circuit board 3 (step S18), and then the nozzle member 20 is raised at a high speed by driving the air cylinder 25. (Step S19).
[0051]
In this mode, the nozzle member 20 is lowered by the air cylinder 25 at a high speed after the height position is adjusted by driving the servo motor 21 at the time of component suction and component mounting. The cycle time is shortened by the nozzle 25 being raised by the cylinder 25 at a high speed. In this case, the suction force of the nozzle member 20 sufficiently acts on the standard chip component, and the air cushion effect is exerted by the cushion mechanism. Also, no parts are dropped or displaced.
[0052]
Next, FIG. 11 shows an elevation control mode in a case where the target component is a specially shaped component (for example, a component having irregularities, grooves, and the like on the upper surface) in which the suction force of the nozzle member 20 is likely to decrease, or a heavy component. Is shown. At the time of component suction, as shown in FIG. 3A, first, the height position of the nozzle member 20 is adjusted by driving the servo motor 21 (step S21), and then the nozzle member 20 is driven by driving the air cylinder 25. Is lowered at a low speed, that is, when the solenoid valve 44 is switched to the lowering drive state and the operation speed switching valve 52 is turned on, the piston 33 is operated at a lower speed in the lowering direction (step S22). Then, the nozzle member 20 reaches the lower end position and the component is sucked (step S23). Then, the nozzle member 20 is raised at a low speed by the driving of the air cylinder 25, that is, the solenoid valve 44 is switched to the rising drive state and the operation speed switching valve 52 is kept on, whereby the piston 33 is raised. It is operated at a low speed in the direction (step S24).
[0053]
On the other hand, at the time of component mounting, first, the height position of the nozzle member 20 is adjusted by driving the servomotor 21 (step S25) as shown in FIG. The member 20 is lowered at a low speed (step S26). When the member 20 reaches the lower end position, the component is mounted on the printed circuit board 3 (step S27), and then the nozzle member 20 is raised at a low speed by driving the air cylinder 25. (Step S28).
[0054]
Further, FIG. 12 shows a lifting / lowering control mode when the target component is a component that requires particularly high precision mounting, for example, QFP. At the time of component suction, as shown in FIG. 3A, first, the nozzle member 20 is lowered at a low speed by driving the air cylinder 25 (step S31), whereby the nozzle member 20 is moved to a position close to the target component. After lowering, the nozzle member 20 is gently lowered to a position where the nozzle member 20 contacts the component by driving the servomotor 21 (step S32). Then, the component is sucked (step S33), and then the nozzle member 20 is raised at a low speed by driving the air cylinder 25, and the servomotor 21 is driven in the upward direction (step S34).
[0055]
On the other hand, at the time of component mounting, the nozzle member 20 is first lowered at a low speed by driving the air cylinder 25 (step S36), as shown in FIG. Then, the nozzle member 20 gradually descends to a position where the nozzle member 20 reaches the printed circuit board 3 by driving the servo motor 21 (step S37). Then, the components are mounted (Step S38), and then the nozzle member 20 is raised at a low speed by driving the air cylinder 25, and the servomotor 21 is driven in the upward direction (Step S39).
[0056]
In the modes shown in FIGS. 11 and 12, the lifting and lowering operation of the nozzle member 20 is performed at a low speed at the time of sucking and mounting the component, and the cushioning mechanism exerts an air cushion effect, so that the target component can be a specially shaped component or the like. Even in the case of a heavy component or a component that requires high-precision mounting, the falling off of the component is effectively prevented. In particular, in the mode shown in FIG. 12, when the component is sucked and mounted, the nozzle member 20 is gently lowered until the nozzle member 20 reaches the component by the drive of the servo motor 21 after the air cylinder 25 lowers the nozzle. When the member 20 contacts the component or when the nozzle member moves up and down in the component suction state, the component is effectively prevented from shifting and moving, thereby increasing the mounting accuracy.
[0057]
As described above, according to the mounting machine, the movement of the nozzle member 20 in the vicinity of the rising end position and the vicinity of the falling end position in the elevating operation is reduced by the air cushion effect of the cushion mechanism provided in the air cylinder 25. Therefore, even if the speed of raising and lowering the nozzle member 20 by the air cylinder 25 is set relatively high, the impact at the rising end position and the falling end position of the nozzle member 20 is effectively alleviated, and the displacement of the suction component is reduced. And falling off can be prevented. In other words, in other words, the mounting speed can be appropriately secured while the cycle time is shortened by setting the rising and lowering speed of the nozzle member 20 by the air cylinder 25 to be high. In particular, by changing and setting the nozzle elevating operation according to the type of the target component as in the above-described embodiment, the cycle time can be reduced as much as possible within a range where the component does not fall off.
[0058]
In addition, the above-described cushion mechanism is provided integrally with the air cylinder 25. Further, the piston and the cylinder of the air cylinder 25 are provided with a shape characteristic, and the piston 33 is provided with a simple structure in which the seal members 39a and 39b are provided. Therefore, the cushioning function can be exerted with a very compact configuration as compared with a configuration in which a damper member or the like is separately provided. Therefore, the provision of the cushion mechanism does not involve any adverse effect such as unnecessarily increasing the size of the head unit 5 or significantly increasing the weight.
[0059]
The mounting machine of the above embodiment is an example of the surface mounting machine according to the present invention, and its specific configuration can be appropriately changed without departing from the gist of the present invention. For example, in the above embodiment, subports 41a and 41b are formed in the upper and lower inner frame portions 40a and 40b of the air cylinder 25, respectively, so that the air sealed in the cushion chambers 42 and 43 is gradually discharged. However, instead of providing such subports 41a and 41b, for example, a narrow groove extending in the axial direction is formed in each of the inner frame portions 40a and 40b, and air sealed in the cushion chambers 42 and 43 through the narrow groove. May be gradually discharged. In addition to providing the subports 41a and 41b and the above-mentioned narrow groove and the like, cuts are provided in the seal members 39a and 39b, whereby the cushion chamber 42, It may be configured to discharge the air sealed in the inside 43.
[0060]
Further, in the above mounting machine, the component recognition camera 17 is arranged between the unit conveyor 2a on the fixed side and the component supply unit 4 on the side thereof, but it is not always necessary to arrange this way. However, in an apparatus having a movable conveyor 2 such as the above-described mounting machine, it is preferable to dispose it as in the above-described embodiment in order to enhance mounting efficiency.
[0061]
That is, when the printed circuit board 3 of the minimum size is transported, the components are normally supplied from the component supply unit 4 close to the printed circuit board 3 in consideration of the mounting efficiency, that is, the component supply unit 4 on the side of the unit conveyor 2a on the fixed side. Since the component recognition camera 17 is disposed between the unit conveyor 2a on the fixed side and the component supply unit 4 on the side thereof, the moving amount of the head unit 5 for component recognition is minimized. The mounting efficiency can be increased.
[0062]
【The invention's effect】
As described above, according to the surface mounter of the present invention, when the piston reaches the vicinity of the moving end position, the small diameter portion of the piston is inserted into the small cylinder portion of the cylinder, and the space between the small cylinder portion and the small diameter portion is formed. Sealing is performed by the sealing member, and in this state, air is sealed between the small diameter portion of the piston and the inner wall of the cylinder, whereby the movement of the piston is reduced by the cushioning action of the sealed air. That is, it is possible to effectively reduce the impact at the rising end position or the falling end position.
[0063]
Therefore, it is possible to preferably prevent the suction component from shifting or falling off at the moving end position of the nozzle member while shortening the cycle time by setting the rising and lowering speed of the nozzle member by the air cylinder to be high.
[0064]
In addition, since the above-described effects can be obtained with a simple configuration in which the piston and the cylinder in the air cylinder are provided with a shape characteristic and the seal member is provided, the head unit is unnecessarily increased in size when the operation is performed, or the weight is significantly increased. Does not accompany the increase.
[0065]
Further, the operation order of the housing by the motor and the nozzle member by the air cylinder is switched according to the type of the electronic component.ForThis makes it possible to mount components more appropriately.
[Brief description of the drawings]
FIG. 1 is a schematic plan view of an entire surface mounter according to an embodiment of the present invention.
FIG. 2 is a front view showing a configuration of a head unit in the mounting machine.
FIG. 3 is a side view of the head unit.
FIG. 4 is a cross-sectional view of a main part showing a nozzle member and a lifting / lowering drive mechanism thereof.
FIG. 5 is a bottom view of the head unit.
FIG. 6 is a partial sectional view showing a structure of a nozzle member.
FIGS. 7A, 7B and 7C are cross-sectional views showing the operation of the air cylinder when the nozzle member descends.
FIGS. 8A, 8B and 8C are cross-sectional views showing the operation of the air cylinder when the nozzle member is raised.
FIG. 9 is a circuit diagram of an air supply system for an air cylinder.
FIGS. 10A and 10B are flowcharts showing control at the time of component suction and component mounting when a standard chip component is to be processed;
FIGS. 11A and 11B are flowcharts showing control at the time of component suction and component mounting when processing specially shaped components and the like;
FIGS. 12A and 12B are flowcharts showing control at the time of component suction and component mounting when components requiring high precision mounting are to be processed;
[Explanation of symbols]
5 Head unit
20 Nozzle member
20a nozzle shaft
20b nozzle holder
20c nozzle
22 Housing
25 Air cylinder
26 Nozzle guide
27,29 Spring
28 Bearing
33 piston
33a sleeve
34 Upper pressure chamber
35 Lower pressure chamber
36, 37 ports
38a, 38b Small diameter part
39a, 39b Seal member
40a, 40b Inner frame
41a, 41b subport
42, 43 Cushion room

Claims (1)

A head unit movable across a component supply unit and a component mounting unit, a surface mounter including a nozzle member that sucks an electronic component and an air cylinder that drives the nozzle member up and down.
The head unit is provided with a housing that is driven up and down by a motor, and the nozzle member and the air cylinder are mounted on the housing, and the raising and lowering operation of the housing by the motor and the raising and lowering operation of the nozzle member by the air cylinder are used together. Thereby, the nozzle member is configured to move up and down,
Before SL air cylinder, a piston connected to the nozzle member, the upper and lower piston has a pair of pressure chambers, is composed of a cylinder with an air supply and discharge port respectively to the pressure chambers, the cylinder least In one pressure chamber, a narrow tube portion is formed on the moving end side of the piston, and the air supply / discharge port is opened in the narrow tube portion. A small diameter portion that can be inserted into the small cylinder portion is provided, and either the small cylinder portion of the cylinder or the small diameter portion of the piston is provided between the small cylinder portion and the small diameter portion when the small diameter portion is inserted into the small cylinder portion. Sealing means for sealing the piston, the sealing means is configured to achieve the sealing before reaching the moving end position of the piston ,
Further, the air supply / discharge system for the air cylinder is provided with an operation speed switching valve that enables switching of the elevation drive speed of the nozzle member between low speed and high speed,
Control means for driving and controlling the motor and the operating speed switching valve is provided to switch the operation sequence of the motor and the air cylinder and the nozzle elevating drive speed according to the type of electronic component sucked by the nozzle member,
The control means includes a first elevating mode in which the electronic component is sucked and mounted by moving the nozzle member up and down with respect to the housing at a high speed after lowering the housing. On the other hand, a second elevating mode in which the electronic component is sucked and mounted by moving the nozzle member at a low speed, and the electronic component is sucked and mounted by lowering the housing after lowering the nozzle member with respect to the housing at a low speed. Then, it is configured to selectively execute any one of a third elevating mode in which the housing is raised and the nozzle member is raised at a low speed with respect to the housing.
A surface mounting machine characterized by the above.

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