JP2021170661A - Inspection apparatus - Google Patents

Abstract

To prevent scattering of a component after measurement of electrical characteristics.SOLUTION: An inspection apparatus is structured so that air is supplied to a component with electrical characteristics measured by an air supply device. Scattering of a component by air supply is prevented by a cover part.SELECTED DRAWING: Figure 3

Description

The present invention relates to an inspection device that inspects parts mounted on a circuit board.

Patent Documents 2 and 3 describe an inspection device including a probe and measuring the electrical characteristics of a component by contact with the probe. Patent Document 1 describes an inspection device that measures electrical characteristics by sandwiching a component placed on a holding table from both ends. In this inspection device, air is supplied from the air outlet 28 along the V-groove of the holding table, and the measured parts on the V-groove are sent to the introduction port 7'. Then, the defective product is discarded, and the non-defective product is used for mounting on the circuit board.

Special Publication No. 52-30703 Jikkenhei 1-76100 Gazette International Publication No. 2014/155657 Pamphlet

An object of the present invention is to prevent scattering of parts after measuring the electrical characteristics in an inspection device capable of automatically measuring the electrical characteristics of the parts.

Means, actions and effects to solve problems

In the inspection device according to the present invention, air is supplied by the air supply device to the parts whose electrical characteristics have been measured. The cover portion prevents the parts from scattering due to the air supply.

It is a perspective view of the mounting machine including the inspection apparatus which is one Embodiment of this invention. It is a perspective view of the main part of the inspection apparatus. It is sectional drawing of the main part of the said inspection apparatus. It is a partial plan view of the said inspection apparatus. It is an air circuit diagram included in the said inspection apparatus. It is a figure which conceptually shows the control device of the said mounting machine. (a) It is a flowchart which shows the LCR measurement program stored in the storage part of the said control device. (b) It is a time chart when LCR is measured by the above inspection apparatus. It is a flowchart which shows the component suitability determination program stored in the storage part of the control device. It is a figure which shows the operation of the said inspection apparatus. It is a diagram showing (a) an initial state, (b) a diagram showing a clamp state, (c) a diagram showing a measurement state, and (d) a diagram showing a disposal state. It is a perspective view seen from the angle different from FIG. 2 of the said inspection apparatus.

Embodiment of the invention

Hereinafter, a mounting machine including an inspection device according to an embodiment of the present invention will be described in detail with reference to the drawings.
The mounting machine shown in FIG. 1 mounts components on a circuit board, and includes a device main body 2, a circuit board transfer holding device 4, a component supply device 6, a head moving device 8, and the like.
The circuit board transport holding device 4 transports and holds the circuit board P (hereinafter, abbreviated as the substrate P) in a horizontal posture. In FIG. 1, the transport direction of the substrate P is the x direction, and the substrate P The width direction is the y direction, and the thickness direction of the substrate P is the z direction. The y-direction and the z-direction are the front-rear direction and the up-down direction of the mounting machine, respectively. These x-direction, y-direction, and z-direction are orthogonal to each other. The component supply device 6 supplies electronic components (hereinafter, abbreviated as components) s mounted on the substrate P, and includes a plurality of tape feeders 14 and the like. The head moving device 8 holds the mounting head 16 and moves it in the x, y, and z directions, and the mounting head 16 has a suction nozzle 18 that sucks and holds the component s.

Reference numeral 20 indicates a camera. The camera 20 captures the component s held by the suction nozzle 18, and whether or not the component s is to be mounted on the circuit board P based on the image captured by the camera 20. It is judged. Reference numeral 22 indicates an inspection device. The inspection device 22 measures and inspects the electrical characteristics of the component s. The electrical characteristics of the part s are measured, and whether or not the measured electrical characteristics match the information (electrical characteristics) about the part s included in the JOB information, that is, the part to be used for the next work. It is determined whether or not the electrical characteristics of s match.
The electrical characteristics of the component s correspond to L (inductance), C (capacitance), R (resistance), Z'(impedance), and the like, and one or more of these are measured by the inspection device 22.

The inspection device 22 is provided on the main body of the circuit board transfer holding device 4 via the trash can 26. The trash can 26 and the inspection device 22 are connected by a disposal passage 28, and the component s whose electrical characteristics have been measured is housed in the trash can 26 via the disposal passage 28. The inspection device 22 is provided in the trash can 26 so that the height can be adjusted. As shown in FIGS. The base portion 30 and the main body 29 are integrally held so as to be able to move up and down. Further, the main body 29 and the base portion 30 are provided with openings 29a and 30a that can communicate with the disposal passage 28, respectively (see FIGS. 3 and 4).
As shown in FIGS. A pair of stylus 37 consisting of a pair of stylus 37, (iv) a holding base moving device 40 for moving the holding base 32, (v) a mover moving device 41 for moving the mover 36 closer to and away from the stator 34, and (vi) electricity. It includes an LCR detection unit 42 and the like as a target characteristic detection unit. In this embodiment, the component s has electrodes at both ends and can be gripped by a pair of stylus 37s. As the component s, for example, a so-called square chip is applicable.

The holding base 32 includes a component mounting portion 44 and a mounting portion holding body 46 that holds the component mounting portion 44. A V groove 44c is formed on the upper surface of the component mounting portion 44, and the component s is mounted. Since it has a V shape, the position of the part s is accurately determined.
The component mounting portion 44 can be made of a material that has conductivity and wear resistance and is difficult to oxidize. The component mounting portion 44 is electrically connected to the base portion 30 via a plurality of conductive members, and when the base portion 30 is grounded, the component mounting portion 44 is also grounded. In this embodiment, the component mounting portion 44 is in contact with the mounting portion holding body 46 and is fixed by the fastening portion 47, and the mounting portion holding body 46 is attached to the main body 29 with a stopper 80 (see FIG. 3). The main body 29 is fixed to the base portion 30 by the fastening portion 31. The mounting portion holding body 46, the stopper 80, the main body 29, the base portion 30, the fastening portions 31, 47 and the like have conductivity. Therefore, the component mounting portion 44 is grounded.
In this way, when the component mounting portion 44 is manufactured of a conductive material and is grounded, the static elimination of the component s mounted on the component mounting portion 44 can be performed. Further, since the component mounting portion 44 is manufactured of a material having wear resistance, it is possible to suppress the wear of the component mounting portion 44 and improve the durability. Further, the component mounting portion 44 can be made less likely to rust by being manufactured of a material in which oxidation is difficult to proceed, that is, a material in which a passivation film which is an oxide film of a metal can be formed. It is possible to make it difficult for rust to adhere to the component s, and it is possible to suppress a decrease in the measurement accuracy of the electrical characteristics of the component s. For example, the component mounting portion 44 may be manufactured of an aluminum alloy, a stainless steel material, or the like.

The stator 34 and the mover 36 have facing surfaces 34f and 36f facing each other, respectively, and the component s is gripped by the pair of facing surfaces 34f and 36f, respectively. The stator 34 is fixed to the main body 29 via the stator holder 55. The mover 36 is integrally movably held by the mover holder 56, and can be approached and separated from the stator 34. In this embodiment, the facing surface 36f has a triangular cross section and is movable along the V groove 44c. In other words, the shape of the facing surface 36f of the mover 36 is substantially corresponding to the V groove 44c, and the facing surface 36f of the mover 36, the facing surface 34f of the stator 34 and the V groove 44c of the holding base 32 are , Located at almost the same height. Therefore, regardless of whether the component s is in the V groove 44c, the component s can be gripped by the pair of facing surfaces 34f and 36f.
Further, the mover 36 is a longitudinal member extending in the y direction (movement direction) in this embodiment, and is held by the mover holder 56 at the retracted end. Further, the portion rearward from the tip portion including the facing surface 36f has a shape having no portion protruding in the x direction from the tip portion. As a result, the holding base 32 and the mover 36 can move relative to each other, and the holding base 32 moves forward of the facing surface 36f with the bottom of the V-groove 44 located below the mover 36. It is possible to move backwards.
Further, an electric circuit 58 including a pair of stylus 37 including a mover 36 and a stator 34, an LCR detection unit 42, a power supply device (not shown), and the like is formed. A current is supplied between the stator 34 and the mover 36, and the flowing current is detected, and the electrical characteristics of the component s are measured by the LCR detection unit 42 based on these relationships. The LCR detection unit 42 is not limited to the detection unit that detects L, C, and R, and can detect one or more physical quantities that represent electrical characteristics such as L, C, R, and Z'. Reference numerals 58a and 58b in FIGS. 2 to 4 are connections of the pair of stylus 37 to the electric circuit 58.

A cover portion 50 is attached to the holding base 32. The cover portion 50 includes a pair of cover plate portions 52, 54 provided on both sides of the V-groove 44c, respectively, separated from each other in the x direction. The cover plate portions 52 and 54 are provided on the stator 34 side of the holding base 32, respectively, and extend in the y direction and the z direction, that is, in the moving direction and the vertical direction of the holding base 32 and the mover 36. , The plate-shaped member forms a bent shape. The cover plate portion 52 has a groove shape in a plan view, and includes a bottom plate portion 52a and side plate portions 52b and 52c provided on both sides thereof at intervals in the x direction. The bottom plate portion 52a has a bent lower portion, an L-shape when viewed from the side, and is attached to the side surface of the component mounting portion 44 on the stator 34 side at the upper portion. Further, at the forward end position of the holding base 32, the lower portion of the bottom plate portion 52 is located above the stator holder 55, and the side plate portion 52b is located outside the stator 34 and above the stator holder 55. , The side plate portion 52c is outside the side plate portion 52b and is located outside the stator holder 55. The side plate portion 52c has a larger vertical dimension than the side plate portion 52b, and the lower end portion extends to the vicinity of the opening 29a of the main body 29. The cover plate portion 54 is attached to the mounting portion holding body 46 on the opposite side of the cover plate portion 52 with respect to the V groove 44c. The cover plate portion 54 is located outside the stator holder 55 at the forward end position of the holding base 32. The cover plate portion 54 has a shape that is bent in the vertical direction, and the lower end portion extends to the vicinity of the opening 29a of the main body 29.
Further, the dimensions of the side plate portion 52c and the cover plate portion 54 in the y direction are almost the entire space between the pair of facing surfaces 34f and 36f at least at one time when the stator 34 and the mover 36 are separated from each other. Is large enough to cover from the x direction.
As will be described later, the cover portion 50 has a function of preventing the diffusion of air and preventing the scattering of the parts s dropped by the ejection of the air.

In the member on the stator side {for example, the upper part of the stator 34 or the upper part of the stator 34 of the stator holder 55 or the main body 29}, the opening 60a of the air passage 60 facing the facing surface 36f of the mover 36 Is formed. As shown in FIG. 3, the air passage 60 includes an air ejection passage 60s extending in the y direction, an internal passage 60h formed in the main body 29, and the like. The air ejection passage 60s is inclined downward as it approaches the mover 36, and when the mover 36 is at a position away from the stator 34, the extension line k is the facing surface 36f of the mover 36. It is extended so as to reach above the portion R or within the portion R. The portion R is a portion that frequently grips the component s on the facing surface 36f of the mover 36, and can be referred to as a grip portion. The air hits the portion where the extension line k of the facing surface 36f intersects from diagonally above.
Air cylinders 64 and 70 are connected to the air passage 60. Further, an ionizer 62 is provided in a portion of the air passage 60 on the downstream side of the air cylinders 64 and 70. The ionizer 62 causes a corona discharge to ionize air, and ionized air can be supplied to the facing surface 36f.

The holding base moving device 40 includes an air cylinder 64 as a drive source fixedly provided on the main body 29 or the base portion 30. A mounting portion holding body 46 is connected to the piston rod 66 (see FIG. 5) of the air cylinder 64. The air cylinder 64 includes two air chambers 64a and 64b partitioned by a piston inside the cylinder housing, and electromagnetic waves are provided between the two air chambers 64a and 64b and the air source 68, the air passage 60, and the filter (atmosphere). A valve device 69 is provided. The solenoid valve device 69 may include one or more solenoid valves, for example, a direction switching valve and a variable throttle as shown in FIG. The direction switching valve controls the moving direction of the mounting portion holding body 46, and the variable throttle controls the moving / stopping of the mounting portion holding body 46. By communicating the air chamber 64b with the air source 68 and the air chamber 64a with the air passage 60 by the solenoid valve device 69, the holding base 32 is advanced (moved in the direction of arrow F in FIG. 3), and the air is moved. When the chamber 64b is opened to the atmosphere and the air chamber 64a communicates with the air source 68, the holding table 32 is retracted (moved in the direction of arrow B in FIG. 3).

The mover moving device 41 includes an air cylinder 70 as a drive source fixedly provided on the main body 29. A mover holder 56 that can move integrally with the mover is connected to the piston rod 71 of the air cylinder 70. The two air chambers 70a and 70b partitioned by a piston inside the housing of the air cylinder 70 are connected to the air source 68, the air passage 60, and the filter (atmosphere) via the solenoid valve device 72. The solenoid valve device 72 includes one or more solenoid valves, and may include, for example, a direction switching valve, a variable throttle, and the like. By communicating the air chamber 70b with the air passage 60 and the air chamber 70a with the air source 68 by the solenoid valve device 72, the mover 36 is retracted, the air chamber 70a is opened to the atmosphere, and the air chamber 70b is opened. Is communicated with the air source 68, so that the mover 36 is advanced.
In this embodiment, the air supply device 73 is composed of air cylinders 64 and 70, an air passage 60 (including an air ejection passage 60s), an opening 60a, a cover portion 50, an ionizer 62, and the like. The air supply device 73 is also a mover supply unit and a drive source interlocking type supply unit. Further, the facing surface 36f corresponds to the supply target surface.
The structure of the solenoid valve devices 69 and 72 is not limited to that of the present embodiment. For example, one 3-position valve may be included, or a plurality of on-off valves may be included. Further, it is not indispensable to provide the ionizer 62.

A pair of guide rods 74 and 75 extending in the y direction are provided between the mover holder 56 and the main body 29, and a pair of guide rods 74 and 75 extending in the y direction are provided between the holding base 32 and the mover holder 56. A pair of guide rods 76 and 77 are provided. One end of the guide rods 74 and 75 is connected to the mover holder 56, and the other end is slidably engaged with the main body 29. The guide rods 76 and 77 are connected to the mounting portion holder 46 at one end and slidably engaged with the mover holder 56. These guide rods 74, 75, 76, 77 make the holding base 32 and the mover 36 relative to each other in the y direction with respect to the main body 29, and the holding base 32 and the mover 36 can move relative to each other in the y direction. It is possible to move relative to.
Further, as shown in FIG. 3, a stopper 82 is provided on the stator side of the mover holder 56, and a stopper 80 is provided on the portion of the main body 29 that holds the stator holder 55. The stopper 82 defines the approach limit between the mover holder 56 and the holding base 32 (mounting portion holding body 46), and the stopper 80 is the stator 34 (main body 29) and the holding base 32 (mounting). It defines the limit of access to the portion holder 46).
In this embodiment, the guide rods 74 to 77 are shared by the holding base moving device 40 and the mover moving device 41, and the stoppers 80 and 82 can be considered to be components of the holding base moving device 40.
As shown in FIG. 3, the gap Ld between the front end portion of the stopper 82 when the mover 36 is in the retracted end position and the mounting portion holding body 46 when the holding base 32 is in the forward end position. Is the distance at which the relative movement between the mover 36 and the holding base 32 is allowed.

The mounting machine includes a control device 100. As shown in FIG. 6, the control device 100 includes a controller 102 mainly composed of a computer and a plurality of drive circuits 104. The controller 102 includes an execution unit 110, a storage unit 112, an input / output unit 114, and the like. In the input / output unit 114, a board transfer holding device 4, a component supply device 6, and a head moving device 8 each have a drive circuit 104. In addition to being connected via, the mover moving device 41, the solenoid valve devices 69, 72 of the holding base moving device 40, and the like are connected. Further, the LCR detection unit 42, the display 116, the mover position sensor 118, the holding base position sensor 120, the nozzle height sensor 122 for detecting the height of the nozzle 18, and the like are connected. A plurality of programs and tables such as the LCR detection program represented by the flowchart of FIG. 7A are stored in the storage unit 112. Further, the time is measured by the timer 124 provided in the controller 102.
In this embodiment, the case where the entire mounting machine is controlled by the control device 100 has been described, but the board transfer holding device 4, the component supply device 6, the head moving device 8, and the like are controlled by individual control devices. It can also be done.

Hereinafter, the operation of the mounting machine will be described.
When a new tape feeder 14 is set, the tape feeder 14 is replaced, etc., such as when the setup is changed, the electrical characteristics of the parts s held by the tape feeder 14 are measured, and the tape is measured. It is inspected whether the feeder 14 (or component s) is suitable. In addition, the inspection result is displayed on the display 116. If inappropriate, the tape feeder 14 is replaced.

The electrical characteristics of the component s are measured by executing the LCR measurement program represented by the flowchart of FIG. 7 (a). Further, the movements of the holding base 32 and the mover 36, and the states of the holding base position sensor 120 and the mover position sensor 118 are shown in FIG. 7 (b).
The inspection device 22 is always in the initial state shown in FIG. 9A. The mover 36 is in the retracted end position, and the holding base 32 is in the forward end position, that is, in a position in contact with the stopper 80. In this state, the holding table 32 is in a state of being grounded by internal continuity or the like. The mover 36 does not exist above the V-groove 44c of the holding base 32, and the component s can be placed on it. Further, the cover portion 50 is located on both sides (separated in the x direction) of the stator 34. Both the mover position sensor 118 and the holding base position sensor 120 are in the ON state.
In step 1 (hereinafter, abbreviated as S1; the same applies to other steps), it is determined whether or not a measurement command for the electrical characteristics of the component s has been issued. When the setup is changed, a command to measure the electrical characteristics is issued. When the measurement command is issued, the mounting head 16 is moved in S2, and for example, the component s held by the newly mounted tape feeder 14 is picked up by the suction nozzle 18 and the V-groove 44c of the holding base 32 is picked up. Can be placed on top. It can be seen that the component s is placed on the V groove 44c by lowering the suction nozzle 18 and opening the component s.

Then, when the nozzle height sensor 122 detects that the suction nozzle 18 has reached the rising end by placing the component s on the V groove 44c, the mover 36 is controlled by the solenoid valve device 72 in S3. It is advanced and the mover position sensor 118 is switched from ON to OFF. The facing surface 36f at the tip of the mover 36 is advanced along the V groove 44c of the component mounting portion 44, and the component s is clamped by the facing surface 36f and the facing surface 34f of the stator 34 {FIG. 9 (Fig. 9). b)}. _{In this embodiment, the stroke L 1} (see FIG. 3) of the mover 36 from the retracted end position to the clamping of the component s is determined in advance by the size of the clamped component s and the like. The advance of the mover 36 is stopped by controlling the variable diaphragm or the like after the advance time, which is the time required for the mover 36 to _{advance by the stroke L 1, has elapsed from the start of the advance of the mover 36.} The advance time is measured by the timer 124. The clamp state is a state in which the holding base 32 is at the forward end position, the mover 36 is advanced, and the parts s are clamped by the pair of facing surfaces 34f and 36f.

In S4, the holding base 32 is retracted under the control of the solenoid valve device 69, and the holding base position sensor 120 is switched from ON to OFF. The holding base 32 is retracted until it comes into contact with the stopper 82 {FIG. 9 (c)} and is held at that position. The stroke of the holding table 32 during that period is L ₂ (see FIG. 3).
L ₂ = Ld-L ₁
In this embodiment, the stroke L ₂ has a size equal to or greater than the set value Lx (L ₂ ≧ Lx), and the component mounting portion 44 is separated from the component s by the set value Lx or more. Accurately detect electrical characteristics such as electrostatic induction and eddy currents when a conductive member (component mounting portion 44) is located near the component s when measuring electrical characteristics. I can't. On the other hand, if the component mounting portion 44 is separated from the component s by the set value Lx or more (if the shortest distance between the component mounting portion 44 and the component s is the set value Lx or more), the component mounting portion 44 will move. It is possible to reduce the measurement error of the electrical characteristics caused by being located in the vicinity of the component s. As described above, the set value Lx is a distance at which the component mounting portion 44 does not easily affect the measurement of the electrical characteristics of the component s, and is a value obtained in advance by an experiment or the like. This state is the measurement state.
Incidentally, from the time of reverse start of the holding base 32, after the retraction time Ta holding base 32 is a time required to retract the stroke L ₂ has elapsed, the retained position of the holding table 32 by the control of the solenoid valve device 69 .. The retreat time Ta is measured by the timer 124.

In S5, it is awaited that the static elimination time, which is the set time, elapses from the time when the component s is opened by the suction nozzle 18 and placed on the V groove 44c. Each of the parts s held by the tape feeder 14 is in a state of being charged by static electricity generated due to vibration accompanying transportation of the tape feeder 14, contact with an object, or the like. The charged component s is manufactured of a conductive material and is statically eliminated by being placed on the grounded component mounting portion 44, or is statically discharged by discharging into the air. The static electricity removal time is the time required to remove the static electricity of the capacity estimated to be possessed by the part s, and can be obtained in advance by an experiment or the like, or theoretically obtained based on the size, characteristics, etc. of the part s. You can do things like that. When the elapsed time since the component s is placed on the component holding table 44 reaches the static elimination time, the determination in S5 becomes YES, and the electrical characteristics of the component s are measured in S6.
Then, when the measurement time, which is the time required for measuring the electrical characteristics, elapses, S7 is executed, and the measurement time may be a time determined by the type of the component s or the like, or a constant time. In any case, it is acquired and stored in advance.

When the measurement time elapses and the measurement of the electrical characteristics of the component s is completed, the mover 36 is retracted under the control of the solenoid valve device 72 in S7. When the retracted end is reached, the mover position sensor 118 is turned on. In S8, the holding base 32 is retracted by the control of the solenoid valve device 69 {FIG. 9 (d)}. The stroke from the measurement state to the contact of the holding base 32 with the stopper 82 of the mover 36 at the retracted end position is L ₁ . Therefore, it can be seen that the holding base 32 has come into contact with the stopper 82 after the retreat time Tb, which is the time required _{for the holding base 32 to retreat by the stroke L 1, has elapsed.} As shown in FIG. 9D, the holding base 32 is located behind the facing surfaces 36f of the mover 36 and does not exist below between the pair of facing surfaces 34f and 36f. This state is the disposal state.
When the holding base 32 is retracted until it comes into contact with the stopper 82, in S9, under the control of the solenoid valve device 69, the air chamber 64b is communicated with the air source 68 in the air cylinder 64, and the air chamber 64a is communicated with the air passage 60. Communicate. When the holding base 32 is advanced and hits the stopper 80, the holding base position sensor 120 is turned on. The holding base 32 is located between the pair of facing surfaces 34f and 36f (the V groove 44 is located below between the facing surfaces 34f and 36f), and the space is above the V groove 44c. Therefore, the component s can be placed. This state is the initial state.

By separating the facing surface 36f of the mover 36 from the facing surface 34f of the stator 34, the parts s gripped between them are released. Further, when the mover 36 is retracted, the air chamber 70a of the air cylinder 70 is communicated with the air passage 60, and the cover plate portions 52 and 54 are in the x direction of the space between the pair of facing surfaces 34f and 36f, respectively. Located on both sides of. Further, since the holding base 32 is moved to the rear of the facing surfaces 36f of the mover 36, it does not exist below between the pair of facing surfaces 34f and 36f, and an opening is provided between the pair of facing surfaces 34f and 36f. It communicates with 29a, 30a and the disposal passage 28.
As the mover 36 retracts, the air discharged from the air chamber 70a is supplied from the opening 60a to the facing surface 36f of the mover 36 from diagonally above, but the space to which the air is supplied, in other words, a pair. The space between the facing surfaces 34f and 36f is covered by the cover portion 50 from the x direction. The air mainly hits the facing surface 36f and then flows downward along the facing surface 36f. Therefore, even if the component s does not fall from the facing surface 36f and adheres to the portion R, it can be dropped satisfactorily. Further, since the air flows in a spiral shape inside the cover portion 50, even if the component s is attached to the facing surface 34f of the stator 34, it can be dropped. Further, the parts s that have fallen from the facing surfaces 34f and 36f and are placed on the holding table 32 can also be dropped by the air, but if the parts s are placed on the V groove 44 and are not dropped by the air. Even if there is, it can be reliably dropped by advancing the facing surface 36f of the mover 36 as the holding base 32 retracts. As described above, in the present embodiment, the discarded state can be considered as a state in which the parts s are satisfactorily dropped.
The parts s that have fallen from the pair of facing surfaces 34f and 36f are satisfactorily stored in the trash can 26 through the openings 29a and 30a and the disposal passage 28.

Further, by providing the cover portion 50, it is possible to prevent the dropped parts s from scattering. Since the side plate portion 52c of the cover plate portion 52 and the lower end portion of the cover plate portion 54 extend to the vicinity of the opening 29a of the main body 29, the parts s are satisfactorily accommodated in the trash can 26 from the opening 29a through the disposal passage 28. be able to. On the other hand, when ionized air is supplied, the facing surfaces 36f and 34f of the mover 36 and the stator 34 can be electrically neutralized, and the measurement accuracy of the electrical characteristics of the next component s can be improved. Can be improved.
Further, in the air cylinder 64, the air chamber 64a is communicated with the air ejection passage 60s when the holding base 32 is advanced (S9). Even when shifting from the discarded state to the initial state, air can be supplied to the facing surface 36f of the mover 36, and the static elimination of the facing surface 36f of the mover 36 can be satisfactorily performed.

On the other hand, the measured electrical characteristics are compared with the electrical characteristics included in the JOB information, and it is determined whether or not the component s should be used for the work (JOB) to be performed, and the determination result is obtained. Is displayed on the display 116.
In S21, the measured value of the electrical characteristic of the component s is acquired, and in S22, the corresponding information is read from the JOB information of the next JOB. In S23, these are compared and it is determined whether they match. The determination result is displayed on the display 116 regardless of whether they match or do not match. If there is a discrepancy, work such as replacing with an appropriate tape feeder is performed.

As described above, in this embodiment, the component mounting portion 44 is made of a conductive material and is grounded. As a result, the static elimination of the component s mounted on the component mounting portion 44 can be satisfactorily performed before the measurement of the electrical characteristics. On the other hand, when the component s is charged, it is difficult to measure the impedance of the component s. On the other hand, in this embodiment, since the static elimination of the component s is performed well, the impedance of the component s can be measured satisfactorily.
Further, the component s can be dropped into the disposal passage 28 in parallel with the retracting of the mover 36, as compared with the case where the retracting of the mover and the delivery of the component s are performed in different steps. The time required to measure the electrical characteristics can be shortened.

As described above, in this embodiment, the movement is controlled by the portion of the controller 102 that stores S4, 7, and 8 of the LCR measurement program, the portion that executes the controller 102, the timer 124, the mover position sensor 118, the holding base position sensor 120, and the like. A device and a relative movement control device are configured. Further, the measurement control unit is composed of the part that stores S4, the part that executes S4, and the like, and the disposal control unit is composed of the part that stores S8, the part that executes, and the like, and the part that stores S9 and executes. The preparation control unit is composed of the parts to be used. The movement control device is also a holding base movement control device and a relative movement control unit.
Further, the air cylinder 70 corresponds to the cylinder for the mover, and the air cylinder 64 corresponds to the cylinder for the holding base. The air supply device 73 is also a mover supply unit and a drive source interlocking type supply unit. Further, the electrical characteristic acquisition device is composed of a pair of stylus 37, an electric circuit 58 including an LCR detection unit 42, a portion of the controller 102 that stores S6, a portion that executes the S6, and the like.
Further, S3 corresponds to the clamping process, S4 and 6 correspond to the measuring process, S7 and 8 correspond to the disposal process, and S9 corresponds to the preparation process.

Both of the pair of stylus can be moved, and the holding base can be fixed to the main body. Even in that case, the holding table can be separated from the parts s by a set value or more by grasping the parts s mounted on the holding table by a pair of stylus and moving the pair of stylus. ..
Further, the holding table can be made movable in the vertical direction. Even in that case, the holding table can be separated from the component s by a set value or more while the component s is clamped by the pair of stylus.
Further, an air ejection passage may be provided on the side of the main body 29 of the inspection device 22 so as to have an opening generally open in the x direction. In other words, one of the cover plate portions 52 and 54 may be eliminated (for example, the cover plate portion 54 may be eliminated), and an air ejection passage having an opening in the x direction may be provided on the eliminated side. As a result, the air is supplied toward the cover plate portion 52 along the facing surfaces 34f and 36f (surfaces extending in the xz direction), whereby the air adheres to the pair of facing surfaces 34f and 36f. It is possible to drop the removed parts s.
Further, after measuring the electrical characteristics of the component s, the holding base 32 can be retracted (for example, simultaneously retracted) as the mover 36 retracts. The state in which the holding base 32 and the mover 36 are retracted can be regarded as a discarded state.
Further, the mover position sensor 118 and the holding base position sensor 120 are not indispensable. For example, the solenoid valve devices 69 and 72 can be controlled by measurement by the timer 124. In addition to the embodiments described in the above embodiment, the present invention can be implemented in various modifications and improvements based on the knowledge of those skilled in the art, such that the air supply device is not indispensable.

22: Inspection device 26: Recycle bin 28: Disposal passage 29: Main body 29a: Opening 30:
Base part 30a: Opening 31: Fastening part 32: Holding base 34: Stator 36: Movable child
34f, 36f: Facing surface 40: Holding base moving device 41: Mover moving device 42: LCR detection unit 44: Parts mounting part 44c: V groove 50: Cover part 72: Air supply device 100: Control device 118: Mover Position sensor 118: Holding base position sensor 124: Timer

Claimable invention

(1) An inspection device included in a mounting machine that picks up parts supplied by a parts supply device and mounts them on a circuit board.
A holding table that can hold parts and
A pair of stylus that can be approached and separated from each other and can measure the electrical characteristics of the component by sandwiching the component.
A holding table moving device for moving the holding table and
From a clamped state in which the holding table movement control device includes a holding table movement control device that controls the holding table moving device, and the holding table movement control device grips the component held by the holding table. An inspection device including a measurement control unit that separates a holding table from the component by a set value or more to bring the electrical characteristics of the component into a measurable measurement state.
The holding table may be movable in a direction parallel to the approaching / separating directions of the pair of stylus, or may be movable in a direction in which they intersect. The set value can be, for example, a distance at which the influence of the holding table is difficult to measure the electrical characteristics of the component when the holding table has conductivity.
(2) The inspection device according to item (1), wherein the holding table has conductivity.
(3) The pair of stylus includes a pair of facing surfaces that face each other and can contact the component, and the pair of facing surfaces are brought close to each other to hold the component and separate the components from each other. The above parts are released by
When the holding table moving device moves the holding table from the measurement state, the holding table is placed in a disposal state in which the holding table does not exist below between the pair of facing surfaces separated from each other. The inspection device according to paragraph (1) or (2), which includes.
(4) An initial stage in which the holding table movement control device moves the holding table downward between the pair of facing surfaces separated from each other from the discarded state, and the holding table can hold the component. The inspection device according to item (3), which includes a preparatory control unit to be in a state.
(5) Any one of items (1) to (4), wherein the mounting machine includes a disposal passage connected to the inspection device, and the main body of the inspection device has an opening communicating with the disposal passage. The inspection device described in 1.
The position and size of the opening can be determined so that it is at least in the downward opening state between the pair of facing surfaces in the disposal state.
(6) Acquisition of electrical characteristics in which the inspection device supplies a current between the pair of stylus and detects a current flowing between the pair of stylus to acquire the electrical characteristics of the component. Delayed measurement in which the electrical characteristic acquisition device including the device starts measuring the electrical characteristics of the component when a set time or more has elapsed from the time when the component is placed on the holding table. The inspection apparatus according to any one of items (1) to (5), which includes a part.
The set time can be, for example, the static elimination time, which is the time required for static elimination of the parts. The static elimination time may be a time determined by the parts or a predetermined time regardless of the parts.
The time when the parts are placed on the holding table can be set as the static elimination time.
(7) The pair of stylus includes a stator fixed to the main body and a mover that can move relative to the stator.
The inspection device includes a mover moving device that moves the mover with respect to the stator, and a mover movement control unit that moves the pair of stylus to approach and separate from each other by controlling the mover moving device. The inspection device according to any one of paragraphs (1) to (6) including.
(8) The inspection device according to item (7), wherein the inspection device includes a connecting mechanism for connecting the mover and the holding table so as to be relatively movable with each other.
For example, the mover may have a longitudinal shape extending parallel to the moving direction of the mover. Further, the holding base may be located in front of the tip of the mover or in the rear.
(9) The holding table has a V-groove having a V-shaped cross section, and the cross section of at least one tip of the pair of stylus has a triangular shape corresponding to the V-groove. The inspection device according to any one of items (1) to (8).

(10) An inspection device included in a mounting machine that picks up parts supplied by a parts supply device and mounts them on a circuit board.
A holding table that can hold parts and
A pair of stylus that can be approached and separated from each other and can measure the electrical characteristics of the component by sandwiching the component.
A relative moving device that moves the pair of stylus and the holding table relative to each other,
The component and the relative movement control device include the relative movement control device for controlling the relative movement device, and the relative movement control device holds the component and the component from a clamped state in which the pair of stylus grips the component held by the holding table. An inspection device including a measurement control unit that keeps a holding table away from a set value by a set value or more to bring the electrical characteristics of the component into a measurable measurement state.
The technical features described in any one of paragraphs (1) to (9) can be adopted for the inspection apparatus described in this section.
The relative moving device is a device that (a) fixes the holding table and moves a pair of stylus, or (b) fixes one of the pair of stylus and moves the other of the pair of stylus and the holding table. It can be used as a device for making it. In the case of (a), for example, in a state where the parts held on the holding table are clamped by the pair of stylus, the pair of stylus is moved relative to the holding table, and the parts and the holding table are set. This applies when the distance is greater than or equal to the value.

(11) Parts supplied by the parts supply device are picked up and installed on a mounting machine to be mounted on a circuit board. An inspection method for inspecting the electrical characteristics of the component in an inspection device including a pair of stylus capable of measuring the electrical characteristics of the component by sandwiching the component.
A clamping process in which a pair of stylus grips a part held on the holding table, and
An inspection method comprising a measurement step of measuring the electrical characteristics of the parts by separating the holding table from the parts gripped by the pair of stylus by a set value or more.
The inspection method described in this section may be performed in the inspection apparatus according to any one of paragraphs (1) to (10).
(12) After the execution of the measurement step, the pair of stylus is separated from each other, and the holding table is retracted from the lower region between the facing surfaces of the pair of stylus facing each other, and a disposal step.
The inspection method according to item (11), which includes a preparatory step of intruding the holding table downward between the facing surfaces of the pair of stylus facing each other to bring the parts into a holdable initial state.
In the disposal step, the pair of stylus may be separated and the holding table may be retracted in order or in parallel.

(13) An inspection device included in a mounting machine that picks up parts supplied by a parts supply device and mounts them on a circuit board.
A holding base that has conductivity and holds parts,
An inspection device including an electrical characteristic acquisition device that grips the component held by the holding table and acquires the electrical characteristics of the component in a state where the component is separated from the holding table.
The inspection apparatus described in this section can adopt the technical features described in any one of paragraphs (1) to (12).

(14) When the pair of stylus are brought close to each other, the pair of facing surfaces sandwich the component, measure the electrical characteristics of the component, and are separated from each other, whereby the pair of facing surfaces are separated from each other. The above parts are released from
Items (1) to (13) include an air supply device that supplies air to a supply target surface that is at least one of the pair of facing surfaces when the pair of stylus is separated from each other. The inspection device according to any one of the items.
The case where the pair of stylus is separated corresponds to the time when they are separated from each other, a part or the whole stroke while they are separated, the time when the separation starts, the time when the separation ends, and the like.
(15) The inspection device according to item (14), wherein the air supply device includes an ionizer that ionizes the air and supplies the ionized air to the supply target surface.
(16) The inspection device according to item (14) or (15), wherein the air supply device includes an air passage having an opening facing the supply target surface.
When the supply target surface is one of the pair of facing surfaces, one opening facing the one supply target surface is provided, and when the supply target surface is both of the pair of facing surfaces, each of them is provided. Two openings are provided facing each other.
(17) The inspection device according to item (16), wherein the air passage includes an air ejection passage that is inclined downward as it approaches the supply target surface.
(18) The inspection device according to (17), wherein the inclination angle of the air ejection passage is an angle at which the air hits above the portion of the supply target surface that grips the component.
(19) The pair of stylus includes a stator fixed to the main body and a mover capable of approaching / separating the stator.
Item (14) to (14) to (14), wherein the air supply device includes a mover supply unit that supplies the air to the facing surface of the mover, which is the supply target surface, when the mover is separated from the stator. 1
The inspection device according to any one of items 8). (20) The inspection device includes a mover cylinder, and includes a mover moving device that moves the mover closer to and further from the stator by operating the mover cylinder.
The air supply device includes a drive source interlocking supply unit that supplies air flowing out of the mover cylinder as the mover separates from the stator to the facing surface of the mover (1).
The inspection device described in 9). (21) The inspection device according to any one of (1) to (20), wherein the inspection device includes a cover portion that covers the pair of facing surfaces in a state of being separated from each other.
The cover portion covers most of the space between the pair of facing surfaces, and does not necessarily have to cover the entire space between the pair of facing surfaces, even if the cover portion covers with some gaps. good.
It is desirable to cover the entire space between the pair of facing surfaces from both sides at least for a period of time when the pair of facing surfaces are separated from each other. (22) The item (21), wherein the cover portion is attached to the holding base and covers most of the space between the pair of facing surfaces from the side in a state where the holding base is in the retracted end position. Inspection equipment.

Claims (3)

An inspection device that is installed in a mounting machine that picks up parts supplied by a parts supply device and mounts them on a circuit board, and measures the electrical characteristics of the parts.
An air supply device that supplies air to the component after the electrical characteristics have been measured, and
An inspection device including a cover portion for preventing scattering of the parts due to the supply of air from the air supply device. The inspection device further comprises a pair of facing surfaces that are brought close to each other to sandwich the component and are separated from each other to release the component.
The inspection device according to claim 1, wherein the cover portion covers between the pair of facing surfaces in a separated state. The air supply device supplies air in one direction and
The inspection device according to claim 1 or 2, wherein the cover portion extends over a vertical surface parallel to the one direction.

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