JP4597804B2 - Surface mount machine - Google Patents

Description

  The present invention provides a surface mounting machine, in particular, a component suction nozzle that can be replaced with respect to a mounting head, and can be replaced with another nozzle housed in a nozzle replacement unit as necessary. The present invention relates to a surface mounting machine configured as described above.

  Conventionally, a mounting head movable between a component supply unit and a printed circuit board positioned at a predetermined work position has been provided, and a component suction nozzle attached to the tip of the head is used to absorb the component from the component supply unit. A surface mounter for mounting on a printed circuit board is known.

Further, in this type of surface mounting machine, the nozzle is detachably attached to the mounting head, and a nozzle station (nozzle replacement unit) containing the replacement nozzle is disposed in the movable area of the mounting head. In addition, there is also known one in which the nozzle is replaced during the mounting operation according to the type of the mounted component (for example, Patent Document 1).
JP 2002-246800 A

  The surface mounter is configured to switch between negative pressure supply and positive pressure supply to the nozzle tip, while negative pressure is supplied to the nozzle tip during component suction, while promoting negative pressure breakage during component mounting. A positive pressure is supplied to the tip of the nozzle.

  By the way, it is empirically known that when negative pressure is supplied to the tip of the nozzle as described above, the nozzle sucks foreign matter, dust, and the like due to its action and adheres to the nozzle and the passage leading to the nozzle. Such adhesion of foreign matter or the like sometimes prevents proper supply of negative pressure and positive pressure, and induces component adsorption mistakes and mounting mistakes, and therefore must be prevented in advance. Therefore, it is conceivable that a predetermined cleaning space is provided, and a positive pressure is supplied to the tip of the nozzle in the space to forcibly discharge foreign matters and the like, thereby preventing the above trouble.

  On the other hand, in recent years, the diversification of parts has further progressed, and the types of nozzles have been diversified accordingly. Therefore, it is considered that the frequency of nozzle replacement is increased in the surface mounting machine in which the mounting operation is performed while the nozzle station is provided and the nozzle is automatically replaced as described above.

  Therefore, it is conceivable that the tact time will be greatly lost if an attempt is made to clean the nozzles as described above while performing the nozzle replacement operation at the nozzle station.

  The present invention has been made in view of the above circumstances, and while proceeding with the mounting operation while replacing the nozzle in the nozzle station with respect to the head, during this mounting operation, the cleaning operation of the nozzles and the like as described above The purpose is to be able to implement efficiently.

In order to solve the above-described problem, the present invention is provided with one or a plurality of nozzles including a replaceable nozzle in a movable head, and a negative pressure for sucking a component through an internal passage of the head with respect to the nozzle. In a surface mounter configured to be selectively supplied with air blow as a positive pressure, a nozzle replacement unit in which a replacement nozzle is housed in the movable region of the head is provided, and the nozzle replacement unit or near the cleaning unit of the nozzle and the inner passage with an exhaust passage for exhausting the air blow ejected from the nozzles set in the set portion of the setting portion Toko to set nozzle attached to said head is provided, the cleaning unit includes a nozzle insertion hole communicating with the exhaust passage as the mounting portion, the this nozzle insertion hole Roh The nozzle inserted into the nozzle insertion hole through the air passage has an air passage that opens in the middle of the nozzle insertion hole. The air blow is applied from the outside to the above (claim 1).

According to this apparatus, the nozzle mounted on the head is disposed in the cleaning unit (set unit), and in this state, air blow is supplied to the tip of the nozzle through the internal passage of the head, so that foreign matter or dirt adhered to the inside of the nozzle or the like. Is removed and discarded through the exhaust passage. Since such a cleaning unit is provided at or near the nozzle replacement unit, the nozzles and the like are efficiently cleaned using the timing of nozzle replacement as described in detail in the embodiment of the invention. Can be done.
Further, according to this apparatus, since the air blow is discharged in a state where the nozzle is inserted into the nozzle insertion hole, for example, for a nozzle having a tip shaft shape, the air blow to the outside is prevented, and the nozzle etc. It becomes possible to proceed with the cleaning work.
Further, according to this apparatus, the air blow is supplied to the nozzle from the outside of the nozzle separately from the air blow supplied to the nozzle tip through the internal passage of the head, so that it is supplied through the inside of the nozzle, for example, the edge of the nozzle opening. Thus, it is possible to suitably remove deposits that are difficult to remove by air blow.

In the above apparatus, it is preferable that the cleaning unit is provided in the nozzle replacement unit (Claim 2 ), and a storage hole of a replacement nozzle provided in the nozzle replacement unit is also used as the nozzle insertion hole. It is more preferable (Claim 3 ).

  According to this apparatus, the space occupied by the cleaning unit can be suppressed and the cost can be reduced as compared with the configuration in which the cleaning unit is provided independently. In particular, when the replacement nozzle housing hole is also used as the nozzle insertion hole, the space efficiency is improved because it is not necessary to provide a dedicated insertion hole as the nozzle insertion hole.

Further, in the above-described apparatus, by inserting the nozzle into the nozzle insertion hole and discharging an air blow through the internal passage and the air passage of the nozzle, the parts adsorbed on the nozzle are separated from the nozzle. It is as discarded, wherein the intermediate portion of the exhaust passage, trapping member for trapping waste components separated from said nozzle while passing through the exhaust of the air blow preferably Ru arranged assessment (claim 4).

  According to this apparatus, the cleaning part of the nozzle can also be used as a waste space for waste parts (defective parts).

According to the surface mounter according to the first and second aspects of the present invention, since the cleaning unit for cleaning the internal passages of the nozzle and the head by air blow is provided in the nozzle replacement unit or in the vicinity thereof, the nozzle with respect to the head While performing the mounting operation while performing the replacement, the nozzles and the like can be efficiently cleaned using the nozzle replacement timing. Therefore, a series of mounting operations can proceed smoothly while minimizing the tact time loss associated with cleaning of the nozzles and the like. In addition, according to the surface mounter of the third aspect , since the storage hole of the replacement nozzle of the nozzle replacement unit is also used as the nozzle insertion hole, a rational apparatus configuration that suppresses the space occupied by the cleaning unit is achieved. The

  Embodiments of the present invention will be described with reference to the drawings.

  1 and 2 schematically show a surface mounter according to the present invention. In these drawings, a substrate transporting conveyor 2 is disposed on a base 1 of a surface mounting machine (hereinafter abbreviated as a mounting machine), and a printed circuit board 3 (hereinafter simply referred to as a board 3) is disposed on the conveyor 2. ) Is transported and stopped at a predetermined mounting work position, and is held by a substrate holding means such as a push-up pin or a substrate clamp device (not shown). In the following description, the conveyance direction of the substrate 3 by the conveyor 2 is the X axis direction, the direction orthogonal to the X axis on the horizontal plane is the Y axis direction, and the direction orthogonal to the X axis and the Y axis is the Z axis direction. I will proceed.

  On both sides of the conveyor 2, component supply units 4 for supplying electronic components to be mounted on the substrate 3 are provided. In these component supply units 4, multiple rows of tape feeders 4 a are arranged in the X-axis direction. Each tape feeder 4a is detachably mounted with a reel on which a tape on which small chip components such as ICs, transistors, capacitors, etc. are stored and held at predetermined intervals is wound. The tape is picked up by the head unit 5 described later while picking up the tape intermittently to the component pick-up section.

  Above the base 1, a component mounting head unit 5 is further provided. The head unit 5 is movable in the X-axis direction and the Y-axis direction within a certain area so that the components can be sucked from the component supply unit 4 and mounted on the substrate 3. That is, the support member 11 of the head unit 5 is disposed on the base 1 so as to be movable along the fixed rail 7 in the Y-axis direction, and the head unit 5 is guided on the support member 11 in the X-axis direction. It is supported so that it can move along. The support member 11 is screwed to the ball screw 8 driven by the Y-axis servo motor 9 so that the support member 11 is moved in the Y-axis direction while being driven by the X-axis servo motor 15. When the head unit 5 is mounted on the ball screw 13, the head unit 5 is configured to move in the X-axis direction.

  The head unit 5 is mounted with a plurality of mounting heads 20 for picking up components and mounting them on the substrate 3. In this embodiment, the two mounting heads 20 are arranged in the X-axis direction. It is mounted with.

  Each head 20 has a hollow nozzle shaft having a passage for supplying negative pressure and air blow (positive pressure) therein, and is supported by the frame of the head unit 5 via the nozzle shaft. Yes. The nozzle shaft is connected to an elevating mechanism using a Z-axis servomotor (not shown) as a drive source and connected to a rotation mechanism using an R-axis servomotor (not shown) as a drive source. The mounting head 20 is configured to move in the vertical direction (Z-axis direction) relative to the head unit 5 and to rotate around the nozzle shaft (movement in the R-axis direction).

  A nozzle assembly block 22 is assembled to the front end (lower end) of each mounting head 20 via a holder 21.

  As shown in FIG. 6 (a), the nozzle assembly block 22 is a member provided with a plurality of nozzles 23a to 23e and a nozzle holder 24 in a radial pattern, and is attached to the holder 21 via a horizontal axis (horizontal axis) 21a. It is rotatably supported and is rotationally driven by a block drive mechanism (not shown). That is, one of the nozzles 23a to 23e and the nozzle holder 24 (hereinafter referred to as the nozzles 23a to 23e, etc. unless otherwise distinguished) is selectively used by the rotation of the nozzle assembly block 22. The position is set at a position where the nozzle or the like is directed downward (the position of the nozzle holder 24 in FIG. 6A).

  As shown in FIG. 2, the nozzle shaft of each mounting head 20 is connected to a compressor 29 via an ejector 26, a valve 27, etc., and negative pressure or air blow (positive pressure) is applied to the internal passage of the nozzle shaft and Through the internal passage of the holder 21, the nozzles 23a to 23e set at the use position are supplied.

  Specifically, the nozzle assembly block 22 is formed with independent passages communicating with the nozzles 23a to 23e and the nozzle holder 24, respectively, and the nozzles set at the use position among the nozzles 23a to 23e and the like. An internal passage on the holder 21 side is provided so as to communicate with passages such as 23a to 23e. When the negative pressure is supplied, the exhaust valve 28 attached to the ejector 26 is opened. In this state, air is supplied from the compressor 29 to the ejector 26 and is exhausted to the outside, whereby the inside of the nozzle shaft is caused by the action of the ejector 26. As a result, the negative pressure is supplied to the nozzles 23a to 23e and the like at the use position through the internal passage of the nozzle shaft. Further, when supplying the air blow (positive pressure), the exhaust valve 28 is closed, and in this state, the air is supplied from the compressor 29 to the ejector 26 so that the air is introduced into the nozzle shaft as a result. Air blow is supplied to the nozzles 23a to 23e in the use position through the internal passage of the nozzle shaft.

  At the time of taking out the parts from the tape feeder 4a, negative pressure is supplied to the tips of the nozzles 23a to 23e and the like at the use position, and the suction of the parts is performed by this negative pressure, while the parts are mounted and the defective parts are discarded. The air blow (positive pressure) is supplied to the tips of the nozzles 23a to 23e and the like at the use position to accelerate the release of negative pressure, and the air blow serves as a back pressure and the nozzles 23a to 23e at the use position and the like. The removal of parts from the vehicle is promoted. Also, during the cleaning operation described later, the nozzles 23a to 23e and the like to be cleaned are positioned at the use position, and air blow is supplied in the same manner, whereby the internal passage of the mounting head 20 (that is, the nozzle shaft) And the nozzles 23a to 23e and the like are cleaned. In FIG. 2, the supply system for negative pressure and air blow (positive pressure) is shown only for one mounting head 20, but the ejector 26, the compressor 29, and the like are similarly connected to the other mounting heads 20. Switching between negative pressure supply and air blow (positive pressure) supply is performed individually.

  As shown in FIG. 6A, the nozzle holder 24 mounted on the nozzle assembly block 22 includes a shaft portion 24a for fitting and mounting the nozzle, and a pair of plate springs 24b for holding the nozzle. As shown in FIG. 6B, the nozzle 25 (hereinafter, all the nozzles (replaceable nozzles attached to the nozzle holder 24) are indicated by reference numeral 25) are fitted to the shaft portion 24a. Then, the upper edge 25a of the nozzle 25 is elastically held by the leaf spring 24b, thereby holding the nozzle 25, and when an external force larger than the holding force by the leaf spring 24b acts in the nozzle pulling direction, The nozzle 25 is configured to be separated from the holder main body 24.

  On the base 1, a component recognition camera 17 is further provided for recognizing an image of the suction state of the component by each mounting head 20. The component recognition camera 17 is provided between the conveyor 2 and the component supply unit 4, and the head unit 5 takes a predetermined image above the component recognition camera 17 as necessary, for example, after removing a component from the tape feeder 4 a. By moving to the position, the suction parts by the mounting heads 20 and the tips of the nozzles 23a to 23e are imaged from the lower side, and the image data is output to the controller described later. Further, as shown in FIG. 2, a pressure sensor 100 that detects the pressure in the internal passage of the mounting head 20 from the ejector 26 to the tip openings of the nozzles 23 a to 23 e and the like is arranged. The pressure sensor 100 outputs pressure detection data to a controller described later.

  Further, on the base 1, a nozzle replacement unit 18 that houses a nozzle 25 for replacement with respect to the mounting head 20 (nozzle holder 24) is installed in an intermediate region between the conveyor 2 and the component supply unit 4. A defective part disposal box 19 is provided immediately to the side of the replacement unit 18.

  3 to 5 schematically show the nozzle replacement unit 18. As shown in these figures, the nozzle replacement unit 18 includes a rectangular nozzle holding portion 30 having a plurality of storage holes 31 for storing and holding various types of nozzles 25 having different sizes and shapes, and the nozzles. The clamp plate 32 includes a plurality of insertion holes 33 that are slidably stacked on the upper surface of the holding unit 30 and correspond to the storage holes 31.

  As shown in FIG. 3A, the clamp plate 32 includes a clamp release position where each insertion hole 33 matches the storage hole 31, and a clamp position where each insertion hole 33 is deviated from the storage hole 31 by a certain amount. (Position shown in FIG. 3B) is slidable along the guide 35 so as to be movable, and when the clamp plate 32 is arranged at the clamp position, the insertion hole 33 The peripheral edge portion is covered on the upper side of the flange portion 25b of the nozzle 25 (see FIG. 6A).

  Connection plates 36 are attached to the clamp plate 32 on the lower surfaces of both end portions in the moving direction (Y-axis direction) (lower surfaces of both left and right end portions in FIG. 4). The connecting plate 36 protrudes below the nozzle holding portion 30 through a notch 30 a formed in the nozzle holding portion 30 and is fixed to the lower surface of the nozzle holding portion 30. , 37b, respectively. That is, the clamp plate 32 is displaced between the clamp position and the clamp release position by the reciprocating movement of the air cylinder 37.

  Here, the nozzle replacement in the nozzle replacement unit 18, that is, the operation of detaching the nozzle 25 from the nozzle holder 24 of the mounting head 20 will be described as follows.

  When the nozzle 25 is mounted on the nozzle holder 24, first, the nozzle holder 24 is set at the use position by the rotation of the nozzle assembly block 22, and in this state, as shown in FIG. Is disposed above the nozzle replacement unit 18. Then, after the clamp plate 32 is set at the clamp release position by the operation of the air cylinder 37, the mounting head 20 is lowered, and the nozzle holder 24 is inserted into the predetermined storage hole 31 of the nozzle holder 30 through the insertion hole 33. Is done. As a result, the shaft portion 24a of the nozzle holder 24 is inserted into the nozzle 25 housed in the housing hole 31, and the nozzle 25 is coupled to the nozzle holder 24 as shown in FIG. At this time, when the mounting head 20 is lowered, the leaf spring 24b is pushed and expanded by the nozzle 25, and when the shaft portion 24a is completely inserted into the nozzle 25, the upper edge 25a of the nozzle 25 is moved by the leaf spring 24b. The nozzle 25 is held against the nozzle holder 24 by being elastically held. Then, after the mounting of the nozzles 25, the mounting head 20 is raised, so that the nozzles 25 are taken out from the nozzle replacement unit 18 with the nozzles 25 mounted on the nozzle holder 24.

  On the other hand, when the nozzle 25 mounted on the nozzle holder 24 is removed, first, the mounting head 20 is disposed above the nozzle replacement unit 18 and the clamp plate 32 is set at the clamp release position. As the head 20 is lowered, the nozzle 25 is inserted into the empty storage hole 31 of the nozzle holder 30, that is, the empty storage hole 31 in which the nozzle 25 is to be stored. Then, after the clamp plate 32 is switched to the clamp position, the mounting head 20 is raised. In this way, the flange portion 25b of the nozzle 25 engages with the clamp plate 32 to prevent the nozzle 25 from being pulled out, and the nozzle 25 is separated from the nozzle holder 24 and left in the storage hole 31. As a result, the nozzle 25 25 will be removed from the nozzle holder 24.

  The nozzle replacement unit 18 further cleans the internal passages of the mounting head 20 (the internal passages of the nozzle shaft, the internal passages of the holder 21 and the passages in the nozzle assembly block 22), the nozzles 23a to 23e, and the like. A cleaning unit 40 according to the present invention is provided.

  That is, as shown in FIGS. 3 to 5, the four corner portions of the nozzle holding portion 30 are provided with protruding portions 30 b that are raised above the clamp plate 32 and whose end surfaces are substantially flat. Nozzle insertion holes 42 that open upward are provided in the protrusions 30b.

  As shown in FIG. 7, these nozzle insertion holes 42 allow insertion of tapered nozzles for small parts (nozzles 23b, 23c, etc. shown in FIG. 6; hereinafter referred to as tapered nozzles 23b, etc. if necessary). On the other hand, for wide-mouth nozzles (23a, 23d, 23e, etc. shown in FIG. 6; hereinafter referred to as wide-mouth nozzles 23a, etc. if necessary), as shown in FIG. The diameter of the hole is set so that the nozzle opening communicates with the nozzle insertion hole 42 by the contact. In the present embodiment, the nozzle insertion hole 42 is the set portion of the present invention for the tapered nozzle 23b and the like, and the upper end surface of the protruding portion 30b corresponds to the set portion for the wide-mouth nozzle 23a and the like.

  Each nozzle insertion hole 42 is provided so as to penetrate the nozzle holding portion 30 in the vertical direction, and is connected to the filter 44 and the silencer 45 via an exhaust hose 43 (exhaust passage) connected to the lower surface of the nozzle holding portion 30. Communication connection is established. That is, as shown in FIG. 7, the tapered nozzle 23b or the like (nozzle 25 in FIG. 7) is inserted into the nozzle insertion hole 42, or the wide-mouth nozzle 23a or the like (nozzle 23e in FIG. 8) protrudes as shown in FIG. The air blow is supplied to the internal passage of the mounting head 20 in contact with the end face of the portion 30b, so that the internal passage of the nozzle shaft, the internal passage of the holder 21 and each passage in the nozzle assembly block 22, or each Dirt and foreign matter adhering to the inside of the nozzles 23a to 23e and the like are captured and collected by the filter 44 while being discharged from the nozzle tip by the action of air blow.

  Further, as shown in FIG. 7, the nozzle holding portion 30 is provided with an air passage 46 that opens in the middle of each nozzle insertion hole 42. These air passages 46 are provided with valves 47 and filters (not shown). Or the like) through the compressor 48. Thus, when cleaning the tapered nozzle 23b and the like, air blow is applied from the outside of the nozzle 23b and the like through the air passage 46.

  Although not shown, the mounting machine configured as described above is a well-known CPU that executes logical operations, a ROM that stores various programs for controlling the CPU in advance, and various data temporarily during operation of the apparatus. And a controller (control means) composed of a RAM and the like for storing the head unit 5 in a series of mounting operations (driving the nozzle assembly block 22 and negative pressure to the nozzles 23a to 23e). This includes the switching of air blow (positive pressure) supply), driving of the nozzle replacement unit 18 (including supply of air blow to the nozzle insertion hole 42), or component recognition processing by the component recognition camera 17 all by this controller. Controlled.

  Hereinafter, an example of the mounting operation based on the control of the controller will be described with reference to the flowchart of FIG. In the following description, it is assumed that the nozzle 25 is attached to the nozzle holder 24 of each mounting head 20 in advance.

  When the mounting operation is started, the substrate 3 is carried in by driving the conveyor 2, and is positioned at a predetermined mounting work position by the substrate holding means (step S1).

  Then, it is determined whether or not the nozzle 25 mounted on the nozzle holder 24 of each mounting head 20 needs to be replaced (step S2). If YES is determined here, it is further determined whether or not it is a cleaning timing (step S15). The determination as to whether or not it is the cleaning timing is made based on, for example, the number of times of mounting (the number of mounting points) by a counter (not shown), and when the count value exceeds the set value, it is determined as the cleaning timing.

  If YES is determined in the step S15, the process proceeds to a step S16 to execute a nozzle cleaning program (step S16).

  FIG. 10 is a flowchart showing a subroutine for executing the nozzle cleaning program in step S16.

  When this processing is started, first, the mounting head 20 is arranged above the nearest cleaning unit 40 of the nozzle replacement unit 18 as the head unit 5 moves, and during this movement, a nozzle assembly is arranged as necessary. By rotating the attached block 22, the nozzle 23a to 23e, 25 having the largest nozzle opening diameter is set at the use position (step S21). Then, the nozzles 23a to 23e, 25 set at the use positions are inserted into the nozzle insertion holes 42 or brought into contact with the protruding portions 30b as the mounting head 20 descends (step S22). Thereafter, air blow generated by the compressor 29 in response to switching of the valves 27 and 28 is supplied to the internal passage of the mounting head 20, and the supply and shutoff of the air blow are intermittently performed at a predetermined number of times. Repeatedly (steps S23 to S25). As a result, the internal passage of the nozzle shaft, the internal passage of the holder 21, the passage in the nozzle assembly block 22, and the dirt and foreign matter adhering to the inside of the nozzles 23a to 23e, 25 at the use positions are removed by air blow. Are collected by the filter 44 while being discharged into the nozzle insertion hole 42 from ˜23e, 25. At this time, air blow is supplied from the outside to the nozzle 23 b by supplying air blow into the nozzle insertion hole 42 through the air passage 46. As a result, dirt, foreign matter and the like adhering to the outer periphery of the tip of the nozzles 23a to 23e, 25 (nozzle lower end surface and side surface of the nozzle tip) are removed and similarly collected by the filter 44.

  When the cleaning of the nozzles and the like is completed, the nozzles 23a to 23e and 25 are pulled out from the nozzle insertion hole 42 or separated from the protruding portion 30b as the mounting head 20 is raised, and then the presence or absence of an uncleaned nozzle is determined. (Steps S26, S27).

  If YES is determined here, the nozzle assembly block 22 is rotationally driven, and the next nozzles 23a to 23e and 25, specifically, the nozzles 23a to 23e and 25 having the next largest nozzle opening diameter are used. Then, the process proceeds to step S22 (step S28).

  By repeating step S22 to step S28 in this manner, the internal passage of the nozzle shaft and the internal passage of the holder 21 are cleaned for each mounting head 20, and the nozzles 23a to 23e and 25 having a large nozzle opening diameter are sequentially arranged. The cleaning of the nozzles 23a and the like and the cleaning of the passages in the nozzle assembly block 22 are sequentially performed, and when it is finally determined NO in step S27, the processing of the subroutine is terminated.

  Returning to FIG. 9, when the nozzle cleaning or the like (nozzle cleaning program) is completed, the nozzle 25 attached to the nozzle holder 24 is exchanged with the nozzle exchange unit 18 (step S17). The specific replacement operation of the nozzle 25 is as described above, and the description thereof is omitted here.

  When nozzle replacement is completed for one mounting head 20 in this way, it is determined whether or not nozzle replacement is necessary for the other mounting head 20 (step S18). If necessary, nozzle replacement is performed in the same manner. Then, the process proceeds to step S4.

  When it is determined NO in step S2 (when it is determined that nozzle replacement is unnecessary), the process proceeds to step S3, where it is determined whether a nozzle clogging check is necessary. Whether nozzle clogging is necessary is determined based on, for example, the number of mountings (the number of mounted parts) counted by a counter (not shown). If the count value exceeds the set value, it is determined that a nozzle clogging check is necessary. The

  If YES is determined in step S3, the mounting head 20 is disposed above the component recognition camera 17, and imaging of the nozzle tips of the nozzles 23a to 23e and 25 is performed as the nozzle assembly block 22 rotates. Sequentially performed, the contamination on the outer periphery of the nozzle tip and the adhesion of foreign matter are checked based on the image data, and the nozzle clogging is checked based on the pressure data from the pressure sensor 100 (step S4). In the process of step S4 immediately after passing through the processes of steps S15 to S18, the nozzle tip is imaged only for the nozzle 25 newly attached to the nozzle holder 24, and the nozzle contamination and nozzle clogging are examined. This is because, for the other nozzles 23a to 23e, since nozzle cleaning has already been performed in the process of step S16, there is a low possibility that nozzle clogging or the like has occurred.

  Then, the presence or absence of nozzle clogging or the like is determined, and if it is determined that nozzle clogging or the like has occurred in any of the nozzles 23a to 23e, 25 (YES in step S5), the nozzle cleaning program is executed. After being executed, the process proceeds to step S7 (step S6). The processing in step S6 is the same as the subroutine of step S16 (the flowchart in FIG. 10) except that cleaning is performed only for the nozzles 23a to 23e, 25 in which nozzle clogging or the like has occurred. Done. The clogging of the internal passages of the mounting head 20 and the internal passages of the nozzles and the like is a pressure when a negative pressure or a positive pressure is applied in a state where no components are adsorbed to the tip portions of the nozzles 23a to 23e, 25. This can be determined from pressure detection data by the sensor 100. When the negative pressure detection value when negative pressure is applied is smaller than a predetermined value of a certain width (large in absolute pressure), the internal passage on the ejector 26 side is clogged from the position where the pressure sensor 100 is attached, and the negative pressure is negative. When the pressure detection value is larger than a predetermined value of a certain width, the pressure sensor 100 can detect that the internal passages on the nozzles 23a to 23e, 25, etc. are clogged. Further, when the positive pressure detection value when positive pressure is applied is smaller than a predetermined value of a certain width, the internal passage on the ejector 26 side is clogged from the position where the pressure sensor 100 is attached, and the positive pressure detection value is When the width is larger than a predetermined value, the pressure sensor 100 can detect that the internal passages on the nozzles 23a to 23e, 25, etc. are clogged.

  On the other hand, if NO is determined in steps S3 and S5, the head unit 5 moves to the component supply unit 4 and components are taken out from the tape feeder 4a as the mounting heads 20 are moved up and down ( Step S7). At this time, the nozzle assembly block 22 is rotationally driven, so that the nozzles 23a to 23e and 25 corresponding to the target parts are set at the use positions, and then the mounting head 20 is switched according to the switching of the valves 27 and 28. A negative pressure for component suction is supplied to the tips of the nozzles 23a to 23e, 25 through the internal passage. As a result, the parts are sucked by the nozzles 23a to 23e, 25.

  When the suction of the component is completed, the head unit 5 is then moved onto the component recognition camera 17, whereby the suction component is imaged, and the component is recognized based on the image data (step S8).

  Based on this component recognition, the suction displacement of the component with respect to the nozzles 23a to 23e, 25 is checked, and it is determined whether the suction component is a defective component with a defect or the like or is not a desired component ( Step S9). If NO is determined here, the process proceeds to step S12, and the suction component is mounted on the substrate 3 as described later.

  On the other hand, if YES is determined in step S9, that is, if it is determined that the sucked part is a defective part or a defective part of an improper part, the process proceeds to step S10 and the part disposal program is executed. (Step S10).

  FIG. 11 is a flowchart showing a subroutine for executing the component disposal program in step S10.

  In this process, it is first determined whether or not the nozzle that adsorbs a defective component or the like is the wide-mouth nozzle 23a or the like. If YES is determined here, the mounting head 20 is moved as the head unit 5 moves. It is arranged above the disposal box 19 (step S39). Then, in response to the switching of the valves 27 and 28, the supply of negative pressure to the wide-mouth nozzle 23a is stopped, whereby defective parts and the like adsorbed by the wide-mouth nozzle 23a are discarded in the disposal box 19 ( Step S40), and then the process proceeds to Step S38.

  On the other hand, if NO is determined in step S31, that is, if it is determined that the nozzle that sucks the defective component is the tapered nozzle 23b or the like that sucks the small component, the head unit 5 moves. The mounting head 20 is disposed above the nearest cleaning unit 40 of the nozzle replacement unit 18, and the tapered nozzle 23b and the like are inserted into the nozzle insertion hole 42 together with the suction component as the mounting head 20 descends (step S32, 33).

  Thereafter, the supply of negative pressure to the tapered nozzle 23b and the like is shut off in accordance with the switching of the valves 27 and 28, and at the same time, air blow is supplied to the tapered nozzle 23b and the like through the internal passage of the mounting head 20, and this The supply and shutoff of air blow are intermittently repeated a predetermined number of times at regular intervals (steps S34 to S36). As a result, the release of negative pressure is promoted, and this air blow (positive pressure) acts as a back pressure when the component is detached from the tapered nozzle 23b or the like, so that the suction state of the component is quickly released and the defective component is removed. It is discarded into the filter 44 through the nozzle insertion hole 42. At this time, the air blow is supplied into the nozzle insertion hole 42 through the air passage 46, and the air blow is applied from the outside of the tapered nozzle 23b and the like, thereby detaching the parts from the tapered nozzle 23b and the like is promoted.

  When the component disposal is completed, the tapered nozzle 23b and the like are pulled out from the nozzle insertion hole 42 as the mounting head 20 is raised, and the presence / absence of other discarded components is determined (steps S37 and S38).

  If YES is determined here, the process proceeds to step S31 so as to discard the defective part or the like adsorbed by the other mounting head 20, and the processes of steps S32 to S37 or the processes of steps S39 and S40 are repeatedly performed. The If it is finally determined NO in step S38, the subroutine processing is terminated.

  Returning to FIG. 9, when the disposal of defective parts or the like (part disposal program) is completed, it is determined whether or not there are any mounting parts remaining in each mounting head 20. The component is mounted on the substrate 3 (steps S11 and S12).

  Specifically, after the head unit 5 moves to the mounting position on the substrate 3, the mounting head 20 is driven up and down. At this time, the valves 27 and 28 are moved at a predetermined timing when the head 20 reaches the lower end position. By switching, the supply of negative pressure to the nozzles 23a to 23e, 25 is stopped, and the supply of air blow (positive pressure) is performed for a very short time. Thereby, the suction state of the components by the nozzles 23 a to 23 e and 25 is quickly released, and the components are mounted on the substrate 3.

  When the mounting of the components is completed, it is determined whether any other components to be mounted on the board 3 remain. If YES is determined here, the process proceeds to step S2. On the other hand, if NO is determined in step S13, the board 3 is carried out to the next process by driving the conveyor 2 (step S14), thereby completing a series of component mounting operations on the board 3. It will be.

  According to the mounting machine as described above, as described above, the cleaning unit 40 provided in the movable region of the mounting head 20 has a predetermined timing (the timing at which the nozzles 23a to 23e and 25 are mounted a predetermined number of times). Mounting timing at the time when clogging of the internal passages of each part such as the internal passage of the mounting head 20 is detected, the timing at which dirt or foreign matter is detected at the tips of the nozzles 23a to 23e, 25, or the replacement timing of the nozzle 25) The head 20 is moved, and here, air blows to the nozzles 23a to 23e, 25 through the internal passages of the mounting head 20 (that is, the internal passages of the nozzle shaft, the internal passages of the holder 21 and the passages in the nozzle assembly block 22) ( Cleaning the internal passage and the nozzles 23a to 23e, 25, that is, the internal passage. Since it is configured to remove dirt and foreign matter adhering to the surface, it is possible to effectively prevent occurrence of component adsorption mistakes and mounting mistakes due to the supply of negative pressure etc. being hindered by the foreign substances etc. it can. In other words, the predetermined timing here refers to the case where nozzle clogging, nozzle fouling, or the like occurs in steps S4 and S5 regardless of the nozzle replacement timing. Further, since it is also configured to remove dirt and foreign matter adhering to the tip portions of the nozzles 23a to 23e and 25, correct component suction to the tip portion can be performed, and the occurrence of suction mistakes and mounting mistakes is effective. Can be prevented.

  In particular, in the mounting machine of this embodiment, since the cleaning unit 40 is provided in the nozzle holding unit 30 of the nozzle replacement unit 18, the space can be reduced and the cost can be reduced as compared with the case where the cleaning unit 40 is arranged independently. Can be reduced. Further, as described above, it is possible to clean the nozzles using the nozzle replacement timing, and in this case, the amount of movement of the mounting head 20 is substantially the same as that for nozzle replacement while performing nozzle cleaning. Since only the movement amount is required, the total movement distance of the mounting head 20 can be suppressed. Accordingly, the loss of tact time associated with nozzle cleaning or the like can be minimized, and as a result, the mounting operation can be efficiently advanced.

In addition, during nozzle cleaning (during step S16), the cleaning is performed in order from the nozzles 23a to 23e and 25 having larger nozzle opening diameters, so that the problem of inducing nozzle clogging by cleaning is avoided. there is also an advantage that possible. That is, cleaning may be performed in order from the smallest nozzle opening diameter, but in this case, foreign matter in the internal passage of the mounting head 20 is discharged through the nozzle, so immediately after the start of cleaning, the amount of foreign matter is large. When a nozzle having a small nozzle opening diameter is set at the use position, the foreign matter may be clogged in the nozzle. On the other hand, when cleaning is performed in order from the largest nozzle opening diameter as in the above embodiment, the one with the larger nozzle opening diameter is set at the use position when the amount of foreign matter immediately after the start of cleaning is large. The foreign matter will be discharged through the nozzle without difficulty. Accordingly, it is possible to appropriately clean the nozzles while effectively avoiding the harmful effects such as nozzle clogging.

  Further, in this mounting machine, when the nozzle 25 in the nozzle replacement unit 18 is used after the use, the mounting usage count has reached a predetermined number of times, or when it is the cleaning timing at which nozzle clogging or nozzle tip contamination is detected. Since the cleaning is always performed before returning to the nozzle replacement unit 18 (steps S2, S15 to S18 in FIG. 9), the nozzle 25 to which foreign matter or the like is attached is stored in the nozzle replacement unit 18 as it is. Can be effectively prevented. Moreover, for the nozzle 25 (nozzle 25 housed in the nozzle replacement unit 18), immediately after mounting on the mounting head 20, the pressure sensor 100 always determines the pressure detection value of the internal passage and recognizes the image of the nozzle tip. When the nozzle 25 is clogged or foreign matter adheres to the tip of the nozzle, cleaning is performed by air blow, so that the nozzle 25 is replaced with the nozzle replacement unit 18 while the foreign matter etc. remains attached. Even if it is returned to the case, it becomes possible to remove the foreign matter or the like before the next use. That is, the nozzle 25 in the nozzle replacement unit 18 is cleaned both after use and before use (only when necessary) triggered by nozzle replacement. It is possible to start the mounting operation in an appropriate state without adhesion of foreign matter or the like. Therefore, regarding the nozzles 25 in the nozzle replacement unit 18, it is possible to effectively prevent occurrence of component adsorption mistakes and mounting mistakes due to insufficient adsorption force due to clogging or adhesion of foreign matters regardless of their frequency of use.

  Further, among the nozzles 23 a to 23 e and 25 mounted on the mounting head 20, when cleaning the tapered nozzle 23 b and the like is performed in a state of being inserted into the nozzle insertion hole 42, a horizontal hole (air Since air blow is also given from the outside of the tapered nozzle 23b through the passage 46), not only foreign matter adhering to the nozzle opening to block the nozzle opening, but also dirt adhering to the nozzle tip and its surroundings. Foreign matter and the like adhering to the surface can also be suitably removed.

  Further, in this mounting machine, when a defective part is found by image recognition of the suction part and the part is a suction part (small part) by the tapered nozzle 23b or the like, the tapered nozzle 23b or the like is used as the suction part. At the same time, it is inserted into the nozzle insertion hole 42 of the cleaning unit 40 and the air blow is given to the tapered nozzle 23b etc. in the same way as when cleaning the nozzle so that the defective part is discarded. There is also an advantage that a rational configuration in which the cleaning unit 40 is also used as a waste space for defective parts is achieved. That is, for example, when discarding a very small part of 0.4 mm × 0.2 mm, the suction state by the tapered nozzle 23 b or the like cannot be released simply by stopping the negative pressure supply, and a so-called part take-out phenomenon may occur. However, as described above, by using the cleaning unit 40 and with the tapered nozzle 23b and the like inserted into the nozzle insertion hole 42, air suction is applied to the suction component from the inside and outside of the nozzle, so that the air pressure can be surely and quickly. The suction component can be removed from the nozzle tip and discarded.

  By the way, the mounting machine described above is an embodiment 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, the following configuration (modification example) may be employed.

  (1) In the embodiment, the present invention is applied to a surface mounter of a type in which a nozzle assembly block 22 in which a plurality of nozzles 23 a to 23 e and the like are assembled is rotatably provided on the mounting head 20. A plurality of shaft-like mounting heads are mounted on the head unit 5 in a state of being arranged in a line, and nozzles are detachably attached to the tip (lower end) of each mounting head, and each nozzle is replaced with a nozzle. The present invention is also applicable to a surface mounter of a type that can be replaced with each other.

  (2) In the embodiment, the cleaning unit 40 is provided integrally with the nozzle replacement unit 18, but the cleaning unit 40 configured separately from the nozzle replacement unit 18 is adjacent to or adjacent to the nozzle replacement unit 18. You may make it arrange | position to. In this case, in the flowchart of FIG. 9, the processes of steps S161 to S163 shown in FIG. 12 may be executed instead of the process of step S16. That is, when it is determined in S5 that the cleaning timing is reached, the mounting head 20 is first moved to the cleaning unit 40 separate from the nozzle replacement unit 18 (step S161), and the cleaning program is executed here (step S162). Thereafter, the mounting head 20 is moved to the nozzle replacement unit 18 to perform nozzle replacement (step S163). Even in such a configuration, as in the configuration of the above-described embodiment, when performing nozzle cleaning using the nozzle replacement timing, mounting work is efficiently performed while suppressing a loss of tact time associated with nozzle cleaning and the like. Can proceed.

  (3) In the embodiment, the cleaning unit 40 is configured by providing the nozzle replacement unit 18 with the dedicated nozzle insertion hole 42, but the cleaning unit also uses the storage hole 31 of the nozzle replacement unit 18 as the nozzle insertion hole 42. 40 may be configured. Specifically, an exhaust hole penetrating the nozzle holding portion 30 is provided at the bottom of each storage hole 31, and the exhaust hose 43 including the filter 44 and the silencer 45 is provided for each storage hole 31. .

  According to this configuration, it is possible to perform nozzle cleaning or the like inside the storage hole 31 when the nozzle 25 is detached and attached in the nozzle replacement unit 18b. Therefore, nozzle cleaning and the like can be performed more efficiently during a series of mounting operations. In particular, in the type of apparatus in which all the nozzles are provided so as to be replaceable with respect to the nozzle replacement unit as in the modified example (1), if the configuration in which the storage hole 31 is also used as the nozzle insertion hole 42 is employed, the cleaning unit Since the space of 40 itself becomes unnecessary, there is an advantage that the space can be saved more favorably and the cost can be further reduced.

  In the case of this configuration, a common large filter is provided on the lower surface of the nozzle holding portion 30 for each storage hole 31 (nozzle insertion hole 42), and foreign substances and waste parts are collectively captured and collected by this large filter. You may comprise as follows.

(4) In the embodiment, the nozzle cleaning program is executed when the nozzle is replaced and the count value of the number of times of mounting (number of mounted parts) by a counter (not shown) exceeds a predetermined set value. However (steps S15 and S16 in FIG. 9), of course, the nozzle cleaning program can be executed at other timings. For example, when a certain working time has elapsed, dirt or foreign matter is detected at the tip of any of the nozzles 23a to 23e, 25, or internal passages such as internal passages of the mounting head 20 are clogged. If it is also detected, it may be executed nozzle cleaning program.

  In the embodiment, when the nozzles are not replaced, the nozzle tips of the nozzles 23a to 23e and 25 are temporarily recognized, and whether the nozzles are contaminated with foreign matter or foreign matter is detected by the pressure sensor. Although the nozzle cleaning program is executed only for the nozzles in which nozzle clogging occurs (steps S4 to S6), of course, the nozzle cleaning program is unconditionally performed for all the nozzles 23a to 23e and 25 without performing image recognition. May be executed.

  Furthermore, in the embodiment, after the nozzle replacement, for the newly mounted nozzle 25, the process proceeds to step S4 to perform image recognition and pressure detection of the internal passage, Although the nozzle clogging is checked, for example, the processing may be shifted to step S7 without performing these processes. As a result, it is possible to save time when the nozzle 25 accommodated in the nozzle insertion hole 42 is newly replaced and used in a state where it has been cleaned in advance. In addition, for nozzles 25 that are newly mounted after nozzle replacement, the nozzle cleaning program may be executed unconditionally without performing image recognition or the like by moving to step S6.

  Further, after the nozzle replacement, the nozzle separated from the mounting head 20 and housed and held in the nozzle insertion hole 42 may be blown from the air passage 46. Further, only the pressure detection value of the internal passage by the pressure sensor 100 may be determined, and the nozzle clogging may be determined. Alternatively, nozzle clogging due to foreign matter adhering to the nozzle opening may be determined only by image recognition, and if there is nozzle clogging, the internal passage may be blown with positive pressure. Furthermore, when nozzle clogging due to adhesion of foreign matter to the nozzle opening is detected only by image recognition, or when adhesion of dirt to the nozzle tip is detected, air blow may be performed only from the air passage 46. Further, the filter 44 serves as a capturing member that captures defective parts and the like (waste parts) in addition to capturing dirt and foreign matter.

1 is a schematic plan view showing a surface mounter according to the present invention. It is a front schematic diagram of the surface mounter. It is a schematic plan view showing the nozzle replacement unit ((a) shows a state where the clamp plate is in the clamp release position, and (b) shows a state where the clamp plate is in the clamp position). It is the sectional view on the AA line of FIG. 3 which shows a nozzle exchange unit. FIG. 4 is a cross-sectional view taken along line B-B in FIG. 3 illustrating a nozzle replacement unit (including a cleaning unit). It is a figure which shows the nozzle mounting | wearing (exchange) operation | movement in a nozzle exchange unit. It is sectional drawing of the nozzle exchange unit which shows the state at the time of nozzle cleaning (in the case of a tapered nozzle; CC sectional view taken on the line of FIG. 3). It is sectional drawing (in the case of a wide mouth nozzle) of the nozzle replacement unit which shows the state at the time of nozzle cleaning. It is a flowchart which shows the mounting operation in a surface mounting machine. It is a flowchart which shows the subroutine of nozzle cleaning program execution. It is a flowchart which shows the subroutine of components disposal program execution. It is a flowchart which shows the modification of mounting operation | movement.

Explanation of symbols

4 Component supply unit 5 Head unit 18 Nozzle replacement unit 20 Mounting heads 23a to 23e, 25 Nozzle 40 Cleaning unit 42 Nozzle insertion hole 43 Exhaust hose 44 Filter 45 Silencer

Claims (4)

One or a plurality of nozzles including replaceable nozzles are mounted on a movable head, and negative pressure for component suction and air blow as positive pressure are alternatively supplied to the nozzles through an internal passage of the head. In a surface mount machine configured to be
With nozzle changing unit accommodating the nozzle for replacement are provided in the movable area of the head, this nozzle exchange unit or near the set in the set portion of the setting portion Toko to set nozzle attached to said head A cleaning portion for the nozzle and the internal passage provided with an exhaust passage for exhausting the air blow discharged from the nozzle ,
The cleaning portion has a nozzle insertion hole communicating with the exhaust passage as the set portion, and is configured to discharge air blow from the nozzle in a state where the nozzle is inserted into the nozzle insertion hole. A surface mount having an air passage that opens in a middle portion of the insertion hole, and configured to give air blow from the outside to the nozzle inserted into the nozzle insertion hole through the air passage. Machine. In the surface mounting machine according to claim 1,
Surface mounter, wherein the cleaning unit is found provided on the nozzle changing unit. In the surface mounting machine according to claim 2,
A surface mounting machine, wherein a storage hole for a replacement nozzle provided in the nozzle replacement unit is also used as the nozzle insertion hole. In the surface mounter according to any one of claims 1 to 3,
The nozzle is inserted into the nozzle insertion hole, and an air blow is discharged through the internal passage and the air passage of the nozzle, so that the parts adsorbed by the nozzle are separated from the nozzle and discarded, and the exhaust A surface mounting machine characterized in that a catching member for catching a waste part detached from the nozzle while allowing the exhaust of the air blow to pass therethrough is disposed in the middle part of the passage .

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