JP3737915B2 - Electronic component mounting method and apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is suitable for use in an electronic component mounting apparatus in which electronic components are mounted by vertical movement of an electronic component suction nozzle provided in the mounting head and horizontal movement of an XY table on which a substrate is placed. The present invention relates to an electronic component mounting method and apparatus.
[0002]
[Prior art]
Conventionally, electronic component mounting apparatuses are required to mount a wide variety of electronic components with high reliability and high speed.
[0003]
FIG. 4 is a plan view showing a schematic configuration of this type of conventional electronic component mounting apparatus. As shown in FIG. 4, the electronic component mounting apparatus 1 supplies the electronic components with the apparatus main body 2 interposed therebetween. A system 3 and a mounting system 4 for mounting electronic components on a substrate are configured. The apparatus main body 2 includes an index unit (not shown) that forms the main body of the drive system, a rotary table 12 connected to the index unit, and a plurality (12) of mounting heads mounted on the outer periphery of the rotary table 12. The rotary table 12 is intermittently rotated at an intermittent pitch corresponding to the number of mounting heads 13 by an index unit (not shown). When the rotary table 12 rotates intermittently, the suction nozzle 14 mounted on each device head 13 appropriately faces the supply system 3 and the mounting system 4 and sucks the electronic components supplied from the supply system 3 and then rotates and conveys the mounting system 4 to the mounting system 4. Then, this is mounted on the substrate B introduced into the mounting system 4 by vertical movement.
[0004]
The mounting system 4 includes an XY table 31 that moves the placed substrate B in the X-axis direction and the Y-axis direction, a carry-in conveyance path 32 and a carry-out carry-in path 33 disposed before and after the XY table 31, and a carry-in conveyance path 32. The upper substrate B is constituted by an XY table 31 and a substrate transfer device 34 for simultaneously transferring the substrate B on the XY table 31 to a carry-out conveyance path 33. The substrate B that has been sent to the downstream end of the carry-in conveyance path 32 is moved onto the XY table 31 by the substrate transfer device 34, and the substrate B on the XY table 31 on which the mounting of the electronic components is completed is transferred to this substrate transfer device. It is transferred to the carry-out conveyance path 33 by the device 34. The board B introduced on the XY table 31 is appropriately moved in the XY direction by the XY table 31, and the component mounting part is made to face the apparatus position corresponding to the electronic components sent one after another by each mounting head. The electronic components are mounted by the vertical movement of each suction nozzle 14.
[0005]
[Problems to be solved by the invention]
As described above, the mounting of the electronic component in this type of electronic component mounting apparatus is performed by the overlapping operation of the movement of the component mounting nozzle 14 in the vertical direction (vertical direction) and the movement of the XY table 31 in the horizontal direction. . Therefore, when electronic components are mounted at a narrow pitch, there is a problem of interference between the already mounted electronic component and the new electronic component to be mounted. In other words, if an electronic component is to be mounted at an adjacent position after mounting a relatively thick component, the vertical movement of the suction nozzle is hindered. In an extreme case, the suction nozzle 14 is placed at a corner portion of the electronic component. There may be a situation where it becomes impossible to attach due to contact.
[0006]
Therefore, when there is a possibility of interference, that is, there is a possibility that the relatively oblique movement locus caused by the overlap movement between the suction nozzle 14 and the XY table 31 may contact the electronic component already mounted on the substrate. In some cases, there is a limit to the distance that the XY table 31 can move horizontally within a predetermined mounting tact. Therefore, the mounting tact due to the vertical movement of the suction nozzle 14 must be lengthened (tact down), and therefore the thickness of the XY table 31 is increased. It was dealt with by means such as mounting with few parts. This is because there is no means for determining the position of a mounted part, and even if the position can be determined, it cannot be processed at high speed. After mounting, the mounting tact time was uniformly extended (tact down was performed), which hindered the speedup of the electronic component mounting apparatus.
[0007]
The present invention provides an electronic component mounting method and apparatus that can process the determination of the position of a mounted component and the determination of the possibility of interference with another component to be mounted at high speed and can easily and quickly mount the electronic component. The purpose is to provide.
[0008]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided an electronic component mounting method in which the vertical movement of the suction nozzle that sucks the electronic component and the horizontal movement of the XY table on which the substrate is placed are moved relatively obliquely in the vertical direction. An electronic component mounting method for mounting the electronic component on the substrate having a trajectory, wherein coordinates on the XY table or the substrate are set in an XY direction according to a size of the electronic component mounted on the substrate. Is divided into cells having a predetermined size area, expressed in a two-dimensional matrix, and cell values indicating predetermined tact limits including presence / absence of mounted electronic components at each cell position are stored as matrix data. Each time a component is mounted, a cell position calculating step for calculating the cell position of the target cell to be mounted on the two-dimensional matrix, and every time an electronic component is mounted, the cell of the target cell is calculated. By referring to the value, an interference possibility determining step for determining whether or not there is an interference possibility that the oblique movement trajectory touches the mounted electronic component, and if there is an interference possibility, according to the cell value of the target cell. A tact control process for performing a tact down control for extending the mounting tact of the electronic component to be mounted, and a cell value update for updating the cell value of the target cell and a predetermined cell located in the vicinity thereof after mounting the electronic component And an electronic component mounting method comprising the steps of:
[0009]
The electronic component mounting apparatus according to claim 6 of the present invention is relatively oblique in the vertical direction by overlapping movement of the vertical movement of the suction nozzle that sucks the electronic component and the horizontal movement of the XY table on which the substrate is placed. An electronic component mounting apparatus that mounts the electronic component on the substrate with a movement locus of the coordinate on the XY table or the substrate in accordance with the size of the electronic component mounted on the substrate. Storage means for dividing a cell having a region of a predetermined size in the XY direction, expressing it as a two-dimensional matrix, and storing a cell value indicating a predetermined tact limit including presence / absence of a mounted electronic component at each cell position as matrix data And a cell position calculating means for calculating a cell position of a target cell to be mounted on the two-dimensional matrix every time an electronic component is mounted, and every time an electronic component is mounted, By referring to the cell value of the target cell, an interference possibility determining means for determining whether or not there is an interference possibility that the oblique movement locus touches the mounted electronic component, and if there is an interference possibility, In accordance with the cell value, tact control means for performing tact-down control for extending the mounting tact of the electronic component to be mounted, and updating the cell value of the target cell and a predetermined cell located in the vicinity thereof after mounting the electronic component An electronic component mounting apparatus comprising: a cell value updating means for performing
[0010]
In this electronic component mounting method and apparatus, the coordinates on the XY table or the substrate are divided into cells having a predetermined size area in the XY direction according to the size of the electronic component mounted on the substrate, and the two-dimensional Cell values that are expressed in a matrix and indicate a predetermined tact limit including the presence / absence of a mounted electronic component at each cell position are stored as matrix data. As a result, by simply referring to each cell value, it is possible not only to determine whether or not an electronic component has been mounted at that cell position, but also to easily and quickly grasp the tact limit of each cell position, and to perform tact control easily and quickly. be able to. In addition, since the cell value of the target cell and a predetermined cell located in the vicinity of the target cell is updated after the electronic component is mounted, the position determination of the mounted component and tact restriction are always performed based on the latest and optimal cell value. Based on tact control. Also, each time an electronic component is mounted, the cell position of the target cell to be mounted on the two-dimensional matrix is calculated, and the slanted movement trajectory touches the mounted electronic component by referring to the cell value of the target cell. Since the presence / absence of interference is determined, the position determination of installed parts and the presence / absence determination of interference possibility can be processed at high speed, and if there is a possibility of interference, depending on the cell value of the target cell Since tact down control is performed to increase the mounting tact time of the electronic component to be mounted, the average mounting tact time can be shortened compared to the case of uniform tact down, and the electronic component can be mounted easily and quickly. As a whole, the operating rate can be improved.
[0011]
According to a second aspect of the present invention, in the electronic component mounting method according to the first aspect, the cell value is multi-valued according to the thickness of the mounted electronic component. When the cell value of the target cell of the electronic component to be exceeded exceeds a predetermined threshold, it is determined that there is a possibility of the interference.
[0012]
In general, even if the movement trajectory of the electronic component to be mounted is the same, the possibility of interference varies depending on the thickness of the mounted electronic component. However, in this electronic component mounting method, the cell value is the same as that of the mounted electronic component. Since it is multi-valued according to the thickness, simply determining whether or not the cell value of the target cell of the electronic component to be mounted exceeds a predetermined threshold, there is a possibility of interference with a nearby mounted component. Presence / absence can be determined easily and quickly. That is, even when electronic components with various thicknesses are mounted, appropriate tact control can be easily and quickly performed according to the thicknesses, and mounting of electronic components can be performed easily and quickly. .
[0013]
According to a third aspect of the present invention, there is provided the electronic component mounting method according to the second aspect, wherein the predetermined threshold is determined according to a thickness of the electronic component to be mounted.
[0014]
In general, even if the movement trajectory of the suction nozzle that adsorbs the electronic component is the same, the movement trajectory of the electronic component (for example, the movement trajectory of the lower end of the electronic component) varies (shifts) depending on the thickness of the electronic component to be mounted. However, in this electronic component mounting method, since the predetermined threshold is determined according to the thickness of the electronic component to be mounted, it is determined whether or not the cell value of the target cell exceeds the predetermined threshold. It is possible to easily and quickly determine whether or not there is a possibility of interference with a mounted part in the vicinity. That is, even when electronic components having various thicknesses are mounted, it is possible to perform finer tact control according to the thicknesses, and it is possible to easily and quickly mount the electronic components.
[0015]
According to a fourth aspect of the present invention, in the electronic component mounting method according to any one of the first to third aspects, the predetermined cell includes eight cells adjacent in the eight directions of the target cell. Features. This makes it easier to determine whether or not there is a possibility of interference with an already mounted electronic component when a new electronic component is subsequently mounted at an adjacent cell position.
[0016]
The electronic component mounting method according to claim 5 of the present invention is an electronic component mounting method for mounting an electronic component on the substrate, wherein the coordinates on the substrate are set to the size of the electronic component mounted on the substrate. The cell value is divided into cells having a predetermined size area in the X and Y directions, expressed in a two-dimensional matrix, and cell values indicating predetermined tact limits including presence / absence of mounted electronic components at each cell position are stored as matrix data. When the electronic component is mounted, the cell position of the target cell to be mounted on the two-dimensional matrix is calculated, and the tact control is performed with reference to the cell value of the target cell. After the mounting, the cell value of the target cell and a predetermined cell located in the vicinity thereof is updated.
[0017]
In this electronic component mounting method, the coordinates on the board are divided into cells having regions of a predetermined size in the XY direction according to the size of the electronic parts mounted on the board, and expressed in a two-dimensional matrix. A cell value indicating a predetermined tact limit including the presence or absence of a mounted electronic component at a cell position is stored as matrix data, and when mounting an electronic component, the cell position of the target cell to be mounted on the two-dimensional matrix And tact control is performed with reference to the cell value of the target cell. That is, by simply referring to each cell value, it is possible not only to determine whether or not an electronic component has been mounted at that cell position, but also to easily and quickly grasp the tact limit at each cell position, so tact control is easily and quickly performed. be able to. In addition, since the cell value of the target cell and a predetermined cell located in the vicinity thereof is updated after the electronic component is mounted, it is always based on the position determination and tact limit of the mounted component based on the latest and optimum cell value. Tact control is possible.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a block diagram of a control system showing an embodiment of an electronic component mounting apparatus of the present invention. Since the mechanical schematic configuration is the same as that of the above-described conventional configuration in FIG. 3, the corresponding components are denoted by the same reference numerals, and only the control system will be described below.
[0019]
In FIG. 1, the control unit 6 includes a control unit main body 60, a touch panel 61, and an external storage device (ES) 62 such as a hard disk or a magneto-optical disk. The touch panel 61 is a means for inputting, editing, and displaying the electronic component mounting apparatus 1 and has a display screen as a so-called monitor, and an operator can perform touch input on the monitor screen (display screen). Various instruction data can be input to perform operations such as editing, and the results can be confirmed and grasped by displaying the editing results and various errors.
[0020]
The ES 62 includes an NC program area 621 for storing numerical control (NC) programs, a part library data area 622 for storing part library data, a part terminal development data area 623 for storing part terminal development data, and other various programs. And other areas 624 for storing various data.
[0021]
The NC program is a program for mounting electronic components on a board based on NC data prepared in advance. In the NC data, which electronic component is to be mounted on which position on the board is set as layout data. The component library data includes data related to all electronic components that can be handled by the electronic component mounting apparatus. Specifically, the component dimension data, the terminal form of the target component, the unit terminal data related to the pitch, These are all terminal arrangement data and all missing terminal arrangement data related to the arrangement of all terminals.
[0022]
The control unit main body 60 includes a CPU 601, a ROM 602, a RAM 603, an input / output controller (IOC) 604, and an external storage controller (ESC) 605, which are connected to each other via an internal bus 606. The ROM 602 contains a system startup program in addition to various control programs including a screen display device and a control device such as the above-described data expansion processing. Further, in relation to the present invention, the procedure shown in the flowchart in FIG. 3 is also programmed and recorded. Details will be described later.
[0023]
The RAM 603 is used as an internal storage unit of the control main body 60, for example, for various work areas and buffers used when expanding as the above-described individual position data. In relation to the present invention, the matrix table shown in FIG. 2 is generated and stored in accordance with the program stored in the ROM 602. Details will be described later.
[0024]
The IOC 604 includes the rotary table 12, the XY table 31, the component recognition unit 8 (line sensor 9 and component recognition (CCD) camera 10) for confirming the posture of the component, the touch panel 61 in the control unit 6, and the electronic It is connected to a peripheral device such as an external input device 65 other than the component mounting device 1. The IOC 604 controls input / output of various control signals and various data between these peripheral devices and the control unit main body 60 in accordance with instructions from the CPU 601. The ESC 605 drives and controls the ES 62 according to a command from the CPU 601, and controls various control signals and various data input / output between the ES 62 and the control unit main body 60.
[0025]
With the above-described configuration, the CPU 601 uses the work area of the RAM 603, the evacuation area of the ES 62, etc. according to the built-in program of the ROM 602, the control program stored in the ES 62, etc. The entire data processing necessary for the device 1 is performed, and the entire electronic component device mounting 1 is controlled via the IOC 604 and the ESC 605.
[0026]
The external input device 65 includes an input unit 651 similar to the touch panel 61, a control unit 652 similar to the control unit main body 60 described above, and a storage unit 653 similar to the ES 62, and instead of the control unit 6. It is configured to allow various data input, creation and processing, and is connected to the control unit 6 via a circuit network capable of data communication (transmission / reception). That is, in the following description, it is assumed that the data processing device is built in the main body of the electronic component mounting device 1 (also used as the control unit 6). However, the electronic component mounting device 1 is configured like the external input device 65. It is also possible to connect to the electronic component mounting apparatus 1 by communication means. In addition, when the ES 62 is a storage medium that is detachable from the main body, such as a magneto-optical disk, various data input via the external input device 65 that is a component data input device is stored in the removable storage medium. By storing it in a medium and loading it again as ES 62 of the control unit 6 of the electronic component mounting apparatus 1, it is possible to use various input data as data of the electronic component mounting apparatus 1 without communication means.
[0027]
FIG. 2 is a diagram cited for explaining the operation of the embodiment of the present invention, and shows the structure of the matrix table 610 allocated and stored in the RAM 603 shown in FIG.
[0028]
The matrix table 610 is obtained by dividing the coordinates allocated to the XY table 31 described above into cells of appropriate areas, expressing them as a two-dimensional matrix, and allocating the storage areas of the RAM 603 corresponding to the cells. The size of one cell is determined in consideration of the size of the electronic component to be mounted. Here, the size of one cell is assigned in units of an integer of the smallest electronic component that can be mounted on the electronic component mounting apparatus 1. Therefore, a plurality of cells are usually occupied by one electronic component. In the following description, for the sake of simplicity, it is assumed that one cell is assigned to one electronic component.
[0029]
Each time an electronic component is mounted, the CPU 601 calculates at least one cell (target cell) corresponding to the mounting target from the coordinate position to be mounted on the substrate B, and the corresponding area (matrix) of the RAM 603 allocated to a cell located in the vicinity. Write values to table 610). Here, the vicinity means eight in the up-down and left-right diagonal directions adjacent to the cell corresponding to the mounting position. In FIG. 2, the x mark is a mounted cell position, and eight cells (◯ mark) that surround the x are vertically and horizontally inclined. In addition, the value (cell value) written in the corresponding cell area of the matrix table 610 is “1” when there is a risk of causing interference with subsequently mounted electronic components, and “0” when there is no risk. “1” and “0” are uniquely determined by the dimensions of the electronic component to be mounted. The value set in the cell area of the RAM 603 is updated each time an electronic component is mounted in the vicinity.
[0030]
Next, when a new electronic component is to be mounted, the CPU 601 performs coordinate calculation based on a program stored in the ROM 602, and when a corresponding cell (target cell) is determined, it corresponds to a cell located in the vicinity of the cell. The contents of the cell area of the RAM 603 (matrix table 610) are referred to and transmitted to the head unit 7 (suction nozzle) that performs tact control as “tact down” when “1” and no tact restriction when “0”.
[0031]
In the above example, the presence / absence of tact restriction is defined by binary values. However, in order to perform precise control, it is expressed by multiple values, the cell values are classified by the thickness of the electronic component, and the neighborhood is determined by the threshold value. You may define the tact restriction | limiting in a cell area | region. As a relatively simple example, it is conceivable that tact restriction is performed if the value is other than “0”, the degree of tact restriction is variable depending on the value, and “0” is no tact restriction. Further, for example, the cell value of the mounting position (target cell) may be set in stages, such as “3”, the cell value of an adjacent cell is “2”, and the cell value outside thereof is “1”. Further, the stepped cell value may be changed according to the thickness of the mounted electronic component. For example, in the matrix table 610 of FIG. 2, when the current position is point C, there is a risk of interference when mounting an electronic component at point B ((b) moving from point C to point B). However, when mounting at point A ((a) mounting from point C to point A), it is safe and tact down is not required. For this reason, the cell value of each cell is judged in consideration of the current position, the target position, or the movement locus at that time, and it is also possible to determine whether it is safe or how much tact restriction is performed. it can.
[0032]
Next, FIG. 3 is a schematic flowchart showing the operation by the above-described control. The schematic operation will be described below with reference to the flowchart of FIG.
[0033]
First, the CPU 601 clears all data in the matrix table 610 allocated and stored in a specific area of the RAM 603 (step S301). Then, NC data indicating which chip component is to be mounted at which coordinate position is obtained from the NC program area 621, the coordinates of the target position are calculated, and the cell position of the corresponding cell (target cell) is obtained (step S302). At the same time, the cell value data of the target cell position (and its vicinity if necessary) is acquired (step S303), and when the electronic component is newly mounted based on the cell value, It is determined whether or not it is a safe area with no interference (step S304).
[0034]
Here, if it is determined to be safe, there is no tact restriction (step S305), and if it is determined to be dangerous, tact down (step S306) is set / instructed to mount the electronic component at the target position (step S307). . Of course, when an electronic component has already been mounted in the target cell due to NC data fraud or the like, this fact may be notified (by an error display or the like).
[0035]
Then, the cell value data in the matrix table 610 (RAM 603) corresponding to the mounting position of the mounted electronic component and the cell located in the vicinity thereof is updated (step S308). Finally, it is checked whether or not all the electronic components have been mounted (step S309). If not, a series of processes from the target position coordinate calculation process (step S302) to the matrix data update process (step S308) are performed. repeat.
[0036]
As described above, the present invention divides the XY table coordinates into cells of appropriate areas, expresses them in a two-dimensional matrix, and shows a predetermined tact limit including the presence or absence of mounted electronic components at each cell position. By storing the values in the matrix table (RAM 603), it is possible to easily and quickly grasp not only whether or not an electronic component has been installed at the cell position, but also the tact limit at each cell position by simply referring to each cell value. Therefore, the tact limit at each cell position can be easily and quickly grasped, and tact control can be easily and quickly performed. In addition, since the cell value of the target cell and a predetermined cell located in the vicinity of the target cell is updated after the electronic component is mounted, the position determination of the mounted component and tact restriction are always performed based on the latest and optimal cell value. Based on tact control. Also, each time an electronic component is mounted, the cell position of the target cell to be mounted on the two-dimensional matrix is calculated, and the slanted movement trajectory touches the mounted electronic component by referring to the cell value of the target cell. Since the presence / absence of interference is determined, it is possible to perform high-speed processing for determining the position of installed parts and determining the presence / absence of interference based on that, and if there is a possibility of interference, depending on the cell value of the target cell The tact down control that increases the mounting tact time of the electronic component to be mounted is performed, so that the average mounting tact time can be shortened compared to the case where the tact time is uniformly reduced, and the electronic component can be mounted easily and quickly. As a whole, the operating rate can be improved.
[0037]
In addition, as described above, cell values are stored in multiple values according to the thickness of the mounted electronic component, and interference is possible when the cell value of the target cell of the mounted electronic component exceeds a predetermined threshold value. It is also possible to perform tact control by determining that there is a possibility. In general, even if the movement trajectory of the electronic component to be mounted is the same, the possibility of interference varies depending on the thickness of the mounted electronic component. In this case, the cell value is multivalued according to the thickness of the electronic component. Therefore, by simply determining whether or not the cell value of the target cell exceeds a predetermined threshold value, it is possible to easily and quickly determine whether or not there is a possibility of interference with a nearby mounted part. That is, even when electronic components with various thicknesses are mounted, appropriate tact control can be easily and quickly performed according to the thicknesses, and mounting of electronic components can be performed easily and quickly. .
[0038]
Further, the predetermined threshold may be determined according to the thickness of the electronic component to be mounted. In general, even if the movement trajectory of the suction nozzle that adsorbs the electronic component is the same, the movement trajectory of the electronic component (for example, the movement trajectory of the lower end of the electronic component) varies (shifts) depending on the thickness of the electronic component to be mounted. However, in this case, since the predetermined threshold is determined according to the thickness of the electronic component to be mounted, it is only necessary to determine whether the cell value of the target cell exceeds the predetermined threshold. It is possible to easily and quickly determine whether or not there is a possibility of interference with a nearby mounted part. That is, even when electronic components having various thicknesses are mounted, it is possible to perform finer tact control according to the thicknesses, and it is possible to easily and quickly mount the electronic components.
[0039]
In the above-described embodiment, the mounting system is shown only as an example in which the mounting system is intermittently rotated at an intermittent pitch corresponding to the number of mounting nozzles via the rotary table. Even in an electronic component mounting apparatus that is movably arranged and has a mounting head (suction nozzle) mounted on each XY stage, by dividing the coordinates on the substrate into cells and expressing them in a two-dimensional matrix, The same applies.
[0040]
【The invention's effect】
As described above, according to the electronic component mounting method and apparatus therefor according to the present invention, the coordinates on the XY table or the substrate are divided into cells of appropriate areas and expressed by a two-dimensional matrix, and at each cell position. By storing a cell value indicating a predetermined tact limit including the presence or absence of a mounted electronic component as matrix data, the position determination of the mounted electronic component can be processed at high speed, and a new electronic component is mounted in the vicinity thereof. There is an effect that the possibility of interference can be easily and quickly determined, and the operating rate can be improved by tacting down only when there is a risk of component interference.
[Brief description of the drawings]
FIG. 1 is a block diagram of a control system of an electronic component mounting apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram showing a data structure of a matrix table assigned to a RAM in FIG.
FIG. 3 is a flowchart showing an operation in mounting control of the embodiment.
FIG. 4 is a plan view showing an example of a schematic structure of a conventional electronic component mounting apparatus.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 4 ... Mounting unit, 6 ... Control unit, 12 ... Rotary table, 13 ... Mounting head, 14 ... Suction nozzle, 31 ... XY table, 62 ... External storage device (ES), 601 ... CPU, 602 ... ROM, 603 ... RAM 604, input / output controller (IOC), 610, matrix table, 621, NC program area, A, electronic component, B, substrate

Claims (6)

Due to the overlap movement of the vertical movement of the suction nozzle that picks up the electronic component and the horizontal movement of the XY table on which the substrate is placed, the electronic component has a relatively oblique movement locus in the vertical direction. An electronic component mounting method for mounting,
The coordinates on the XY table or the substrate are divided into cells having a region of a predetermined size in the XY direction according to the size of the electronic component mounted on the substrate, and expressed in a two-dimensional matrix. Cell values indicating a predetermined tact limit including the presence / absence of a mounted electronic component are stored as matrix data,
A cell position calculating step for calculating a cell position of a target cell to be mounted on the two-dimensional matrix each time an electronic component is mounted;
Each time an electronic component is mounted, by referring to the cell value of the target cell, an interference possibility determination step of determining whether or not there is an interference possibility that the oblique movement locus touches the mounted electronic component;
A tact control process for performing tact down control to increase the mounting tact of the electronic component to be mounted, depending on the cell value of the target cell, when there is a possibility of interference;
A cell value update step of updating the cell value of the target cell and a predetermined cell located in the vicinity thereof after mounting the electronic component;
An electronic component mounting method comprising: The cell value is multivalued according to the thickness of the mounted electronic component,
The said interference possibility determination process WHEREIN: When the cell value of the target cell of the electronic component to mount | wear has exceeded the predetermined threshold value, it determines with the said interference possibility being characterized by the above-mentioned. Electronic component mounting method. The electronic component mounting method according to claim 2, wherein the predetermined threshold is determined according to a thickness of the electronic component to be mounted. The electronic component mounting method according to claim 1, wherein the predetermined cell includes eight cells adjacent to the target cell in eight directions. An electronic component mounting method for mounting an electronic component on a board,
The coordinates on the substrate are divided into cells having a predetermined size area in the XY direction according to the size of the electronic component mounted on the substrate, and expressed in a two-dimensional matrix, and the mounted electrons at each cell position Cell values indicating predetermined tact limits including the presence or absence of parts are stored as matrix data,
When mounting an electronic component, calculate the cell position of the target cell to be mounted on the two-dimensional matrix, perform tact control with reference to the cell value of the target cell, and after mounting the electronic component, An electronic component mounting method, comprising: updating cell values of a target cell and a predetermined cell located in the vicinity thereof. Due to the overlap movement of the vertical movement of the suction nozzle that picks up the electronic component and the horizontal movement of the XY table on which the substrate is placed, the electronic component has a relatively oblique movement locus in the vertical direction. An electronic component mounting device to be mounted,
The coordinates on the XY table or the substrate are divided into cells having a region of a predetermined size in the XY direction according to the size of the electronic component mounted on the substrate, and expressed in a two-dimensional matrix. Storage means for storing, as matrix data, cell values indicating a predetermined tact limit including the presence or absence of mounted electronic components in
Cell position calculating means for calculating a cell position of a target cell to be mounted on the two-dimensional matrix each time an electronic component is mounted;
Interference possibility determination means for determining whether or not there is an interference possibility that the oblique movement trajectory touches the mounted electronic component by referring to the cell value of the target cell every time the electronic component is mounted,
Tact control means for performing tact down control to lengthen the mounting tact of the electronic component to be mounted according to the cell value of the target cell when there is a possibility of interference,
Cell value update means for updating the cell value of the target cell and a predetermined cell located in the vicinity thereof after mounting the electronic component;
An electronic component mounting apparatus comprising:

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