JP4584869B2 - Board inventory quantity simulation method and component mounting method - Google Patents

Description

  The present invention relates to a board inventory quantity simulation method, and more particularly to a simulation method for simulating the inventory quantity of boards on which components such as electronic boards are mounted by a component mounting machine.

In recent years, various methods for determining the mounting order of components when mounting components on a printed circuit board by a component mounting machine have been proposed. Among such methods for determining the mounting order, there is a method in which the mounting order is determined so as to reduce the production time (tact time) per substrate (see, for example, Patent Document 1). If a board on which components are mounted is produced according to the mounting order determined by such a determination method, more boards can be produced per unit time.
JP 2002-50900 A

  However, even if a large number of boards can be produced by reducing the takt time, if you produce more boards than the number of orders, you will have board inventory, which leads to cost loss due to inventory. There are challenges.

  FIG. 21 is a diagram for explaining the above-described problem. For example, it is assumed that a mounting line 602 capable of producing 200 substrates A per day and a mounting line 604 capable of producing 150 substrates B per day exist in the factory. It is assumed that an order 606 that “I want to produce 150 substrates A and 120 substrates B in one day” arrives at this factory. In such a case, when the two mounting lines 602 and 604 are fully operated, 200 boards A and 150 boards B are produced, and the board of the order number is shipped, the board A is 50 (= 200− 150) is in stock, and for substrate B, 30 (= 150-120) is in stock. Therefore, it leads to cost loss. Note that the inventory of products shipped from the factory in this way is hereinafter referred to as “shipment inventory”.

  In the case where a plurality of mounting lines are related to each other and one board or one product is produced and the tact times in the plurality of mounting lines are different and the line balance is poor, Inventories occur during the board production process. For this reason, even in such a case, there is a problem that it leads to a cost loss due to holding inventory. In addition, the inventory generated in the production process of the product is hereinafter referred to as “process inventory”.

  FIG. 22 is a diagram for explaining a problem related to the above-described process inventory. For example, a board A mounting line 608 for producing the board A and a board B mounting line 610 for producing the board B exist, and the board A and the board B are provided in the next process of the two mounting lines 608 and 610. Assume that there is an assembly step 612. Further, it is assumed that the board A and the board B are produced in parallel on the board A mounting line 608 and the board B mounting line 610. At this time, the line tact time in the board A mounting line 608 (time required to produce one board) is 12 seconds, and the line tact time in the board B mounting line 610 is 20 seconds. And Therefore, when the number of substrates produced per unit time is compared, there are more substrates A. For this reason, the substrate A remains as a process inventory.

FIG. 23 is another diagram for explaining the problem relating to the process inventory. The production system 626 shown in the figure is a system for mounting components on both sides of a board, and includes a back surface mounting line 622, a stocker 30a, a conveyor 154, a board reversing device 156, and a surface mounting line 624. It has.

  The back surface mounting line 622 is a mounting line for mounting components on the back surface of the substrate. The stocker 30a stocks a substrate on which components are mounted on the back surface by a back surface mounting line 622. The conveyor 154 conveys the substrate stocked in the stocker 30a. The substrate reversing device 156 reverses the front and back of the substrate conveyed by the conveyor 154. The surface mounting line 624 is a mounting line for mounting components on the surface of the substrate whose front and back are reversed by the conveyor 154. That is, the substrate sequentially flows in the direction indicated by the arrow in the figure.

  At this time, the line tact time in the back surface mounting line 622 is 12 seconds, and the line tact time in the front surface mounting line 624 is 20 seconds. Therefore, there are more backside substrates that compare the number of substrates produced per unit time. For this reason, the production of the front substrate cannot catch up with the production of the rear substrate, and the rear substrate is stocked as a process stock in the stocker 30a.

  The present invention has been made to solve the above-described problems, and an object thereof is to provide a substrate inventory quantity simulation method and the like that can reduce cost loss due to shipment inventory or process inventory.

  To achieve the above object, a board inventory quantity simulation method according to the present invention is a board inventory quantity simulation method for simulating an inventory quantity of boards by a component mounting machine for mounting components on a board, wherein the component mounting machine A production condition input receiving step for receiving the production condition input, and a simulation step in which the computer simulates the stock quantity of the substrates based on the production condition.

  According to this configuration, since the number of stocks can be simulated in advance, the operator can determine appropriate production conditions. For this reason, it is possible to reduce cost loss due to shipment stock or process stock.

  Preferably, the above-described substrate inventory number simulation method further includes a graph display step of displaying a graph of a transition of the simulated inventory number of the substrates.

  According to this configuration, the operator can know at a glance whether or not the stock quantity is appropriate.

  The present invention can be realized not only as a substrate inventory quantity simulation method including such characteristic steps, but also as a board inventory quantity simulation apparatus using the characteristic steps included in the substrate inventory quantity simulation method. Or a program that causes a computer to execute the characteristic steps included in the board inventory quantity simulation method. Needless to say, such a program can be distributed via a recording medium such as a CD-ROM (Compact Disc-Read Only Memory) or a communication network such as the Internet.

  It is possible to provide a substrate inventory quantity simulation method and the like that can reduce cost loss due to shipment inventory or process inventory.

  A substrate production system according to an embodiment of the present invention will be described below with reference to the drawings.

[Embodiment 1]
In the first embodiment of the present invention, a substrate production system capable of reducing cost loss due to shipment inventory will be described.

  FIG. 1 is an external view of a substrate production system according to Embodiment 1 of the present invention. The production system 10 is a system for producing a component mounting board in which components are mounted on a board, and includes a mounting line 200 and a board production number control device 300.

  The mounting line 200 is a system for transporting a board from an upstream production facility to a downstream production facility to produce a board on which components are mounted. The stocker 14 and 30, the solder printer 16, the conveyor 18, 26, an adhesive application device 21, component mounters 22 and 24, and a reflow furnace 28.

  The stockers 14 and 30 are devices for stocking substrates, and the stocker 14 is located on the uppermost stream of the production line, and the stocker 30 is located on the most downstream side of the production line. That is, the stocker 14 is stocked with a board on which no components are mounted, and the stocker 30 is stocked with a finished product board with components mounted thereon.

  The solder printing device 16 is a device that prints solder on a substrate. The conveyors 18 and 26 are apparatuses for transporting the substrate. The adhesive application device 21 is an apparatus that applies an adhesive on a substrate. The component mounters 22 and 24 are devices for mounting components on a board. The reflow furnace 28 is an apparatus for fixing a component on the substrate after melting the solder or the like by heating the substrate on which the component is mounted.

  The board production number control device 300 is a computer for controlling the number of boards produced at each production facility constituting the mounting line 200. The configuration of the board production number control apparatus 300 will be described later.

  FIG. 2 is an external view showing the configuration of the component mounter 22. The component mounter 24 has a similar configuration.

  The component mounting machine 22 includes two sub facilities (a front sub facility 130a and a rear sub facility 130b) that perform component mounting in cooperation with each other (or in an alternate operation). The front sub-equipment 130a includes a component supply unit 124a having an arrangement of parts feeders 123 for storing component tapes, and a plurality of suction nozzles (hereinafter simply referred to as “suction nozzles”) that can suck electronic components from the parts feeders 123 and mount them on the substrate 20. Multi-mounting head 121 having a “nozzle”), beam 122 to which multi-mounting head 121 is attached, and suction state of components sucked by multi-mounting head 121 are two-dimensionally or three-dimensionally inspected. A component recognition camera 126 and the like are provided.

  The rear sub-equipment 130b has the same configuration as the front sub-equipment 130a. The rear sub-equipment 130b includes a tray supply unit 128 that supplies tray components, but the tray supply unit 128 and the like may not be provided depending on the sub-equipment. One display 150 is provided for each of the front sub-equipment 130a and 132a and the rear sub-equipment 130b and 132b.

FIG. 3 is a plan view showing a main configuration inside the component mounter 22.
The component mounter 22 shown in FIG. 2 is provided with two sub-equipment, but the component mounter 22 shown in FIG. 8 is replaced with the component mounter 22 shown in FIG. It is assumed that the internal configuration when two units are connected in the transport direction is described below.

The component mounter 22 includes sub-equipment arranged in the transport direction (X-axis direction) of the substrate 20 therein, and further includes sub-equipment in the front-rear direction (Y-axis direction) of the component mounter 22. A total of four sub-equipment 130a, 132a, 130b, and 132b are provided. The sub-equipment (130a and 132a, 130b and 132b) arranged side by side in the X-axis direction is independent from each other, and different mounting operations can be performed at the same time. Further, the sub-equipment (130a and 132b, 132b and 130b) is also independent of each other, and different mounting operations can be performed at the same time. On the other hand, the sub-equipment (130a and 130b, 132a and 132b) arranged to face each other in the front-rear direction (Y-axis direction) performs a mounting operation on one board in cooperation with each other. Hereinafter, the sub facilities 130a and 130b are collectively referred to as “left sub facility 120c”, and the sub facilities 132a and 132b are collectively referred to as “right sub facility 120d”. That is, in each of the left sub-equipment 120c and the right sub-equipment 120d, the two multi mounting heads 121 perform component mounting work on one substrate 20 in cooperation.

  Each sub-equipment 130a, 132a, 130b, 132b includes a beam 122, a multi-mounting head 121, and component supply units 124a, 125a, 124b, 125b for the sub-equipment 130a, 132a, 130b, 132b. Yes. Further, the component mounter 22 is provided with a pair of rails 129 for transporting the substrate 20 between the front and rear sub-equipment.

  Note that the component recognition camera 126, the tray supply unit 128, and the like are not the main points of the present invention, and are not shown in FIG.

  The beam 122 is a rigid body that extends in the X-axis direction, and moves on a track (not shown) provided in the Y-axis direction (perpendicular to the conveyance direction of the substrate 20) while being parallel to the X-axis direction. Is something that can be done. Further, the beam 122 can move the multi-mounting head 121 attached to the beam 122 along the beam 122, that is, in the X-axis direction. The multi mounting head 121 can be moved freely in the XY plane by moving the multi mounting head 121 moving in the Y axis direction in the X axis direction.

  As shown in FIG. 4, the beam 122 and the like are provided with motors 24 a and 24 b for driving the beam 122 and the multi-mounting head 121. The mounting control unit 23 controls the motors 24a and 24b and the like, thereby controlling the moving speed of the beam 122 and the multi mounting head 121.

FIG. 5 is a block diagram showing a functional configuration of the board production number control apparatus 300.
The board production number control device 300 includes an arithmetic control unit 301, a display unit 302, an input unit 303, a memory unit 304, a board production number control program storage unit 305, a communication I / F (interface) unit 306, a database unit 307, and the like. Is done.

The arithmetic control unit 301 is a CPU (Central Processing Unit), a numerical processor, or the like, and loads and executes a necessary program from the board production number control program storage unit 305 to the memory unit 304 in accordance with an instruction from the operator. Each component 302 to 307 is controlled according to the execution result.

  The display unit 302 is a CRT (Cathode-Ray Tube), LCD (Liquid Crystal Display), or the like, and the input unit 303 is a keyboard, a mouse, or the like. It is used for dialogue between the apparatus 300 and an operator.

  The communication I / F unit 306 is a LAN (Local Area Network) adapter or the like, and is used for communication between the board production number control device 300 and the component mounting machine 22 constituting the mounting line 200. The memory unit 304 is a RAM (Random Access Memory) or the like that provides a work area for the arithmetic control unit 301.

  The database unit 307 stores input data (mounting point data 307a, component library 307b, mounting machine information 307c, etc.) used for the mounting program creation processing by the board production number control device 300, the obtained mounting program, and the like. Such as a hard disk.

  6 to 8 are diagrams illustrating examples of the mounting point data 307a, the component library 307b, and the mounting machine information 307c, respectively.

  The mounting point data 307a is a collection of information indicating mounting points of all components to be mounted. As shown in FIG. 6, one mounting point pi includes a component type ci, an X coordinate xi, a Y coordinate yi, a mounting angle θi, and control data φi. Here, “component type” corresponds to a component name in the component library 307b shown in FIG. 7, and “X coordinate” and “Y coordinate” are coordinates of a mounting point (coordinates indicating a specific position on the board). Yes, the “mounting angle” is the rotation angle of the component at the time of component mounting, and the “control data” is constraint information related to mounting of the component (type of usable suction nozzle, maximum moving speed of the multi mounting head 121, etc. ).

  The component library 307b is a library in which unique information about all the component types that can be handled by the component mounter 22 and the like is collected. As shown in FIG. 7, the component size and tact (constant) for each component type are collected. A tact peculiar to the part type under the condition), and other constraint information (a type of suction nozzle that can be used, a recognition method by the part recognition camera 126, a maximum speed level of the multi mounting head 121, and the like). In the drawing, the external appearance of the components of each component type is also shown for reference.

  The mounting machine information 307c is information indicating the apparatus configuration for each of the sub-equipment constituting the production line, the above-described restrictions, and the like. As shown in FIG. 8, the type of the multi mounting head 121, that is, the multi mounting head 121 The head information related to the number of suction nozzles, etc., the nozzle information related to the types of suction nozzles that can be mounted on the multi mounting head 121, the cassette information related to the maximum number of parts feeders 123, etc., are stored in the tray supply unit 128. It consists of tray information related to the number of trays and the like.

  The board production number control program storage unit 305 is a hard disk or the like that stores various control programs for realizing the functions of the board production number control apparatus 300, and functions functionally (when executed by the arithmetic control unit 301). As a processing unit), it includes a board inventory quantity calculation part 305a, a board production quantity control part 305b, an inventory quantity display control part 305c, and a mounting order determination part 305d.

  The board inventory quantity calculation unit 305 a is a processing unit that calculates the inventory quantity of boards produced in the mounting line 200. The board production number control unit 305b is a processing unit that controls the number of board productions in the mounting line 200 so that the stock quantity is equal to or less than a predetermined appropriate stock quantity. The inventory quantity display control unit 305 c is a processing unit that displays a graph indicating the inventory quantity on the display unit 302. The mounting order determination unit 305d is a processing unit that determines the mounting order of components so that the line tact is minimized within given mounting conditions.

  Next, processing executed by the board production number control apparatus 300 will be described. FIG. 9 is a flowchart of processing executed by the board production number control apparatus 300.

  The board inventory quantity calculation unit 305a takes in an order (production plan) input by the operator using the input unit 303 (S2). For example, as shown in FIG. 21, it is assumed that an order “I want to produce 150 boards A in one day” is input, and the board inventory quantity calculation unit 305a takes the order.

  The board inventory quantity calculation unit 305a fetches the current number of boards A existing in the factory before board production, which is input by the operator using the input unit 303 (S4). For example, it is assumed that the current number of substrates A is 30.

  The mounting order determination unit 305d fetches input data (mounting point data 307a, component library 307b, mounting machine information 307c, etc.) registered in the database unit 307 for creating a mounting program (S6).

  The board production number control unit 305b sets the mounting tact level that defines the mounting speed of each component in the component mounting machine 22 or 24 to the maximum speed level set in the component library for each component type (S8).

  The maximum speed level is the level of the moving speed of the multi-mounted head 121, and is divided into eight levels from level 1 to level 8, as shown in FIG. The maximum speed level is set in the part library for each part type. Level 1 is the maximum speed level at which the multi mounting head 121 can be moved at the maximum speed, and level 8 is the maximum speed level at which the multi mounting head 121 can be moved at the minimum speed. In the term “maximum speed level”, “maximum” means the maximum speed at which the part can be sucked and moved.

  In S8, for example, the component type for which level 4 is set in the component library is set to level 4 because the maximum speed level is level 4.

  The mounting order determining unit 305d determines the mounting order of components on the board 20 based on the input data acquired in the input data capturing process (S6) and the set maximum speed level of the multi mounting head 121 (S10). . Various methods for determining the mounting order have been proposed so far and are not the main point of the present invention, and therefore, detailed description thereof will not be repeated here.

  The board inventory quantity calculation unit 305a calculates the line tact time in the mounting line 200 based on the result of the determination process (S10) and the mounting tact level of the multi mounting head 121 (S12). For example, it is assumed that the tact time per substrate is 3 minutes.

  The board inventory quantity calculation unit 305a calculates the number of boards produced within the operation time based on the line tact time (S14). Here, the operating time is, for example, a time during which the factory is operating, for example, 8 hours. Then, the production number of substrates is obtained by the following equation (1).

      Number of sheets produced = operation time / tact time (1)

  As described above, when the tact time is 3 minutes / sheet and the operation time is 8 hours (= 480 minutes), when these values are applied to the equation (1), the following equation (2) is obtained. .

      Number of production = 480/3 = 160 (2)

  That is, the number of substrates produced within the operation time (8 hours) is required to be 160.

  The board inventory quantity calculation unit 305a calculates the shipment inventory quantity after the operation time has elapsed according to the following equation (3) (S16).

      Shipment stock quantity = production quantity + current warehouse quantity-order quantity (3)

  When the above-mentioned value is applied to the following equation (3), the shipment inventory quantity is as shown in the following equation (4).

      Shipment stock quantity = 160 + 30−150 = 40 (4)

  That is, the number of boards shipped after the operation time has elapsed is calculated to be 40.

The board production quantity control unit 305b checks whether or not the shipment inventory quantity is within the predetermined appropriate inventory quantity TH1 (S18). If the shipment inventory quantity is less than or equal to the appropriate inventory quantity TH1 (YES in S18), the board production quantity control unit 305b starts board production while maintaining the production conditions such as the currently set mounting tact level. (S22). In addition, the inventory quantity display control unit 305c causes the display unit 302 to display a graph showing the temporal transition of the shipment inventory quantity of the board (S24).

  FIG. 10 is a diagram illustrating an example of the displayed graph. In the upper part of this graph, the order tact time and the actual tact time are compared and displayed. The order tact time is a value obtained by dividing the operation time by the number of orders. The actual tact time is a value obtained by the above-described tact time calculation process (S12). In the lower part of the graph, a graph showing the temporal transition of the shipment inventory quantity is displayed, and the appropriate inventory quantity TH1 is shown in the graph. That is, it can be seen at a glance whether or not the shipment inventory quantity exceeds the appropriate inventory quantity TH1.

  If the shipment stock quantity is larger than the appropriate stock quantity TH1 (NO in S18), the board production quantity control unit 305b lowers the mounting tact level in the component mounter 22 or 24 by one rank (S20). That is, the moving speed of the multi mounting head 121 is lowered by one rank. Thereafter, the processing after the mounting order determination processing (S10) is executed. For example, when the appropriate inventory quantity TH1 is 30, the shipment inventory quantity obtained earlier is 40, so the condition of S18 is not satisfied. Therefore, the board production number control unit 305b lowers the mounting tact level by one rank (S20). As a result, the line tact time is increased and the number of sheets produced within the operation time is reduced. Therefore, the number of shipment stocks also decreases, and eventually, the board production start process (S22) and the graph display process (S24) are executed.

  As a method of lowering the mounting tact level, for example, a method of uniformly reducing the speed of all parts, a method of reducing a speed by selecting a specific part, a level of only a part of the maximum speed level (for example, level 1), etc. Can be illustrated.

  As described above, according to the production system 10 according to the first embodiment, the determination is made while changing the mounting conditions such as the moving speed of the multi-mounting head so that the shipment stock quantity is equal to or less than the proper stock quantity. For this reason, the number of shipping stocks can be reduced as much as possible, and cost loss due to shipping stocks can be reduced.

  Further, the power consumption of the drive motor can be reduced by lowering the mounting tact level.

  In addition, the time transition of the shipment inventory is displayed in a graph. Therefore, the operator can know at a glance whether or not the shipment stock quantity is appropriate.

  Moreover, although the above demonstrated the example of the line as embodiment, the said description only showed one Embodiment of this invention, and this invention is not limited to the said embodiment. Therefore, in the present invention, the production number of one component mounting machine may be controlled so that the inventory quantity related to one component mounting machine is within the appropriate inventory quantity.

  In the above embodiment, the mounting condition is determined. However, the determination includes optimization for determining the optimal mounting condition. Alternatively, the mounting condition includes the mounting order, and the determination of the mounting order so that the mounting time is shortened is also included in the determination of the mounting condition.

  Further, in the above embodiment, the mounting tact level is exemplified, but the present invention is not limited to this. For example, in the case of a component mounting machine or a production line having a plurality of sub facilities, the sub facilities The beam may be stopped (power supply is stopped) to adjust the number of shipments to an appropriate inventory number or less and reduce power consumption. In the case of a multi-mounted head having a plurality of suction nozzles, the use of a part of the suction nozzles is stopped. For example, when the suction nozzles are arranged in two rows, one of the suction nozzles is not used and shipped. The power consumption may be reduced while adjusting the number below the proper stock quantity. Here, the power consumption can be reduced by stopping the use of a part of the suction nozzle because the use of the suction nozzle is stopped by closing the vacuum system connected to each suction nozzle with a valve. This is because leakage is reduced and the load on the vacuum pump is reduced.

[Embodiment 2]
In Embodiment 2 of the present invention, a substrate production system capable of reducing cost loss due to process costs will be described. Note that description common to the first embodiment is omitted as appropriate.

  FIG. 11 is an external view of the substrate production system according to the second embodiment of the present invention as viewed from above. FIG. 12 is a schematic diagram of the production system shown in FIG.

  The production system 1000 is a system for producing a component mounting board in which components are mounted on a board, and includes a back surface mounting line 700, a stocker 30a, a conveyor 154, a board reversing device 156, and a surface mounting line 800. And a board production number control device 300 (not shown). The substrate sequentially flows in the direction indicated by the arrows in FIGS.

  The back surface mounting line 700 is a mounting line for mounting components on the back surface of the substrate. From the upstream side, the stocker 14a, the solder printing device 16a, the conveyor 18a, the adhesive application device 21a, and the component mounting machine 22a. The component mounting machine 24a, the conveyor 26a, and the reflow furnace 28a are provided.

  The surface mounting line 800 is a mounting line for mounting components on the surface of the substrate. From the upstream side, the solder printing device 16b, the conveyor 18b, the adhesive application device 21b, the component mounting machine 22b, and the component mounting machine. 24b, a conveyor 26b, a reflow furnace 28b, and a stocker 14b.

  The stockers 14 a, 30 a, and 14 b are devices for stocking boards. The stocker 14 a is located on the uppermost stream of the back surface mounting line 700, and the stocker 30 a is located on the most downstream side of the back surface mounting line 700. The stocker 14b is located on the most downstream side of the surface mounting line 800.

  That is, the stocker 14a is stocked with a substrate on which no component is mounted facing upward, the stocker 30a is stocked with a substrate with components mounted only on the back surface, and the stocker 14b has components mounted on both sides. The finished product substrate is stocked.

The solder printing devices 16a and 16b are devices that print solder on the surface of the substrate.
The conveyors 18a, 26a, 154, 18b, and 26b are devices that transport substrates. The adhesive application devices 21a and 21b are devices that apply an adhesive on a substrate.

  The reflow furnaces 28a and 28b are devices that fix the components on the substrate after melting the solder and the like by heating the substrate 20 on which the components are mounted.

  The substrate reversing device 156 is a device that reverses the front and back of the substrate conveyed by the conveyor 154.

  The configuration of the component mounters 22a, 24a, 22b, and 24b is the same as that of the component mounters 22 and 24 shown in the first embodiment.

  The board production number control device 300 is a computer for controlling the number of boards produced in each production facility constituting the back surface mounting line 700 and the front surface mounting line 800, and the configuration thereof will be described in the first embodiment. It is the same as what I did.

  Next, processing executed by the board production number control apparatus 300 will be described. FIG. 13 is a flowchart of processing executed by the board production number control apparatus 300.

  In the production system 1000, a process for capturing the current number of boards to be produced (S4), a process for capturing input data for creating a mounting program (S6), and for each component in the component mounters 22a, 24a, 22b and 24b. The processing for setting the mounting tact level that defines the mounting speed to the maximum speed level (S8), the mounting order determination processing for components on the board (S10), and the line tact time calculation processing (S12) are the same as in the first embodiment. is there.

  In the line tact time calculation process (S12), the line tact time in the back surface mounting line 700 and the line tact time in the front surface mounting line 800 are calculated. For example, the line tact time of the back surface mounting line 700 is 12 seconds, and the line tact time of the front surface mounting line 800 is 20 seconds.

  The board inventory quantity calculation unit 305a identifies a neckline among a plurality of component mounting lines (S32). The neckline is a line having the longest line tact time among a plurality of component mounting lines. That is, when there are two types of component mounting lines, the back surface mounting line 700 and the front surface mounting line 800, the front surface mounting line 800 is identified as a neck line.

  The board inventory quantity calculation unit 305a calculates the process inventory quantity of the component mounting line of interest other than the neckline according to the following equation (5) (S34).

Number of process stocks = current number of warehouses + operating time / line tact time of the target component mounting line
-Operating time / Neckline line tact time (5)

  Here, as an example, assuming that the current number of warehouses is 10 and the operation time is 1 hour (= 3600 seconds), the process inventory quantity is as shown in the following equation (6).

      Process inventory quantity = 10 + 3600 / 12-3600 / 20 = 130 (6)

  That is, the number of substrate process stocks after the operating time has elapsed is required to be 130. Therefore, when the production of the component board is started under the current mounting conditions, 130 substrates having components mounted only on the back surface are stocked in the stocker 30a as a process inventory after the operation time has elapsed.

  The board production quantity control unit 305b checks whether or not the process inventory quantity is within the predetermined appropriate inventory quantity TH2 (S36). When the process inventory quantity is equal to or less than the predetermined appropriate inventory quantity TH2 (YES in S36), the board production quantity control unit 305b performs board production while maintaining the production conditions such as the currently set mounting tact level. Start (S22). In addition, the inventory quantity display control unit 305c causes the display unit 302 to display a graph showing the temporal transition of the process inventory quantity of the substrate (S24).

  FIG. 14 is a diagram illustrating an example of the displayed graph. In the upper part of this graph, the tact time of the back surface mounting line 700 and the tact time of the front surface mounting line 800 are displayed in comparison. Further, in the lower part of the graph, a graph showing the temporal transition of the process inventory quantity is displayed, and the appropriate inventory quantity TH2 is shown in the graph. That is, it can be seen at a glance whether the process inventory quantity exceeds the appropriate inventory quantity TH2.

  If the process inventory quantity is larger than the appropriate inventory quantity TH2 (NO in S36), the board production quantity control unit 305b lowers the mounting tact level in the component mounter 22a or 24a by one rank (S20). The mounting tact level lowering process (S20) is the same as that described in the first embodiment. Thereafter, the processing after the mounting order determination processing (S10) is executed. For example, when the appropriate inventory quantity TH2 is 20, the process inventory quantity obtained earlier is 130, so the condition of S36 is not satisfied. Therefore, the board production number control unit 305b sequentially decreases the mounting tact level until the process inventory quantity becomes equal to or less than the appropriate inventory quantity TH2. From equation (5), when the line tact time of the component mounting line of interest and the line tact time of the neckline are equal, the number of process stocks and the current number of warehouses are equal.

  As described above, according to the production system 1000 according to the second embodiment, the determination is made while changing the mounting conditions such as the moving speed of the multi-mounting head so that the process inventory quantity is equal to or less than the appropriate inventory quantity. For this reason, the number of process inventory can be reduced as much as possible, and cost loss due to process inventory can be reduced.

  Moreover, the time transition of the process inventory quantity is displayed in a graph. Therefore, the operator can know at a glance whether or not the number of process stocks is appropriate.

  Note that the mounting tact level of the line of interest has been reduced in S20 of FIG. 15, but this is not the case. For example, a part of the component mounted on the neckline so that the process inventory quantity is equal to or less than the appropriate inventory quantity. It is also possible to change the distribution destination to the line that focuses on.

[Embodiment 3]
In the third embodiment of the present invention, a substrate production system for reducing cost loss due to shipping inventory will be described. Note that the description common to the first and second embodiments is appropriately omitted.

  The configuration of the substrate production system according to the third embodiment of the present invention uses a substrate inventory number simulation device instead of the substrate production number control device 300 in the configuration of the production system shown in the first embodiment. is there.

  FIG. 15 is a block diagram showing a functional configuration of the board inventory quantity simulation apparatus.

  The board inventory quantity simulation apparatus 500 uses the board inventory quantity simulation program storage section 505 instead of the board production quantity control program storage section 305 in the configuration of the board production number control apparatus 300 shown in FIG. Since the other processing units are the same as those shown in FIG. 5, detailed description thereof will not be repeated here.

  The board inventory quantity simulation program storage unit 505 is a hard disk or the like that stores various programs for realizing the functions of the board inventory quantity simulation apparatus 500, and is functionally (a process that functions when executed by the arithmetic control unit 301). As a unit), and includes a simulation unit 505a, an inventory quantity display control unit 305c, a mounting order determination unit 305d, and the like.

  The stock quantity display control unit 305c and the mounting order determination unit 305d are processing units similar to those described in the first embodiment.

  The simulation unit 505 a is a processing unit that simulates the number of boards shipped in stock based on the production conditions for the mounting line 200.

  Next, processing executed by the board inventory quantity simulation apparatus 500 will be described. FIG. 16 is a flowchart of processing executed by the board inventory quantity simulation apparatus 500.

  The simulation unit 505a executes an order take-in process (S2) and a current store quantity take-in process (S4). These processes are the same as the processes executed by the board production number control apparatus 300 shown in the first embodiment.

  Next, the mounting order determination unit 305d executes input data fetch processing (S6) for creating a mounting program. This process is the same as that described in the first embodiment.

  The simulation unit 505a takes in the production conditions as the mounting tact level defined in the component library as the initial production conditions (S42). Here, it is assumed that the simulation unit 505a takes in the mounting tact level of the multi mounting head 121 shown in Embodiment 1 from the component library 307b as an example of production conditions.

  Next, the mounting order determination unit 305d executes a mounting order determination process (S10) of components on the board. As described in the first embodiment, this process uses any of various known methods.

  The simulation unit 505a executes a line tact calculation process (S12). This process is the same as that described in the first embodiment.

  The simulation unit 505a calculates the number of substrates produced every predetermined time (for example, every 5 minutes) (S44). This process is the same as the line tact time calculation process (S12) and the production number calculation process (S14) in the first embodiment.

  The simulation unit 505a calculates the shipment inventory quantity for each predetermined time (S46). This process is the same as the shipping inventory quantity calculation process (S16) in the first embodiment.

  The inventory quantity display control unit 305c causes the display unit 302 to display a graph showing the temporal transition of the shipment inventory quantity of the board (S24). This process is the same as that described in the first embodiment. That is, the inventory quantity display control unit 305c causes the display unit 302 to display a graph as shown in FIG. As a result, the shipment stock quantity is displayed every predetermined time.

  When the operator wants to change the production conditions, for example, in the simulation result displayed in S24, the shipment inventory quantity exceeds the appropriate inventory quantity so that the shipment inventory quantity falls within the appropriate inventory quantity. When it is necessary to change the production conditions (YES in S48), the operator inputs the production conditions again using the input unit 303, and the simulation unit 505a takes in the production conditions. (S42), the processing after the mounting order determination processing (S10) is repeated.

  As described above, according to the production system according to the third embodiment, the shipping inventory can be simulated while the operator changes various production conditions of the mounting line. For this reason, the operator can find the optimal production conditions for reducing the cost loss due to the shipping inventory.

[Embodiment 4]
In Embodiment 4 of the present invention, a substrate production system for reducing cost loss due to process inventory will be described. In addition, about the description which is common in the above-mentioned Embodiment 1-3, it abbreviate | omits suitably.

  The configuration of the substrate production system according to the fourth embodiment of the present invention uses a substrate inventory number simulation device instead of the substrate production number control device 300 in the configuration of the production system shown in the second embodiment. is there.

  The board inventory quantity simulation apparatus is a computer for controlling the number of boards produced at each production facility constituting the back surface mounting line 700 and the front surface mounting line 800, and the configuration thereof has been described in the third embodiment. It is the same as that.

  Next, processing executed by the board inventory quantity simulation apparatus 500 will be described. FIG. 17 is a flowchart of processing executed by the board inventory quantity simulation apparatus 500.

  The processes from the current warehouse number import process (S4) to the line tact calculation process (S12) are the same as those described in the third embodiment.

  The neckline specifying process (S32) is the same process as that described in the second embodiment.

The production number calculation process (S44) is the same process as described in the third embodiment.
Next, the simulation unit 505a calculates the number of process inventory for every predetermined time (for example, every 5 minutes) used in the production number calculation process (S44) (S52). This process is the same as the process inventory quantity calculation process (S34) in the second embodiment.

  The inventory quantity display control unit 305c causes the display unit 302 to display a graph showing the temporal transition of the process inventory quantity of the substrate (S24). This process is the same as that described in the second embodiment. That is, the inventory quantity display control unit 305c causes the display unit 302 to display a graph as shown in FIG. Thereby, the number of process stocks is displayed every predetermined time.

The production condition change determination process (S48) is the same as that in the third embodiment.
As described above, according to the production system of the fourth embodiment, the process inventory can be simulated while the operator changes various production conditions of the mounting line. For this reason, the operator can find the optimal production conditions for reducing cost loss due to process inventory.

  As for the production condition change, for example, the distribution destination may be changed to a line for which a part of the component mounted on the neckline is focused so that the process inventory quantity is equal to or less than the appropriate inventory quantity.

  The production system according to the embodiment of the present invention has been described above, but the present invention is not limited to this embodiment.

  For example, in the first to fourth embodiments, the number of process inventory was adjusted by changing the moving speed of the multi mounting head, but by changing the number of component mounting machines used for component mounting, The process inventory quantity may be adjusted. For example, if there are 5 component mounters on the mounting line, if all 5 units are used, if the number of inventory increases, 4 units will be operated and 1 unit will be mounted. Alternatively, only the substrate passing operation may be performed.

  In addition, as described with reference to FIGS. 2 and 3, the component mounter used in the first to fourth embodiments is a so-called multi-function type in which components are mounted on a substrate by moving a multi mounting head. A component mounter called a component mounter. However, the component mounter is not limited to such a multifunctional component mounter, and a so-called high-speed component mounter may be used.

Hereinafter, the high-speed component mounting machine will be described.
FIG. 18 is an external view of a component mounter called a so-called high-speed component mounter as viewed obliquely from the front.

  The component mounter 400 is a mounting device that mounts a plurality of types of components on a printed circuit board constituting an electronic device at high speed. The component mounter 400 picks up, conveys, and mounts components, and the rotary head 403 receives various types of components. And an XY table 404 for moving the placed printed board in the horizontal plane direction.

FIG. 19 is a schematic diagram showing the positional relationship between the component supply unit and the rotary head.
As shown in the upper part of FIG. 19, the rotary head 403 includes 18 mounting heads 406 as mounting means for mounting components on a printed circuit board. Further, the mounting head 406 is attached to a rotating base 405 that rotates without moving in the height direction so as to be movable in the height direction, and a suction nozzle (not shown) that can hold components by vacuum suction. 6 are provided.

  As shown in the lower part of FIG. 19, the component supply unit 402 includes component cassettes 123 that can sequentially provide the same components to the mounting head 406 in a horizontal row. The component supply unit 402 has a function of selecting a component to be mounted by moving and positioning the component supply unit 402 with respect to the rotary head 403 in the Z-axis direction in FIG.

  FIG. 20 is a diagram schematically illustrating the positional relationship among the rotary head, the substrate, and the component supply unit.

  As shown in the figure, the rotary shaft of the rotary head 403 does not move, and the mounting head 406 provided around the rotary shaft rotates intermittently to perform work corresponding to each position. Briefly, the mounting head 406 positioned at the upper part (position B) of the suction opening 409 provided in each of the component cassettes 123 sucks the component through the suction opening 409, and the mounting head 406 is positioned at a position E facing the mounting head 406. The components that are attracted to the substrate 20 when placed are mounted.

  The substrate 20 to be mounted with the component is placed on an XY table (not shown) that can move in the horizontal plane, and the position where the component is to be mounted is determined by moving the substrate 20.

  In such a component mounter called a high-speed component mounter, the inventory quantity may be adjusted by changing the rotational speed of the rotary head. Further, the inventory quantity may be adjusted by changing the moving speed of the XY table. Further, the inventory quantity may be adjusted by changing the moving speed of the component supply unit.

  Further, the appropriate stock quantity may be determined based on the cost required to maintain the stock quantity of the substrate. For example, the upper limit of inventory cost is determined from the viewpoint of profit being obtained by adding the cost of board and parts to inventory cost, and the appropriate inventory is determined based on the determined upper limit of inventory cost. May be. Further, the cost may be the inventory cost + the board / part cost plus the power charge.

  Further, in the board production quantity control apparatus 300 or the board inventory quantity simulation apparatus 500 according to the first to fourth embodiments, various data are fetched based on the operator's data input (for example, order fetch processing ( S2)), it is not always necessary for the operator to input data, and necessary data may be stored in advance in a storage device such as the database unit 307, and various data may be fetched therefrom.

  Furthermore, the component mounter may have the functions of the board production number control device or the board inventory number simulation device.

  Further, the operation time or the predetermined time described above may be specified in units of time or may be specified in units of days.

  The present invention can be used for a board production number control device or the like by a component mounter for mounting components on a board.

1 is an external view of a substrate production system according to Embodiment 1 of the present invention. It is an external view which shows the structure of a component mounting machine. It is a top view which shows the main structures inside a component mounting machine. It is a block diagram which mainly shows the mechanical structure of a component mounting machine. It is a block diagram which shows the functional structure of a board | substrate production number control apparatus. It is a figure which shows an example of mounting point data. It is a figure which shows an example of a component library. It is a figure which shows an example of mounting machine information. It is a flowchart of the process which a board | substrate production number control apparatus performs. It is a figure which shows an example of the displayed graph. It is an external view at the time of looking down at the board | substrate production system which concerns on Embodiment 2 of this invention from diagonally upward. It is a schematic diagram at the time of looking down at the production system shown in FIG. It is a flowchart of the process which a board | substrate production number control apparatus performs. It is a figure which shows an example of the displayed graph. It is a block diagram which shows the functional structure of a board | substrate stock quantity simulation apparatus. It is a flowchart of the process which a board | substrate stock quantity simulation apparatus performs. It is a flowchart of the process which a board | substrate stock quantity simulation apparatus performs. It is the external view which looked at the component mounting machine called what is called a high-speed component mounting machine from diagonally forward. It is the schematic which shows the positional relationship of a components supply part and a rotary head. It is the figure which showed typically the positional relationship of a rotary head, a board | substrate, and a component supply part. It is a figure for demonstrating the subject of a prior art. It is a figure for demonstrating the subject regarding process inventory. It is another figure for demonstrating the subject regarding process inventory.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Production system 200 Mounting line 300 Board production number control apparatus 301 Arithmetic control part 302 Display part 303 Input part 304 Memory part 305 Board production number control program storage part 305a Board inventory number calculation part 305b Board production number control part 305c Inventory number display control Section 305d Mounting order determining section 306 Communication I / F section 307 Database section 307a Mounting point data 307b Component library 307c Mounting machine information 500 Board inventory quantity simulation device 505 Board inventory quantity simulation program storage section 505a Simulation section

Claims (9)

A board inventory quantity simulation method for simulating the inventory quantity of a board by a component mounting line composed of a plurality of component mounting machines and mounting a component on a board,
The component mounting line includes a component mounter that moves a head that sucks the component and mounts the component on the board.
A production condition input receiving step for receiving information on the moving speed of the head as a production condition;
A simulation step in which a computer simulates the stock quantity of the substrate based on the production conditions;
A substrate inventory quantity simulation method comprising: A board inventory quantity simulation method for simulating the inventory quantity of a board by a component mounting line composed of a plurality of component mounting machines and mounting a component on a board,
The component mounting line includes a high-speed component mounter that picks up a component by a rotary head that rotates around a predetermined axis and mounts the component on the substrate while moving the substrate.
A production condition input receiving step for receiving information on the rotation speed of the rotary head as a production condition;
A simulation step in which a computer simulates the stock quantity of the substrate based on the production conditions;
A substrate inventory quantity simulation method comprising: A board inventory quantity simulation method for simulating the inventory quantity of a board by a component mounting line composed of a plurality of component mounting machines and mounting a component on a board,
The component mounting line includes a plurality of component mounting machines,
A production condition input receiving step for receiving, as a production condition, the number of component mounters used for mounting the component on the board ;
A simulation step in which a computer simulates the stock quantity of the substrate based on the production conditions;
A substrate inventory quantity simulation method comprising: The substrate stock quantity simulation method according to any one of claims 1 to 3, further comprising a graph display step of graphically displaying a transition of the stock quantity of the simulated board. 5. The substrate inventory quantity simulation method according to claim 4 , wherein the graph display step further displays whether or not the inventory quantity of the board is within a range of a predetermined appropriate inventory quantity. Furthermore, a production condition change input receiving step for receiving a change input of the production conditions of the component mounting machine is included,
In the simulation step, if there is a change input of the production conditions, based on the production condition of the changed any of claims 1-5, characterized in that the re-simulate inventory of the substrate 2. The substrate inventory quantity simulation method according to claim 1.   A component mounting method for simulating the number of boards in stock by a component mounting line composed of a plurality of component mounting machines and mounting the components on the board,
  The component mounting line includes a component mounter that moves a head that sucks the component and mounts the component on the board.
  A production condition input receiving step for receiving information on the moving speed of the head as a production condition;
  A simulation step in which a computer simulates the stock quantity of the substrate based on the production conditions;
A component mounting method comprising: A component mounting method for simulating the number of boards in stock by a component mounting line composed of a plurality of component mounting machines and mounting the components on the board,
  The component mounting line includes a high-speed component mounter that picks up a component by a rotary head that rotates around a predetermined axis and mounts the component on the substrate while moving the substrate.
  A production condition input receiving step for receiving information on the rotation speed of the rotary head as a production condition;
  A simulation step in which a computer simulates the stock quantity of the substrate based on the production conditions;
A component mounting method comprising: A component mounting method for simulating the number of boards in stock by a component mounting line composed of a plurality of component mounting machines and mounting the components on the board,
  The component mounting line includes a plurality of component mounting machines,
  A production condition input receiving step for receiving, as a production condition, the number of component mounters used for mounting the component on the board;
  A simulation step in which a computer simulates the stock quantity of the substrate based on the production conditions;
A component mounting method comprising:

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