JP2017174995A - Substrate production management apparatus, substrate production device, and substrate production line - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a substrate production management apparatus capable of contributing to at least one of remarkable energy saving effects and high process work quality.SOLUTION: The present invention relates to a substrate production management apparatus 2 configured to constitute a substrate production line 1 together with multiple substrate production devices 41-48 and further to manage the multiple substrate production devices. The substrate production management apparatus comprises: a production time acquisition part (step S2) for acquiring a production time Tp(i) of each of the multiple substrate production devices; a substrate presence/absence confirmation part (step S3) for confirming the presence/absence of substrates in the multiple substrate production devices; predetermined time prediction part (steps S6 and S7) for predicting at least either a predetermined substrate carry-in time t3(i) or a predetermined substrate carry-out time t4(i) of each of the multiple substrate production devices based on the production time Tp(i) and the presence/absence of substrates; and a predetermined time notification part (step S10) for notifying each substrate production device of at least the one predetermined time of each of the multiple substrate production devices.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a substrate production management device and a substrate production device that constitute a substrate production line, and further relates to the entire substrate production line.

  As a device for producing a substrate on which a large number of components are mounted, there are a solder printing device, an electronic component mounting device, a reflow device, a substrate inspection device, and the like. It is common to configure a substrate production line by connecting these substrate production apparatuses. In the substrate production line, the transfer of the substrate from the upstream device to the downstream device is interrupted due to various factors, and at least some of the substrate production devices may stop.

  For example, if the component supply unit mounted on the electronic component mounting apparatus is out of components, the component mounting process is interrupted, and the board cannot be carried out to the downstream apparatus. In addition, the board cannot be carried into the electronic component mounting apparatus from the upstream apparatus, and as a result, the operation of the board production line is temporarily stopped. This temporary suspension is eliminated when the operator performs a parts supply operation. Further, if there is a difference in production time (required time for process work) between the substrate production apparatuses, the substrate conveyance may be congested or the substrate conveyance may be sparse. Also in this case, the substrate production apparatus pauses briefly.

  In recent years, energy saving in the board production line has become a big issue, and it is desirable to stop the power supply to the electric load and shift to the energy saving mode as much as possible even in the illustrated temporary and small pauses. It is. On the other hand, demands for improving the operation rate of the substrate production line and improving the quality of the substrate are increasing, and consideration is required when returning from the energy saving mode to the normal operation mode. Patent Documents 1 to 5 disclose technical examples related to the transition to the energy saving mode during operation of the substrate production line and related matters.

  The electronic component mounting apparatus of Patent Document 1 includes a component supply device having a power supply device for supplying a power supply device and a power supply device for controlling a supply device, a component transfer device, and a control device. When the control device detects an operation stop of the component supply device due to the out-of-part of the electronic component, the control device cuts off the power supply to the power supply device for power supply device and maintains the power supply to the power supply device for supply device control To do. According to this, it is said that the power source for power to the stopped component supply apparatus can be cut off, and unnecessary power consumption is eliminated.

  Moreover, the monitoring method of patent document 2 is disclosing the monitoring method of the board | substrate production line comprised from a some production facility. This monitoring method includes a monitoring step for monitoring the operating status of at least one production facility, and an operation control step for controlling another production facility to an operating state or a non-operating state based on the monitoring result of the monitoring step. Further, in the monitoring step, it is detected whether or not a substrate has been carried into the upstream production facility, and in the operation control step, the start timing of the downstream production facility is determined so that the substrate is in operation when it arrives. . According to this, energy saving can be achieved without deteriorating the production efficiency and quality of the substrate. Patent Document 3 also discloses a similar technique.

  The electronic component mounting apparatus of Patent Literature 4 includes an essential component having a substrate holding and moving device, a component supply device, and a component transfer device, and a control device that controls the essential component. And according to each level of three states, the operation waiting state in a normal state, a non-normal state, and the component supply suspension state in a normal state, the apparatus in an essential component part part is selected, and electric power supply is interrupted | blocked. In other words, a plurality of levels are set in the energy saving mode according to the three states. According to this, it is said that power consumption can be reduced compared with the past.

  The electronic component mounting apparatus of Patent Document 5 is based on means for mounting an electronic component on a circuit board, means for measuring the amount of positional deviation of the electronic component actually mounted on the circuit board, and the measurement result of the amount of positional deviation. Means for calculating a mounting position correction amount for the mounting position information. In the driving of the electronic component mounting apparatus, the mounting position information is updated on the basis of the amount of positional deviation in the predetermined number of circuit boards obtained by sampling. In other words, the mounting position information is periodically calibrated. According to this, even if a position shift occurs in the electronic component, it can be automatically corrected in a timely manner, and since it is a sampling measurement, it can be operated at a high operating rate.

Japanese Patent No. 3841585 JP 2006-310750 A JP 2001-320199 A JP 2003-264399 A JP-A-7-326895

  By the way, the technical example of patent document 1 transfers to an energy-saving mode, when a stop factor generate | occur | produces inside an electronic component mounting apparatus. Therefore, when a stop factor occurs in one of the upstream devices and the board cannot be carried in, or when a stop factor occurs in any of the downstream devices and the board cannot be carried out, the energy saving mode is set. Cannot migrate. That is, the interaction between a plurality of substrate production apparatuses constituting the substrate production line is not considered.

  On the other hand, Patent Document 2 is a technology in which control is performed by a host-side substrate production management device that performs monitoring. The substrate production management device performs process work based on the timing when a substrate is carried into an upstream device. The later carry-out timing is estimated, and the start timing of the downstream device is determined and commanded accordingly. Therefore, in the technical example of Patent Document 2, the interaction from the upstream device to the downstream device is considered, and the reverse interaction is not considered. That is, even if the substrate production apparatus cannot carry out the substrate subjected to the process work due to a downstream stop factor, the substrate production apparatus receives the start command under a situation where the next substrate can be carried in, and therefore cannot shift to the energy saving mode.

  Moreover, in patent document 2, it is actually difficult to determine the starting timing of a downstream apparatus appropriately. Furthermore, in Patent Document 4, it is difficult to return from a plurality of levels of energy saving mode, and in Patent Document 5, it is difficult to balance the execution timing of the calibration process with the energy saving mode. More specifically, a return time is required to return from the stop state or the energy saving mode to the normal operation mode. For example, the display of the display device can be instantaneously restored, but generally, the restoration time becomes longer as the electric load having a larger energy saving effect amount such as a power source or temperature control management. In addition, there are various types and differences in characteristics of the board production apparatus, and the operation status changes from time to time. Therefore, the required recovery time varies depending on the electric load stopped in the energy saving mode, and further depends on the type and characteristics of the board production apparatus.

  For this reason, when the board production management apparatus centrally determines the start timing of each board production apparatus, a harmful effect occurs. For example, the transition from the energy saving mode to the operation mode becomes too late in the board production apparatus, so that the return time is not secured, and the quality of the process work is deteriorated. Conversely, the transition from the energy saving mode to the operation mode becomes too early, and the opportunity to obtain a sufficient energy saving effect is lost. Therefore, the board production management device notifies the timing of board loading and unloading, and the board production device considers individual characteristics and operating conditions, and shifts to and returns to energy-saving mode autonomously. It is preferable to switch the energy saving mode of the level.

  The present invention has been made in view of the above problems of the background art, and predicts at least one of a scheduled loading time and a scheduled loading time when a substrate can be loaded and unloaded in a substrate production apparatus. Accordingly, it is an object to be solved to provide a substrate production management device, a substrate production device, and a substrate production line that can contribute to at least one of a large energy saving effect and good process work quality.

  The substrate production management apparatus according to claim 1 of the present invention for solving the above-mentioned problems is a substrate production line together with a plurality of substrate production apparatuses that are arranged side by side and each carry in a substrate, carry out a predetermined process operation, and carry it out. And a substrate production management apparatus for managing the plurality of substrate production apparatuses, each of the plurality of substrate production apparatuses acquiring a production time required for performing the process operation on one substrate. A production time acquisition unit, a substrate presence / absence confirmation unit for confirming whether or not the substrate is present in each of the plurality of substrate production apparatuses, the production time of each of the plurality of substrate production apparatuses, and the substrate Based on the presence / absence of the information, information on a scheduled loading time when the substrate can be loaded into each of the plurality of substrate production apparatuses, and the substrate is unloaded from each of the plurality of substrate production apparatuses. A scheduled time predicting unit that predicts at least one of the information related to the scheduled carry-out time scheduled to become active, and at least one information of each of the plurality of substrate production apparatuses is notified to each substrate production apparatus And a scheduled time notification unit.

  A substrate production apparatus according to claim 2 of the present invention constitutes the substrate production line together with the substrate production management device according to claim 1, and further carries the substrate into the substrate, carries out the process operation, and carries it out. An apparatus, a scheduled time acquisition unit that acquires the at least one information from the scheduled time notification unit of the substrate production management apparatus, the at least one information, and whether or not the substrate is present in the apparatus. An operation status change unit that changes the operation status based on the confirmed substrate presence / absence information.

  Furthermore, a substrate production line according to an eighth aspect of the present invention includes the substrate production management device according to the first aspect and a plurality of the substrate production devices according to the second aspect.

  The substrate production management apparatus according to claim 1 of the present invention predicts information related to at least one of a scheduled loading time and a scheduled unloading time based on the production time of a plurality of substrate production apparatuses and the presence or absence of a substrate in the apparatus, Notify each board production device. This suggests a time for changing the operating status of the board production apparatus. Specifically, at least one of the timing for switching between the operation mode and the energy saving mode of the substrate production apparatus and the timing for starting the preparatory work prior to the process work is suggested. Therefore, the board production management apparatus can contribute to at least one of selection of an appropriate energy saving mode and timely preparation work in the board production apparatus. In other words, the board production management device can contribute to at least one of a large energy saving effect and good process work quality.

  Further, the substrate production apparatus according to claim 2 of the present invention can change the operation status based on the acquired information on at least one of the scheduled carry-in time and the scheduled carry-out time. Specifically, the board production system autonomously decentralizes in consideration of individual characteristics and operating conditions, and at least one of the switching time between the operation mode and the energy saving mode and the start time of the preparation work prior to the process work. decide. According to this, the substrate production apparatus can appropriately select the energy saving mode, or can perform the preparation work in a timely manner and proceed to the process work smoothly. Therefore, at least one of a large energy saving effect and good process work quality is realized.

  Furthermore, according to the substrate production line of claim 8 of the present invention, at least one of a large energy saving effect and good process work quality is realized in each of the plurality of substrate production apparatuses constituting the line.

It is a block diagram which shows typically the structure of the board | substrate production line of 1st Embodiment, and also combines the figure which shows the condition when the first board | substrate is carried in to the 1st board | substrate production apparatus of a board | substrate production line in the 1st example. ing. It is the functional block diagram which showed the function structure of the board | substrate production line of 1st Embodiment. It is the figure which showed the processing flow of the board | substrate production management apparatus of embodiment. It is the figure which showed the processing flow of the board | substrate production apparatus of embodiment. It is a figure which shows the condition immediately after the process operation | work of a 1st board | substrate production apparatus was complete | finished with delay in the 1st case, and the board | substrate was conveyed toward the 2nd board | substrate production apparatus from the 1st board | substrate production apparatus. It is the figure which showed the condition immediately after the 1st board | substrate was carried in to the 1st board | substrate production apparatus of a board | substrate production line in the 2nd example. It is the figure which showed the condition immediately after the last board | substrate was carried in to the 3rd board | substrate production apparatus of a board | substrate production line in the 2nd example. It is the figure which showed the condition immediately after the board | substrate which was stopped in the 7th board | substrate production apparatus of a board | substrate production line in the 2nd example, and a board | substrate was simultaneously carried in to the 2nd and 1st board | substrate production apparatuses. In the second example, it is a diagram showing a situation in which a transportation jam occurs because the fourth board production apparatus (electronic component mounting apparatus) of the board production line is out of components and the mounting process work is not performed on the board. It is the functional block diagram which showed the function structure of the board | substrate production line of 2nd Embodiment. It is the figure which showed the processing flow of the board | substrate production management apparatus in 2nd Embodiment. It is the figure which showed the processing flow of the board | substrate production apparatus in 2nd Embodiment. It is the figure which illustrated the condition at the time of the start of a substrate damming function. It is the figure which illustrated the situation where the substrate damming function is acting. It is the figure which illustrated the condition at the time of the end of a substrate damming function.

(1. Configuration and function of the board production line 1 of the first embodiment)
A substrate production line 1 according to a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a configuration diagram schematically showing the configuration of the substrate production line 1 of the first embodiment. The board production line 1 is composed of one board production management apparatus 2 and eight first to eighth board production apparatuses 41 to 48. The substrate production management device 2 is also an embodiment of the substrate production management device of the present invention. Each of the first to eighth substrate production apparatuses 41 to 48 is also an embodiment of the substrate production apparatus of the present invention. The seventh and eighth substrate production apparatuses 47 and 48 are omitted in FIG.

  The board production management device 2 can be configured using, for example, a computer device having a CPU and operating with software. The board production management device 2 includes a display device and an input device (not shown) as an interface tool for exchanging information with an operator. The first to eighth substrate production apparatuses 41 to 48 are arranged side by side, and each carries a substrate from the upstream side, performs a predetermined process operation, and carries it out to the downstream side.

  A solder printing apparatus can be exemplified as the first board production apparatus 41, and a solder inspection apparatus can be exemplified as the second board production apparatus. As the third to sixth substrate production apparatuses 43 to 46, electronic component mounting apparatuses can be exemplified. A substrate appearance inspection device can be exemplified as the seventh substrate production device 47, and a reflow device can be exemplified as the eighth substrate production device 48. The contents of the process operations of the exemplified substrate production apparatus are publicly known and will not be described. The first to eighth substrate production apparatuses 41 to 48 may be substrate production apparatuses other than those exemplified. Further, the number of substrate production apparatuses constituting the substrate production line 1 is not limited to eight.

  The board production management apparatus 2 and the first to eighth board production apparatuses 41 to 48 are connected for communication by a communication means (not shown) such as a local area LAN. The board production management apparatus 2 notifies various information and commands related to board production to the first to eighth board production apparatuses 41 to 48 (broken arrows in FIG. 1). Conversely, the first to eighth substrate production apparatuses 41 to 48 notify the substrate production management apparatus 2 of various information and responses for reporting the operation status (solid arrows in FIG. 1).

  FIG. 2 is a functional block diagram showing a functional configuration of the board production line 1 of the first embodiment. The substrate production management device 2 has functions of a production time acquisition unit 21, a substrate presence / absence confirmation unit 22, a scheduled time prediction unit 23, a scheduled time notification unit 24, and a production end notification unit 25. On the other hand, each of the 1st-8th board | substrate production apparatuses 41-48 has the function of the scheduled time acquisition part 61, the waiting time estimation part 62, and the operation condition change part 63. The operating status changing unit 63 includes an energy saving mode switching unit 64 and a preparation work starting unit 65.

(2. Operation of the board production management device 2 of the embodiment)
Next, the operation of the substrate production management apparatus 2 of the embodiment will be described. FIG. 3 is a diagram illustrating a processing flow of the substrate production management apparatus 2 according to the embodiment. In FIG. 3, “Each apparatus” represents the first to eighth substrate production apparatuses 41 to 48. In order to change the type of substrate produced on the substrate production line 1, a setup change operation is performed. In conjunction with the setup change work, the board production management apparatus 2 performs the processes of steps S1 and S2 in FIG.

  That is, in the initial setting in step S1, the production end notification unit 25 of the board production management device 2 sets the type of board to be produced and the planned production number Nt. The type of substrate and the planned production number Nt are input by, for example, an operator operating an input device. Further, the production end notification unit 25 sets the number of actual productions Nn (i) of each of the first to eighth substrate production apparatuses 41 to 48 to zero, and clears each end flag F (i). The subscript i in parentheses of the production record number Nn (i) and the end flag F (i) indicates the first to eighth differences. In the middle of production, the actual production numbers Nn (1) to Nn (8) of the first to eighth substrate production apparatuses 41 to 48 are different from each other. The end flag F (i) is a flag that indicates that the actual production number Nn (i) of the board has reached the planned production number Nt.

  In the next step S2, the production time acquisition unit 21 acquires the production times Tp (i) of the first to eighth substrate production apparatuses 41 to 48. The production time Tp (i) is a time required for each of the first to eighth substrate production apparatuses 41 to 48 to perform a process operation on one substrate. The production time Tp (i) includes the time required for substrate loading, positioning, position release, and unloading. The production time Tp (i) is estimated by, for example, a production optimization simulation, stored in a database (not shown), and transferred to the production time acquisition unit 21. Note that the production time Tp (i) may be replaced with the actual production time when the production of the substrate progresses and the actual production time is determined.

  When the process of step S2 is completed and the setup change work is completed, the board production management device 2 advances the execution of the process flow to step S3. Thereafter, the substrate production management device 2 repeats the processing cycles after step S3 at predetermined cycle time intervals. In step S <b> 3, the substrate presence / absence confirmation unit 22 confirms whether or not there is a substrate in each of the first to eighth substrate production apparatuses 41 to 48.

  In the next step S4, the production end notification unit 25 performs management for increasing the production result number Nn (i) by 1 with respect to the substrate production apparatus that has unloaded the substrate. The substrate production apparatus that has unloaded the substrate can be identified from the fact that there is a substrate in the apparatus in the previous processing cycle, the process operation is normally completed, and there is no substrate in the current processing cycle.

  In the next step S5, the scheduled time predicting unit 23 carries in a substrate t1 (i) when a substrate is actually loaded from a substrate production apparatus that has no substrate in the apparatus in the previous processing cycle and has a substrate in the current processing cycle. To get. Further, the scheduled time prediction unit 23 acquires the unloading time t2 (i) when the substrate is actually unloaded from the substrate production apparatus in which the substrate is present in the apparatus in the previous processing cycle and the substrate is not present in the current processing cycle.

  In the next step S <b> 6, the scheduled time predicting unit 23 predicts a scheduled loading time t <b> 3 (i) that is scheduled when a substrate can be loaded into each of the first to eighth substrate production apparatuses 41 to 48. This prediction is performed based on the production time Tp (i) of each of the first to eighth substrate production apparatuses 41 to 48 and the presence / absence of the substrate, and the carry-in time t1 (i) is also referred to. For example, in the most upstream first substrate production apparatus 41, there is no upstream apparatus, so that it is possible to carry in immediately if a substrate is prepared. Accordingly, the scheduled carry-in time t3 (1) is predicted to be the current time tnow.

  Further, for example, in the second substrate production apparatus 42, the scheduled carry-in time t3 (2) depends on the progress status of the process work of the upstream first substrate production apparatus 41. When there is a substrate in the apparatus of the first substrate production apparatus 41 and the process work is completed, it is possible to immediately carry it out toward the second substrate production apparatus 42. Therefore, the second substrate production apparatus 42 The scheduled carry-in time t3 (2) is predicted to be the current time tnow.

  Further, even if there is a substrate in the apparatus of the first substrate production apparatus 41, if it is immediately after the process operation is started, the substrate is carried out toward the third substrate production apparatus 43 after the process operation is completed. The Accordingly, the scheduled carry-in time t3 (2) of the second substrate production apparatus 42 is delayed from the current time tnow by the production time Tp (1) of the first substrate production apparatus 41. Furthermore, when there is a substrate in the apparatus of the first substrate production apparatus 41 and the process operation is in progress, the scheduled carry-in time t3 (2) of the second substrate production apparatus 42 is the carry-in time of the first substrate production apparatus 41. The time is delayed by the production time Tp (1) from t1 (1).

  Further, for example, in the third substrate production apparatus 43, the scheduled carry-in time t3 (3) depends on the progress status of the process work of the first and second substrate production apparatuses 41 and 42 on the upstream side. That is, when there is a substrate in the apparatus of the second substrate production apparatus 42 and the process work is completed, the second substrate production apparatus 42 can be immediately carried out toward the third substrate production apparatus 43. Accordingly, the scheduled carry-in time t3 (3) of the third substrate production apparatus 43 is predicted to be the current time tnow.

  Further, it can be assumed that there is no substrate in the apparatus of the second substrate production apparatus 41 and there is a substrate in the apparatus of the first substrate production apparatus 41 and immediately after the process work is started. In this case, after the process work of the first substrate production apparatus 41 and the process work of the second substrate production apparatus 42 are completed, the substrate is carried out toward the third substrate production apparatus 43. Therefore, the scheduled loading time t3 (3) of the third substrate production apparatus 43 is the sum of the production time Tp (1) of the first substrate production apparatus 41 and the production time Tp (2) of the second substrate production apparatus 42. Delayed from the current time tnow.

  As can be seen from the above description, the scheduled loading time t3 (i) of the first to eighth substrate production apparatuses 41 to 48 depends on the progress status of the process work of the upstream substrate production apparatus. Therefore, the scheduled time predicting unit 23 sequentially carries the scheduled loading times t3 (1), t3 (2),... From the first substrate production apparatus 41 on the upstream side to the eighth substrate production apparatus 48 on the downstream side. t3 (8) is predicted.

  In the next step S7, the scheduled time predicting unit 23 predicts the scheduled unloading time t4 (i) when the substrate can be unloaded from each of the first to eighth substrate production apparatuses 41 to 48. This prediction is performed based on the production time Tp (i) of each of the first to eighth substrate production apparatuses 41 to 48 and the presence or absence of the substrate. Here, it is self-evident that the first to eighth substrate production apparatuses 41 to 48 cannot carry out substrates that have not been processed. The above-mentioned scheduled carry-out time t4 (i) means a scheduled time at which the board can be carried out when the board cannot be carried out due to a traffic jam in the downstream apparatus. That is, the scheduled carry-out time t4 (i) is predicted regardless of the presence / absence of the substrate in the apparatus and the progress of the process work. For example, the eighth substrate production apparatus 48 at the most downstream side can carry out immediately since there is no downstream apparatus, and the scheduled carry-out time t4 (8) is the current time tnow.

  Further, for example, in the seventh substrate production apparatus 47, the scheduled carry-out time t4 (7) depends on the progress status of the process work of the eighth substrate production apparatus 48 on the downstream side. That is, when there is a substrate in the apparatus of the eighth substrate production apparatus 48 and the process operation is completed, the ready state for receiving the next substrate is ready. Accordingly, it is possible to immediately carry in the substrate to the eighth substrate production apparatus 48, and the estimated carry-out time t4 (7) of the seventh substrate production apparatus 47 is predicted to be the current time tnow. In addition, even if there is a substrate in the apparatus of the eighth substrate production apparatus 48, if it is immediately after the process operation is started, the next substrate is ready to be received after the process operation is completed. Accordingly, the scheduled carry-out time t4 (7) of the seventh substrate production apparatus 47 is delayed from the current time tnow by the production time Tp (8) of the eighth substrate production apparatus 48.

  As can be seen from the above description, the scheduled carry-out time t4 (i) of the first to eighth substrate production apparatuses 41 to 48 depends on the progress status of the process work of the downstream apparatus. Therefore, the scheduled time predicting unit 23 sequentially carries out the scheduled carry-out times t4 (8), t4 (7),... From the eighth substrate production apparatus 48 on the downstream side to the first substrate production apparatus 41 on the upstream side. t4 (1) is predicted. Even if there is no substrate in any of the first to eighth substrate production apparatuses 41 to 48, the first to eighth substrate production apparatuses 41 to 48 are predicted in order by predicting the scheduled carry-out time t4 (i). The respective unloading scheduled times t4 (i) are obtained.

  In step S6, the scheduled time predicting unit 23 carries in until the substrate is scheduled to be loaded into each of the first to eighth substrate production apparatuses 41 to 48, instead of the scheduled loading time t3 (i). The waiting time may be predicted. Similarly, in step S7, the scheduled time prediction unit 23 replaces the scheduled carry-out time t4 (i) until the substrate is scheduled to be carried out from each of the first to eighth substrate production apparatuses 41 to 48. The unloading waiting time may be predicted.

  In the next step S8, the production end notifying unit 25 determines whether the production performance number Nn (i) of the first to eighth substrate production apparatuses 41 to 48 has reached the planned production number Nt. Determine the branch destination. When a part or all of the actual production numbers Nn (1) to Nn (8) of the first to eighth substrate production apparatuses 41 to 48 have reached the planned production number Nt, in step S9, An end flag F (i) is set. The set end flag F (i) corresponds to a production end command.

  When none of the actual production numbers Nn (i) of the first to eighth substrate production apparatuses 41 to 48 has reached the production scheduled number Nt, and after the execution of step S9, the production end notification unit 25 executes the processing flow. To step S10. In step S10, the scheduled time notification unit 24 notifies the first to eighth substrate production apparatuses 41 to 48 of the scheduled loading time t3 (i) and the scheduled loading time t4 (i), respectively. That is, the scheduled time notification unit 24 notifies the first substrate production apparatus 41 of the scheduled carry-in time t3 (1) and the scheduled carry-out time t4 (1), and the scheduled carry-in time t3 (2) and the scheduled carry-out time t4 (2). Is notified to the second substrate production apparatus 42..., And the eighth substrate production apparatus 48 is notified of the scheduled carry-in time t 3 (8) and the scheduled carry-out time t 4 (8).

  Further, the production end notifying unit 25 notifies the first substrate production apparatus 41 of the end flag F (1), notifies the second substrate production apparatus 42 of the end flag F (2),. The eighth substrate production apparatus 48 is notified of (8). This completes a series of processing cycles, and the execution of the processing flow is returned to step S3.

(3. Operation of substrate production apparatus of embodiment)
Next, the operation of the substrate production apparatus of the embodiment will be described. Since the operations of the first to eighth substrate production apparatuses 41 to 48 are the same, the “first to eighth” articles and the subscript i with parentheses are omitted. FIG. 4 is a diagram illustrating a processing flow of the substrate production apparatus according to the embodiment.

  In the initial setting in step S31 of FIG. 4, the energy saving mode switching unit 64 of the substrate production apparatus 2 sets the first energy saving transition time Ts1 and the second energy saving transition time Ts2. This setting is performed by, for example, an operator's input operation. The second energy saving transition time Ts2 is a threshold time for dividing the operation mode and the second energy saving mode as described later. The first energy saving transition time Ts1 is longer than the second energy saving transition time Ts2, and is a threshold time for dividing the second energy saving mode and the first energy saving mode as will be described later.

  In the first energy saving mode and the second energy saving mode, the board production apparatus stops a part of the electric load in the apparatus itself. In the first energy saving mode, the range of the electric load to be stopped is expanded as compared with the second energy saving mode. Therefore, the first energy saving mode has a relatively large energy saving effect amount as compared with the second energy saving mode.

  For example, in the second energy saving mode, the electronic component mounting apparatus stops a drive motor of the substrate transport unit, a tape feeding motor of the feeder-type component supply unit, a component camera that images the electronic components collected by the mounting head, and the like. Furthermore, in the first energy saving mode, the electronic component mounting apparatus stops the XY drive mechanism that drives the mounting head in addition to the drive motor, the tape feeding motor, and the component camera described above. In addition, for example, the solder printing apparatus stops the drive motor and the like of the board transport unit in the second energy saving mode. Further, in the first energy saving mode, the solder printing apparatus stops the drive motor that reciprocally drives the solder temperature adjustment management unit and the printing squeegee in addition to the drive motor described above.

  As can be seen from the above example, the electrical load that stops in the first energy saving mode and the second energy saving mode varies depending on the type of the board production apparatus. There are also various characteristics of the electric load that returns from the stopped state. Therefore, the first energy saving transition time Ts1 and the second energy saving transition time Ts2 do not have to be the same for all the board production apparatuses, and may be different for each board production apparatus. For example, the first energy saving transition time Ts1 is set to 60 seconds, and the second energy saving transition time Ts2 is set to 30 seconds. There may be a board production device that does not set the first energy saving transition time Ts1 and the second energy saving transition time Ts2, in other words, a board production device that does not expect an energy saving effect.

  Returning to the processing flow, in the initial setting in step S31, the preparation work starting unit 65 sets the preparation time Ts3. This setting is performed by, for example, an operator's input operation. The preparation time Ts3 is set in order to secure time for preparation work prior to process work. The preparation time Ts3 is set to be equal to or shorter than the second energy saving transition time Ts2. Actually, the preparation time Ts3 is determined first, and then the second energy saving transition time Ts2 that is equal to or longer than the preparation time Ts3 is determined.

  For example, a calibration operation of an XY drive mechanism can be exemplified as a preparation operation in the electronic component mounting apparatus. More specifically, when the constituent members of the XY drive mechanism expand and contract depending on the temperature, a control error occurs at the position of the mounting head. Therefore, by performing the calibration work, the influence of the control error can be reduced, and the work quality of the component mounting process can be improved. The calibration work is preferably performed at regular time intervals (for example, every 30 minutes), but is not limited thereto.

  Further, for example, as a preparatory work in the solder printing apparatus, a cleaning work of a mask on which a print pattern is formed can be exemplified. More specifically, if solder printing is continued, the solder may adhere to the mask and cause printing unevenness. For this reason, the work quality of the solder printing process can be improved by cleaning the mask using the automatic cleaning function. The cleaning operation is preferably performed every time the printing process operation is performed on a predetermined number of substrates, but is not limited thereto. In addition, a temperature management operation in which the temperature adjustment management unit returns from the stopped state to optimize the solder temperature is an example of the preparation operation.

  The preparation time Ts3 is set longer than the time required for performing the calibration operation of the electronic component mounting apparatus, the cleaning operation of the solder printing apparatus, and the temperature management operation. Therefore, it is preferable that the preparation time Ts3 is individually set according to the type and characteristics of the substrate production apparatus. There may be a substrate production apparatus that does not require the preparation time Ts3.

  When the process of step S31 ends, the board production apparatus advances the execution of the process flow to step S32. Thereafter, the substrate production apparatus repeats the processing cycles after step S32 at predetermined cycle time intervals. In step S <b> 32, the scheduled time acquisition unit 61 acquires the scheduled loading time t <b> 3 and the scheduled loading time t <b> 4 from the scheduled time notification unit 24 of the substrate production management apparatus 2. In addition, the energy saving mode switching unit 64 acquires the end flag F from the production end notification unit 25 of the board production management device 2.

  In the next step S33, the energy saving mode switching unit 64 determines whether or not the end flag F is set. When the end flag F is set, the energy saving mode switching unit 64 advances the execution of the processing flow to step S39. When the end flag F is cleared, the energy saving mode switching unit 64 advances the execution of the processing flow to step S34.

  In step S34, the waiting time prediction unit 62 determines whether or not there is a substrate in its own device, and further determines the progress status of the process work when there is a substrate. The waiting time prediction unit 62 advances the execution of the processing flow to step S35 when there is no substrate, and advances the execution of the processing flow to step S37 when there is a substrate for which the process work has been completed. If there is, the process flow is advanced to step S41.

  In step S35, the waiting time predicting unit 62 subtracts the current time tnow from the scheduled loading time t3 to obtain a loading waiting time T5. Further, the energy saving mode switching unit 64 determines whether or not the carry-in waiting time T5 exceeds the first energy saving transition time Ts1, and if so, the process flow proceeds to step S39, and if not, the processing is performed. The execution of the flow proceeds to step S36. In step S36, the energy saving mode switching unit 64 determines whether or not the carry-in waiting time T5 exceeds the second energy saving transition time Ts2, and if so, the process flow is advanced to step S40. Then, the process flow is advanced to step S41.

  In step S37, the waiting time predicting unit 62 subtracts the current time tnow from the scheduled carry-out time t4 to obtain the carry-out waiting time T6. Further, the energy saving mode switching unit 64 determines whether or not the carry-out waiting time T6 exceeds the first energy saving transition time Ts1, and if so, the process flow proceeds to step S39, and if not, the processing is performed. The execution of the flow proceeds to step S38. In step S38, the energy saving mode switching unit 64 determines whether or not the carry-out waiting time T6 exceeds the second energy saving transition time Ts2, and if it exceeds, the process flow proceeds to step S40, and does not exceed it. Then, the process flow is advanced to step S41.

  In step S <b> 39, the energy saving mode switching unit 64 selects the first energy saving mode in the following first to third cases as a change in the operation status. The first case is a case where the end flag F is set. In the first case, there is no possibility of operation for a long time after the production of a certain type of substrate is completed and the setup change operation is completed corresponding to the type of substrate to be produced next. The second case is a case where there is no substrate in the apparatus and the carry-in waiting time T5 exceeds the first energy saving transition time Ts1. In the second case, since the substrate cannot be carried in for a relatively long time, there is no possibility of operating during that time. The third case is a case where there is a substrate in which the process work is completed in the own apparatus and the unloading waiting time T6 exceeds the first energy saving transition time Ts1. In the third case, since the substrate cannot be carried out for a relatively long time, there is no possibility of operating during that time. Therefore, even if the first energy saving mode having a relatively large energy saving effect amount is selected in the first to third cases, there is no problem in operation. After execution of step S39, execution of the processing flow is returned to step S32.

  In step S40, the energy saving mode switching unit 64 selects the second energy saving mode in the following fourth and fifth cases as the change of the operation status. The fourth case is the four cases where there is no substrate in the apparatus and the carry-in waiting time T5 is equal to or shorter than the first energy saving transition time Ts1 and exceeds the second energy saving transition time Ts2. In the fourth case, since the substrate cannot be carried in for a relatively short time, there is no possibility of operating during that time. The fifth case is a case where there is a substrate in which the process work is completed in the own apparatus, and the unloading waiting time T6 is equal to or shorter than the first energy saving transition time Ts1 and exceeds the second energy saving transition time Ts2. In the fifth case, since the substrate cannot be carried out for a relatively short time, there is no possibility of operating during that time. Therefore, even if the second energy saving mode having a relatively small energy saving effect amount is selected in the fourth and fifth cases, there is no trouble in operation. After execution of step S40, execution of the processing flow is returned to step S32.

  In step S41, the energy saving mode switching unit 64 selects the normal operation mode in the following sixth to eighth cases as the change of the operation status. The sixth case is a case where there is a substrate in which the process work is not completed in its own apparatus. In the sixth case, since it is necessary to perform a process operation, it is natural that some electric loads cannot be stopped. The seventh case is a case where the carry-in waiting time T5 is equal to or shorter than the second energy saving transition time Ts2. The eighth case is a case where the unloading waiting time T6 is equal to or shorter than the second energy saving transition time Ts2. In the seventh and eighth cases, since at least one of board loading and unloading is imminent, a part of the electric load cannot be stopped.

  In step S42 following step S41, the preparatory work starting unit 65 satisfies both the first condition in which the preparatory work is necessary and the second condition in which the carry-in waiting time T5 is reduced to the preparatory time Ts3 or less. Determine whether or not. The first condition can be determined, for example, based on whether or not a certain time interval has elapsed in the calibration operation described above, or whether or not a predetermined number of substrates have been reached in the cleaning operation described above.

  In step S43 when the first condition and the second condition are satisfied, the preparation work starting unit 65 starts the preparation work. When at least one of the first condition and the second condition is not satisfied in step S42, and after performing the process of step S43, the process flow is advanced to step S44. In step S44, the substrate production apparatus is in a normal operation state. That is, the substrate production apparatus can perform any of substrate loading, process work, and substrate unloading. This completes a series of processing cycles, and the execution of the processing flow is returned to step S32.

  If the preparation time Ts3 and the second energy saving transition time Ts2 are set equal, it is clear that the second condition has already been established in step S36. In this case, the switching from the second energy saving mode to the operation mode and the start of the preparation work are simultaneously performed.

(4. First example of overall operation of the board production line 1 of the first embodiment)
Next, the overall operation of the substrate production line 1 of the first embodiment will be described using a first case. In order to simplify the following description, consider the following first case. The seventh and eighth substrate production apparatuses 47 and 48 are omitted, the production times Tp (i) of the first to sixth substrate production apparatuses 41 to 46 are all 50 seconds, the first energy saving transition time Ts1 is 60 seconds, 2. All energy saving transition times Ts2 are 30 seconds. The current time tnow is 9:00:00. The substrate production management device 2 and the first to sixth substrate production devices 41 to 46 execute the first processing cycle at 8:59:50, and thereafter the cycle time interval of 10 seconds (actually, more than 10 seconds) Repeat the treatment cycle. The processing time and communication time of the substrate production management device 2 and the first to sixth substrate production devices 41 to 46 are extremely short and can be ignored.

  FIG. 1 is also a diagram illustrating a situation when the first substrate K is loaded into the first substrate production apparatus 41 of the substrate production line 1 in the first case. In this case, the board production management apparatus 2 executes the second processing cycle at 9:00:00 of the current time tnow. Accordingly, the substrate presence / absence confirmation unit 22 acquires the “Existence of substrate” information Ex from the first substrate production apparatus 41, and acquires the “No substrate” information Ne from the second to sixth substrate production apparatuses 42 to 46. . Further, the scheduled time prediction unit 23 acquires 9:00:00 of the carry-in time t1 (1) from the first substrate production apparatus 41 whose state has changed from “no substrate” to “with substrate”.

  Next, the scheduled time prediction unit 23 predicts the scheduled loading times t3 (i) of the first to sixth substrate production apparatuses 41 to 46. The scheduled carry-in time t3 (1) of the first substrate production apparatus 41 is predicted to be 9:00:00 of the current time tnow. The scheduled carry-in time t3 (2) of the second substrate production apparatus 42 is delayed by the amount that the first substrate production apparatus 41 performs the production process. Therefore, the scheduled delivery time t3 (2) of the second substrate production apparatus 42 is obtained by adding the production time Tp (1) = 50 seconds of the first substrate production apparatus 41 to the current time tnow, and 9:00:50 It is predicted.

  The scheduled delivery time t3 (3) of the third substrate production apparatus 43 is predicted to be 9:01:40 because it is delayed by the production process performed by the first and second substrate production apparatuses 4142. Hereinafter, the scheduled loading time t3 (4) of the fourth substrate production apparatus 44 is 9:02:30, the scheduled loading time t3 (5) of the fifth substrate production apparatus 45 is 9:03:20, and the sixth substrate production. The scheduled loading time t3 (6) of the device 46 is predicted to be 9:04:10, respectively.

  Moreover, the scheduled time prediction unit 23 predicts the scheduled carry-out times t4 (1) to t4 (6) of the first to sixth substrate production apparatuses 41 to 46. At the current time tnow, there are no substrates in the second to seventh substrate production apparatuses 42 to 47 which are downstream apparatuses. For this reason, the scheduled carry-out times t4 (1) to t4 (6) of the first to sixth substrate production apparatuses 41 to 46 are all predicted to be 9:00:00 of the current time tnow.

  Next, the scheduled time notification unit 24 of the substrate production management apparatus 2 notifies the scheduled loading time t3 (i) and the scheduled loading time t4 (i) to the first to sixth substrate production apparatuses 41 to 46, respectively. The reported scheduled loading times t3 (1) to t3 (6) are respectively shown below the first to sixth substrate production apparatuses 41 to 46 in FIG.

  On the other hand, in the first substrate production apparatus 41, the waiting time predicting unit 62 obtains the loading waiting time T5 (1) and the unloading waiting time T6 (1) because there is a substrate in which the process work has not been completed. There is no need. Then, the energy saving mode switching unit 64 selects the operation mode. In the second substrate production apparatus 42, the waiting time predicting unit 62 obtains the loading waiting time T5 (2) because there is no substrate in the own apparatus. The carry-in waiting time T5 (2) is obtained by subtracting 9:00:50 of the current time tnow from 9:00:50 of the scheduled carry-in time t3 (2), and is 50 seconds. Therefore, the energy saving mode switching unit 64 selects the second energy saving mode.

  Moreover, in the 3rd board | substrate production apparatus 43, since there is no board | substrate in an own apparatus, the waiting time estimation part 62 calculates | requires carrying-in waiting time T5 (3). The carry-in waiting time T5 (3) is 1 minute 40 seconds. Therefore, the energy saving mode switching unit 64 selects the first energy saving mode. Furthermore, in the 4th-6th board | substrate production apparatuses 44-46, carrying in waiting time T5 (4)-T5 (6) becomes larger than 1 minute 40 seconds. Accordingly, each energy saving mode switching unit 64 selects the first energy saving mode.

  When time elapses and the current time tnow becomes 9:00:10, the substrate production management device 2 and the first to sixth substrate production devices 41 to 46 execute the third processing cycle. At this time, each scheduled carry-in time t3 (i) predicted by the scheduled time prediction unit 23 does not change. Further, the predicted carry-out time t4 (i) is all 9:00:10. The operating status of the first to sixth substrate production apparatuses 41 to 46 does not change.

  When the time further elapses and the current time tnow becomes 9:00:20, the substrate production management device 2 and the first to sixth substrate production devices 41 to 46 execute the fourth processing cycle. At this time, each scheduled carry-in time t3 (i) predicted by the scheduled time prediction unit 23 does not change. Further, the estimated carry-out scheduled times t4 (i) are all 9:00:20.

  Here, in the 2nd board | substrate production apparatus 42, since there is no board | substrate in an own apparatus, the waiting time estimation part 62 calculates | requires carrying-in waiting time T5 (2). The carry-in waiting time T5 (2) is obtained by subtracting 9:00:20 of the current time tnow from 9:00:50 of the scheduled carry-in time t3 (2), and is 30 seconds. Therefore, the energy saving mode switching unit 64 ends the second energy saving mode and selects the operation mode. Thereby, the 2nd board | substrate production apparatus 42 will be in the condition in which a preparatory work and normal operation | movement are possible. On the other hand, the operation status of the first, third to sixth substrate production apparatuses 41, 43 to 46 does not change. When the time further elapses and the carry-in waiting time T5 (2) is reduced to the preparation time Ts3 in the second substrate production apparatus 42, the necessary preparation work is started.

  Next, it is assumed that the process work of the first substrate production apparatus 41 is delayed for some reason and the unloading of the substrate K becomes 9:10:00. FIG. 5 is a first example. The process operation of the first substrate production apparatus 41 is completed with a delay, and immediately after the substrate K is transferred from the first substrate production apparatus 41 toward the second substrate production apparatus 42. It is a figure which shows a condition. At this time, the first substrate production apparatus 41 only carries out the substrate K and does not carry it in.

  In the above case, the substrate production management device 2 and the first to sixth substrate production devices 41 to 46 execute a processing cycle at 9:10:00. As a result, the substrate presence / absence confirmation unit 22 acquires the information Ex of “with substrate” from the second substrate production apparatus 42, and “no substrate” from the first and third to sixth substrate production apparatuses 41, 43 to 46. Information Ne is acquired. Further, the scheduled time predicting unit 23 acquires 9:10:00 of the unloading time t2 (1) from the first substrate production apparatus 41 whose state has changed from “with substrate” to “without substrate”. Furthermore, the scheduled time prediction unit 23 acquires 9:10:00 of the carry-in time t1 (2) from the second substrate production apparatus 42 whose state has changed from “no substrate” to “with substrate”.

  Next, the scheduled time prediction unit 23 predicts the scheduled loading times t3 (i) of the first to sixth substrate production apparatuses 41 to 46. The scheduled carry-in times t3 (1) and t3 (2) of the first and second substrate production apparatuses 41 and 42 are predicted to be 9:10:00 of the current time tnow. The scheduled carry-in time t3 (3) of the third substrate production apparatus 43 is delayed by the amount that the second substrate production apparatus 42 performs the production process. Therefore, the scheduled carry-in time t3 (3) is 9:10:50 by adding 50 seconds of the production time Tp (2) of the second substrate production apparatus 42 to 9:10:00 of the current time tnow. It is predicted. Hereinafter, the scheduled loading time t3 (4) of the fourth substrate production apparatus 44 is 9:11:40, the scheduled loading time t3 (5) of the fifth substrate production apparatus 45 is 9:12:30, and the sixth substrate production. The scheduled carry-in time t3 (6) of the device 46 is predicted to be 9:13:20, respectively.

  Further, the scheduled time predicting unit 23 predicts each scheduled carry-out time t4 (i) of the first to sixth substrate production apparatuses 41 to 46. At the current time tnow, there are no substrates in the third to seventh substrate production apparatuses 43 to 47 which are downstream apparatuses. Accordingly, the unloading scheduled times t4 (2) to t4 (6) of the second to sixth substrate production apparatuses 42 to 46 are predicted to be 9:10:00 of the current time tnow. The scheduled carry-out time t4 (1) of the first substrate production apparatus 41 is predicted to be 9:10:50 because it is delayed from the current time tnow by the production time Tp (2) of the second substrate production apparatus.

  Next, the scheduled time notification unit 24 of the substrate production management apparatus 2 notifies the scheduled loading time t3 (i) and the scheduled loading time t4 (i) to the first to sixth substrate production apparatuses 41 to 46, respectively. The scheduled carry-in times t3 (1) to t3 (6) and the scheduled carry-out times t4 (1) to t4 (6) respectively notified below the first to sixth substrate production apparatuses 41 to 46 in FIG. It is shown.

  On the other hand, in the 1st board | substrate production apparatus 41, since there is no board | substrate in an own apparatus, the waiting time estimation part 62 calculates | requires carrying-in waiting time T5 (1). The carry-in waiting time T5 (1) is obtained by subtracting the current time tnow from the scheduled carry-in time t3 (1), and is 0 second. Therefore, the energy saving mode switching unit 64 selects the operation mode. In the second substrate production apparatus 42, the waiting time prediction unit 62 needs to obtain the loading waiting time T5 (2) and the unloading waiting time T6 (2) because there is a substrate in which the process work is not completed in its own device. Absent. Then, the energy saving mode switching unit 64 selects the operation mode.

  In the third substrate production apparatus 43, the waiting time predicting unit 62 obtains a loading waiting time T5 (3) because there is no substrate in its own apparatus. The carry-in waiting time T5 (3) is obtained by subtracting the current time tnow from the scheduled carry-in time t3 (3), and is 50 seconds. Therefore, the energy saving mode switching unit 64 selects the second energy saving mode. In the fourth substrate production apparatus 44, the waiting time prediction unit 62 obtains a loading waiting time T5 (4) because there is no substrate in the apparatus. The carry-in waiting time T5 (4) is obtained by subtracting the current time tnow from the planned carry-in time t4 (3), and is 1 minute 40 seconds. Therefore, the energy saving mode switching unit 64 selects the first energy saving mode. Further, in the fifth and sixth substrate production apparatuses 45 and 46, the loading waiting times T5 (5) and T5 (6) are larger than 1 minute 40 seconds. Accordingly, each energy saving mode switching unit 64 selects the first energy saving mode.

  As described above, the first to sixth substrate production apparatuses 41 to 46 appropriately select the operation mode, the second energy saving mode, and the first energy saving mode according to the length of the substrate loading waiting time T5 (i). it can. Accordingly, a large energy saving effect can be obtained comprehensively. Further, before or at the same time when the carry-in waiting time T5 (i) is reduced to the preparation time Ts3, the operation mode is shifted from the second energy saving mode. Accordingly, the preparation work can be completed in a timely manner before the substrate is actually carried in, and the process work can be smoothly proceeded to, so that a good process work quality can be obtained.

(5. Second example of overall operation of substrate production line 1 of the first embodiment)
Next, the overall operation of the substrate production line 1 of the first embodiment will be described using a second example. In order to simplify the following explanation, consider the following second case. The production times Tp (i) of the first to eighth substrate production apparatuses 41 to 48 are all 25 seconds, the first energy saving transition time Ts1 is all 60 seconds, and the second energy saving transition time Ts2 is all 30 seconds.

  FIG. 6 is a diagram showing a situation immediately after the first substrate K1 is carried into the first substrate production apparatus 41 of the substrate production line 1 in the second case. In this example, in the first substrate production apparatus 41, since there is a substrate that has not completed the process work in its own apparatus, the energy saving mode switching unit 64 selects the operation mode. In the second substrate production apparatus 42, the waiting time prediction unit 62 predicts the loading waiting time T5 (2) = 25 seconds. Therefore, the energy saving mode switching unit 64 selects the operation mode.

  Further, in the third substrate production apparatus 43, the waiting time prediction unit 62 predicts the loading waiting time T5 (3) = 50 seconds. Therefore, the energy saving mode switching unit 64 selects the second energy saving mode. In the fourth substrate production apparatus 44, the waiting time prediction unit 62 predicts the loading waiting time T5 (4) = 1 minute 15 seconds. Therefore, the energy saving mode switching unit 64 selects the first energy saving mode. In the fifth to eighth substrate production apparatuses 45 to 48, the loading waiting times T5 (5) to T5 (8) are longer than 1 minute 15 seconds, so that each energy saving mode switching unit 64 selects the first energy saving mode. To do.

  FIG. 7 is a diagram showing a situation immediately after the last substrate K2 is carried into the third substrate production apparatus 43 of the substrate production line 1 in the second case. At this time, the substrates are carried into the fourth to eighth substrate production apparatuses 44 to 48 at the same time in order. In this case, the first and second substrate production apparatuses 41 and 42 have finished unloading the last substrate K whose production record number reaches the planned production number. Therefore, the production end notification unit 25 of the substrate production management apparatus 2 notifies the set end flags F (1) and F (2) to the first and second substrate production apparatuses 41 and 42. In addition, the production end notification unit 25 notifies the cleared end flags F (3) to F (8) to the third to eighth substrate production apparatuses 43 to 48.

  In the first and second substrate production apparatuses 41 and 42, the energy saving mode switching unit 64 selects the first energy saving mode based on the set end flags F (1) and F (2). In the third to eighth substrate production apparatuses 43 to 48, there are substrates that have not completed the process work in their own apparatuses, and therefore the energy saving mode switching unit 64 selects the operation mode.

  FIG. 8 shows a second case in which the suspended substrate K3 is loaded into the seventh substrate production apparatus 47 of the substrate production line 1 and the substrates K4 and K5 are loaded into the second and first substrate production apparatuses 42 and 41 at the same time. It is the figure which showed the condition immediately after. At this time, there are no substrates in the third to sixth and eighth substrate production apparatuses 43 to 46 and 48. The suspended substrate K3 means a state in which there are no substrates in the front and rear sixth and eighth substrate production apparatuses 46 and 48.

  In this case, in the first and second substrate production apparatuses 41 and 42, there are substrates that have not completed the process work in their own devices, so the energy saving mode switching unit 64 selects the operation mode. In the third substrate production apparatus 43, the waiting time prediction unit 62 predicts the loading waiting time T5 (3) = 25 seconds. Therefore, the energy saving mode switching unit 64 selects the operation mode. Further, in the fourth substrate production apparatus 44, the waiting time prediction unit 62 predicts the loading waiting time T5 (4) = 50 seconds. Therefore, the energy saving mode switching unit 64 selects the second energy saving mode.

  In the fifth substrate production apparatus 45, the waiting time prediction unit 62 predicts the loading waiting time T5 (5) = 1 minute 15 seconds. Therefore, the energy saving mode switching unit 64 selects the first energy saving mode. In the sixth substrate production apparatus 46, the waiting time prediction unit 62 predicts the loading waiting time T5 (6) = 1 minute 40 seconds. Therefore, the energy saving mode switching unit 64 selects the first energy saving mode. In the seventh substrate production apparatus 47, since there is a substrate in which the process work has not been completed in its own apparatus, the energy saving mode switching unit 64 selects the operation mode. In the eighth substrate production apparatus 48, the waiting time prediction unit 62 predicts the loading waiting time T5 (8) = 25 seconds. Therefore, the energy saving mode switching unit 64 selects the operation mode.

  FIG. 9 shows a second example of a situation in which a component jam has occurred in the fourth substrate production apparatus 44 (electronic component mounting apparatus) of the substrate production line 1 and the mounting process work has not been performed on the substrate K7, resulting in a transport congestion. FIG. Under this situation, the fifth to seventh substrate production apparatuses 45 to 47 have already carried the substrate K6 for which the process work has been completed to the eighth substrate production apparatus 48. In this case, in the first to third substrate production apparatuses 41 to 43, the substrate process work in the own apparatus is completed.

  The scheduled time prediction unit 23 of the substrate production management device 2 predicts the scheduled loading times t3 (1) to t3 (5) of the first to fifth substrate production devices 41 to 45 as the current time tnow. The reason is that there is a possibility that parts are supplied to the fourth board production apparatus 44 immediately, the process work is completed in a short time, and the board is transported. Therefore, in the first to fifth substrate production apparatuses 41 to 45, the waiting time prediction unit 62 predicts the loading waiting time T5 (5) = 0 seconds. Therefore, each energy saving mode switching unit 64 selects an operation mode.

  In the sixth substrate production apparatus 46, the waiting time prediction unit 62 predicts the loading waiting time T5 (6) = 25 seconds. Therefore, the energy saving mode switching unit 64 selects the operation mode. In the seventh substrate production apparatus 47, the waiting time prediction unit 62 predicts the loading waiting time T5 (7) = 50 seconds. Therefore, the energy saving mode switching unit 64 selects the second energy saving mode. In the eighth substrate production apparatus 48, since there is a substrate in which the process work has not been completed in its own apparatus, the energy saving mode switching unit 64 selects the operation mode.

  Next, in the situation of FIG. 9, a case is assumed in which the component supply time required for component supply of the fourth substrate production apparatus 44 is set to 3 minutes, for example. The parts replenishment time can be set in advance as a predetermined value, or can be individually set by the operator each time a part runs out. In this case, the scheduled time prediction unit 23 of the board production management device 2 sets the scheduled loading time t3 (4) and the scheduled loading time t4 (4) of the fourth board production device 44 to 3 minutes after the parts supply time has elapsed. Predictable. Furthermore, the scheduled time predicting unit 23 can predict the unloading scheduled times t4 (1) to t4 (3) of the first to third substrate production apparatuses 41 to 43 as being three minutes later, and the fifth to eighth substrate production apparatuses 45. It can be predicted that the carry-in fixed times t3 (5) to t3 (8) of ˜48 will be after 3 minutes.

  Thereby, the unloading waiting times T6 (1) to T6 (4) in the first to fourth substrate production apparatuses 41 to 44 and the loading waiting times T5 (4) to T5 (in the fourth to eighth substrate production apparatuses 44 to 48 ( 8) is 3 minutes or more. Therefore, each energy saving mode switching unit 64 can select the first energy saving mode. And with the passage of time, the unloading waiting times T6 (1) to T6 (4) and the unloading waiting times T5 (4) to T5 (8) decrease. Therefore, each energy saving mode switching unit 64 can appropriately shift from the first energy saving mode to the second energy saving mode and from the second energy saving mode to the operation mode.

  Here, the component supply in the fourth substrate production apparatus 44 is not always completed within the set component supply time. When the component supply is completed earlier than the component supply time elapses, the scheduled time prediction unit 23 is corrected so as to advance the scheduled carry-in time t3 (i) and the scheduled carry-out time t4 (i) in the immediately subsequent processing cycle. To do. In addition, when the component supply is not completed even after the component supply time has elapsed, in the subsequent processing cycle, the scheduled time prediction unit 23 sets the scheduled carry-in time t3 (i) and the scheduled carry-out time t4 (i) to the cycle time interval. Modify to delay by one. Along with these corrections, the scheduled time notifying unit 24 notifies the corrected scheduled loading time t3 (i) and the scheduled unloading time t4 (i) to the first to eighth substrate production apparatuses 41 to 48, respectively.

  As a result, the energy saving mode switching unit 64 of the first to eighth substrate production apparatuses 41 to 48 that has received the notification transitions from the first energy saving mode to the second energy saving mode and from the second energy saving mode to the operation mode. The timing of the transition can be corrected as appropriate.

  As described in the second example, it is effective in the first to eighth substrate production apparatuses 41 to 48 by grasping the loading waiting time T5 (i) and the unloading waiting time T6 (i) related to the substrate transfer status. The first energy saving mode and the second energy saving mode can be selected.

(6. Aspects and effects of the substrate production line 1 of the first embodiment)
The substrate production management device 2 of the embodiment is arranged alongside each other, and a substrate production line together with a plurality of first to eighth substrate production devices 41 to 48 that carry in and carry out a predetermined process operation. 1 is a substrate production management apparatus 2 that manages the first to eighth substrate production apparatuses 41 to 48, and each of the first to eighth substrate production apparatuses 41 to 48 performs a process operation on one substrate. The production time acquisition unit 21 that acquires the production time Tp (i) required when performing the process, and the substrate presence / absence confirmation that confirms whether or not there is a substrate in each of the first to eighth substrate production apparatuses 41 to 48 Based on the production time Tp (i) of each of the unit 22 and each of the first to eighth substrate production apparatuses 41 to 48 and the presence or absence of the substrate, a substrate is placed on each of the first to eighth substrate production apparatuses 41 to 48. Scheduled carry-in time t3 ( ) And scheduled time prediction for predicting at least one of the information related to the scheduled unloading time t4 (i) when the substrate can be unloaded from each of the first to eighth substrate production apparatuses 41 to 48. And a scheduled time notification unit 24 for notifying each of the first to eighth substrate production apparatuses 41 to 48 of information of at least one of the first to eighth substrate production apparatuses 41 to 48. .

  According to this, based on the production time Tp (i) of the first to eighth substrate production apparatuses 41 to 48 and the presence / absence of the substrate in the apparatus, the scheduled loading time t3 (i) and the scheduled unloading time t4 (i ) Is predicted and notified to the first to eighth substrate production apparatuses 41 to 48. This suggests a time for changing the operating status of the first to eighth substrate production apparatuses 41 to 48. Specifically, at least one of the switching time between the operation mode and the energy saving mode of the first to eighth substrate production apparatuses 41 to 48 and the start time of the preparation work prior to the process work is suggested. Therefore, the board production management apparatus 2 can contribute to at least one of selection of an appropriate energy saving mode and timely preparation work in the first to eighth board production apparatuses 41 to 48. In other words, the board production management device 2 can contribute to at least one of a large energy saving effect and good process work quality.

  Moreover, the board | substrate production apparatuses 41-48 of board | substrate are board | substrate production apparatuses which comprise the board | substrate production line 1 with the board | substrate production management apparatus 2 of embodiment, and also carry in a board | substrate and carry out process work, The scheduled time acquisition unit 61 that acquires information on at least one of the scheduled loading time t3 and the scheduled loading time t4 from the scheduled time notification unit 24 of the production management device 2, at least one of the information, and whether or not there is a substrate in the own device And an operation status change unit 63 that changes the operation status based on the substrate presence / absence information that has been confirmed.

  According to this, based on the information regarding at least one of the acquired scheduled carry-in time t3 and scheduled carry-out time t4, the operating status can be changed. Specifically, the board production apparatuses 41 to 48 are autonomously decentralized in consideration of individual characteristics and operation status, and the timing of switching between the operation mode and the energy saving mode and the start time of the preparation work prior to the process work. Determine at least one. According to this, the board production apparatuses 41 to 48 can appropriately select the energy saving mode, or can perform the preparation work in a timely manner and smoothly proceed to the process work. Therefore, at least one of a large energy saving effect and good process work quality is realized.

  Furthermore, the operation status change unit 63 switches between the normal operation mode and the energy saving mode in which some of the electric loads in the apparatus are stopped as the operation status change. According to this, a large energy saving effect is realized.

  Furthermore, the operating status changing unit 63 switches between a plurality of types of energy saving modes having different energy saving effect amounts as a change in operating status. According to this, a greater energy saving effect is realized by using a plurality of types of energy saving modes in combination.

  Furthermore, the plurality of types of energy saving modes include a first energy saving mode with a relatively large energy saving effect amount and a second energy saving mode with a relatively small energy saving effect amount. If there is, the unloading waiting time T6 waiting for unloading of the substrate is predicted based on the information regarding the unloading scheduled time t4, and if there is no substrate in the own apparatus, the unloading of the substrate is waited based on the information regarding the unloading scheduled time t3. The waiting time prediction unit 62 for predicting the loading waiting time T5 is further provided, and the operation status changing unit 63 (energy saving mode switching unit 64) includes the operation mode when there is a substrate in which the process work is not completed. When the carry-in waiting time T5 or the carry-out waiting time T6 exceeds the relatively long first energy saving transition time Ts1, the first energy saving mode is selected, and the carry-in waiting time T Alternatively, when the unloading waiting time T6 is equal to or shorter than the first energy saving transition time Ts1 and exceeds the relatively short second energy saving transition time Ts2, the second energy saving mode is selected, and the loading waiting time T5 or the unloading waiting time T6 is The operation mode is selected when the second energy saving transition time Ts2 or less.

  According to this, a greater energy saving effect can be realized by using a plurality of types of energy saving modes in combination while grasping the loading waiting time T5 or the unloading waiting time T6 related to the substrate transfer status.

  The apparatus further includes a waiting time prediction unit 62 for predicting a loading waiting time T5 for waiting for loading of a substrate based on information related to the scheduled loading time t3 when the substrate is not present in the own apparatus, and an operation status changing unit 63 (preparation) When the carry-in waiting time T5 is reduced to the predetermined preparation time Ts3, the work starting unit 65) starts the preparation work prior to the process work as a change in the operation status. According to this, since the preparation work is completed in a timely manner before the substrate is actually carried in, good process work quality is ensured.

  Further, the operating status change unit 63 (energy saving mode switching unit 64), as the operating status change, has a normal operating mode and an energy saving mode in which a part of the electric load in the own device including the electric load for performing the preparatory work is stopped. When the carry-in waiting time is reduced to the preparation time during the energy saving mode, the operation mode is entered. That is, by setting the preparation time Ts3 and the second energy saving transition time Ts2 equal to each other, the switching from the second energy saving mode to the operation mode and the start of the preparation work can be performed at the same time.

  According to this, since the preparation work is completed in a timely manner before the substrate is actually carried in, good process work quality is ensured and the time zone in the energy saving mode is ensured for a long time to realize a large energy saving effect. The

  Further, the substrate production line 1 of the first embodiment is configured to include a substrate production management device 2 and a plurality of substrate production devices 41 to 48. Accordingly, at least one of a large energy saving effect and good process work quality is realized in each of the plurality of substrate production apparatuses 41 to 48 configuring the line.

  Furthermore, in the board production line 1 of the first embodiment, the board production management device 2 grasps the planned production number Nt for each type of board and manages the production record number Np (i) of the board. The substrate production apparatus 41 is further provided with a production completion notification unit 25 for notifying a production completion command (set completion flag (i)) to the board production apparatus that has unloaded the last board whose Np (i) has reached the planned production number Nt. The operation status changing unit 63 to 48 saves a part of the electric load in the own device from the normal operation mode as a change in the operation status when the production end command is acquired (first energy saving mode). Migrate to

  According to this, the board production apparatuses 41 to 48 are kept in the energy saving mode for a long time from the end of the production of a certain type of board to the end of the setup change operation corresponding to the type of board to be produced next. As a result, a large energy saving effect is realized.

(7. Substrate production line 1A of the second embodiment)
Next, regarding the substrate production line 1A of the second embodiment, differences from the first embodiment will be mainly described. Also in the second embodiment, the substrate production line 1A includes one substrate production management device 2A and eight first to eighth substrate production devices 41 to 48. FIG. 10 is a functional block diagram showing a functional configuration of the board production line 1A of the second embodiment. In the second embodiment, the board production management device 2 </ b> A further includes a damming notification unit 26. On the other hand, the operation status changing unit 63A of the first to eighth substrate production apparatuses 41 to 48 further includes a damming execution unit 66. In the second embodiment, a substrate damming function is added to the first embodiment. The substrate damming function is a function of damming the substrate to be conveyed when the flow of substrate conveyance becomes sparse and promoting the shift to the energy saving mode.

  FIG. 11 is a diagram showing a processing flow of the board production management apparatus 2A in the second embodiment. In 2nd Embodiment, step S21-step S24 are added before step S10 of the processing flow of 1st Embodiment shown by FIG. In step S21, the damming notification unit 26 of the board production management apparatus 2A targets the board production apparatus having the board in the apparatus, subtracts the current time tnow from the scheduled carry-in time t3 (i), and carries-in waiting time T5. Each (i) is obtained. Further, the damming notification unit 26 determines whether there is a substrate production apparatus in which there is a substrate in the apparatus and the carry-in waiting time T5 (i) exceeds the predetermined damming time Ts4. The damming time Ts4 is set equal to, for example, the first energy saving transition time Ts1, and is not limited thereto. When there is no corresponding substrate production apparatus, the damming notification unit 26 advances the execution of the processing flow to step S10 without using the substrate damming function.

  In step S22 to step S24 when there is a corresponding substrate production apparatus, the damming notification unit 26 uses a substrate damming function. Specifically, in step S22, the damming notification unit 26 executes a correction prediction that delays the scheduled carry-out time t4 (i) of the substrate production apparatus until the scheduled carry-in time t3 (i). This means that even if the process operation is completed in the substrate production apparatus, the substrate unloading is restricted, and the substrate unloading after the process operation is completed and the next substrate is carried in at the same time.

  In the next step S23, the damming notification unit 26 corrects and predicts the scheduled carry-in time t3 (i) for the substrate production apparatus downstream of the substrate production apparatus. For example, it is predicted that the scheduled carry-in time t3 (i) of the latest substrate production apparatus on the downstream side of the substrate production apparatus is equal to the scheduled carry-out time t4 (i) of the board production apparatus. Based on this prediction, the scheduled carry-in time t3 (i) of the second and subsequent substrate production apparatuses on the downstream side is also predicted in order. In the next step S24, the damming notification unit 26 notifies the substrate production apparatus of a damming command, and then advances the execution of the processing flow to step S10.

  On the other hand, FIG. 12 is a diagram showing a processing flow of the substrate production apparatus in the second embodiment. In the second embodiment, step S51 and step S52 are added before step S33 of the processing flow of the first embodiment shown in FIG. In step S51, the damming execution unit 66 of the substrate production apparatus determines whether a damming command has been acquired. If not acquired, the damming execution unit 66 advances the execution of the processing flow to step S33 without using the substrate damming function. In step S52 in the case of acquisition, the damming execution unit 66 uses the substrate damming function that regulates the unloading of the substrate for which the process work has been completed until the scheduled loading time t3 (i), and then executes the processing flow. Proceed to step S33.

  Next, the operation by the substrate damming function of the substrate production line 1A of the second embodiment will be described by way of examples. To simplify the following explanation, consider the following case. The production times Tp (i) of the first to eighth substrate production apparatuses 41 to 48 are all 25 seconds, the first energy saving transition time Ts1 is all 60 seconds, and the second energy saving transition time Ts2 is all 30 seconds. The damming time Ts4 is set to 60 seconds. The current time tnow is 9:20:00.

  FIG. 13 is a diagram illustrating the situation at the start of the substrate damming function. FIG. 14 is a diagram illustrating a situation where the substrate damming function is operating. FIG. 15 is a diagram illustrating the situation at the end of the substrate damming function. As shown in FIG. 13, in this case, at 9:20:00 of the current time tnow, the suspended substrate K11 is carried into the sixth substrate production apparatus 46 of the substrate production line 1A, and at the same time the second and second Substrates K12 and K13 are carried into one substrate production apparatuses 42 and 41. At this time, there are no substrates in the third to fifth, seventh, and eighth substrate production apparatuses 43 to 45, 47, and 48.

  The scheduled time predicting unit 23 of the substrate production management device 2A predicts the scheduled loading times t3 (i) of the first to eighth substrate production devices 41 to 48. The scheduled carry-in time t3 (1) of the first substrate production apparatus 41 is predicted to be 9:20:00 of the current time tnow. The scheduled carry-in time t3 (2) of the second substrate production apparatus 42 is delayed by the amount that the first substrate production apparatus 41 performs the production process. Therefore, the scheduled loading time t3 (2) of the second substrate production apparatus 42 is 9:20:25 by adding the production time Tp (1) = 25 seconds of the first substrate production apparatus 41 to the current time tnow. It is predicted. Similarly, the scheduled carry-in time t3 (3) of the third substrate production apparatus 42 is also predicted to be 9:20:25.

  The scheduled delivery time t3 (4) of the fourth substrate production device 44 is predicted to be 9:20:50 because it is delayed by the production process performed by the second and third substrate production devices 4142. Hereinafter, the scheduled loading time t3 (5) of the fifth substrate production apparatus 45 is predicted to be 9:21:15, and the scheduled loading time t3 (6) of the sixth substrate production apparatus 46 is predicted to be 9:21:40. . In addition, the scheduled carry-in time t3 (7) of the seventh substrate production apparatus 47 is delayed by the amount that the sixth substrate production apparatus 41 performs the production process. For this reason, the scheduled carry-in time t3 (7) of the seventh substrate production apparatus 47 is once predicted to be 9:20:25. Further, the scheduled carry-in time t3 (8) of the eighth substrate production apparatus 48 is once predicted to be 9:20:50.

  Further, the scheduled time predicting unit 23 predicts the scheduled carry-out times t4 (i) of the first to eighth substrate production apparatuses 41 to 48. For example, since there is no substrate in the seventh substrate production apparatus 47 that is the downstream apparatus at the current time tnow, the scheduled carry-out time t4 (6) of the sixth substrate production apparatus 46 is 9:20:00 of the current time tnow. It is predicted.

  Next, the damming notification unit 26 subtracts the current time tnow from the scheduled carry-in time t3 (i) for the first, second, and sixth substrate production apparatuses 41, 42, and 46 that have substrates in the apparatus. Then, the loading waiting time T5 (i) is obtained. The loading waiting time T5 (1) of the first substrate production apparatus 41 is 0 seconds, the loading waiting time T5 (2) of the second substrate production apparatus 42 is 25 seconds, and the loading waiting time T5 (6) of the sixth substrate production apparatus 46. Will be 1 minute 40 seconds. Accordingly, the damming notification unit 26 has a substrate in the apparatus, and the sixth substrate production apparatus 46 corresponding to the condition that the loading waiting time T5 (6) exceeds the damming time Ts4 (= 60 seconds). Is the target of the substrate damming function.

  Next, the damming notification unit 26 executes a correction prediction that delays the scheduled carry-out time t4 (6) of the sixth substrate production apparatus 46 until the scheduled carry-in time t3 (6). As a result, the scheduled carry-out time t4 (6) is corrected from 9:20:00 to 9:21:40. Next, the dam notification part 26 corrects and predicts the scheduled loading times t3 (7) and t3 (8) for the seventh and eighth substrate production apparatuses 47 and 48. The scheduled carry-in time t3 (7) of the seventh substrate production apparatus 47 is corrected to 9:21:40, which coincides with the planned carry-out time t4 (6) of the sixth substrate production apparatus 46. The scheduled carry-in time t3 (8) of the eighth substrate production apparatus 48 is corrected to 9:22:05.

  Next, the damming notification unit 26 notifies the sixth substrate production apparatus 46 of a damming command. Next, the scheduled time notification unit 24 notifies the first to eighth substrate production apparatuses 41 to 48 of the scheduled carry-in time t3 (i) and the scheduled carry-out time t4 (i), respectively. Informed upper scheduled times t3 (1) to t3 (8) are shown above the first to eighth substrate production apparatuses 41 to 48 in FIG.

  Here, the first to fifth substrate production apparatuses 41 to 45 are not affected by the substrate damming function. For this reason, the 1st-5th board | substrate production apparatuses 41-45 perform a process operation | work to a board | substrate at the same timing as the case of 1st Embodiment, and convey it, and select an energy saving mode at the same timing. On the other hand, the sixth to eighth substrate production apparatuses 46 to 48 are affected by the substrate damming function. For this reason, in the sixth to eighth substrate production apparatuses 46 to 48, the substrate transport timing is delayed as compared with the first embodiment, and the selection of the energy saving mode is changed.

  Specifically, in the sixth substrate production apparatus 46, the process work applied to the substrate K11 ends at 9:20:25. When the current time tnow becomes 9:20:25, in the first embodiment, the unloading waiting time T6 (6) is 0 seconds, that is, the substrate can be unloaded, and the operation mode is selected. On the other hand, in the second embodiment, the unloading waiting time T6 (6) is obtained by subtracting 9:20:25 of the current time tnow from 9:21:40 of the corrected unloading scheduled time t4 (6). 1 minute 15 seconds. For this reason, the first energy saving mode is selected.

  In the seventh substrate production apparatus 47, in the first embodiment, the carry-in waiting time t5 (7) is obtained by subtracting the current time tnow from 9:20:25 of the scheduled carry-in time t3 (7). Therefore, the operation mode is selected. On the other hand, in the second embodiment, the carry-in waiting time t5 (7) is obtained by subtracting the current time tnow from 9:21:40 of the corrected carry-in scheduled time t3 (7). Accordingly, the first energy saving mode is selected until 9:20:40, the second energy saving mode is selected until 9:21:10, and the operation mode is selected thereafter.

  In the eighth substrate production apparatus 48, in the first embodiment, the carry-in waiting time t5 (8) is obtained by subtracting the current time tnow from 9:20:50 of the scheduled carry-in time t3 (8). Therefore, the second energy saving mode is selected until 9:20:20, and the operation mode is selected thereafter. On the other hand, in the second embodiment, the carry-in waiting time t5 (8) is obtained by subtracting the current time tnow from 9:22:05 of the modified carry-in scheduled time t3 (8). Therefore, the first energy saving mode is selected until 9:21:05, the second energy saving mode is selected until 9:21:35, and the operation mode is selected thereafter.

  As described above, in the second embodiment, the sixth substrate production device 46 that is the target of the substrate damming function, and the seventh and eighth substrate production devices 47 and 48 on the downstream side of the sixth substrate production device 46 The energy saving mode is promoted as compared with the embodiment.

  On the other hand, in the second and first substrate production apparatuses 42 and 41, the process work applied to the substrates K12 and K13 is completed at 9:20:25. Thereafter, the substrates K12, K13, and K14 are transported to the third to first substrate production apparatuses 43 to 41 in the forward direction. As a result, the current time tnow illustrated in FIG. 14 becomes 9:20:40. While the substrate damming function is operating, the sixth substrate production apparatus 46 dams the substrate K11 that has undergone the process operation without carrying it out. On the other hand, in the 5th-1st board | substrate production apparatuses 45-41 of an upstream, a process operation is implemented sequentially and a board | substrate is conveyed. The scheduled loading times t3 (1) to t3 (8) notified at 9:20:40 are shown above the first to eighth substrate production apparatuses 41 to 48 in FIG.

  When 1 minute and 40 seconds have elapsed from the start of the substrate damming function and the current time is 9:21:40, the situation shown in FIG. 15 is obtained. During the elapsed 1 minute 40 seconds, 4 cycles of process operations are performed. Thereby, it will be in the state which has the board | substrates K12-K16 which the process operation | work completed in each apparatus of the 5th-1st board | substrate production apparatuses 45-41. That is, including the sixth substrate production apparatus 46, the six substrates K11 to K16 are brought together. For this reason, the six sixth to first substrate production apparatuses 46 to 41 can carry out and carry in the substrates K11 to K16 all at once at the next moment.

  Note that the final production time of the last substrate K16 and the subsequent production substrates are the same as when the substrate damming function is not used. That is, even if the substrate damming function is used, the production end time of the mass-produced substrate is not delayed, and there is no production loss.

  In the substrate production line 1A of the second embodiment, the substrate production management device 2A obtains the loading waiting time T5 (i) for waiting for the loading of the substrate based on the information related to the scheduled loading time of each of the substrate production devices, respectively. When a carry-in waiting time T5 (6) exceeds a predetermined damming time Ts4 in one substrate production apparatus (sixth substrate production apparatus 46) having a substrate in it, a damming instruction is given to one substrate production apparatus. Is further provided, and the operation status change unit (damage execution unit 66) of the one substrate production apparatus carries out the removal of the substrate K11 as a change in the operation status when the dam command is obtained. To regulate.

  Thereby, when the flow of substrate conveyance becomes sparse, the substrates can be dammed with one substrate production apparatus, and the intervals between the substrates on the upstream side can be reduced. Therefore, while the substrates are gathered, the substrate production apparatus downstream of the one substrate production apparatus is not loaded with the substrate, and the shift to the energy saving mode is promoted.

  Further, the operation status changing unit (damming execution unit 66) of one substrate production apparatus (sixth substrate production apparatus 46) regulates the removal of the substrate K11 until the scheduled carry-in time t3 (6). According to this, damming can be performed for a long time until there is a substrate in all the substrate production apparatuses upstream of the one substrate production apparatus. Therefore, the substrate production apparatus downstream of the one substrate production apparatus is maximally promoted to shift to the energy saving mode. In addition, it is possible to carry out overlap conveyance in which a plurality of substrate production apparatuses simultaneously carry out and carry in substrates, thereby improving the conveyance efficiency.

(8. Application and modification of embodiment)
Note that various settings related to the energy saving mode and the preparation work described in the substrate production line 1 of the first embodiment can be modified as appropriate. In addition, the substrate damming function described in the substrate production line 1A of the second embodiment can simultaneously target a plurality of substrate production apparatuses. The present invention can have various other applications and modifications.

DESCRIPTION OF SYMBOLS 1, 1A: Board | substrate production line 2, 2A: Board | substrate production management apparatus 21: Production time acquisition part 22: Board | substrate presence confirmation part 23: Schedule time prediction part 24: Schedule time notification part 25: Production completion notification part 26: Damping notification Units 41 to 48: First to eighth substrate production apparatuses 61: Scheduled time acquisition unit 62: Wait time prediction unit 63, 63A: Operation status change unit 64: Energy saving mode switching unit 65: Preparatory work start unit 66: Damping execution Part K, K1 to K7, K11 to K16: substrate

Claims (11)

A substrate production management device configured to form a substrate production line together with a plurality of substrate production apparatuses that are arranged side by side and each carry in a substrate, carry out a predetermined process operation, and then carry out, and further manage the plurality of substrate production apparatuses Because
A production time acquisition unit that acquires a production time required when each of the plurality of substrate production apparatuses performs the process operation on one substrate;
A substrate presence / absence confirmation unit for confirming whether or not the substrate is present in each of the plurality of substrate production apparatuses;
Based on the production time of each of the plurality of substrate production apparatuses and the presence / absence of the substrate, information on a scheduled carry-in time when the substrate can be carried into each of the plurality of substrate production apparatuses, and the plurality A scheduled time predicting unit that predicts at least one of information related to the scheduled unloading time when the substrate can be unloaded from each of the substrate production apparatuses;
A board production management apparatus comprising: a scheduled time notification unit that notifies each of the substrate production apparatuses of the at least one information of each of the plurality of board production apparatuses. A substrate production apparatus that constitutes the substrate production line together with the substrate production management device according to claim 1, further carries in the substrate, performs the process operation, and carries it out.
A scheduled time acquisition unit for acquiring the at least one information from the scheduled time notification unit of the substrate production management device;
A substrate production apparatus comprising: an operation status change unit that changes an operation status based on the at least one information and the substrate presence / absence information that confirms whether or not the substrate is present in the device itself.   The substrate production apparatus according to claim 2, wherein the operation status change unit switches between a normal operation mode and an energy saving mode in which a part of an electric load in the apparatus is stopped as the change of the operation status.   The substrate production apparatus according to claim 3, wherein the operation status change unit switches a plurality of types of energy saving modes having different energy saving effect amounts as the change of the operation status. The plurality of types of energy saving modes include a first energy saving mode with a relatively large energy saving effect amount and a second energy saving mode with a relatively small energy saving effect amount,
When there is a substrate for which the process work has been completed in its own device, predicting the unloading waiting time for waiting for unloading of the substrate based on information on the unloading scheduled time, and when there is no substrate in its own device, A waiting time prediction unit for predicting a loading waiting time waiting for loading of the substrate based on information on a scheduled loading time;
The operating status change unit
Select the operation mode when there is a substrate that has not completed the process work in its own device,
Selecting the first energy saving mode when the loading waiting time or the unloading waiting time exceeds a relatively long first energy saving transition time;
Selecting the second energy saving mode when the loading waiting time or the unloading waiting time is less than the first energy saving transition time and exceeds a relatively short second energy saving transition time;
The board | substrate production apparatus of Claim 4 which selects the said operation mode when the said carrying-in waiting time or the said carrying-out waiting time is below the said 2nd energy saving transition time. When there is no substrate in its own apparatus, further comprising a waiting time prediction unit that predicts a loading waiting time for waiting for loading of the substrate based on information on the scheduled loading time,
The said operation condition change part will start the preparation work prior to the said process work as a change of the said operation condition, if the said carrying-in waiting time reduces to predetermined preparation time. Board production equipment. The operating status change unit
As the change of the operation status, switching between a normal operation mode and an energy saving mode in which a part of the electric load in the own device including the electric load performing the preparation work is stopped, and
The board | substrate production apparatus of Claim 6 which transfers to the said operation mode if the said carrying-in waiting time reduces to the said preparation time during the said energy saving mode.   A substrate production line comprising the substrate production management device according to claim 1 and a plurality of substrate production devices according to any one of claims 2 to 7. The substrate production management device is:
Based on the information related to the scheduled loading time of each of the substrate production apparatuses, a loading waiting time for waiting for loading of the substrate is obtained, and the loading waiting time is predetermined in one substrate production apparatus having the substrate in the apparatus. A damming notification unit for notifying the damming command to the one substrate production apparatus when the damming time is exceeded;
The substrate production line according to claim 8, wherein the operation status change unit of the one substrate production apparatus regulates the unloading of the substrate as the change of the operation status when the damming instruction is acquired.   The substrate production line according to claim 9, wherein the operation status change unit of the one substrate production apparatus regulates the unloading of the substrate until the scheduled loading time. The substrate production management device is:
The number of production schedules for each board type is grasped and the number of production results of the board is managed, and a production end command is notified to the board production apparatus that has unloaded the last board that has reached the production production quantity. Further comprising a production end notification unit,
When the operation status change unit of the substrate production apparatus acquires the production end command, the operation status change unit shifts from the normal operation mode to the energy saving mode in which a part of the electric load in the apparatus is stopped as the change of the operation status. The board production line according to any one of claims 8 to 10.

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