JP2007328384A - Measuring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measuring device capable of activating a plurality of measuring modules without fail by a power supply module with small capacity. <P>SOLUTION: The measuring device 1 includes one power supply module and a plurality of measuring modules 11 activated when electric power for operation is supplied via a power supply line 42 from the power supply module. Each of the measuring modules 11 includes a switch part 21 for outputting the electric power for the operation supplied from the power supply module to a measurement part 22 inside the measurement module 11 responding to a supply start signal Ss, and a control part 23 for outputting the supply start signal Ss to the switch part 21 in timing mutually different from other measuring modules 11 when the electric power for the operation is supplied. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a measurement apparatus configured with a plurality of measurement modules.

As this type of measuring apparatus, a multi-point data collecting apparatus including a plurality of measuring modules (measuring modules) and a main module is disclosed in Japanese Patent Application Laid-Open No. 2004-280325. In this multipoint data collection device, the main module controls each measurement module to measure the physical quantities assigned in advance, thereby measuring the physical quantities at a plurality of measurement points. In general, a measurement apparatus such as this multipoint data collection apparatus employs a configuration including one power supply module that supplies power to the measurement module and the main module. In this type of measurement apparatus, when power is supplied to the measurement apparatus, the main module controls the power supply module to simultaneously start power supply to a plurality of measurement modules.
JP 2004-280325 A (page 2-6, FIG. 1)

  However, the above measuring apparatus has the following problems. That is, in this type of measuring apparatus, one power supply module starts supplying power to a plurality of measurement modules simultaneously. Accordingly, since a plurality of measurement modules try to start at the same time when power supply is started, for example, when the measurement module has a circuit such as an FPGA (Field Programmable Gate Array) that consumes a large amount of power at the time of startup, The power consumed by the measurement module is also very large. For this reason, in this type of measurement device, when the power consumption exceeds the capacity of the power supply module, the measurement module cannot be activated as a result of being unable to supply power necessary for activation to each measurement module. There is a problem. In this case, for example, it is conceivable to employ a large-capacity power supply module, but this configuration is adopted because there is a risk of increasing the overall size of the apparatus and increasing manufacturing costs as the capacity of the power supply module increases. It is difficult.

  The present invention has been made in view of such a problem, and a main object of the present invention is to provide a measurement apparatus that can reliably start a plurality of measurement modules with a power supply module having a small capacity.

  In order to achieve the above object, the measuring apparatus according to claim 1 includes one power supply module and a plurality of measurement modules that are activated when operating power is supplied from the power supply module via the power supply line. In each of the measurement modules, each measurement module has a switching unit that outputs the operation power supplied from the power supply module to a predetermined circuit in the measurement module according to a supply start signal, and the operation power is And a control unit that outputs the supply start signal to the switching unit at a timing different from that of the other measurement modules when supplied. Note that “activation of the measurement module” in this specification means that not all the components of the measurement module are activated, but all the components required for measurement by the measurement module are activated.

  The measuring device according to claim 2 is the measuring device according to claim 1, wherein identification information is assigned to each of the plurality of measurement modules, and the control unit of each measurement module is assigned to the measurement module. The supply start signal is output at different timings based on the identification information.

  The measuring apparatus according to claim 3 is the measuring apparatus according to claim 2, wherein the identification information is configured to be given a priority in advance, and the control unit of each measurement module is assigned to the measurement module. The supply start signal is output when the priority of the identification information being higher than the priority of all the identification information assigned to other measurement modules that have not been started. Different timings.

  According to a fourth aspect of the present invention, in the measurement apparatus according to the second aspect, the plurality of measurement modules are provided with different numbers as the identification information for the respective measurement modules, and each of the measurement modules. The control unit calculates a standby time obtained by multiplying the number of the measurement module by a time longer than the startup time of the measurement module, and outputs the supply start signal when the standby time has elapsed. Different timings.

  In the measuring apparatus according to claim 1, each control unit outputs a supply start signal to each switching unit at a timing different from that of the other measurement modules when the operating power is supplied. Power for operation is output at a different timing from the module. For this reason, for example, even if the measurement module has a circuit that consumes a large amount of power at startup as a predetermined circuit, the power consumption at startup is averaged, resulting in the maximum power consumption at startup in multiple measurement modules. Can be suppressed to a small power less than the capacity of the power supply module. Therefore, according to this measuring apparatus, even if a power module with a small capacity is used, it is possible to reliably supply the power necessary for starting up to each measuring module. Can be activated.

  In the measuring apparatus according to the second aspect, the control unit of each measurement module outputs supply start signals at different timings based on the identification information given to the measurement module when the operating power is supplied. Therefore, according to this measuring apparatus, for example, by giving different identification numbers to each measurement module, each measurement module is activated separately at a timing based on each identification information, so each measurement module is activated. The timing can be easily changed.

  In the measurement device according to claim 3, the control unit of each measurement module assigns the priority of the identification information given to the measurement module to the other measurement modules that have not been activated when the operating power is supplied. A supply start signal is output when the priority order of all the identification information is higher. Therefore, according to this measurement apparatus, since the measurement modules with high priority are automatically activated one by one at different timings, the maximum power consumption at the time of activation of the plurality of measurement modules can be reduced. Even if a small-capacity power supply module is used, all measurement modules can be reliably started.

  In the measurement device according to claim 4, the control unit of each measurement module calculates a standby time obtained by multiplying the number of the measurement module by a time longer than the activation time of the measurement module when the operating power is supplied. When each waiting time has elapsed, a supply start signal is output. In this case, since the numbers given as identification numbers to the respective measurement modules are different from each other, the standby times are also different from each other. Therefore, according to this measuring device, since the measurement module having the smaller number, that is, the measurement module having the shorter standby time, is automatically activated one by one at different timings, As a result, the maximum power consumption can be kept small, so that even if a power module with a small capacity is used, all the measurement modules can be reliably started.

  Hereinafter, the best mode of a measuring apparatus according to the present invention will be described with reference to the accompanying drawings.

  Initially, the structure of the measuring apparatus 1 as an example of the measuring apparatus which concerns on this invention is demonstrated with reference to drawings. As shown in FIG. 1 and FIG. 2, a measuring apparatus 1 shown in FIG. 1 includes a plurality of (three as an example) measuring modules 11a, 11b, and 11c (hereinafter also referred to as “measuring modules 11” when not distinguished). The power supply module 12 and the module bus 13 are provided so that the parameters of the measurement object 51 can be measured.

  The measurement module 11 is configured to be attachable / detachable to / from the slot of the module bus 13. In addition, when the measurement module 11 is mounted on the module bus 13, a connector (not shown) disposed on the back surface and a connector 41 (see FIG. 1) of the module bus 13 are connected to each other via the module bus 13. To the power supply module 12. As shown in FIG. 3, the measurement module 11 includes a switch unit 21, a measurement unit 22, a control unit 23, a timer 24, and a storage unit 25. The switch unit 21 corresponds to a switching unit in the present invention, and its input terminal is connected to the power supply line 42 of the module bus 13 and its output terminal is connected to the measurement unit 22. In this case, when the supply start signal Ss is output from the control unit 23, the switch unit 21 connects the input terminal and the output terminal, and operates power supplied from the power supply module 12 via the power supply line 42. Is output to the measurement unit 22.

  The measurement unit 22 corresponds to a predetermined circuit in the present invention, and includes, for example, an FPGA (Field Programmable Gate Array) that consumes a certain amount of power at the time of startup and configures the measurement circuit. The measuring unit 22 is operated by inputting (consuming) the current I when operating power is supplied from the power supply module 12, and the measuring object 51 (for example, a power supply device) is controlled according to the control of the control unit 23. ) Is measured, and measurement data Dm is output to the control unit 23.

  The control unit 23 operates with the operating power supplied from the power supply module 12 and controls the switch unit 21, the measurement unit 22, and the timer 24. In this case, when the operating power is supplied from the power supply module 12, the control unit 23 operates immediately and executes the startup process 70 shown in FIG. In the activation process 70, the control unit 23 outputs a supply start signal Ss to the switch unit 21 at a timing different from that of the other measurement modules 11. In this case, each measurement module 11 stores identification information Id configured with priorities assigned in advance in the storage unit 25, and the control unit 23 determines that the priority of the identification information Id is other than that which has not been activated. The output timing of the supply start signal Ss is made different from each other by outputting the supply start signal Ss when the priority is higher than the priority of all the identification information Id given to the measurement module 11. Here, the identification information Id is defined such that, for example, the number “1” has the highest priority, and the priority decreases as the number increases. As an example, in this remote monitoring system 1, a priority of “1” is given to the measurement module 11a, a priority of “2” is given to the measurement module 11b, and a priority of “3” is given to the measurement module 11c. Has been.

  In addition, the control unit 23 reads the identification information Id from the storage unit 25 and starts output processing of the read identification information Id at the start of supply of operating power from the power supply module 12. Further, the control unit 23 controls the timer 24 to count the elapsed time tl1 from the output of the supply start signal Ss, and when the timer signal is output from the timer 24 after a predetermined activation time ts has elapsed. Then, the output process is stopped. In addition, when the output of the identification information data Id from all the measurement modules 11a to 11c is stopped, the control unit 23 controls the measurement unit 22 to start the above parameter measurement and the measurement output from the measurement unit 22 A measurement process for storing the data Dm in the storage unit 25 is executed.

  The timer 24 counts the elapsed time tl1 according to the control of the control unit 23 and outputs a timer signal to the control unit 23 when the activation time ts of the measurement module 11 is reached. The storage unit 25 stores identification information Id, measurement data Dm, and activation time data Dt. Here, the activation time data Dt is composed of data indicating the activation time ts (for example, 2 seconds) that is at least necessary for the measurement module 11 to be activated.

  The power supply module 12 is connected to, for example, commercial AC and supplies operating power to the measurement module 11 mounted on the module bus 13 via the power supply line 42. Further, as shown in FIG. 1, the power supply module 12 includes a power switch 31 for starting or stopping supply of operating power to the measurement module 11. The module bus 13 includes a plurality of slots for mounting the modules 11 and 12, and a plurality of connectors 41 (see FIG. 1; only one in the figure) connected to connectors (not shown) of the modules 11 and 12. And a power supply line 42 for supplying power to the measurement module 11 installed in each slot, and a communication line 43 for data communication between the measurement modules 11 installed in each slot.

  Next, operation | movement of the measuring apparatus 1 is demonstrated with reference to drawings.

  When measuring the parameters of the measurement object 51, as shown in FIG. 2, the measurement module 11 is connected to the measurement object 51 and the power switch 31 (see FIG. 1) of the power supply module 12 is operated. At this time, the power supply module 12 starts supplying operating power (application of power supply voltage) to the measurement module 11 via the power supply line 42 of the module bus 13. In response to this, the control unit 23 of each measurement module 11 inputs the power for operation and starts up. Note that the total power consumed by all the measurement modules 11 (power P1 shown in FIG. 5) when the control unit 23 is started up (time point t1 shown in FIG. 5) is that the control unit 23 consumes little power. The power is sufficiently smaller than the power capacity Pmax of the power module 12.

  At this time, each control unit 23 starts an activation process 70 shown in FIG. In the activation process 70, each control unit 23 first reads out the identification information Id from the storage unit 25 and starts an output process for outputting the read identification information Id via the power line 42 (step 71). . In this case, the measurement module 11a outputs identification information Id indicating “1”, the measurement module 11b outputs identification information Id indicating “2”, and the measurement module 11c outputs identification information Id indicating “3”. .

  Next, each control unit 23 outputs the priority of the identification information Id read from each storage unit 25 (hereinafter, this identification information Id is also referred to as “self identification information Id”) from the other measurement modules 11. It is determined whether or not the priority is higher than the priority of the identification information Id (hereinafter, this identification information Id is also referred to as “other identification information Id”) (step 72). At this time, for example, the control unit 23 of the measurement module 11a has its own identification information Id “1” and the other identification information Id “2” and “3”. It is determined that the priority is higher than the priority of the other identification information Id, and the supply start signal Ss is output to the switch unit 21 (step 73). In this case, the switch unit 21 operates according to the supply start signal Ss output from the control unit 23 and starts outputting the operating power to the measurement unit 22. In response to this, the FPGA of the measurement unit 22 starts up while consuming a certain amount of operating power. For this reason, as shown in FIG. 5, although a certain amount of power (power P2 shown in the figure) is instantaneously consumed at the time point t2, only one measuring unit 22 is activated, so that power is consumed at that time. The electric power P2 is less than the power supply capacity Pmax.

  Subsequently, the control unit 23 controls the timer 24 to start counting the elapsed time tl1 from when the supply start signal Ss is output (step 74). Next, the control unit 23 determines whether or not the elapsed time tl1 has reached the activation time ts (the activation time ts has elapsed) (step 75). At the start of this determination process, the control unit 23 determines that the activation time ts has not elapsed, and repeatedly executes this determination process. On the other hand, since the priority of the identification information Id of the measurement module 11a is the highest at this time, each control unit 23 of the measurement modules 11b and 11c has another priority of the identification information Id of its own at the time of the discrimination process in step 72. It is determined that the priority is lower than the priority of the identification information Id, and the determination process of step 72 is repeatedly executed.

  Next, when the elapsed time tl1 from the output of the supply start signal Ss in the measurement module 11a reaches the activation time ts (time t3 shown in FIG. 5), the timer 24 of the measurement module 11a controls the timer signal to the control unit. To 23. In response to this, the control unit 23 determines that the elapsed time tl1 has reached the activation time ts during the determination processing in step 75, and stops outputting the identification information Id (step 76). In this state, since the measurement module 11a has already been started, as shown in FIG. 5, the power consumed in that state slightly increases from the power P1 to become power P3. Subsequently, the control unit 23 of the measurement module 11a determines whether or not output of all identification information Id is stopped (step 77). At this time, since the identification information Id is still output from the other measurement modules 11, the control unit 23 determines that the output of all the identification information Id is not stopped, and the determination process in step 77 Repeatedly.

  In this case, since the output of the identification information Id from the measurement module 11a is stopped, the identification information Id indicating “2” and “3” is output from the two measurement modules 11b and 11c to the communication line 43. For this reason, the control unit 23 of the measurement module 11b determines that the priority of its own identification information Id is higher than the priority of other identification information Id during the determination process in step 72, and the measurement module 11a described above. The measurement unit 22 is activated in the same manner as the processing by the control unit 23.

  Further, as shown in FIG. 5, when the measurement unit 22 of the measurement module 11b is activated (time t4 in the figure), a certain amount of electric power (electric power P4 shown in the figure) is instantaneously consumed, but activation is started. Due to the above reason that there is one measuring unit 22 in the middle, the power P4 consumed at that time is also equal to or less than the power source capacity Pmax. Next, the control unit 23 executes the processes of steps 74 and 75 in the same manner as the process by the control unit 23 of the measurement module 11a. On the other hand, since the priority of the identification information Id of the measurement module 11b is the highest at this time, the control unit 23 of the measurement module 11c determines that the priority of the identification information Id of the measurement module 11c is other identification information. It is determined that the priority order is lower than Id, and the determination process in step 72 is repeatedly executed.

  Subsequently, when the elapsed time tl1 from the output time of the supply start signal Ss in the measurement module 11b reaches the activation time ts (time t5 shown in FIG. 5), the timer 24 of the measurement module 11b uses the timer signal as a control unit. To 23. In response to this, the control unit 23 determines that the elapsed time tl1 has reached the activation time ts during the determination processing in step 75, and stops outputting the identification information Id (step 76). In this state, since the measurement unit 22 of the measurement module 11b has already been started, as shown in FIG. 5, the power consumed in this state slightly increases from the power P3 to become power P5. Next, the control unit 23 repeatedly executes the determination processing in step 77 in the same manner as the processing by the control unit 23 of the measurement module 11a.

  At this time, since the output of the identification information Id from the measurement module 11b is stopped, only the identification information Id indicating “3” is output from the measurement module 11c to the communication line 43. Therefore, the control unit 23 of the measurement module 11c determines that the priority of its own identification information Id is higher than the priority of other identification information Id during the determination process in step 72, and the measurement module described above. The measurement unit 22 is activated in the same manner as the processing by the control unit 23 of 11a.

  Further, as shown in FIG. 5, when the measurement unit 22 of the measurement module 11c is activated (time t6 in the figure), a certain amount of electric power (electric power P6 shown in the figure) is instantaneously consumed. For this reason, the power P6 consumed at that time is also equal to or less than the power supply capacity Pmax. Subsequently, the control unit 23 executes the processes of steps 74 and 75 in the same manner as the process by the control unit 23 of the measurement module 11a. In this case, since the measurement module 11c is already activated, the power consumed at that time slightly increases from the power P5 to become power P7 as shown in FIG. Next, when the elapsed time tl1 from the output of the supply start signal Ss in the measurement module 11c reaches the activation time ts (time t7 shown in the figure), the timer 24 of the measurement module 11c controls the timer signal to the control unit. To 23. In response to this, the control unit 23 determines that the elapsed time tl1 has reached the activation time ts during the determination processing in step 75, and stops outputting the identification information Id (step 76). At this time, since the output of the identification information Id from all the measurement modules 11c is stopped, each control unit 23 of the three measurement modules 11a to 11c receives all the identification information Id during the discrimination process in step 77. Is determined to have stopped. Subsequently, each control unit 23 controls each measurement unit 22 to start the above-described parameter measurement and starts measurement processing to store the measurement data Dm output from each measurement unit 22 in the storage unit 25. (Step 78), the activation process 70 is terminated.

  As described above, in the measurement apparatus 1, the switch unit 21 of each measurement module 11 is operated at a timing (time points t 1, t 3, t 5 shown in FIG. 5) different from those of the other measurement modules 11 according to the control of the control unit 23. Since the power for operation is output and the measurement unit 22 is activated, the maximum power consumption at the time of activation of the plurality of measurement modules 11 is suppressed to be small, and even if the power supply module 12 having a small capacity is used, all the measurement modules 11 are used. Will start reliably. Moreover, in this measuring apparatus 1, the control part 23 of the measurement module 11a in which the priority of its own identification information Id is higher than the priority of all other identification information Id sequentially outputs the supply start signal Ss. Then, the measurement modules 11 having higher priority are sequentially started one by one at different timings.

  Thus, in this measuring apparatus 1, each control part 23 is a supply start signal at the start timing (time t1, t3, t5 shown in FIG. 5) mutually different from the other measurement modules 11 at the time of supply of operation electric power. Ss is output to each switch unit 21. In this case, each switch unit 21 outputs operating power at a timing different from that of the other measurement modules 11, so that each measurement module 11 can be started at a different timing. For this reason, even if each measuring unit 22 consumes a certain amount of power at startup, the power consumption is averaged. As a result, the maximum power consumption at startup of the plurality of measurement modules 11 is less than or equal to the power supply capacity Pmax of the power supply module 12. Can be suppressed to a small electric power. Therefore, according to this measuring apparatus 1, even if the power supply module 12 having a small capacity is used, the power required for starting can be reliably supplied to the three measurement modules 11a to 11c. All of the measurement modules 11a to 11c can be reliably activated.

  Moreover, in this measuring apparatus 1, the control part 23 of each measurement module 11 outputs the supply start signal Ss at a mutually different timing based on the identification information Id given to the measurement module 11 when supplying the operating power. To do. Therefore, according to the measurement apparatus 1, each measurement module 11 is started at a timing based on the identification information Id by giving different identification numbers to the measurement modules. The timing of starting can be easily changed.

  Moreover, in this measuring apparatus 1, the control part 23 of each measurement module 11 is the priority of the identification information Id provided to the measurement module 11 at the time of supply of operation power, and other measurement modules 11 which are not started. A supply start signal Ss is output when the priority order of all assigned identification information Id is higher. Therefore, according to this measuring apparatus 1, since the measurement modules 11 with high priority are automatically activated one by one at different timings, the maximum power consumption at the time of activation of the plurality of measurement modules 11 can be kept small. As a result, even if the power module 12 having a small capacity is used, all the measurement modules 11 can be reliably started.

  In addition, this invention is not limited to said structure. For example, although the example in which the priority is higher as the number of the identification information Id is smaller has been described, the present invention is not limited to this. For example, a configuration having a higher priority as the number of the identification information Id is larger can be adopted. Also, the order of numerical values of the identification information Id is not associated with the order of priorities, and priorities are given so that the priorities increase in an arbitrary order such as “2”, “3”, and “1”, for example. You can also Further, although the configuration in which each measurement module 11 stops the output of the identification information Id in order to make the other measurement modules 11 identify the completion of the activation has been described above, the present invention is not limited to this. For example, it is possible to adopt a configuration in which each measurement module 11 outputs arbitrary data indicating the completion of activation.

  Next, the configuration of a measuring apparatus 1A as another example of the measuring apparatus according to the present invention will be described with reference to the drawings. As shown in FIG. 1 and FIG. 2, the measuring apparatus 1A shown in FIG. 1 replaces the measuring modules 11a to 11c with measuring modules 111a, 111b, and 111c (hereinafter also referred to as “measuring module 111” when not distinguished). The measuring apparatus 1 is configured in the same manner as described above except that The control unit 23, the timer 24, and the storage unit 25 in the measurement module 111 are partially different from the control unit 23, the timer 24, and the storage unit 25 of the measurement module 11 described above. Different functions will be described, and redundant description will be omitted. In addition, the same components as those of the measurement device 1 and the measurement module 11 are denoted by the same reference numerals, and redundant description is omitted.

  The control unit 23 executes the startup process 80 shown in FIG. 6 at the start of supply of operating power from the power supply module 12. In the activation process 80, the control unit 23 of each measurement module 111 has a time (for example, 3 seconds) longer than the activation time ts by an integer number (another example of identification information in the present invention) N assigned to the measurement module 111. ) To calculate the waiting time tw. In this case, each control unit 23 controls the timer 24 to count the elapsed time tl2 from the start of supplying the operating power, and when the elapsed time tl2 reaches the standby time tw (the standby time tw is set). By outputting the supply start signal Ss when the time has elapsed), the output timing of the supply start signal Ss is made different from each other. Here, in the measurement apparatus 1A, different numbers N are assigned to the measurement modules 111 as the identification numbers Id. For example, as the number N, an integer “1” is assigned to the measurement module 111a, an integer “2” is assigned to the measurement module 111b, and an integer “3” is assigned to the measurement module 111c. .

  Further, the control unit 23 reads the identification information Id indicating the number N from the storage unit 25 at the start of supplying the operating power from the power supply module 12, and starts output processing of the read identification information Id. Further, the control unit 23 controls the timer 24 to count the elapsed time tl3 from the output of the supply start signal Ss, and stops the output process when the activation time ts has elapsed. In addition, when the output of the identification information Id from all the measurement modules 111a to 111c is stopped, the control unit 23 controls the measurement unit 22 to start the parameter measurement and the measurement output from the measurement unit 22. A measurement process for storing the data Dm in the storage unit 25 is executed.

  Under the control of the control unit 23, the timer 24 counts the elapsed time tl2 from the start of supply of the current I and outputs a timer signal to the control unit 23 when the standby time tw is reached, and the supply start signal Ss The timer signal is also output to the control unit 23 when the elapsed time t3 from the output time is counted and the activation time ts is reached. The storage unit 25 stores identification information Id, measurement data Dm, and activation time data Dt.

  Next, the operation of the measuring apparatus 1A will be described with reference to the drawings.

  When measuring the parameters of the measurement object 51, as shown in FIG. 2, the measurement object 51 is connected to the measurement module 111 and the power switch 31 (see FIG. 1) is operated. At this time, the power supply module 12 starts supplying operation power to the measurement module 111 via the power supply line 42. In response to this, the control unit 23 of each measurement module 111 is activated. The power consumed by all the measurement modules 111 (power P11 shown in FIG. 7) when the control unit 23 is activated (time t11 shown in FIG. 7) is not consumed by the control unit 23. The power is sufficiently smaller than the power supply capacity Pmax of the module 12.

  At this time, each control unit 23 starts an activation process 80 shown in FIG. In the activation process 80, each control unit 23 first starts the output process of the identification information Id in the same manner as the process of step 71 of the activation process 70 of FIG. 4 (step 81). At this time, the measurement module 111a outputs identification information Id indicating “1”, the measurement module 111b outputs identification information Id indicating “2”, and the measurement module 111c outputs identification information Id indicating “3”. Output.

  Next, each control unit 23 calculates a standby time tw by multiplying the number N indicated by each identification information Id read from each storage unit 25 by a time longer than the activation time ts (in this case, 3 seconds) (step 82). . In this case, for example, the control unit 23 of the measurement module 111a multiplies the number N given to the measurement module 111a (in this case, “1”) by 3 seconds to set the standby time tw (hereinafter, this standby time tw). It is also calculated as “standby time tw1”. Similarly, the control unit 23 of the measurement module 111b multiplies the number N (in this case, “2”) given to the measurement module 111b by 3 seconds, and sets the standby time tw (hereinafter, this standby time tw to “ It is also calculated as “standby time tw2”). Further, the control unit 23 of the measurement module 111c multiplies the number N given to the measurement module 111c (in this case, “3”) by 3 seconds to set the standby time tw (hereinafter, this standby time tw to “standby time”). tw3 ”).

  Subsequently, each control unit 23 controls each timer 24 to start counting the elapsed time tl2 from the start of supplying the operating power (step 83). Next, each control unit 23 determines whether or not the elapsed time tl2 has reached each waiting time tw (step 84). In this case, each control unit 23 determines that the elapsed time tl2 has not reached the standby time tw until each standby time tw has elapsed, and repeatedly executes this determination processing. Subsequently, for example, when the standby time tw1 (in this case, 3 seconds) has elapsed (time t12 shown in FIG. 7), the control unit 23 of the measurement module 111a waits for the elapsed time tl2 during the determination processing in step 84. It is determined that the time tw1 has been reached, and the supply start signal Ss is output to the switch unit 21 (step 85). At this time, the switch unit 21 starts outputting the operating power to the measuring unit 22 in accordance with the supply start signal Ss output from the control unit 23. In this case, as shown in FIG. 7, when the measurement unit 22 is started up (time point t13 shown in FIG. 7), a certain amount of power (power P13 shown in FIG. 7) is instantaneously consumed, Since there is only one measuring unit 22, the power P13 consumed at that time is equal to or less than the power supply capacity Pmax.

  Next, the control unit 23 controls the timer 24 to start counting the elapsed time tl3 from when the supply start signal Ss is output (step 86). Subsequently, the control unit 23 determines whether or not the elapsed time tl3 has reached the activation time ts (step 87). At this time, the control unit 23 determines that the activation time ts has not been reached until the activation time ts has elapsed, and repeatedly executes the determination processing in step 87. Next, when the activation time ts has elapsed (time t14 shown in FIG. 7), the control unit 23 determines that the elapsed time tl3 has reached the activation time ts and stops outputting the identification information Id ( Step 88). In this state, since the measurement unit 22 of the measurement module 111a has already been activated, the power consumed in that state is slightly increased from the power P11 to become power P14 as shown in FIG. Subsequently, the control unit 23 determines whether or not output of all the identification information Id is stopped (step 89). At this time, since the identification information Id is still output from the other measurement module 111, the control unit 23 determines that the output of all the identification information Id is not stopped, and the determination process of step 89 Repeatedly.

  On the other hand, the control unit 23 of the measurement module 111b executes the processes of steps 84 to 89 in the same manner as the process performed by the control unit 23 of the measurement module 111a. In this case, as shown in FIG. 7, when the standby time tw2 (in this case, 6 seconds) has elapsed (time t15 shown in FIG. 7), the control unit 23 of the measurement module 111b performs the discrimination process in step 84. It is determined that the elapsed time tl2 has reached the standby time tw2, and the supply start signal Ss is output to the switch unit 21 (step 85). In this case, as shown in the figure, a certain amount of power (power P16 shown in the figure) is instantaneously consumed when the measuring unit 22 is activated (time t16). The power P16 consumed at this time is also equal to or less than the power supply capacity Pmax. Next, when the elapsed time tl3 reaches the activation time ts (time t17 shown in the figure), the control unit 23 determines that the activation time ts has been reached, and stops outputting the identification information Id ( Step 88). In this state, since the measurement module 111b has already been activated, the power consumed in that state slightly increases from the power P14 to become power P17, as shown in FIG.

  Moreover, the control part 23 of the measurement module 111c performs the process of steps 84-89 similarly to the process by the control part 23 of the measurement module 111a. In this case, as shown in FIG. 7, when the standby time tw3 (9 seconds in this case) has elapsed (time t18 shown in FIG. 7), the control unit 23 of the measurement module 111c performs the discrimination process in step 84. It is determined that the elapsed time tl2 has reached the standby time tw3, and the supply start signal Ss is output to the switch unit 21 (step 85). In this case, as shown in the figure, when the measuring unit 22 is activated (time point t19), a certain amount of electric power (electric power P19 shown in the figure) is instantaneously consumed. The power P19 consumed in the state is also equal to or less than the power supply capacity Pmax. Next, when the activation time ts has been reached (time t20 shown in the figure), the control unit 23 determines that the elapsed time tl3 has reached the activation time ts and stops outputting the identification information Id (step S20). 88). In this state, since the measurement module 111c is already activated, the power consumed in that state is slightly increased from the power P17 to become power P20 as shown in FIG.

  At this time, since the output of the identification information Id from all of the measurement modules 111c is stopped, each control unit 23 of the three measurement modules 111a to 111c receives all of the identification information Id at the time of the discrimination process in step 89. Is determined to have stopped. Next, each control unit 23 starts the measurement process (step 90) in the same manner as the process of step 78 in the activation process 70, and ends the activation process 80.

  As described above, in the measurement apparatus 1A, the control unit 23 of each measurement module 111 multiplies the number N of the measurement module 111 by a time longer than the activation time ts (in this case, 3 seconds) when the operating power is supplied. The standby time tw is calculated, and the supply start signal Ss is output when each standby time tw has elapsed. In this case, since the numbers N given as the identification numbers Id to the measurement modules 111 are different from each other, the standby times tw are also different from each other. Therefore, according to this measuring apparatus 1A, since the measurement module 111 with the smaller number N, that is, the measurement module 111 with the shorter waiting time tw, is automatically started one by one at different timings, As a result of suppressing the maximum power consumption when starting up the measurement module 111, even if the power module 12 having a small capacity is used, all the measurement modules 111 can be started up reliably.

  In addition, although the example of a structure which calculates the waiting time tw by multiplying the number N as identification information by "3 second" as time longer than starting time ts was demonstrated, this invention is not limited to this. For example, the waiting time tw can be calculated by multiplying the number N by an arbitrary time longer than the activation time ts. In addition, the number N is not only an integer, but a pure decimal number (for example, 0.5) or a band decimal number (for example, 1.5, 2.5, etc.) as long as the times when the measurement modules 111 are activated do not overlap. Can also be given. In this configuration, the activation start time can be advanced by setting the number N assigned to the measurement module 111 to be activated first to a pure decimal number (for example, 0.5).

It is a block diagram which shows the structure of the measuring apparatuses 1 and 1A. It is a block diagram which shows the structure of the measuring devices 1 and 1A. 2 is a block diagram showing a configuration of measurement modules 11 and 111. FIG. 5 is a flowchart of activation processing 70. FIG. 6 is a characteristic diagram showing electric power P consumed when starting the measuring apparatus 1. 7 is a flowchart of activation processing 80. It is a characteristic view showing electric power P consumed for starting of measuring device 1A.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,1A Measuring apparatus 11a-11c, 111a-111c Measurement module 12 Power supply module 13 Module bus 21 Switch part 22 Measurement part 23 Control part 24 Timer 25 Storage part 42 Power supply line I Current Id Identification information N number P1-P7, P11 P20 power Ss supply start signal t1 to t7, t11 to t20 time point ts start time tw1 to tw3 standby time

Claims (4)

A measuring apparatus configured to include one power supply module and a plurality of measurement modules that are activated when operating power is supplied from the power supply module via a power supply line,
Each of the measurement modules includes a switching unit that outputs the operation power supplied from the power supply module to a predetermined circuit in the measurement module according to a supply start signal, and the other power supply when the operation power is supplied. A measurement apparatus comprising: a control unit that outputs the supply start signal to the switching unit at a timing different from that of the measurement module. Identification information is given to each of the plurality of measurement modules,
The measurement apparatus according to claim 1, wherein the control unit of each measurement module outputs the supply start signal at the different timings based on the identification information given to the measurement module. The identification information is configured with priorities given in advance,
The control unit of each measurement module is configured such that the priority of the identification information given to the measurement module is higher than the priority of all the identification information given to other measurement modules that have not been activated. The measuring apparatus according to claim 2, wherein the timing is made different by outputting the supply start signal when the level becomes high. Each of the plurality of measurement modules is given a different number for each measurement module as the identification information,
The control unit of each measurement module calculates a standby time obtained by multiplying the number of the measurement module by a time longer than the startup time of the measurement module, and outputs the supply start signal when the standby time has elapsed. The measuring apparatus according to claim 2, wherein the timings are different from each other.

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