JP2013245975A - Test system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a test system 1 capable of performing operations more flexibly by making a device management apparatus 7 manage inspection, maintenance or the like for each testing device 4 appropriately and properly.SOLUTION: The device management apparatus 7 is provided with: an operation detecting unit 71 for detecting that a connecting/disconnecting operation for connecting or disconnecting testing devices 4 has been performed; and a device condition information obtaining unit 75 for obtaining device condition information indicating current or past conditions of the corresponding testing device 4 at the timing when the operation detecting unit 71 detects a connecting operation.

Description

  The present invention relates to a test system for testing components such as an internal combustion engine used for a moving body in addition to a moving body such as a vehicle, a ship, and an airplane.

  Conventionally, for example, as a test system for automobiles, as shown in Patent Document 1, a plurality of measurement devices (measurement devices) are connected to one measurement management device, and measurement devices are collectively connected to this management device. What is managed is known. Further, as shown in Patent Document 2, there is an apparatus in which an automatic test management apparatus is provided above the management apparatus so that a test schedule can be determined by the automatic test management apparatus.

  By the way, the measuring device may cause performance degradation due to use and the reliability of measurement accuracy cannot be ensured. Therefore, it is necessary to periodically inspect, calibrate, and maintain. The timing of such inspection may be determined by the test regulations.

Japanese Patent No. 3524754 JP 2005-49353 A

  By the way, there are cases in which the performance of measurement devices degrades as they continue to be used and the reliability of measurement accuracy cannot be guaranteed. Therefore, it is necessary to periodically inspect, calibrate, and maintain. . Such items and time of inspection may be determined by the regulation of the test.

However, regardless of a rigid system in which the same device management device is always connected to the measurement device, it is possible to move the measurement device to another test room and connect it to another device management device. When making a flexible system that can, device status information related to the past inspection history and calibration history of the measurement device when connected to another management device can not be inherited, it has been reset, There is a risk of losing proper inspection and maintenance time.
Such a problem is not limited to the measurement device, but is common to various test devices.

  The present invention has been made in view of such a problem, and it is possible to properly and reliably inspect and maintain each test device with the device management apparatus regardless of which test device is connected to which device management apparatus. The main goal is to provide a test system that can be managed and operated more flexibly.

  That is, the test system according to the present invention is for testing a target object such as a vehicle, a ship, an airplane or the like or a device used in the mobile object, and is used for the test. One or a plurality of test devices, and a device management apparatus that is communicably connected to the test device and manages the test device, and the device management apparatus connects or disconnects the test device. Device state information indicating the current or past state of the corresponding test device, triggered by the detection of the connection operation by the operation detection unit and the operation detection unit that detects that the connection / disconnection operation has been performed. And a device state information acquisition unit to acquire.

If this is the case, no matter which test device is connected to which device management apparatus, the current or past device status information of the connected test device at that time (for example, past inspection time and items) Or the current performance state) is recognized by the device management apparatus, so that the operator is automatically notified of the next inspection time, maintenance time, items, etc. of each test device connected in the device management apparatus. Management will be ensured. As a result, since the test device and the device management apparatus can be easily connected without selecting the other party, the test device can be easily replaced, and the test system can be operated more flexibly.
The “connection operation” includes not only a connection operation on the console but also an operation of connecting a communication cable, for example.

  As a more specific system construction example that can realize the present invention more easily, the device state information is stored in a local storage unit provided in a test device, and the device state information acquisition unit A device characterized in that the device status information of the test device is acquired by accessing the storage unit.

  In addition, for example, a storage device that shares and stores device status information of each test device that can be connected is provided, and when the test device is connected, the device management device accesses the storage device. It is also conceivable to obtain the device status information of the corresponding test device. In this case, it is necessary to consider how to cope with network construction and when a test device is used outside the network.

  To enable operators to recognize changes in test device status over time or trends, and to deal with test devices more accurately, it recognizes time-series changes in the device status information. It is preferable that the information processing apparatus further includes a management main body section that displays the information on the screen as much as possible and notifies the fact when the value of the device status information exceeds a predetermined threshold value.

  Specific device status information includes pump pressure information that is information indicating the suction pressure by the pump when the test device is a pump, and functions of the measurement device when the test device is a measurement device. Examples thereof include function information, accumulated operation time information indicating the accumulated operation time of the test device, and inspection time specifying information which is information for specifying a predetermined inspection time of the test device.

  As a specific embodiment, it is desirable that the test device is a measurement device that measures a state quantity of the object, and more specifically, the measurement device is provided in an exhaust path of an internal combustion engine. There may be mentioned one that measures the exhaust gas that is provided and flows through the exhaust path.

  According to the present invention configured as described above, regardless of which test device is connected to which device management apparatus, current or past device state information (for example, past inspection) of the connected test device is Time, items, or current performance status) is recognized by the device management device. The device management device automatically notifies the operator of the next inspection time, maintenance time, items, etc. of each connected test device. Management such as informing the user can be surely performed. As a result, the test device and the device management apparatus can be easily connected without selecting the other party, so that the test system can be operated more flexibly.

1 is a schematic configuration diagram of a vehicle performance test system according to an embodiment of the present invention. It is a fluid circuit diagram which shows the gas flow path of the embodiment simply. It is a functional block diagram of the measurement device and the device management apparatus of the embodiment. It is a screen block diagram which shows the plug-in screen of the embodiment. It is a screen block diagram which shows the device status history screen operation | movement condition of the embodiment. It is a screen block diagram which shows the other device state log | history screen operation | movement condition of the embodiment.

  An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 schematically shows an entire vehicle performance test system 1 according to the present embodiment. As shown in the figure, the vehicle performance test system 1 includes a chassis dynamometer 2, an automatic driving device 3, an automatic test management device 6, a plurality of test devices (exhaust gas measurement devices) 4, a device management device 7 and the like. The vehicle VH can be put in a simulated running state on the chassis dynamometer 2, and the vehicle performance can be tested by measuring the fuel consumption, exhaust gas components, etc. of the vehicle VH. It is also possible to test the engine alone using this test system 1.
Each part will be described.

  The chassis dynamometer 2 includes a rotating drum 21, a motor and a flywheel (not shown) for applying a load to the rotating drum 21, and a dynamo control device 22 for controlling them. The rotating drum 21, the motor, or the flywheel is installed in the test chamber 10, and the driving wheel of the vehicle VH is set to a test position that is located immediately above the top of the rotating drum 21, so that it is the same as in actual running. It is configured to be able to run in a stable state. The dynamo control device 22 is accommodated in, for example, a measurement chamber provided adjacent to the test chamber 10. The test chamber 10 and the measurement chamber (or in addition to these, the pits) are referred to as so-called cells and laboratories.

  The automatic driving device 3 includes a driving robot (not shown) that is mounted in a cab of the vehicle VH and drives an accelerator, a brake, a clutch, and the like, and a robot control device 31 that is connected to the driving robot and controls the driving robot. Therefore, by giving various command signals to the robot controller 31, the driving robot is controlled and, for example, the vehicle VH according to various standardized regulations (for example, CFR 1065, 10 mode, etc.) The engine performance test is possible. The robot control device 31 is accommodated in the measurement chamber, for example.

  The automatic test management apparatus 6 has a basic function of setting a schedule for a running test, although a detailed description is omitted. Setting the driving test schedule includes, for example, the setting of the regulation and the setting of the test date. However, the behavior of the vehicle VH such as the vehicle speed and the engine speed can be set in more detail, the measurement target, the measurement timing, etc. It may also include setting. The automatic test management device 6 is provided with a communication port so that the measurement device 4, the chassis dynamometer 2, the automatic driving device 3, etc. can communicate with the automatic test management device 6 by wire or wirelessly. Connected.

  When the schedule is set by the operator, the automatic test management device 6 transmits a command according to the schedule to the chassis dynamometer 2, the automatic driving device 3, the device management device 7, etc., and the test according to the schedule. Control them to be done automatically.

  In FIG. 1, one device management apparatus 7 is connected to one test automatic management apparatus 6, but a plurality of device management apparatuses 7 may be connected. The automatic test management apparatus 6 can schedule each device management apparatus 7 independently.

As the exhaust gas measuring device 4 (hereinafter, also simply referred to as the measuring device 4), here, for example, a device for measuring HC, NO _x , CO, CO ₂ or the like in exhaust gas flowing through an exhaust path of an internal combustion engine, The thing which performs the pre-processing for measuring an exhaust gas component like CVS is prepared. The measuring device 4 is configured by assembling one or more gas analysis units 9 which are unit devices and other operation units, but is not necessarily physically integrated. For example, a plurality of separated configurations may be referred to as one measurement device, or a plurality of measurement devices may be provided in one housing. The gas analysis unit 9 is, for example, a FID for measuring THC, a CLD for measuring NOx, NDIR for measuring CO, CO ₂ , or the like.
The measuring device 4 is also set as a management unit in the storage unit 76 of the device management apparatus 5 to be described later or in a database shared by them. If the data structure in the storage unit 76 is described in detail, a tree structure in which a group hierarchy to which a group belongs below the device hierarchy to which the measurement device 4 belongs, and a unit hierarchy to which an analysis unit or the like belongs below is formed. Are stored in the storage unit 76.
A group is defined as a set of one or more analysis units 7 operating for a common purpose, for example. The common purpose is, for example, component analysis of exhaust gas at a predetermined sampling point of the intake / exhaust path LG, or measurement of predetermined performance (for example, EGR rate, exhaust gas flow rate, etc.) of the internal combustion engine EG.
In this embodiment, a change operation to the storage unit 76 such as promotion of a group to a measurement device or change of an analysis unit belonging to the group is possible, and the group or device is a unit. It is a condition that it has a physical configuration that can operate independently (for example, it can be equipped with a pump and can sample gas independently).
A plurality of types of measurement devices 4 in this embodiment are exemplified. For example, the measurement groups G1 to G3 and the EGR rate measurement device G4 configured by a plurality of gas analysis units 9 having different measurement principles are provided. A first measuring device 401, a second measuring device 402 configured by a constant-capacity sampling apparatus, a third measuring device 403 configured by a measuring group Gn including an EGR rate measuring apparatus, and the like.

  The measurement device 4 includes a local computer, and a device main body 4a that controls the operation mode (measurement mode, calibration mode, purge mode, etc.) and state mode (sleep mode, standby mode, etc.) of the measurement device 4 A communication unit 4b is provided for receiving a command signal from the device management apparatus 5 and transmitting operation status information to the device management apparatus 5.

  As schematically shown in FIG. 2, each measurement device 4 is connected to a sampling pipe LD for sampling intake gas or exhaust gas from an intake / exhaust path LG of the engine. In FIG. 2, symbol LS indicates a span gas introduction tube for introducing calibration span gas, symbol LZ indicates a zero gas introduction tube for introducing calibration zero gas, and symbol V indicates a valve for switching. ing.

Each measuring device 4 measures the amount of each component such as HC, NO _x , CO, and CO ₂ related to the gas sampled through the sampling pipe LD. From the measured value, the vehicle VH such as an engine or a catalyst is measured. It is also possible to calculate a performance value of the device to be configured, for example, fuel consumption, EGR rate, and the like.
For this purpose, each measurement device 4 has a local computer in addition to a sensor 4a for measurement provided for each analysis unit, as shown in FIG.

  This local computer is physically equipped with a CPU, a memory, an A / D converter, a communication interface, etc., and performs measurement to indicate the amount of each component by correcting or calibrating the output value from the sensor 4a. A calculation unit 41 that calculates the device performance value from the measurement value, and communication that transmits the measurement value and the device performance value calculated by the calculation unit 41 to the device management apparatus 7 using a predetermined protocol The function as the part 42 is demonstrated.

  The local computer receives a command signal from the device management apparatus 7 and controls the valve V, the temperature control mechanism 4b, the pump 4c, and the like, and operates the operation mode (measurement mode, calibration mode, Purge mode, etc.) and state mode (sleep mode, standby mode, etc.), control unit 43, calibration unit 44 for calibrating the sensor 4a, device status information from the past to the present of the measuring device 4, etc. Are further acquired, such as a local storage unit 45 provided in a predetermined area of the memory.

  The device status information is information indicating the status of the measuring device 4 or its analysis unit, or more detailed equipment or related equipment. For example, pump pressure information indicating the suction pressure by the built-in pump 4c, sensor 4a. Function information that is information related to the function (for example, sensitivity), accumulated operation time information that indicates the accumulated operation time of each unit, and inspection time specifying information that is information for specifying a predetermined inspection time of the measurement device 4 Etc. This device status information includes calibration (0 point correction, span correction, conversion type correction), quality check (functional inspection of each part of the analysis unit, pipe leakage inspection, pump performance check, etc.) ) And other results.

The device management apparatus 7 is configured by installing a predetermined program on a general-purpose computer, for example, and physically includes a CPU, a memory, a display, input means (keyboard, mouse, etc.), a communication interface, and the like. Yes. As the CPU and its peripheral devices cooperate in accordance with the program stored in the memory, the device management apparatus 7 includes an operation detection unit 71, a display unit 72, a management main unit 73, as shown in FIG. It functions as the communication unit 74, device information acquisition unit 75, storage unit 76, and the like. The device management apparatus 7 is provided with a communication port, and the measurement device 4 is connected to the device management apparatus 7 in a communicable manner by wire or wireless.
Next, the operation of each part of the device management apparatus 7 will be described as well.

  First, the operator physically connects the measuring device 4 to the device management apparatus 7 with a connector cable after performing various operations (such as piping) related to the measuring device 4.

  On the display 7a of the device management apparatus 7, a screen (hereinafter also referred to as a plug-in screen) 8A as shown in FIG. 4 is displayed as an initial screen by the function of the display unit 72. On the plug-in screen 8A, a plurality of device indicators 81 indicating the measurement devices 4 registered in advance are arranged so as not to overlap. Each device indicator 81 has a rectangular shape, and in addition to the schematic diagram showing the corresponding measurement device 4, the connection button 82 for connecting to the measurement device 4 and the connection of the measurement device 4 are disconnected. A disconnect button 83 for performing the connection and a connection state display area 84 indicating the connection state are provided.

  When the operator clicks the connection button 82 on the plug-in screen 8A, for example, the operation detection unit 71 detects the operation as a connection operation. In response to this, the communication unit 74 starts communication with the communication unit 42 of the corresponding measurement device 4, the predetermined connection protocol ends normally, and a connection state in which mutual communication is possible (hereinafter simply referred to as a connection state). Display) is displayed in the connection status display area 84 in the device indicator. Until the mutual communication is established, a display “Initialization” indicating a state of preparation for connection is displayed in the connection state display area 84.

  On the other hand, when the disconnect button 83 is clicked from this connected state, the operation detection unit 71 detects the operation as a disconnect operation. Then, the communication unit 74 blocks communication with the communication unit 42 of the corresponding measurement device 4 and displays a display “Stopped” indicating a state in which the connection is released in the connection state display area 84.

  Note that if the connection button 82 is clicked when the connector cable is disconnected, or if the connector cable is disconnected during the connection state, the operation detection unit 71 detects this and indicates a state in which the connection has failed. A connection state display area 84 is displayed.

  In the connected state, a new reconnection button (restart button) 85 is displayed. When the reconnection button 85 is clicked, the communication unit 74 starts the connection protocol again and reconnects.

  By the way, in this embodiment, in the connection protocol, the step of sucking the device status information of each measurement device 4 into the device management apparatus 7 is automatically performed.

  More specifically, when the connection button 82 or the reconnection button 85 is clicked, the operation detection unit 71 detects the operation, and the device information acquisition unit 75 stores the local storage of the corresponding measurement device 4 accordingly. The device state is accessed via the communication units 42 and 74, and the device state information from the past to the present of the measurement device 4 stored in the local storage unit 45 is automatically acquired.

After the connection, the device information acquisition unit 75 sequentially accesses the local storage unit 45 of the measurement device 4 and additionally acquires device state information.
The management main body 73 performs various management operations such as issuing commands such as operation modes to the measurement device 4 and acquiring measurement values and functional performance values from the measurement device 4.
The device status information acquired in this way is managed by the management main body 73, but can be displayed on the screen in time series.

  FIG. 5 shows an example of the display screen (hereinafter also referred to as a device status history screen). On this screen 8B, changes over time in the sensitivity and drift of the gas analysis unit selected by the operator are displayed as graphs 86 and 87 and a list 88 with the horizontal axis as time. The sensitivity of the analysis unit is a primary output value of the sensor 4a when sensing a span gas having a predetermined concentration. A decrease in this value indicates that the sensor sensitivity is decreased. The drift is a primary output value of the sensor 4a when sensing zero gas (a gas having a zero concentration), and increasing this value indicates that the offset of the sensor 4a is increasing. Since the sensitivity and the drift amount are measured when the measuring device 4 is calibrated, they are additionally recorded in the local storage unit 45 of the measuring device 4 at that time.

  Therefore, the management main body 73 of the device management apparatus 7 notifies that maintenance or replacement is necessary when the device state information exceeds a predetermined threshold value (is exceeded or below). This threshold value is provided with a first threshold value for issuing a final alarm and a second threshold value for notifying that it is a previous stage regarding the drift amount and sensitivity. As an example of notification, here, when the first threshold is exceeded, the corresponding column of the list is changed to another display mode such as red on the same screen 8B. The same applies to the second threshold value. Here, the second threshold value is changed to, for example, orange so that it can be distinguished from the case where the first threshold value is exceeded.

Then, the operator can readjust the analysis unit according to the notification alarm.
Further, another display example of the device status history screen is shown in FIG. Here, the time series change of the vacuum pump pressure provided in the CLD of the analysis unit is displayed in a list 89 and a graph 810. Here, in addition to the display in the list as shown in FIG. 5, the first threshold and the second threshold are displayed as line segments on the graph 810 as the notification operation when the threshold is exceeded.

  According to the present embodiment configured as described above, the measurement device 4 stores its own device state information, and the device state information is automatically taken up by the device management apparatus 7 at the time of connection. Even if the device 7 is changed, the device state information is inherited without leaking, and it becomes possible to comply with the regulations and to maintain the measuring device 4 with certainty.

  Therefore, the device management apparatus 7 can reliably perform management such as automatically informing the operator of the next inspection time, maintenance time, items, etc. of each connected measuring device 4.

  In particular, in this embodiment, the connection state of a plurality of measurement devices 4 can be freely controlled by an operator's connection / disconnection operation on the device management apparatus 7 side, and each connectable measurement device 4 has a standardized format, In other words, since it can be registered in advance as a device indicator 81 in a plurality of device management apparatuses 7, a measurement device 4 is physically connected to another device management apparatus 7 in another cell and connected in the same manner. You can make it easy to recognize.

  In addition, since the measuring device 4 and the device management apparatus 7 can be easily connected without selecting the other party in this way, the test system can be operated more flexibly.

  In addition, while displaying the change and trend of device status information on the screen, when the value of the device status information exceeds the threshold value on the same screen, a warning is issued without displaying the change trend. Compared to the above, the operator can more accurately determine the cause of the notification or warning. For example, in the case of a warning that is output when the value suddenly goes up and down out of the tendency, the operator can determine that it is due to a measurement error, a calibration error, etc., and can reduce unnecessary maintenance.

  The present invention is not limited to the above embodiment. The display mode of the screen can be variously changed. Further, for example, it can be applied to a test with an engine alone, and can also be used for a test of an airplane, a ship, or its equipment.

DESCRIPTION OF SYMBOLS 1 ... Vehicle performance test system 4 ... Measuring device 7 ... Device management apparatus 71 ... Operation detection part 72 ... Display part 73 ... Management main-body part 81 ... Device label | marker 82. ..Connection / disconnection buttons (connection buttons)
83 ... Connection / disconnection operation button (disconnection button)
VH ... Moving object (vehicle)

Claims (6)

For testing a moving object such as a vehicle, a ship, an airplane, etc. or an apparatus used for the moving object,
Comprising one or a plurality of test devices used for the test, and a device management apparatus that is communicably connected to the test device and manages the test device;
The device management apparatus includes:
An operation detection unit for detecting that a connection / disconnection operation for connecting or disconnecting the test device is performed;
A test comprising: a device state information acquisition unit that acquires device state information indicating a current or past state of a corresponding test device when the operation detection unit detects a connection operation. system.   The device state information is stored in a local storage unit provided in the test device, and the device state information acquisition unit accesses the local storage unit to acquire device state information of the test device. The test system according to claim 1.   A time series change of the value of the device status information is displayed on the screen so as to be recognizable, and further provided with a management main body for notifying the fact when the value of the device status information exceeds a predetermined threshold. The test system according to claim 1 or 2, characterized in that   The device status information includes pump pressure information that is information indicating the suction pressure by the pump when the test device is a pump, and information related to the function of the measurement device when the test device is a measurement device. The functional time information, the accumulated operation time information indicating the accumulated operation time of the test device, or the inspection time specifying information which is information for specifying a predetermined inspection time of the test device. The test system according to any one of 1 to 3.   The test system according to claim 3 or 4, wherein the test device is provided in an exhaust path of an internal combustion engine and measures exhaust gas flowing through the exhaust path. It is communicably connected to one or a plurality of test devices for testing a moving object such as a vehicle, a ship, an airplane, etc., or a device used in the moving object,
An operation detection unit for detecting that a connection / disconnection operation for connecting or disconnecting the test device is performed;
A device state information acquisition unit that acquires device state information indicating a current or past state of a corresponding test device, triggered by the detection of a connection operation by the operation detection unit. Device management device.