JP2016038762A - Display device - Google Patents

Abstract

To enable a user to easily check a relationship between a current measurement result displayed on a trend screen and a setting.
A setting range graph generation unit generates a setting range display graph indicating the numerical range on a measurement value axis having the same scale as the measurement value change graph. The display control unit 104 simultaneously displays the measurement value change graph generated by the measurement value graph generation unit 101, the event generation display graph generated by the event generation graph generation unit 102, and the setting range display graph generated by the setting range graph generation unit 103. , And displayed on the display unit 109 as a trend screen.
[Selection] Figure 1

Description

  The present invention relates to a display device that displays a monitoring state by a controller.

  A temperature controller that adjusts the temperature of various temperature environments, etc., displays the temperature of the monitoring target detected using a temperature sensor such as a thermocouple or resistance temperature detector, and the detected temperature (PV value). A control output (MV value) for the heating / cooling device is obtained according to the set temperature (SP value), and the temperature to be monitored is controlled. By the way, the temperature controller cannot enlarge the area which displays each information for size reduction.

  For this reason, trend graphs showing time-series changes in measured values can be confirmed on the trend screen on the monitor of small computer devices such as personal computers, tablet terminals, and smartphones connected to the controller. (See Patent Document 1). On the trend screen, the setting state of the controller, changes in measured values, etc. are displayed in a table or graph. For example, as shown in FIG. 4, changes in the temperature measurement results for two monitoring targets are shown in a graph in a region 401. In addition, a result of measuring a value outside the set numerical range is displayed in a timing diagram as an alarm on / off change in region 402. In addition, it is configured such that the controller setting can be changed by a connected computer device.

JP 2004-178157 A

  However, in the above-described trend screen, there is a problem that it is not possible to easily determine whether the measurement value is correctly related to the setting and the result reflecting the setting, and the cause of the measurement result. For example, in the example shown in FIG. 4, it cannot be instantaneously determined which measured value in the graph display exceeds the set range. In addition, on the trend screen described above, the set values are displayed as a table with a list of numerical values, and the changes in the measured values are displayed as graphs. Even if these values are displayed simultaneously, the relationship between the measured values and the set values is displayed. Is not easy to recognize intuitively.

  The present invention has been made to solve the above problems, and allows the user to easily check the relationship between the current measurement result displayed on the trend screen and the setting. With the goal.

  The display device according to the present invention is a measurement value graph generation unit that generates a measurement value change graph showing a change in measurement values measured in a monitoring target in time series, and a measurement value axis of the same scale as the measurement value change graph, A setting range graph generation unit that generates a setting range display graph indicating a numerical range set for the occurrence of an event, a measurement value change graph generated by the measurement value graph generation unit, and a setting range display graph generated by the setting range graph generation unit Is simultaneously displayed on the display unit.

  In the display device, the setting range graph generation unit may generate a setting range display graph including a numerical display of a numerical range.

  The display device includes a numerical value connection line generation unit that generates a line parallel to a time axis indicating a numerical range in which an event occurs in a measurement value graph in a state where the line is connected to the setting range display graph, and the display control unit includes: In addition to the measured value change graph and the setting range display graph, the lines generated by the numerical value connection line generation unit may be displayed on the display unit at the same time.

  The display device includes an event generation graph generation unit that generates an event generation display graph that indicates whether or not an event has occurred in a timing diagram corresponding to a change in the measurement value on the same time scale as the measurement value change graph. The control unit may cause the display unit to simultaneously display the event occurrence display graph generated by the event occurrence graph generation unit in addition to the measurement value change graph and the setting range display graph.

  In the above display device, the event occurrence graph generation unit may generate an event occurrence display graph indicating whether or not a plurality of events have occurred.

  In the display device, the setting range graph generation unit may generate a setting range display graph in which setting ranges corresponding to a plurality of events are in different display states.

  In the above display device, the measurement value graph is divided using the line generated by the numerical value connection line generation unit as a boundary line, and the measured value is changed to the same display state as the corresponding event occurrence display graph in the divided measurement value graph A graph display change unit may be provided, and the display control unit may cause the display unit to display the measurement value graph changed by the measurement value graph display change unit.

  The display device includes a simulated data generation unit that generates an event generation display graph in a simulated manner by changing the input simulated measurement value and the input numerical range, and the display control unit is a simulation generated by the simulated data generation unit. A typical event occurrence display graph may be displayed on the display unit. Moreover, you may make it provide the setting reflection part which reflects the numerical value range which the simulation data generation part used for generation | occurrence | production of the simulation event generation | occurrence | production display graph on an actual setting value.

  As described above, according to the present invention, it is possible to obtain an excellent effect that the relationship between the current measurement result displayed on the trend screen and the setting can be easily confirmed by the user.

FIG. 1 is a configuration diagram showing a configuration of a display device according to an embodiment of the present invention. FIG. 2 is a configuration diagram illustrating a display example on the display unit 109 of the display device according to the embodiment of the present invention. FIG. 3 is a configuration diagram illustrating a display example on the display unit 109 of the display device according to the embodiment of the present invention. FIG. 4 is a configuration diagram showing a display configuration of a conventional display device.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram showing a configuration of a display device according to an embodiment of the present invention. The display device includes a measured value graph generation unit 101, an event generation graph generation unit 102, a setting range graph generation unit 103, a display control unit 104, a display unit 109, and an input unit 110.

  The measured value graph generation unit 101 generates a measured value change graph that shows changes in measured values measured by the monitoring target in time series. The event occurrence graph generation unit 102 generates an event occurrence display graph indicating whether or not an event has occurred with a timing diagram in association with a change in the measurement value on the same time scale as the measurement value change graph. The event is generated from an event generation unit (not shown). The event generation unit detects a measurement value that falls within the numerical range set for the occurrence of the event and generates an event. The event is, for example, an alarm.

  In addition, the setting range graph generation unit 103 generates a setting range display graph indicating the numerical range on the measurement value axis having the same scale as the measurement value change graph. The display control unit 104 causes the display unit 109 to simultaneously display the measurement value change graph generated by the measurement value graph generation unit 101 and the setting range display graph generated by the setting range graph generation unit 103 as a trend screen. Further, the display control unit 104 displays the event occurrence display graph generated by the event occurrence graph generation unit 102 on the display unit 109 as a trend screen together with the measured value change graph and the setting range display graph.

  For example, as shown in FIG. 2, a measurement value change graph is displayed in the measurement value change display area 121 of the display unit 109, and an event occurrence display graph (timing diagram) is displayed in the event occurrence display area 122. In the example shown in FIG. 2, a graph indicating a time series change of two temperature measurement values is displayed as a part of the trend screen. In addition, in the example shown in FIG. 2, with respect to the time series change of one measurement value, the event occurrence graph 131 indicating whether or not the alarm 1 is generated, the event occurrence graph 132 indicating whether or not the alarm 2 is generated, and whether or not the alarm 3 is generated Is displayed as a part of the trend screen.

  In addition, in the present invention, a setting range display graph is displayed in the setting range display area 123 of the display unit 109. In the example shown in FIG. 2, a range graph 141 indicating the numerical range set for the alarm 1 issuance, a range graph 142 indicating the numerical range set for the alarm 2 issuance, and the numerical range set for the alarm 3 is shown. A range graph 143 shown is displayed as part of the trend screen.

  In the example shown in FIG. 2, a dead zone set for each numerical value range is also shown. For example, regarding the setting range for alarm 1, the range graph 141 indicates that 100 to 110 ° C. is set as the dead zone for the upper limit. Further, regarding the setting range for the alarm 2, the range graph 142 shows that the lower limit is set to 50 to 60 ° C. and the upper limit is set to 80 to 90 ° C. as the dead zone. In addition, regarding the setting range for the alarm 2, the range graph 142 indicates that the lower limit is set to 30 to 40 ° C. and the upper limit is set to 130 to 140 ° C. as the dead zone.

  Further, in the example shown in FIG. 2, a numerical value display of a numerical value range is displayed in each range graph under the control of the setting range graph generation unit 103. As described above, the setting range graph generation unit 103 may generate a setting range display graph including a numerical value display of the numerical value range and display it.

  Since the setting range display graph is displayed as described above, the relationship between the measurement value and the setting value related to the event occurrence, the range of the measurement value where the event will occur, and the measurement result can be determined instantly. become. Further, as described above, the number of events such as alarms is not limited to one, and a plurality of event occurrences set for the same measurement value may be displayed simultaneously. In this case, the event occurrence graph generation unit 102 generates an event generation display graph indicating whether or not a plurality of events have occurred, and the setting range graph generation unit 103 sets the setting ranges corresponding to the plurality of events to different display states. Generate the set range display graph.

  In addition, the display device includes a numerical connection line generation unit 105. The numerical value connection line generation unit 105 generates a line parallel to the time axis indicating the numerical value range where the event occurs in the measurement value graph in a state where the line is connected to the setting range display graph.

  When the numerical connection line generation unit 105 generates the connection line in this way, the display control unit 104 displays the generated connection line at the same time in addition to the measurement value change graph, the event occurrence display graph, and the setting range display graph. 109 is displayed. For example, as shown in FIG. 2, a dotted line 161 is displayed from the setting range display area 123 to the measurement value change display area 121. By doing so, the relationship between the set value and the measurement result becomes easier to understand.

  The display device also includes a measured value graph display changing unit 106, a simulated data generating unit 107, and a setting reflecting unit 108. The measurement value graph display changing unit 106 divides the measurement value graph using the line generated by the numerical value connection line generation unit 105 as a boundary line, and displays the divided regions in the measurement value graph in the same display state as the corresponding event occurrence display graph. Change to

  Thus, when the measurement value graph display change unit 106 changes the display, the display control unit 104 causes the display unit 109 to display the measurement value graph changed by the measurement value graph display change unit 106. For example, as shown in FIG. 3, the range 151 of the measurement value change display area 121 indicating the range of the range graph 141 is displayed in the same color as the range graph 141. Further, the range 152 of the measurement value change display area 121 indicating the range of the range graph 142 is displayed in the same color as the range graph 142. Further, the range 153 of the measurement value change display area 121 indicating the range of the range graph 143 is displayed in the same color as the range graph 141. Each display color is a different color so as to be identifiable. By displaying in different colors in this way, the relationship between the set value and the measurement result becomes easier to understand.

  By the way, the setting of the alarm is conventionally performed for an actual controller, and the alarm operation is confirmed by actually applying the voltage, resistance value, etc. suitable for the input type as an input. In order to check this kind of operation, prepare and turn on the power of the main unit, make various settings to the controller, and actually change the measured value by inputting it with a voltage generator. I had to make sure that the alarm worked as it was considered. Moreover, in the state where it is actually incorporated in the system, a sensor or the like is attached, and it is difficult to artificially change the measurement value with a voltage generator or the like. Therefore, it was virtually impossible to confirm whether the setting was as expected.

  On the other hand, if it is possible to simulate the alarm action on a display that can be visually recognized by the user, the set value can be set after confirming the alarm action even if the controller main body is incorporated in the system. It becomes possible to write. The simulation data generation unit 107 enables the simulation.

The simulated data generation unit 107 generates an event generation display graph in a simulated manner by changing the input simulated measurement value and the input numerical range. For example, when a simulated measurement value input from the input unit 110 and a changed numerical range are input, the simulated data generation unit 107
An event occurrence display graph corresponding to the changed numerical value range is simulated for the input measured measurement value for the current measured value. When the simulated event occurrence display graph is generated in this way, the display control unit 104 causes the display unit 109 to display the graph.

  In particular, since there are many settings related to alarm generation, it is difficult to accurately assume what the behavior will be when using these functions in combination. Even if the user is familiar with the specifications, there is a possibility of misunderstanding by a combination of complicated settings. If the setting is made with such a misunderstanding, for example, a situation may occur in which an alarm does not occur as expected despite an alarm for avoiding a high-temperature danger, which may lead to an accident. If simulation can be performed by the simulation data generation unit 107 and the operation can be confirmed in advance, the above-described accident can be avoided.

  The setting reflection unit 108 reflects the numerical range used by the simulated data generation unit 107 for generating the simulated event occurrence display graph on the actual setting value. For example, after the preliminary operation is confirmed as described above, the numerical ranges of the setting items such as the confirmed alarm on / off point, hysteresis, and delay time are reflected on the controller connected by the setting reflection unit 108. As a result, the result confirmed by the simulation can be reliably set as an actual set value at high speed without fail.

  By the way, if the input unit 110 is a touch panel sensor integrally attached to the display unit 109, the numerical value range can be easily changed as described above. For example, in the measured value change display area 121 of the display unit 109, a simulated measured value is input by drawing a waveform indicating a time-series change of the measured value by tracing with a fingertip. It is possible to confirm how an alarm is issued by changing the set value for the simulated measurement value input in this way.

  As described above, according to the present invention, a setting range display graph indicating a numerical range is generated on the measurement value axis having the same scale as the measurement value change graph in which the change of the measurement value is displayed. Since it is displayed together with it, the relationship between the current measurement result displayed on the trend screen and the setting can be easily confirmed by the user.

  In the conventional trend screen, in order to confirm whether the setting, the result reflecting the setting, the measurement result, and the relationship between these results are correct or the reason for the result, rely on the memory of the setting. However, it was difficult to intuitively judge whether the condition was good or bad. Even if the set value is displayed, it is an enumeration of numbers, and it is difficult to intuitively know the relationship between the monitor value and the set value even if the trend screen graph and the numerical value are arranged.

  Intuitively knowing how all the settings are, especially when using the alarm deadband operation, standby operation, on-delay, and off-delay that are unique to temperature controllers, This is important to prevent setting errors. However, conventionally, it has not been possible to intuitively determine the relationship between the setting and the measurement value that are causing the current alarm result.

  On the other hand, according to the present invention, the setting range can be intuitively understood on one screen in addition to the current measured value and alarm state without separately checking the numerical value of the setting. Compared with the measurement results, it is possible to significantly prevent work efficiency and mistakes from being confirmed.

  The present invention is not limited to the embodiment described above, and many modifications and combinations can be implemented by those having ordinary knowledge in the art within the technical idea of the present invention. It is obvious. In the present invention, it is important to display the measured value change graph and the setting range display graph simultaneously on the display unit as a trend screen under the control of the display control unit. Can be combined as appropriate.

  DESCRIPTION OF SYMBOLS 101 ... Measurement value graph generation part, 102 ... Event generation graph generation part, 103 ... Setting range graph generation part, 104 ... Display control part, 105 ... Numerical value connection line generation part, 106 ... Measurement value graph display change part, 107 ... Simulation Data generation unit 107 ... Setting reflection unit 109 ... Display unit 110 ... Input unit

Claims (9)

A measurement value graph generation unit that generates a measurement value change graph showing a change in the measurement value measured in the monitoring target in time series; and
A setting range graph generating unit that generates a setting range display graph indicating a numerical range set with respect to the occurrence of an event on the measurement value axis of the same scale as the measurement value change graph;
A display device comprising: a display control unit configured to simultaneously display a measurement value change graph generated by the measurement value graph generation unit and a setting range display graph generated by the setting range graph generation unit on a display unit. The display device according to claim 1,
The setting range graph generation unit generates the setting range display graph including a numerical display of a numerical range. The display device according to claim 1 or 2,
A numerical value connection line generation unit that generates a line parallel to the time axis indicating the numerical value range in which the event occurs in the measurement value graph in a state of being connected to the setting range display graph;
The display control unit causes the display unit to simultaneously display lines generated by the numerical value connection line generation unit in addition to the measurement value change graph and the setting range display graph. The display device according to any one of claims 1 to 3,
Corresponding to the change of the measurement value on the same scale as the measurement value change graph, the event generation graph generating unit for generating an event generation display graph showing the occurrence of the event in a timing diagram,
The display control unit causes the display unit to simultaneously display the event generation display graph generated by the event generation graph generation unit in addition to the measurement value change graph and the setting range display graph. The display device according to claim 4, wherein
The event occurrence graph generation unit generates the event occurrence display graph indicating presence / absence of occurrence of a plurality of events. In the display device according to any one of claims 1 to 5,
The display device, wherein the setting range graph generation unit generates the setting range display graph in which setting ranges corresponding to a plurality of events are in different display states. The display device according to claim 6, wherein
A measurement value graph that divides the measurement value graph using the line generated by the numerical value connection line generation unit as a boundary line, and changes the area in the divided measurement value graph to the same display state as the corresponding event occurrence display graph With a display changer,
The display control unit displays the measurement value graph changed by the measurement value graph display change unit on the display unit. The display device according to any one of claims 1 to 7,
A simulation data generation unit that generates the event generation display graph in a simulated manner by changing the input simulated measurement value and the input numerical range;
The display control unit causes the display unit to display the simulated event occurrence display graph generated by the simulated data generation unit. The display device according to claim 8, wherein
A display device, comprising: a setting reflection unit that reflects the numerical range used by the simulated data generation unit to generate a simulated event occurrence display graph on an actual setting value.