JP5643367B2 - Inverter panel device - Google Patents

Description

  Embodiments described herein relate generally to a panel device of an inverter device.

  The panel device attached to the inverter device has a display (display means) for displaying various information related to the inverter device and settings for setting various setting values (frequency command value, parameter value, etc.) related to the inverter device. A device (setting means) is provided. Conventionally, a volume composed of a variable resistor or the like has been used as the setting device.

  In the case of a setting device using a volume, a value corresponding to the rotational position is set. Normally, the volume is provided with a scale (notch), and the rotational position can be understood from the positional relationship between the scale and a pointer provided on a knob that is an operation portion of the volume. Therefore, the user can know the outline of the set value (set amount) set by the volume by visually confirming the rotational position of the volume.

  However, in recent years, a setting dial including a pulse encoder, a sheet key (up key, down key), and the like have been used as the setting device. In the case of such a setting device, unlike the volume, the state (operation state) and the set setting value are not necessarily linked. Therefore, the user cannot know the set value even if the operation state is visually confirmed. For this reason, in the case of the above-described configuration, the value is displayed on the display unit as a number while setting the set value. Thereby, the user can know the set value during the setting of the set value. When the setting is completed, a normal display such as the current output frequency or trip code is displayed on the display.

JP 2008-011624 A

  When a pulse encoder or the like is used as the setting device, it is conceivable that the convenience of the user is lowered in the following points as compared with the case where a volume is used. That is, in the case of the configuration using the volume, the user can easily grasp the outline of the set value such as the frequency command value by visually recognizing the rotation position, and as a result, the inverter device can be started quickly. can do.

  On the other hand, in the case of a configuration using a pulse encoder or the like, the user cannot easily grasp a set value such as a frequency command value. In this case, the user needs to use the monitor mode for displaying the set value on the display unit or display the set value on the display unit by changing the set value. That is, it takes a lot of time and labor to confirm the set value, and the operation of the inverter device cannot be started quickly.

  Therefore, there is provided a panel device of an inverter device that allows a user to easily know the outline of the setting value set by the setting means regardless of the type of setting means used.

The panel device of the inverter device of the present embodiment includes display means, setting means, and display control means. The display means displays various types of information related to the inverter device, and has a multi-digit 7-segment display. The setting means has an operation unit that can be operated by the user, and sets various setting values related to the inverter device in accordance with the operation of the operation unit. The display control means controls the display by the display means, and according to the size of an arbitrary set value among the set values set by the setting means among the segments of the multi-digit 7-segment display. The set value expression processing for expressing the size of an arbitrary set value by lighting a certain number of segments is configured to be executed. When the set value expression processing is executed, each of the multiple-digit 7-segment display Among the segments, some or all of the segments arranged on the outer periphery and the dot display segment are to be lit.

The block diagram which shows 1st Embodiment and shows schematic structure of a panel apparatus The figure which shows the aspect in which the display state of a display apparatus changes according to setting operation of a setting value The figure which shows an example of the display method which expresses the outline of a setting value except a number and a character FIG. 3 shows the second embodiment and is a view corresponding to FIG. 3 showing a first modification of the method for expressing the outline of the set value. FIG. 3 equivalent diagram showing a second modification of the method for expressing the outline of the set value FIG. 3 equivalent view showing the third embodiment Diagram showing the relationship between the lower digit of the set value and the display ratio of each lighting pattern

Hereinafter, a plurality of embodiments of a panel device will be described with reference to the drawings. In each embodiment, substantially the same components are denoted by the same reference numerals and description thereof is omitted.
(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS.
A panel device 1 shown in FIG. 1 is attached to an inverter device for variable speed control of an electric motor. The panel device 1 includes a control unit 2, a setting unit 3, an operation key group 4, a display unit 5, an LED driving unit 6, a data memory 7, and the like. The control unit 2 is mainly composed of a microcomputer including a CPU, a ROM, a RAM, and the like. The control unit 2 implements various controls by executing a predetermined program. The control unit 2 can exchange data with a control unit (not shown) of the inverter device by communication or the like. The control unit 2 can detect the operation state of the inverter device by transmitting and receiving the data.

  The setting unit 3 (corresponding to the setting means) includes a setting dial 3a (corresponding to the operation unit) having a knob that can be rotated by the user. The setting dial 3a is provided with a pulse encoder. The setting unit 3 outputs a pulse signal corresponding to the rotation operation of the setting dial 3a. The operation key group 4 is composed of a determination key 4a, a RUN key 4b, a STOP key 4c, and the like, which are push switches that can be pressed by the user. The enter key 4a is operated when determining a value being set. The RUN key 4b is operated when starting the operation of the inverter device. The STOP key 4c is operated when stopping the operation of the inverter device. The operation key group 4 outputs an operation state signal corresponding to the operation state of each key 4a to 4c.

  The control unit 2 is given a pulse signal output from the setting unit 3 and an operation state signal indicating the operation state of the operation key group 4. The control unit 2 detects an operation on the setting dial 3a of the setting unit 3 based on the given pulse signal (setting detection process). Based on the result of the setting detection process, the control unit 2 sets operating conditions such as setting a frequency command value and a numerical value of a parameter. Further, the control unit 2 outputs data related to the various set values thus set to the control unit of the inverter device and stores (stores) the data in the data memory 7.

  The control unit 2 detects an operation on the enter key 4a, the RUN key 4b, and the STOP key 4c based on the given operation state signal (operation detection process). The control unit 2 outputs data related to the operation state of the operation key group 4 to the control unit of the inverter device based on the result of the operation detection process. The control unit of the inverter device controls operations such as operation of the inverter device based on data provided from the control unit 2 of the panel device 1.

  The display unit 5 (corresponding to the display means) is for displaying various information related to the inverter device. The display unit 5 includes 7-segment LED displays 11 to 14 and LEDs 15a to 15e for displaying small dots. The 7-segment LED indicators 11 to 14 (corresponding to the 7-segment indicator) are provided with segments A to G having a rectangular shape and a segment DIP having a circular shape (small particle) for displaying a decimal point. However, the segment DIP is omitted only in the 7-segment LED display 14 representing the least significant digit. In FIG. 1, only a part of the reference numerals (A to G, DIP) for each of the above-described segments is given, and the reference numerals are omitted for the others. The display unit 5 can display four-digit alphanumeric characters and the like by providing four 7-segment LED indicators 11 to 14 together.

  The LEDs 15a to 15e are used to represent units of numerical values to be displayed, an operation state of the inverter device, an operation mode, and the like. The LED driving unit 6 drives each LED of the display unit 5 by PWM (Pulse Width Modulation) based on a control signal given from the control unit 2. The data memory 7 stores various data including data relating to the various setting values described above.

  The control unit 2 has a function as display control means for controlling display by the display unit 5. When the control unit 2 displays the data related to the set values (frequency command values, parameter values, etc.) set by the setting unit 3 among the data stored in the data memory 7, the normal display processing and One of the set value expression processes is executed. The normal display process is a process of displaying the set value as a numerical value on the display unit 5. The set value expression process is a process for schematically displaying (expressing) the size (set amount) of the set value using information other than numbers and characters.

  When the normal display process is executed, the process is as follows. In this case, first, the control unit 2 selects and extracts data to be displayed from the data stored in the data memory 7 (display data selection process). And the control part 2 converts the taken-out data into the data for numerical display for displaying as a numerical value on the 7 segment LED indicators 11-14 of the display part 5, etc. (data conversion process for numerical values display). Thereafter, the control unit 2 outputs a control signal based on the numerical display data to the LED driving unit 6. Thereby, each LED of the display unit 5 is driven, and an arbitrary set value stored in the data memory 7 is displayed as a numerical value.

  Such normal display processing is performed when the setting dial 3a is operated (when a setting value setting operation or changing operation is performed) or when an operation of a predetermined procedure for shifting to the monitor mode is performed. Executed. The monitor mode is normally provided as a function of the inverter device, and is a mode for causing the display unit 5 to display a frequency command value and the like.

  On the other hand, when the set value expression process is executed, the process is as follows. Also in this case, the control unit 2 first executes display data selection processing. And the control part 2 converts the taken-out data into the information display data for displaying on the 7 segment LED indicators 11-14 of the display part 5, etc. by information other than a numerical value or a character (information display data conversion process) ). Thereafter, the control unit 2 outputs a control signal based on the information display data to the LED driving unit 6. Thereby, each LED of the display unit 5 is driven, and the size of an arbitrary set value stored in the data memory 7 is schematically displayed as information other than numerical values and characters.

Such setting value expression processing is executed during a period in which the setting value setting (changing) operation is not performed. Note that the control unit 2 may execute the set value expression processing only for the periods shown in the following (1) and (2) based on the result of detecting the operation state of the inverter device.
(1) At least a part of a period from when the power to the inverter device is turned on until the start of operation (for example, a period from when the initial display displayed after power is turned on until a predetermined time (for example, about several seconds) elapses) )
(2) A period during which the frequency command value for which the inverter device is set is not displayed (for example, a period during which the inverter device is stopped or accelerated / decelerated)
Further, the control unit 2 may execute the set value expression process on condition that a specific operation key is operated instead of the period. That is, the control unit 2 may execute the set value expression processing during a period from when the specific operation key is operated until a predetermined time elapses. As a specific operation key, an operation key for executing the set value expression processing may be provided separately. However, since the RUN key 4b or the STOP key 4c that originally exist can be used as described below, the operation key can be used. It is beneficial.

  That is, since the RUN key 4b is operated when starting the operation of the inverter device, it does not affect the operation of the inverter device even if it is operated during the operation. Therefore, the set value expression process may be executed when the RUN key 4b is operated during the operation of the inverter device. Moreover, since the STOP key 4c is operated when stopping the operation of the inverter device, it does not affect the operation of the inverter device even if it is operated during the stop. Therefore, the set value expression process may be executed when the STOP key 4c is operated while the inverter device is stopped. It should be noted that the period and timing when the set value expression processing is executed may be configured so that the user can appropriately change it by setting parameters, for example.

Next, the operation of the above configuration will be described.
In the present embodiment, when the set value expression process is executed, the number of segments corresponding to the size of the set value set according to the rotation operation of the setting dial 3a is turned on. Specifically, 0 to 10 segments are lit based on the ratio of the set value to the maximum value.

The ratio α of the set value (for example, frequency command value) to the maximum value (for example, maximum frequency value) is represented by the following (1), and will be represented as display data in the following description. However, here, in order to make the explanation easy to understand, the display data is represented by an integer, but it is not necessary to be limited to this. In the equation (1), the set value is represented by Ac and the maximum value is represented by Amax. Furthermore, “INT ()” means that only the integer part is acquired for the value in parentheses.
α = INT (100 × Ac / Amax) (1)

In order to realize such set value expression processing, the control unit 2 (display control means) performs a calculation based on the following equation (2), and obtains the number n of segments to be lit from the set value.
n = INT ((α−1) / 10) +1 (2)
By executing such setting value expression processing, for example, when the set value is relatively small, the number of segments to be lit is relatively small (see FIG. 2A). In contrast, when the set value is relatively large, the number of segments to be lit is relatively large (see FIG. 2B).

  The specific method of lighting the segment is as follows. When the set value expression process is executed, the segment DIP for decimal point display of the 7-segment LED 12 is always lit regardless of the size of the set value.

  As shown in FIG. 3, when the display data is 0%, all the segments of the 7-segment LED indicators 11 to 14 are turned off. When the display data is 1% to 10%, the segment D of the 7-segment LED display 11 is turned on. When the display data is 11% to 20%, the segment E of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 1% to 10%. When the display data is 21% to 30%, the segment F of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 11% to 20%. When the display data is 31% to 40%, the 7 segment LED display 11 segment A is lit in addition to the segments that are lit when the display data is 21% to 30%. When the display data is 41% to 50%, the segment A of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 31% to 40%.

  When the display data is 51% to 60%, the segment A of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 41% to 50%. When the display data is 61% to 70%, the segment A of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 51% to 60%. When the display data is 71% to 80%, the segment B of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 61% to 70%. When the display data is 81% to 90%, the segment C of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 71% to 80%. When the display data is 91% to 100%, the segment D of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 81% to 90%.

  As described above, in the set value expression processing, the segments A, D, E, and F of the 7-segment LED display 11, the segment A of the 7-segment LED display 12 and 13, and the segments A to D of the 7-segment LED display 14. Is the target of lighting. In other words, in the set value expression processing, the segments arranged on the outer periphery among the four segments of the four 7-segment LED displays 11 to 14 provided for the lighting are objects to be lit, and are set according to their lighting states. The magnitude of the value is expressed.

As described above, according to the present embodiment, the following effects can be obtained.
In this embodiment, in order to set a frequency command value, a numerical value of a parameter, and the like using a setting dial 3a including a pulse encoder having a configuration in which it is difficult to estimate a value set from an operation state of an operation unit (knob). The setting unit 3 is configured. Conventionally, in the case of such a configuration, the user uses the monitor mode for displaying the setting value on the display unit 5 or displays the setting value on the display unit 5 by performing a setting value setting operation (changing operation). It was necessary to let them. However, when the setting dial 3a is rotated to display the setting value, the setting value may be changed unintentionally. In addition, in order to use the monitor mode, it is necessary to know the operation procedure in advance, and there is a problem that the subsequent operation of the inverter device cannot be performed quickly because the operation must be performed. there were.

  On the other hand, in the present embodiment, the control unit 2 can execute a setting value expression process for displaying the size of the setting value set by the setting unit 3 on the display unit 5 using information other than numbers and characters. . The set value expression process is to turn on the number of segments corresponding to the size of the set value among the segments of the 7-segment LED indicators 11 to 14 of the display unit 5. By executing such setting value expression processing, regardless of the configuration of the setting unit 3, the user can easily grasp the outline of the setting value set by viewing the display unit 5.

  In the set value expression processing, the segments arranged on the outer periphery are targeted for lighting. In the set value expression processing, the segment DIP of the 7-segment LED display 12 located at the lower center of the display unit 5 is always lit. Depending on the size of the set value, the outer periphery from the segment D of the 7-segment LED display 11 located on the left side of the segment DIP to the segment D of the 7-segment LED display 14 located on the right side of the segment DIP The segments placed in are lit in order in a clockwise direction. That is, in the set value expression processing, the segments are continuously displayed in a ring shape (lighted) in a form similar to the behavior when the circular setting dial 3a is rotated, so that the user can intuitively set the set value. There is an effect that makes it easier to grasp. Furthermore, since the center of rotation is associated with the segment DIP of the 7-segment LED display 12 that is always lit, it becomes easier to grasp the set value. Therefore, according to the present embodiment, the rotation position corresponding to the set amount of the setting dial 3a is displayed on the display unit 5 in the same form as the display using the notch (scale) in the conventional volume. Therefore, the user can use the same usage as the configuration using the volume, and the convenience is improved.

  Further, in the set value expression processing, the set value is classified (decomposed) into stages (0%, 1% to 10%,..., 91% to 100%) according to the ratio to the maximum value, and those stages The number of segments to be lit is changed every time. In addition, in this case, the display data is divided into 10 stages except for the case of 0% (a state where all the segments are turned off). Therefore, the user can know the outline of the set value with 10 levels of resolution (in units of 10%) by checking the increase / decrease in the number of lighting of the segments. It becomes easy to do.

  A period and timing for executing the set value expression processing can be set by the user. In this way, it becomes possible to meet various user requests. For example, if you want to quickly and easily know the outline of the frequency command value etc. before starting the operation of the inverter device, set it to a predetermined period from the end of the initial display after power on until the operation starts The value expression process may be executed. In this way, after the power is turned on, the user can grasp the outline of the set value such as the frequency command value without performing any operation, and as a result, can start the operation of the inverter device quickly. Can do.

  When the user wants to know a set value such as a frequency command value according to his / her operation, the set value expression process may be executed when a specific operation key is operated. In this way, the user can easily know the outline of the set value at his / her desired timing. In this way, the following effects can also be obtained. That is, when the set value expression process is executed, a display other than alphanumeric characters is displayed on the display unit 5. If the set value expression process is executed at an arbitrary timing, there is a possibility that the user who sees the display will misunderstand that a part of the LEDs of the display unit 5 has failed. However, if the setting value expression process is executed in accordance with the operation of a specific operation key, the user understands that the display mode has changed due to the user's own operation. There is nothing.

(Second Embodiment)
Hereinafter, a second embodiment will be described with reference to FIGS. 4 and 5.
The set value expression process only needs to change the number of segments to be lit according to the size of an arbitrary set value among the set values set by the setting unit 3. For example, as a lighting method for each segment in the set value expression process, a method as shown in FIGS. 4 and 5 can be employed. Note that, in any of the lighting methods shown in FIGS. 4 and 5, when the display data is 0%, all the segments of the 7-segment LED indicators 11 to 14 are turned off. FIG. 4 is an example in which the segments arranged on the outer periphery are the objects to be lit as in the first embodiment. On the other hand, FIG. 5 is an example in which segments other than the segments arranged on the outer periphery are also targeted for lighting.

  In the lighting method shown in FIG. 4A, when the display data is 1% to 10%, the segment A of the 7-segment LED display 11 is turned on. When the display data is 11% to 20%, the segment A of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 1% to 10%. When the display data is 21% to 30%, the segment A of the 7-segment LED display 13 is lit in addition to the segment that is lit when the display data is 11% to 20%. When the display data is 31% to 40%, the segment A of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 21% to 30%. When the display data is 41% to 50%, the segment B of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 31% to 40%. When the display data is 51% to 60%, the segment C of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 41% to 50%.

  When the display data is 61% to 70%, the segment D of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 51% to 60%. When the display data is 71% to 80%, the segment D of the 7-segment LED display 13 is lit in addition to the segments that are lit when the display data is 61% to 70%. When the display data is 81% to 90%, the segment D of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 71% to 80%. When the display data is 91% to 100%, the segment D of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 81% to 90%.

  In the lighting method shown in FIG. 4B, when the display data is 1% to 10%, the segment D of the 7-segment LED display 14 is turned on. When the display data is 11% to 20%, the segment D of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 1% to 10%. When the display data is 21% to 30%, the segment D of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 11% to 20%. When the display data is 31% to 40%, the segment D of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 21% to 30%. When the display data is 41% to 50%, the segment E of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 31% to 40%. When the display data is 51% to 60%, the segment F of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 41% to 50%.

  When the display data is 61% to 70%, the segment A of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 51% to 60%. When the display data is 71% to 80%, the segment A of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 61% to 70%. When the display data is 81% to 90%, the segment A of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 71% to 80%. When the display data is 91% to 100%, the segment A of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 81% to 90%.

  In the lighting method shown in FIG. 5A, when the display data is 1% to 10%, the segment D of the 7-segment LED display 11 is lit. When the display data is 11% to 20%, the segment G of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 1% to 10%. When the display data is 21% to 30%, the segment A of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 11% to 20%. When the display data is 31% to 40%, the segment D of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 21% to 30%. When the display data is 41% to 50%, the segment G of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 31% to 40%. When the display data is 51% to 60%, the segment A of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 41% to 50%.

  When the display data is 61% to 70%, the segment D of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 51% to 60%. When the display data is 71% to 80%, the segment G of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 61% to 70%. When the display data is 81% to 90%, the segment A of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 71% to 80%. When the display data is 91% to 100%, the segment D of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 81% to 90%.

  In the lighting method shown in FIG. 5B, when the display data is 1% to 10%, the segment D of the 7-segment LED display 11 is turned on. When the display data is 11% to 20%, the segment D of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 1% to 10%. When the display data is 21% to 30%, the segment D of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 11% to 20%. When the display data is 31% to 40%, the segment D of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 21% to 30%. When the display data is 41% to 50%, the segment G of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 31% to 40%. When the display data is 51% to 60%, the segment G of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 41% to 50%.

  When the display data is 61% to 70%, the segment G of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 51% to 60%. When the display data is 71% to 80%, the segment G of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 61% to 70%. When the display data is 81% to 90%, the segment A of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 71% to 80%. When the display data is 91% to 100%, the segment A of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 81% to 90%.

  In the lighting method shown in FIG. 5C, when the display data is 1% to 10%, the segment D of the 7-segment LED display 11 is lit. When the display data is 11% to 20%, the segment D of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 1% to 10%. When the display data is 21% to 30%, the segment D of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 11% to 20%. When the display data is 31% to 40%, the segment D of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 21% to 30%. When the display data is 41% to 50%, the segments C and G of the 7-segment LED display 14 are turned on in addition to the segments that are turned on when the display data is 31% to 40%. When the display data is 51% to 60%, the segment G of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 41% to 50%.

  When the display data is 61% to 70%, the segment G of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 51% to 60%. When the display data is 71% to 80%, the segment G of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 61% to 70%. When the display data is 81% to 90%, the segments A and F of the 7-segment LED display 11 are turned on in addition to the segments that are turned on when the display data is 71% to 80%. When the display data is 91% to 100%, the segment A of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 81% to 90%.

  In the lighting method shown in FIG. 5D, when the display data is 1% to 10%, the segment E of the 7-segment LED display 11 is lit. When the display data is 11% to 20%, the segment F of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 1% to 10%. When the display data is 21% to 30%, the segments A and B of the 7-segment LED display 11 are lit in addition to the segments that are lit when the display data is 11% to 20%. When the display data is 31% to 40%, the segment C of the 7-segment LED display 11 is turned on in addition to the segments that are turned on when the display data is 21% to 30%. When the display data is 41% to 50%, the segments C and D of the 7-segment LED display 12 are turned on in addition to the segments that are turned on when the display data is 31% to 40%. When the display data is 51% to 60%, the segment B of the 7-segment LED display 12 is turned on in addition to the segments that are turned on when the display data is 41% to 50%.

  When the display data is 61% to 70%, the segments A and B of the 7-segment LED display 13 are lit in addition to the segments that are lit when the display data is 51% to 60%. When the display data is 71% to 80%, the segment C of the 7-segment LED display 13 is turned on in addition to the segments that are turned on when the display data is 61% to 70%. When the display data is 81% to 90%, the segments C and D of the 7-segment LED display 14 are turned on in addition to the segments that are turned on when the display data is 71% to 80%. When the display data is 91% to 100%, the segment B of the 7-segment LED display 14 is turned on in addition to the segments that are turned on when the display data is 81% to 90%.

  As described above, according to the present embodiment in which the lighting method of each LED in the set value expression process is changed, the user can set the setting by visually recognizing the display unit 5 as in the first embodiment. The outline of the value can be easily grasped. Therefore, according to this embodiment, the same operation and effect as those of the first embodiment can be obtained.

(Third embodiment)
Hereinafter, a third embodiment will be described with reference to FIGS. 6 and 7.
In the set value expression processing, the lighting state (brightness, blinking state, etc.) of the segment for expressing the highest value among the lighted segments (hereinafter also referred to as the highest segment) depends on the size of the set value. Thus, the magnitude of the set value can be expressed with higher resolution.

  The highest segment here is a segment that is lit last among the segments that are lit in order according to the size of the set value. In other words, the highest segment is a segment that is first turned off when the set value decreases from a predetermined value. For example, in the display method shown in FIG. 3, when the display data is 31% to 40%, the segment A of the 7-segment LED display 11 becomes the highest segment, and when it is 91% to 100%, 7 segments. The segment D of the LED display 14 becomes the highest segment.

In order to realize such a set value expression process, the control unit 2 (display control means) performs a calculation based on the following formula (3) in addition to the calculation based on the formula (1) described above, and The brightness L is obtained. In this case, the brightness L (%) is a ratio of lighting (an ON pattern described later) and extinguishing (an OFF pattern described later), and the constantly lighting state is 100%.
L = 10 × (α−10 × (n−1)) (3)
In the following description, the brightness L (%) is expressed as the ON pattern display ratio.

  Hereinafter, an example of a specific method for adding the above-described change to the set value expression processing will be described. In this case, as shown in FIG. 6, two types of lighting patterns (OFF pattern and ON pattern) having different lighting states of the highest value segment are prepared for each stage of the display data. When the display data is 0%, both the OFF pattern and the ON pattern are in a state where all segments are turned off, and there is no difference between the patterns.

  The ON pattern is the same as the lighting pattern shown in FIG. On the other hand, in the OFF pattern, the lighting state in a predetermined stage is the same lighting state as the lighting state in the previous stage in the ON pattern. That is, when the display data is 1% to 10%, the lighting state is the same as when the display data in the ON pattern is 0%. When the display data is 11% to 20%, the lighting state is the same as when the display data in the ON pattern is 1% to 10%.

  When the display data is 21% to 30%, the lighting state is the same as when the display data in the ON pattern is 11% to 20%. When the display data is 31% to 40%, the lighting state is the same as when the display data in the ON pattern is 21% to 30%. When the display data is 41% to 50%, the display data in the ON pattern is in the same lighting state as 31% to 40%. When the display data is 51% to 60%, the display data in the ON pattern is in the same lighting state as 41% to 50%.

  When the display data is 61% to 70%, the display data in the ON pattern is in the same lighting state as 51% to 60%. When the display data is 71% to 80%, the display data in the ON pattern is in the same lighting state as 61% to 70%. When the display data is 81% to 90%, the lighting state is the same as when the display data in the ON pattern is 71% to 80%. When the display data is 91% to 100%, the lighting state is the same as when the display data in the ON pattern is 81% to 90%.

  By displaying such an OFF pattern and an ON pattern alternately, the highest segment at that stage is displayed in a blinking manner. In this case, the stage is determined by the value of the upper digit (hundreds and tens) of the display data, and the blinking state (the ratio of lighting and extinguishing) is determined by the value of the lower digit (first digit) of the display data. The blinking state is determined by the OFF pattern and ON pattern display ratio (duty ratio). As shown in FIG. 7, in the blinking state, the smaller the lower digit value of the display data, the higher the turn-off rate, and the larger the lower digit value of the display data, the higher the turn-on rate.

  That is, when the lower digit of the display data is 1%, the ON pattern display ratio is 10% (OFF pattern display ratio is 90%). When the lower digit of the display data is 2%, the ON pattern display ratio is 20% (OFF pattern display ratio is 80%). When the lower digit of the display data is 3%, the ON pattern display ratio is 30% (OFF pattern display ratio is 70%). When the lower digit of the display data is 4%, the ON pattern display ratio is 40% (OFF pattern display ratio is 60%). When the lower digit of the display data is 5%, the ON pattern display ratio is 50% (OFF pattern display ratio is 50%).

  When the lower digit of the display data is 6%, the ON pattern display ratio is 60% (OFF pattern display ratio is 40%). When the lower digit of the display data is 7%, the ON pattern display ratio is 70% (OFF pattern display ratio is 30%). When the lower digit of the display data is 8%, the ON pattern display ratio is 80% (OFF pattern display ratio is 20%). When the lower digit of the display data is 9%, the ON pattern display ratio is 90% (OFF pattern display ratio is 10%).

  When the lower digit of the display data is 0% (display data ≠ 0), the ON pattern display ratio is 100% (OFF pattern display ratio is 0%). The case where the lower digit is 0% (display data ≠ 0) is, for example, the case of 40% at the stage of 31% to 40%, and the case of 100% at the stage of 91% to 100%. . In short, when the value of the lower digit is maximized at each stage, the ON pattern display ratio is 100%, that is, the ON pattern is always displayed. However, when the display data is 0% (display data = 0), all lights are turned off.

  As described above, in the setting value expression processing, if the blinking state (flashing speed) of the highest segment among the segments to be lit is changed according to the size of the setting value, the size of the setting value is changed. It can be expressed with higher resolution. As a method for changing the blinking state, the following method may be employed. That is, only one lighting pattern (for example, one shown in FIG. 3) is prepared, and a PWM signal (a signal for PWM driving each segment LED) output from the LED driving unit 6 to the display unit 5 is prepared. The blinking state may be changed by changing the cycle. Moreover, it can replace with the method of changing the blink state mentioned above, and can also employ | adopt the following methods. For example, a method of changing the lighting brightness of the highest segment may be adopted. In this case, it is preferable to change the brightness of lighting by dynamically changing the drive current to the LEDs constituting each segment by duty control of the PWM signal.

(Other embodiments)
As mentioned above, although some embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention.
About the structure of the setting part 3 for setting a frequency command value, the numerical value of a parameter, etc., it can change suitably. For example, a configuration using a sheet key (up key and down key) or a configuration using a volume composed of a variable resistor may be used.

The data memory 7 is not limited to the configuration provided outside the control unit 2 as illustrated in FIG. 1, and may be a configuration provided (included) inside the control unit 2.
When executing the set value expression processing, the control unit 2 displays a display for expressing the magnitude of the set value and a normal display indicating various information related to the inverter device (for example, output frequency, trip code, etc.). Alternatively, it may be displayed alternately at least once. For example, when the set value expression process is executed during acceleration / deceleration of the inverter device, a display for expressing the magnitude of the set value and the current output frequency may be alternately displayed. In this way, the user can grasp information such as the current output frequency of the inverter device while grasping an outline of the set value (frequency command value and the like).

The display part 5 should just be the structure provided with the 7-segment display of multiple digits. For example, a configuration including a multi-digit 7-segment LCD display may be used.
These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  In the drawings, 1 is a panel device, 2 is a control unit (display control unit), 3 is a setting unit (setting unit), 3a is a setting dial (operation unit), 4b is a RUN key (specific operation key), and 4c is STOP. Keys (specific operation keys), 5 indicates a display unit (display means), and 11-14 indicate a 7-segment LED display (7-segment display).

Claims (6)

Displaying various information related to the inverter device, the display means having a multi-digit 7-segment display,
A setting unit that has an operation unit that can be operated by a user, and sets various setting values related to the inverter device according to the operation of the operation unit;
Display control means for controlling display by the display means;
With
The display control means lights up a number of segments corresponding to the size of an arbitrary set value among the set values set by the setting means among the segments of the multi-digit 7-segment display. Is configured to be able to execute a set value expression process that expresses the size of the arbitrary set value, and when executing the set value expression process, it is arranged on the outer periphery of each segment of the multi-digit 7-segment display. panel device of an inverter device comprising an object and to Rukoto of some or all the lighting segment for segment and dot display is.   2. The panel device for an inverter device according to claim 1, wherein the display control unit executes the set value expression processing during a period in which the setting value is not set by the setting unit.   2. The panel device for an inverter device according to claim 1, wherein the display control unit executes the set value expression processing when an operation is performed on a specific operation key of the inverter device.   The display control means, at the time of executing the set value expression processing, displays at least once a display for expressing the magnitude of the arbitrary set value and a normal display representing various information about the inverter device. The panel device of the inverter device according to any one of claims 1 to 3, wherein the panel device is alternately displayed.   The display control means, when executing the set value expression processing, changes the lighting state of the segment for expressing the highest value among the lighted segments according to the size of the arbitrary set value. 5. The panel device of the inverter device according to claim 1, wherein the magnitude of the arbitrary set value is expressed with a higher resolution. 6.   6. The inverter device according to claim 1, wherein the display control unit executes the set value expression process on condition that the inverter device is stopped or accelerating / decelerating. Panel device.

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