KR101748723B1 - Digital protection relay and controlling method thereof - Google Patents

Abstract

The present disclosure relates to a digital protection relay having a plurality of operating systems (OS) and a control method thereof. To this end, the digital protection relay according to the present invention comprises: a flash memory for storing a plurality of OS image files; SDRAM; And when a first OS image file of a plurality of OS image files stored in advance in the flash memory is not normally patched to the SDRAM within a preset maximum boot time, And a controller for fetching the second OS image file of the plurality of OS image files previously stored in the flash memory into the SDRAM through an internal program counter or a watchdog.

Description

[0001] DIGITAL PROTECTION RELAY AND CONTROLLING METHOD THEREOF [0002]

The present invention relates to a digital protection relay and a control method thereof, and more particularly, to a digital protection relay having a plurality of operating systems (OS) and a control method thereof.

Generally, the digital protection relay controls to supply or cut off power to the lower end such as a motor or an electric motor, and protects the lower end when an accident current such as an overcurrent, a short-circuit current, It is a relay.

Korean Patent Publication No. 10-2009-0016123

It is an object of the present invention to provide a digital protection relay having a plurality of operating systems (OS) and a control method thereof.

It is another object of the present invention to provide a digital protection relay and a control method thereof that perform a normal function through a plurality of different OSs when an OS is in operation.

It is another object of the present invention to provide a digital protection relay and a control method thereof that perform a normal function through an OS provided in each of a plurality of memories in the event of an OS in operation.

A digital protection relay according to an embodiment of the present invention includes: a flash memory for storing a plurality of OS image files; SDRAM; And when the first OS image file of a plurality of OS image files stored in advance in the flash memory is not patched to the SDRAM within a preset maximum boot time, And a controller for fetching a second OS image file of a plurality of OS image files previously stored in the flash memory into the SDRAM through a program counter or a watchdog.

As an example related to the present specification, the control unit may operate the digital protection relay through the second OS image file patched to the SDRAM.

As one example related to the present specification, the plurality of OS image files may include a plurality of images for operating an embedded OS, each including an operating system of one of WINCE (WINCE), ANDROID, and LINUX File.

In one embodiment of the present invention, when the first OS image file stored in advance in the flash memory is patched to the SDRAM within the preset maximum boot time, the controller reads the first OS image patched to the SDRAM The digital protection relay can be operated through a file.

A digital protection relay according to an embodiment of the present invention includes: a flash memory for storing a plurality of OS image files; An SDRAM in which any one of the plurality of OS image files is patched; And an arbitrary OS image file among a plurality of OS image files stored in advance in the flash memory through an internal program counter or a watchdog included in the digital protection relay when the operating system of the digital protection relay in operation is not operating normally And a controller for repeatedly attempting to patch the SDRAM and operating the digital protection relay through the patched OS image file when a patch for the OS image file to the SDRAM is completed.

A digital protection relay according to an embodiment of the present invention includes: a flash memory for storing a first OS image file; An SD memory for storing a second OS image file; SDRAM; And a controller for fetching a second OS image file stored in the SD memory into the SDRAM when a first OS image file stored in the flash memory is not patched to the SDRAM within a preset maximum boot time, .

As one example related to the present specification, the first OS image file and the second OS image file may be a heterogeneous operating system or an OS image file of a homogeneous operating system.

In one embodiment of the present invention, when the remaining capacity of the flash memory is equal to or less than a predetermined set value, the control unit transmits setting data including operation waveform data of a plurality of relay elements included in the digital protection relay to the SD memory Lt; / RTI >

The method of controlling a digital protection relay according to an embodiment of the present invention is characterized in that when a digital protection relay is initially booted, a first OS image file of a plurality of OS image files stored in advance in a flash memory is stored in a SDRAM Determining whether the patch is patched; If it is determined that the first OS image file stored in advance in the flash memory is not patched to the SDRAM within the preset maximum boot time, Patching a second OS image file of a plurality of OS image files stored in advance in the flash memory into the SDRAM; And operating the digital protection relay through the second OS image file patched to the SDRAM.

As one example related to the present specification, the plurality of OS image files may be a plurality of image files for driving an embedded OS each including an operating system of either Win CE, Android, or Linux.

As a result, when the first OS image file stored in advance in the flash memory is patched to the SDRAM within the preset maximum boot time, the first OS image patched to the SDRAM, And operating the digital protection relay through a file.

A method of controlling a digital protection relay according to an embodiment of the present invention includes: checking whether an operating system of an operating digital protection relay is abnormal; If it is determined that the operating system of the digital protection relay does not operate normally, an arbitrary OS image file of a plurality of OS image files stored in advance in the flash memory through an internal program counter or a watchdog included in the digital protection relay Repeatedly patching the SDRAM to the SDRAM; And operating the digital protection relay through the patched OS image file when a patch for the OS image file to the SDRAM is completed.

The control method of the digital protection relay according to the embodiment of the present invention checks whether or not the first OS image file stored in advance in the flash memory is patched to the SDRAM within a preset maximum boot time when the digital protection relay is initially booted step; Fetching a second OS image file stored in advance in the SD memory into the SDRAM when the first OS image file stored in the flash memory is not patched to the SDRAM within the preset maximum boot time; And operating the digital protection relay through the second OS image file patched to the SDRAM.

Storing, in the SD memory, setting data including operation waveform data of a plurality of relay elements included in the digital protection relay when the remaining capacity of the flash memory is less than a predetermined set value ; ≪ / RTI >

The digital protection relay and the control method thereof according to the embodiment of the present invention can prevent OS breakage and perform normal operation even when the OS is in operation by providing a plurality of operating systems (OS).

In addition, the digital protection relay and the control method thereof according to the embodiment of the present invention can improve the reliability of the product and convenience in use by performing a normal function through a plurality of different OSs when the OS is in operation .

In addition, the digital protection relay and the control method thereof according to the embodiment of the present invention perform a normal function through an OS provided in each of a plurality of memories in the event of an OS that is in operation, thereby improving the reliability of the product and convenience in use .

1 is a block diagram illustrating a configuration of a digital protection relay according to an embodiment of the present invention.
2 is a flowchart illustrating a method of controlling a digital protection relay according to a first embodiment of the present invention.
3 is a flowchart illustrating a method of controlling a digital protection relay according to a second embodiment of the present invention.
4 is a block diagram illustrating a configuration of a digital protection relay according to another embodiment of the present invention.
5 is a flowchart illustrating a method of controlling a digital protection relay according to a third embodiment of the present invention.
6 is a flowchart illustrating a method of controlling a digital protection relay according to a fourth embodiment of the present invention.
7 is a flowchart illustrating a method of controlling a digital protection relay according to a fifth embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

1 is a block diagram showing a configuration of a digital protection relay 10 according to an embodiment of the present invention.

1, the digital protection relay 10 includes a control unit 100, a flash memory 200, and a RAM (RAM) 300. Not all of the components of the digital protection relay 10 shown in Fig. 1 are essential components, and the digital protection relay 10 may be implemented by more components than the components shown in Fig. 1, The digital protection relay 10 may also be implemented by components.

The control unit (or a central processing unit (CPU) 100) performs an overall control function of the digital protection relay 10.

When the digital protection relay 10 is initially booted, the controller 100 controls the first OS image file among a plurality of OS image files stored in advance in the flash memory 200 within a preset maximum boot time (Or determines) whether or not the SDRAM 310 included in the RAM 300 is normally patched. Here, the plurality of OS image files may be an image file for operating an embedded OS including an operating system such as a win CE, an ANDROID, and a LINUX.

If the first OS image file stored in advance in the flash memory 200 is not normally patched to the SDRAM 310 within the preset maximum boot time as a result of the checking, A second OS image file of a plurality of OS image files stored in advance in the flash memory 200 through an internal program counter (not shown) or a watchdog (not shown) included in the digital protection relay 10, (Or the embedded system) normally through the patched second OS image file. Here, the first OS image file and the second OS image file may be a homogeneous operating system or a heterogeneous operating system.

If the first OS image file stored in advance in the flash memory 200 is normally patched to the SDRAM 310 within the preset maximum boot time as a result of the checking, The digital protection relay 10 (or the embedded system) operates normally through the first OS image file.

In addition, the control unit 100 may control the operation of the digital protection relay 10 (or the embedded system) that is operating based on any one of the plurality of OS image files patched to the SDRAM 310 Check whether the system is abnormal.

That is, the controller 100 determines whether internal communication is maintained within a predetermined time interval between the controller 100 and the SDRAM 310, And confirms whether or not the operation of the digital protection relay 10 is abnormal.

At this time, the digital protection relay 10 (or the embedded system), which has been booted, performs an internal communication with the additional control unit (not shown) included in the digital protection relay 10 , Serial communication, or parallel communication), or accesses additional SDRAM (not shown) included in the digital protection relay 10. Therefore, it is possible to check whether the internal communication is maintained within the predetermined time in the additional control unit and the additional SDRAM, or whether it is possible to write and erase specific data in the specific memory area of the additional SDRAM, The presence or absence of an abnormality of the operating system of the relay 10 may be checked.

If the operating system of the digital protection relay 10 does not operate normally (or an error occurs in the operating system of the digital protection relay 10) as a result of the checking, A different OS image file of a plurality of OS image files stored in advance in the flash memory 200 is normally patched to the SDRAM 310 through the internal program counter included in the digital protection relay 10 or the watchdog, And operates the digital protection relay 10 (or the embedded system) normally through another patched OS image file. At this time, the operating system of the digital protection relay 10 may not operate normally due to noise, lightening phenomenon, or the like.

If the operating system of the digital protection relay 10 operates normally, the control unit 100 determines whether the digital protection relay 10 is operating normally through any one of the OS image files patched to the SDRAM 310, (Or the embedded system) and returns to the process of confirming the abnormality of the operating system of the digital protection relay 10 (or the embedded system).

The flash memory 200 stores a plurality of OS image files capable of operating an operating system. Here, the plurality of OS image files may be an image file for operating an embedded OS including an operating system such as Win CE, Android, and Linux. In addition, a file capable of running an embedded operating system can be created (or created) as one image file (or one OS image file). For example, the NK.bin file, which is an installation file of the win CE, may be a file including an OS kernel, an application, files, and device drivers.

When the power is applied to the digital protection relay 10 (or the digital protection relay 10 is initialized), the flash memory 200 is controlled by the control unit 100 (For example, a master OS image file) of a plurality of OS image files stored in advance in the RAM 300 to the SDRAM 310 included in the RAM 300.

In the case where the patch is not normally performed, the flash memory 200 may control the OS image file of another OS image file (for example, a slave OS image file) to the SDRAM 310. [

As described above, the flash memory 200 repeatedly fetches an arbitrary OS image file among the plurality of OS image files stored in the SDRAM 310 until the patch is normally completed in the SDRAM 310 .

When the digital protection relay 10 is in operation and the operating system is not operating normally, the flash memory 200 is controlled by the control unit 100 or the additional control unit, An arbitrary OS image file of the image file is repeatedly patched to the SDRAM 310. [

The Random Access Memory (RAM) 300 includes an SDRAM 310 and a Dual-Ported RAM (DPRAM) (not shown).

When the digital protection relay 10 is powered on (or the digital protection relay 10 is initially booted), the SDRAM 310 controls the operation of the digital protection relay 10 by the control of the control unit 100 , Any one of a plurality of OS image files stored in advance in the flash memory 200 is patched.

After the OS image file is patched to the SDRAM 310, the digital protection relay 10 operates normally through the OS image file.

The SDRAM 310 is connected to the flash memory 200 under the control of the control unit 100 or the additional control unit when the digital protection relay 10 is operating and the operating system is not operating normally An arbitrary OS image file among a plurality of pre-stored OS image files is repeatedly attempted to be patched to the SDRAM 310. When the patch is normally completed, the digital protection relay 10 operates normally through the patched OS image file do.

The controller 100, the flash memory 200, the RAM 300, peripheral IC elements (not shown), and the like can drive the operating system.

In this way, a plurality of operating systems (OS) can be provided.

In addition, in the case of an OS that is in operation, a normal function can be performed through a plurality of different OSs.

Hereinafter, a method of controlling the digital protection relay according to the present invention will be described in detail with reference to FIGS. 1 to 7. FIG.

2 is a flowchart illustrating a method of controlling a digital protection relay according to a first embodiment of the present invention.

First, when the digital protection relay 10 is initially booted, the controller 100 determines whether the first OS image file among the plurality of OS image files stored in advance in the flash memory 200 is stored in the RAM 300 (Or determines) whether or not the SDRAM 310 is normally patched. Here, the plurality of OS image files may be an image file for operating an embedded OS including an operating system such as Win CE, Android, and Linux (S210).

If the first OS image file stored in advance in the flash memory 200 is not normally patched to the SDRAM 310 within the preset maximum boot time as a result of the checking, A second OS image file of a plurality of OS image files stored in advance in the flash memory 200 through an internal program counter (not shown) or a watchdog (not shown) included in the digital protection relay 10, (Or the embedded system) through the patched second OS image file (step S220).

If the first OS image file stored in advance in the flash memory 200 is normally patched to the SDRAM 310 within the preset maximum boot time as a result of the checking, The digital protection relay 10 (or the embedded system) is operated normally through the first OS image file (S230).

3 is a flowchart illustrating a method of controlling a digital protection relay according to a second embodiment of the present invention.

First, the control unit 100 confirms whether the operating system of the digital protection relay 10 (or the embedded system) is in operation or not. Here, the digital protection relay 10 in operation may be operating through the first OS image file patched to the SDRAM 310 included in the RAM 300. The first OS image file may be any one of a plurality of OS image files stored in advance in the flash memory 200. Here, the plurality of OS image files may be an image file for operating an embedded OS including an operating system such as Win CE, Android, and Linux.

That is, the controller 100 determines whether internal communication is maintained within a predetermined time interval between the controller 100 and the SDRAM 310, And confirms whether or not the operating state of the digital protection relay 10 is abnormal (S310).

If the operating system of the digital protection relay 10 does not operate normally (or an error occurs in the operating system of the digital protection relay 10), the control unit 100 determines A second OS image file of a plurality of OS image files stored in advance in the flash memory 200 through an internal program counter (not shown) or a watchdog (not shown) included in the digital protection relay 10, (Or the embedded system) normally through the patched second OS image file.

The control unit 100 repeatedly attempts to patch an arbitrary OS image file among a plurality of OS image files stored in advance in the flash memory 200 to the SDRAM 310, If the patch for the file is normally completed, the digital protection relay 10 (or the embedded system) may be normally operated through the patched OS image file at step S320.

If the operating system of the digital protection relay 10 is operating normally, the controller 100 may control the digital protection relay (not shown) through the first OS image file patched to the SDRAM 310 10) (or the embedded system) and returns to the process of checking whether the operating system of the digital protection relay 10 (or the embedded system) is abnormal (S330).

4 is a block diagram showing the configuration of the digital protection relay 10 according to another embodiment of the present invention.

4, the digital protection relay 10 includes a control unit 100, a flash memory 200, a RAM (RAM) 300, and an SD memory 400. All of the components of the digital protection relay 10 shown in Fig. 4 are not essential components, and the digital protection relay 10 may be implemented by more components than the components shown in Fig. 4, The digital protection relay 10 may also be implemented by components.

The controller 100 performs an overall control function of the digital protection relay 10.

When the digital protection relay 10 is initially booted, the controller 100 controls the RAM 300 to store the first OS image file stored in advance in the flash memory 200 within a preset maximum boot time (Or determines) whether or not the SDRAM 310 is normally patched. Here, the first OS image file may be an image file for operating an embedded OS including an operating system such as WinCE, Android, and Linux.

If the first OS image file stored in advance in the flash memory 200 is not normally patched to the SDRAM 310 within the preset maximum boot time as a result of the checking, The second OS image file stored in advance in the SD memory 400 is normally patched to the SDRAM 310 through an internal program counter (not shown) or a watchdog (not shown) included in the digital protection relay 10 , And operates the digital protection relay 10 (or the embedded system) normally through the patched second OS image file. Here, the first OS image file and the second OS image file may be a homogeneous operating system or a heterogeneous operating system.

If the first OS image file stored in advance in the flash memory 200 is normally patched to the SDRAM 310 within the preset maximum boot time as a result of the checking, The digital protection relay 10 (or the embedded system) operates normally through the first OS image file.

In addition, the control unit 100 may include an OS image file (for example, the first OS image file, the second OS image file, or the like) that is patched to the SDRAM 310 (Or an OS image file) of the digital protection relay 10 (or the embedded system) in operation.

That is, the controller 100 determines whether internal communication is maintained within a predetermined time interval between the controller 100 and the SDRAM 310, And confirms whether or not the operation of the digital protection relay 10 is abnormal.

If the operating system of the digital protection relay 10 does not operate normally (or an error occurs in the operating system of the digital protection relay 10) as a result of the checking, Another OS image file among a plurality of OS image files stored in advance in the flash memory 200 or the SD memory 400 through the internal program counter included in the digital protection relay 10 or the watchdog, 310, and normally operates the digital protection relay 10 (or the embedded system) through the patched other OS image file. At this time, the operating system of the digital protection relay 10 may not operate normally due to noise, lightening phenomenon, or the like.

If the operating system of the digital protection relay 10 operates normally, the control unit 100 determines whether the digital protection relay 10 is operating normally through any one of the OS image files patched to the SDRAM 310, (Or the embedded system) and returns to the process of confirming the abnormality of the operating system of the digital protection relay 10 (or the embedded system).

In addition, the control unit 100 may store various setting data (including operation waveform data of various relay elements, for example) of the digital protection relay 10 in a state where the digital protection relay 10 is in normal operation And stores it in the flash memory 200. At this time, the control unit 100 controls the digital protection relay (not shown) according to an arbitrary user input (or user touch / user setting) or a selection (or touch) (Or update) occurs in one or more pieces of setting data among the various setting data of the digital protection relay 10, the changed one or more pieces of setting data or all setting data of the digital protection relay 10 are stored in the flash memory 200 .

If the remaining capacity of the flash memory 200 is less than a preset value, the control unit 100 checks the remaining capacity of the flash memory 200, And stores all setting data of the relay 10 in the SD memory 400. [

That is, when the remaining capacity of the flash memory 200, which is checked in real time, is equal to or less than the predetermined set value, the control unit 100 determines whether the changed one or more setting data or all setting data of the digital protection relay 10 Is stored in the SD memory (400).

The control unit 100 may simultaneously store the changed one or more setting data or all setting data of the digital protection relay 10 in the flash memory 200 and the SD memory 400. [

If the changed one or more setting data or all setting data of the digital protection relay 10 are stored in the SD memory 400 instead of the flash memory 200, (For example, information indicating that the remaining capacity of the flash memory 200 is not large), and output the generated alarm information.

The flash memory 200 stores a plurality of OS image files capable of operating an operating system. Here, the plurality of OS image files may be an image file for operating an embedded OS including an operating system such as Win CE, Android, and Linux. In addition, a file capable of running an embedded operating system can be created (or created) as one image file (or one OS image file). For example, the NK.bin file, which is an installation file of the win CE, may be a file including an OS kernel, an application, files, device drivers, and the like.

When the power is applied to the digital protection relay 10 (or the digital protection relay 10 is initialized), the flash memory 200 is controlled by the control unit 100 (For example, a master OS image file or a first OS image file) among the plurality of OS image files stored in the RAM 300 to the SDRAM 310 included in the RAM 300 .

When the digital protection relay 10 is in operation and the operating system is not operating normally, the flash memory 200 is controlled by the control unit 100 or the additional control unit, An arbitrary OS image file of the image file is repeatedly patched to the SDRAM 310. [

The flash memory 200 stores the changed one or more setting data or all setting data of the digital protection relay 10 in the flash memory 200 under the control of the control unit 100. [

The RAM 300 includes an SDRAM 310 and a DPRAM (not shown).

When the digital protection relay 10 is powered on (or the digital protection relay 10 is initially booted), the SDRAM 310 controls the operation of the digital protection relay 10 by the control of the control unit 100 , Any one OS image file among the plurality of OS image files stored in advance in the flash memory 200 or the SD memory 400 is fetched.

After the OS image file is patched to the SDRAM 310, the digital protection relay 10 operates normally through the OS image file.

The SDRAM 310 may be controlled by the control unit 100 or the additional control unit when the digital protection relay 10 is operating and the operating system is not operating normally, An arbitrary OS image file of a plurality of OS image files stored in advance in the SD memory 400 is repeatedly attempted to be patched to the SDRAM 310. When the patch is normally completed, The relay 10 operates normally.

The SD memory (or SD flash memory) 400 stores a plurality of OS image files capable of operating an operating system. Here, the plurality of OS image files may be an image file for operating an embedded OS including an operating system such as Win CE, Android, and Linux. In addition, a file capable of running an embedded operating system can be created (or created) as one image file (or one OS image file). For example, the NK.bin file, which is an installation file of the win CE, may be a file including an OS kernel, an application, files, device drivers, and the like.

In the case where the patch through the OS image file stored in the flash memory 200 is not normally performed, the SD memory 400 controls the plurality of pre-stored (For example, the slave OS image file or the second OS image file) of the OS image files to the SDRAM 310. [

When the digital protection relay 10 is in operation and the operating system is not operating normally, the SD memory 400 may control the plurality of pre-stored OSs (not shown) under the control of the control unit 100 or the additional control unit. An arbitrary OS image file of the image file is repeatedly patched to the SDRAM 310. [

The flash memory 200 or the SD memory 400 may be controlled by the control unit 100 or the additional control unit until the patches are normally completed in the SDRAM 310, The arbitrary OS image file of the OS image file is repeatedly patched to the SDRAM 310. [

The SD memory 400 stores the changed one or more setting data or all the setting data of the digital protection relay 10 in the flash memory 200 under the control of the control unit 100. [

5 is a flowchart illustrating a method of controlling a digital protection relay according to a third embodiment of the present invention.

First, when the digital protection relay 10 is initially booted, the controller 100 determines whether the first OS image file among the plurality of OS image files stored in advance in the flash memory 200 is stored in the RAM 300 (Or determines) whether or not the SDRAM 310 is normally patched. Here, the first OS image file may be an image file for operating an embedded OS including an operating system such as Win CE, Android, and Linux (S510).

If the first OS image file stored in advance in the flash memory 200 is not normally patched to the SDRAM 310 within the preset maximum boot time as a result of the checking, A second OS image file of a plurality of OS image files stored in advance in the SD memory 400 through an internal program counter (not shown) or a watchdog (not shown) included in the digital protection relay 10 to the SDRAM 310 , And normally operates the digital protection relay 10 (or the embedded system) through the patched second OS image file. Here, the first OS image file and the second OS image file may be an OS image file of a homogeneous operating system or a homogeneous operating system (S520).

If the first OS image file stored in advance in the flash memory 200 is normally patched to the SDRAM 310 within the preset maximum boot time as a result of the checking, The digital protection relay 10 (or the embedded system) is operated normally through the first OS image file (S530).

6 is a flowchart illustrating a method of controlling a digital protection relay according to a fourth embodiment of the present invention.

First, the control unit 100 confirms whether the operating system of the digital protection relay 10 (or the embedded system) is in operation or not. Here, the digital protection relay 10 in operation may be operating through the first OS image file patched to the SDRAM 310 included in the RAM 300. The first OS image file may be any one of a plurality of OS image files stored in advance in the flash memory 200. Here, the plurality of OS image files may be an image file for operating an embedded OS including an operating system such as Win CE, Android, and Linux.

That is, the controller 100 determines whether internal communication is maintained within a predetermined time interval between the controller 100 and the SDRAM 310, And confirms whether or not the operation of the digital protection relay 10 is abnormal (S610).

If the operating system of the digital protection relay 10 does not operate normally (or an error occurs in the operating system of the digital protection relay 10), the control unit 100 determines A second OS image file of a plurality of OS image files stored in advance in the SD memory 400 through an internal program counter (not shown) or a watchdog (not shown) included in the digital protection relay 10 to the SDRAM 310 , And normally operates the digital protection relay 10 (or the embedded system) through the patched second OS image file (S620).

If the operating system of the digital protection relay 10 is operating normally, the controller 100 may control the digital protection relay (not shown) through the first OS image file patched to the SDRAM 310 10) (or the embedded system) and returns to the process of confirming whether the operating state of the digital protection relay 10 (or the embedded system) is abnormal (S630).

7 is a flowchart illustrating a method of controlling a digital protection relay according to a fifth embodiment of the present invention.

First, the control unit 100 determines whether the remaining capacity of the flash memory 200 is equal to or less than a predetermined set value (S710).

If the remaining capacity of the flash memory 200 is equal to or smaller than the set value, the control unit 100 determines whether the digital data of the digital protection relay 10 Data, etc.) in the SD memory 400 (S720).

If the remaining capacity of the flash memory 200 is greater than the set value as a result of the determination, the control unit 100 determines whether or not various setting data (or a plurality of relay elements) of the digital protection relay 10 And the like) in the flash memory 200 (S730).

The digital protection relay 10 stores setting data including waveform data of various relay elements included in the digital protection relay 10 according to the remaining capacity of the flash memory 200 in the flash memory 200 ) And / or in the SD memory 400.

As described above, the embodiment of the present invention includes a plurality of operating systems (OS), so that it is possible to prevent the OS from being broken and to perform a normal operation even when the OS is in operation.

In addition, as described above, the embodiments of the present invention can perform normal functions through a plurality of different OSs when the OS is in operation and improve the reliability and usability of the product.

In addition, as described above, the embodiment of the present invention can perform the normal function through the OS provided in each of the plurality of memories in the case of the OS which is in operation, thereby improving the reliability of the product and convenience in use.

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: digital protection relay 100:
200: flash memory 300: RAM (RAM)
310: SDRAM 400: SD memory

Claims (13)

delete delete delete delete delete A flash memory for storing a first OS image file;
An SD memory for storing a second OS image file;
SDRAM; And
And a controller for storing, in the SD memory, setting data including operation waveform data of a plurality of relay elements included in the digital protection relay when the remaining capacity of the flash memory is equal to or less than a predetermined set value. Protective relay. The method according to claim 6,
The first OS image file and the second OS image file are stored in the first OS image file,
And is an OS image file of a heterogeneous operating system or a homogeneous operating system. delete 7. The apparatus of claim 6,
And the second OS image file is patched to the SDRAM when the digital protection relay is initially booted and the first OS image file is not patched to the SDRAM within a preset maximum boot time. 10. The apparatus according to claim 9,
And operates the digital protection relay via the first OS image file when the first OS image file is patched to the SDRAM within the preset maximum boot time. 7. The apparatus of claim 6,
Wherein the second protection unit relays the second OS image file to the SDRAM when the operating system of the digital protection relay is not operating normally while the digital protection relay is operating through the first OS image file. 12. The apparatus according to claim 9 or 11,
And operates the digital protection relay through the second OS image file. 7. The apparatus of claim 6,
And stores the setting data in the flash memory when the remaining capacity of the flash memory is larger than the set value.

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