JP6317182B2 - Inverter device - Google Patents

Description

  Embodiments described herein relate generally to an inverter device and a method for releasing a locked state of the inverter device.

  In general, an inverter device is sold, for example, from an inverter device manufacturer to a set manufacturer, and sold to an end user in a state where the inverter device is incorporated in a part of the system. Such an inverter device usually has a large number of parameters for performing various settings. This parameter includes a parameter that can be changed by a person other than the inverter device manufacturer and a parameter that cannot be changed. The changeable parameters include, for example, for changing various settings of devices such as an interface and an electric motor connected to the inverter device. This changeable parameter is normally set to a value suitable for the device connected to the inverter device by the set manufacturer.

  These parameters that can be changed include those related to the safety and operation of the system incorporating the inverter device. If this parameter is changed arbitrarily by the end user, there is a risk of causing equipment failure or system failure. There is. For this reason, some inverter devices are equipped with a password protection function so that the end user cannot freely change the parameters. In this case, when the password is set, the inverter device is in a so-called locked state in which change of the changeable parameter is prohibited. For example, only a specific user such as a set maker manages the password to protect against inadvertent changes in parameters and to safely manage the entire system including the inverter device.

  However, if the person who set the password loses the password or sets it incorrectly, the correct password cannot be known. Then, the person is unable to release the locked state of the inverter device and falls into a state where the parameter cannot be changed.

JP-A-5-146194

  Therefore, an inverter device having a release method that can release the locked state even when the password set by the user is lost, etc., is highly confidential and can be easily locked. Provided are an inverter device that can be released and a method for releasing the locked state of the inverter device.

The inverter device according to the present embodiment includes unique information unique to the inverter device provided in a form visible to the user, unique information storage means that stores the unique information in advance, and input means that receives input from the user And password setting means for setting the value input to the input means as a password, password storage means for storing the password set by the password setting means, and change by the user when the password is set The lock means for prohibiting the change of the changeable parameter, the input value input to the input means and the password stored in the password storage means are collated, and the lock state is set when both match. At least using unlocking means to unlock, and a code creation algorithm that is private to the user A contact code calculated from the code calculation information including the unique information and the password and communicated to a predetermined person, and using the password restoration algorithm that is private to the user of the predetermined person together with the specific information Contact code calculating means for calculating a contact code used for calculating the password, and contact means used for contacting the contact code to the predetermined person.

The figure which shows an example of schematic structure of the inverter apparatus by 1st Embodiment The block diagram which shows an example of schematic structure of the inverter apparatus by 1st Embodiment The figure which shows an example of a part of parameter with which the inverter apparatus by 1st Embodiment is provided. The figure which shows the cancellation | release method of the lock state by methods other than the input of the password by 1st Embodiment FIG. 2 equivalent diagram according to the second embodiment FIG. 4 equivalent diagram according to the second embodiment FIG. 4 equivalent diagram according to the third embodiment FIG. 2 equivalent diagram according to the fourth embodiment FIG. 4 equivalent diagram according to the fourth embodiment FIG. 2 equivalent diagram according to the fifth embodiment FIG. 4 equivalent diagram according to the fifth embodiment

  Hereinafter, an inverter device according to a plurality of embodiments and a method for releasing a locked state of the inverter device will be described with reference to the drawings. In addition, in each embodiment, the same code | symbol is attached | subjected to the substantially same component, and description is abbreviate | omitted.

(First embodiment)
As shown in FIG. 1, the inverter device 10 includes an inverter main circuit 11, a plurality of input terminals 12, a plurality of output terminals 13, an operation panel 20, and a control circuit 30. Although not shown in detail, the inverter main circuit 11 includes, for example, a converter unit configured by connecting a diode in a three-phase bridge, and an inverter unit configured by connecting a switching element in a three-phase bridge. Yes. For example, a three-phase AC power supply 101 is connected to the input side of the inverter main circuit 11, and a motor 102 serving as a load is connected to the output side. The inverter main circuit 11 performs drive control of the motor 102 under the control of the control circuit 30.

  Various external devices are connected to the input terminal 12 and the output terminal 13. The control circuit 30 receives a signal from the external device connected to the input terminal 12 and outputs the signal to the external device connected to the output terminal 13.

  The operation panel 20 includes an input unit 21 and a display unit 22 and is connected to the control circuit 30. The input unit 21 is an example of an input unit and includes, for example, a plurality of key switches. The input unit 21 receives an operation input from the user and transmits the operation content to the control circuit 30. The display unit 22 is an example of a contact unit and a display unit, and includes a liquid crystal panel capable of displaying, for example, 7 segments. The display unit 22 displays various information such as setting contents such as parameter values and operation states under the control of the control circuit 30.

  The control circuit 30 controls the entire inverter device 10 including the inverter main circuit 11 and the operation panel 20. As shown in FIG. 2, the control circuit 30 includes a control unit 40, a unique information storage unit 31, a password storage unit 32, a parameter storage unit 33, and the like. The control unit 40 is configured by a computer having a CPU, RAM, ROM, A / D converter, etc. (not shown).

  The unique information storage unit 31 is an example of a unique information storage unit. The unique information storage unit 31 is configured by a non-volatile storage medium such as a ROM or a flash memory. The unique information storage unit 31 stores unique information unique to each inverter device assigned to each inverter device, such as a manufacturing number and an IP address. This unique information is written in the unique information storage unit 31 before the factory shipment by the inverter device manufacturer. In the case of the present embodiment, for example, a nameplate 14 describing this unique information is attached to a place such as the outer surface of the main body of the inverter device 10 that is visible to the user.

  The password storage unit 32 is an example of a password storage unit. The password storage unit 32 is configured by a rewritable nonvolatile storage medium such as a flash memory. The password storage unit 32 stores a password set by the user via the input unit 21.

  The parameter storage unit 33 is an example of a parameter storage unit. The parameter storage unit 33 is configured by a rewritable nonvolatile recording medium such as a flash memory. The parameter storage unit 33 stores parameters that cannot be changed by a preset user and parameters that can be changed by the user. In this case, the password storage unit 32 and the parameter storage unit 33 may have a common configuration. In the following description, parameters that can be changed by the user are referred to as changeable parameters.

  The control unit 40 executes a program in the CPU, thereby allowing an input processing unit 41, a display processing unit 42, a password setting processing unit 43, a parameter change processing unit 44, a lock processing unit 45, an unlock processing unit 46, a communication code. The calculation processing unit 47 and the like are virtually realized by software. Note that these processing units 41 to 47 may be realized in hardware as, for example, an integrated circuit integrated with or separate from the control unit 40.

  The input processing unit 41 executes processing for transmitting the operation content input to the input unit 21 to the control unit 40. The display processing unit 42 performs processing for displaying information on the display unit 22 based on a signal from the control unit 40.

  The password setting processing unit 43 is an example of a password setting unit. The password setting processing unit 43 sets a value input to the input unit 21 by the user as a password, and executes processing for writing the set password in the password storage unit 32.

  The parameter change processing unit 44 is an example of a parameter changing unit. The parameter change processing unit 44 determines the value of the changeable parameter based on the value input to the input unit 21 by the user, and executes a process of writing the value to the parameter storage unit 33.

  The lock processing unit 45 is an example of a lock unit. When the password is set by the password setting processing unit 43, the lock processing unit 45 executes a process of prohibiting the change of the changeable parameter and maintaining the prohibited state. Such a state, that is, a state in which the change prohibition of the changeable parameter is maintained by setting the password is referred to as a locked state. A state in which the changeable parameter can be changed is referred to as a lock release state.

  The lock release processing unit 46 is an example of a lock release unit. The lock release processing unit 46 executes a process for releasing the lock state when a predetermined condition is satisfied in the lock state. In this case, when the password is input from the user via the input unit 21, the lock release processing unit 46 collates the input password with the password stored in the password storage unit 32, and the two match. In addition, it is determined that a predetermined condition has been established, and processing for releasing the lock state is executed.

  Specifically, the password is set and the lock state is released as follows. The inverter device 10 of the present embodiment is configured such that a password can be set to a value from “0001” to “9998”, for example, an arbitrary four-digit number. The inverter device 10 includes parameters F701 to F703 as shown in FIG. 3, for example. In the present embodiment, the parameters F701 to F703 each hold a 4-digit numeric value. Note that the values held by the parameters F701 to F703 are not limited to four-digit numbers. For example, the number of digits can be increased or decreased, and values based on characters such as alphabets may be used.

  The parameter F701 is a parameter for controlling prohibition of changing the changeable parameter. The parameter F701 holds a value of “0000” or “0001”. The parameter F701 is set to a value of “0000” in the initial state. The parameter change processing unit 44 can change changeable parameters including the parameters F701 to F703 when the value of the parameter F701 is “0000”. On the other hand, when the value of the parameter F701 is “0001”, the parameter change processing unit 44 cannot change the values of changeable parameters other than the parameters F701 to F703.

  The user operates the input unit 21 to input a desired changeable parameter value, and then sets the value of the parameter F701 to “0001”, thereby restricting the change of changeable parameters other than the parameters F701 to F703. Can be banned. Thereby, an erroneous setting of the changeable parameter by the user can be prevented. In this case, since the parameter F701 can be freely changed by the user, the changeable parameter is not substantially protected from the change.

  Inverter device 10 can set a password in order to protect changeable parameters other than parameters F702 and F703 from changes by unauthorized persons. A parameter F702 indicates a password setting state, and the password value to be set is input when the password is set. The parameter F702 holds a value in the range of “0000” to “9998”. The parameter F702 is set to a value of “0000” in the initial state. The parameter F702 having a value “0000” indicates that no password is set.

  For example, when the value of the parameter F701 is “0001”, the inverter device 10 can set a password. When setting the password, the user inputs a desired password value to be set, in this case, a value of “0001” to “9998” in the parameter F702. Thereafter, when the password setting is confirmed by a predetermined operation, for example, the operation of the “ENT” key, the password setting processing unit 43 of the control unit 40 writes the password held by the parameter F702 in the password storage unit 32. Then, the lock processing unit 45 of the control unit 40 prohibits the change of the values of the parameters F701 and F702.

  As a result, the user cannot freely change the value of the parameter F701 from “0001” to “0000”, so that the changeable parameter cannot be changed. As a result, changeable parameters are substantially protected from the change. In this case, the display processing unit 42 displays “0000” on the display unit 22 if no password is set. On the other hand, if a password is set, the display processing unit 42 replaces the set password values “0000” to “99998” with “9999” and causes the display unit 22 to display them.

  The parameter F703 can be changed even in the locked state. When the inverter device 10 is in the locked state, the user inputs the password value set for the parameter F703 in order to release the locked state. That is, a value in the range of “0001” to “9998” can be input to the parameter F703. The unlock processing unit 46 collates the password stored in the password storage unit 32 with the parameter F703, and if the two match, the value of the parameter F701 can be changed from “0001” to “0000”. To do. Thereby, the changeable parameter can be changed, and the locked state is released. When the lock state is successfully released in this way, “0000” is displayed on the display unit 22. On the other hand, if the password stored in the password storage unit 32 and the parameter F703 do not match, the lock processing unit 45 maintains prohibition of changing the value of the parameter F701. Thereby, the locked state is maintained. When the unlocking of the locked state fails in this way, “9999” is displayed on the display unit 22.

  The inverter device 10 according to the present embodiment can release the lock state by a special method other than the normal password input, in case the user loses the password. A method for releasing the lock state in that case will be described with reference to FIG. Of the step numbers in FIG. 4, those with “A” indicate processing by the inverter device 10, and those with “B” indicate processing by a user such as a set maker, and “C”. Those marked with indicate the processing by the inverter device manufacturer.

  The inverter device 10 includes a contact code creation algorithm for calculating a contact code from the code calculation information. In the case of this embodiment, the code calculation information includes at least a password set by the user and unique information such as a manufacturing number of the inverter device 10.

  When the password is set by the above-described procedure, the contact code calculation processing unit 47 sends the code calculation information, that is, the unique information and the set password to the unique information storage unit 31 and the password storage unit as shown in step A11. 32. Then, as shown in step A12, the contact code calculation processing unit 47 uses the contact code creation algorithm to create a contact code made up of, for example, four digits from the read code calculation information. . In this case, for example, the contact code calculation processing unit 47 reads the unique information and the password from the unique information storage unit 31 and the password storage unit 32, respectively, and calculates a contact code. The contact code generation algorithm is a calculation formula that is not disclosed to the user and has, for example, a password and unique information as variables.

  Thereafter, the display processing unit 42 displays the created contact code on the display unit 22 as shown in step A13. In this case, the display processing unit 42 may be configured to display a contact code on the display unit 22 when the user performs a predetermined operation on the input unit 21. Moreover, the structure which always displays the code for a contact on the display part 22 in the locked state may be sufficient.

  When the user loses the set password, as shown in Steps B11 and B12, the user receives the specific information such as the serial number described on the nameplate 14 and the communication code displayed on the display unit 22 as a predetermined code. Contact the manufacturer of the inverter device. That is, the display unit 22 is used for the user to contact the inverter device manufacturer with the communication code. The inverter device 10 may automatically contact or transmit one or both of the unique information and the communication code to the inverter device manufacturer through a network line. In this case, the communication means for communicatively connecting the inverter device 10 and the inverter device manufacturer is a communication means used for contacting the communication code to the inverter device manufacturer.

  The inverter device manufacturer has a password restoration algorithm. The password restoration algorithm is a calculation formula that is not disclosed to the user and has, for example, a contact code and unique information as variables. In this case, the password restoration algorithm can be an inverse calculation formula of the above formula having a password and unique information as an example of a contact code creation algorithm as variables.

  As shown in step C11, the inverter device manufacturer calculates a password set by the user from the contact code and unique information received from the user by using a password restoration algorithm. As a result, the password set by the user is restored by the inverter device manufacturer. Thereafter, the inverter device manufacturer informs the user of the restored password as shown in step C12. Then, as shown in step B13, the user inputs the password notified by operating the input unit 21, thereby releasing the lock state as shown in steps A14 and A15.

  As described above, the inverter device 10 according to the present embodiment creates a contact code from the password set by the user and the unique information unique to each inverter device, using a contact code creation algorithm that is not disclosed to the user. The contact code calculation processing unit 47 is provided. Then, the inverter device manufacturer can restore the password set by the user from the contact code and the unique information by using a password restoration algorithm that is not disclosed to the user, and can notify the user of the restored password. . In this case, the contact code used by the user to contact the inverter device manufacturer has a different value for each password set by the user and for each inverter device. That is, a different communication code can be set for each set password and each inverter device.

  According to this, the inverter manufacturing apparatus manufacturer can directly restore the password set by the user from the communication code and the unique information received from the user. And the user can cancel | release the locked state of the inverter apparatus 10 by inputting into the inverter apparatus 10 the password restored by the inverter manufacturing apparatus maker as it is. Therefore, for example, even when the user loses the password, the inverter device manufacturer dispatches personnel to release the locked state of the inverter device 10, or the user returns the inverter device 10 to the inverter device manufacturer. It is not necessary for the inverter manufacturing equipment manufacturer to release the lock state. As a result, the user can easily release the locked state at the site where the inverter device 10 is installed, and the costs associated with dispatching employees and transporting the inverter device 10 can be reduced.

  Further, according to this, even when the password is lost, the user can directly know the password from the inverter manufacturing apparatus manufacturer. Therefore, the inverter device 10 applies a special release method for releasing the lock state by a method other than the password input, for example, “RUN”, “MODE”, “STOP”, and “ENT” keys, a predetermined number of times. There is no need to provide a special release method such as operating in a predetermined order. Therefore, even when the password is lost, the user can input the easy operation, that is, the password and release the locked state without performing such a complicated operation.

  Here, since the release method based on the special operation procedure described above is common to each inverter device, once the special release method is known to the user, it may be applied to other inverter devices. There is. For this reason, the release method using such a conventional special operation procedure has a problem of safety management due to low confidentiality. On the other hand, the inverter device 10 of the present embodiment can set the communication code to a different value for each individual inverter device. Therefore, for example, even if a communication code for a certain inverter device is communicated to the inverter device manufacturer as a communication code for another inverter device, the password of the other inverter device is not restored. Therefore, according to this, it is possible to prevent a decrease in the confidentiality of the password due to the outflow of the contact code, and it is possible to safely manage the cancellation method.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIGS.
In the first embodiment, the inverter manufacturing apparatus manufacturer restores the password set by the user from the communication code and the unique information. On the other hand, the second embodiment differs from the first embodiment in that the inverter manufacturing apparatus manufacturer calculates a verification code instead of the password without restoring the password set by the user.

  That is, the inverter device 10 further includes a verification code calculation processing unit 48 and a verification processing unit 49, as shown in FIG. The control unit 40 virtually executes the verification code calculation processing unit 48 and the verification processing unit 49 by software in the same manner as the other processing units 41 to 47 by executing a program in the CPU. Note that these processing units 48 and 49 may also be realized in hardware as an integrated circuit that is integral with or separate from the control unit 40, for example.

  The verification code calculation processing unit 48 is an example of a verification code calculation unit. The verification code calculation processing unit 48 uses the verification code generation algorithm to generate a verification code from information based on the password and unique information set by the user. In this case, the information based on the password and the unique information may be the password or the unique information itself, or may be a contact code calculated based on the password and the unique information. The verification code creation algorithm is private to the user, for example, a calculation formula having a password and unique information as a variable, or a calculation formula having a contact code and at least one of a password and specific information as a variable. It is. Similar to the communication code, the verification code is composed of, for example, a 4-digit number.

  The verification processing unit 49 is an example of a verification unit. The collation processing unit 49 collates the value input by the input unit 21 in the locked state, that is, the value set in the parameter F703 with the collation code, and when the result satisfies a predetermined condition, the collation processing unit 49 Execute the operation. In the case of the present embodiment, the collation processing unit 49 executes processing for releasing the lock state when the value set in the parameter F703 matches the collation code.

  After calculating the communication code, the verification code calculation processing unit 48 calculates the verification code using the verification code creation algorithm as shown in Step A21 of FIG. Further, the inverter device manufacturer has a collation code creation algorithm similar to that of the inverter device 10. When receiving the contact code and the unique information from the user, the inverter device manufacturer calculates the verification code from the unique information and the contact code using the verification code creation algorithm as shown in step C21. Thereafter, the inverter device manufacturer informs the user of the verification code as shown in step C22.

  When receiving the verification code from the inverter device manufacturer, the user inputs the verification code in parameter F703 as shown in step B21. Then, the collation processing unit 49 collates the collation code set in the parameter F703 with the collation code calculated in step A21 as shown in step A22, and if they match, the parameter F701 is changed. The lock state shown in step A23 is released. On the other hand, the collation processing unit 49 collates the collation code set in the parameter F703 with the collation code calculated in step A21, and if the two do not match, the lock state is not released.

  According to this, the same effect as the first embodiment can be obtained. Further, since the locked state of the inverter device 10 is released, the user can reset the password.

  Moreover, according to the said structure, even if it is a case where a user lose | disappears a password, a locked state can be cancelled | released, without using the password which the user set. That is, for example, even when a common password is set for a plurality of inverter devices, the common password is not taught, so that only the target inverter device can be unlocked. This further improves the confidentiality of the password.

(Third embodiment)
Next, a third embodiment will be described with reference to FIG.
In the third embodiment, the collation processing unit 49 collates the collation code set in the parameter F703 with the collation code calculated in step A21 in step A22, and if they match, as shown in step A31 In addition, a process for returning the changeable parameters including the parameters F701 to F703 to the factory shipment state as a predetermined operation, that is, initialization is executed. In this case, the parameters F701 to F703 all have an initial value “0000”. As a result, the password is not set and the parameter can be changed. Therefore, the password set by the user is invalidated, and the user can reset the password. In this case, the lock state is substantially released by the initialization of the changeable parameter.

On the other hand, the collation processing unit 49 collates the collation code set in the parameter F703 with the collation code calculated in step A21. If the two do not match, the changeable parameter is not initialized.
According to this, the same effect as each said embodiment is acquired.

(Fourth embodiment)
Next, a fourth embodiment will be described with reference to FIGS.
As shown in FIG. 8, the inverter device 10 of the present embodiment further includes a number storage unit 34 and a restriction processing unit 50. The number storage unit 34 is an example of a number storage unit. The number storage unit 34 is configured by a rewritable nonvolatile storage medium such as a flash memory. When the lock processing unit 49 cancels the locked state by inputting the verification code in step A23 in FIG. 9, the verification processing unit 49 sets a numerical value corresponding to the number of times the lock state is canceled by inputting the verification code in step A42. Write to the number storage unit 34. In the following description, the number of times the lock state has been released by the input of the verification code so far, that is, the number of times the lock state has been released by a method other than the password input executed so far is referred to as the number N of release times. In this case, the matching processing unit 49 may write the value of the number of cancellations N itself in the number storage unit 34. Further, the matching processing unit 49 may write the value of L−N, which is a value obtained by subtracting the number N of cancellations from a predetermined number L set in advance as an upper limit, to the number storage unit 34.

  The restriction processing unit 50 is an example of a restriction unit. The control unit 40 virtually implements the restriction processing unit 50 by software by executing a program in the CPU. Note that the restriction processing unit 50 may also be realized in hardware as an integrated circuit that is integral with or separate from the control unit 40, for example, in the same manner as the processing units 41 to 49 described above. The restriction processing unit 50 determines whether the number N of cancellations exceeds a predetermined number L. That is, the restriction processing unit 50 receives the number N of unlocked states by a method other than the password input executed so far stored in the number storage unit 34 in step A41 in FIG. The number N of unlocked states is compared with a predetermined number L set in advance.

  Then, when the number N of cancellations is less than the predetermined number L set in advance, the restriction processing unit 50 proceeds to Step A23 and executes the release of the locked state. On the other hand, when the number N of cancellations is equal to or greater than the predetermined number L set in advance, the restriction processing unit 50 restricts the lock state from being released without proceeding to step A23. In this case, if the number storage unit 34 stores the value of the number of times of cancellation N itself, the restriction processing unit 50 executes the release of the locked state without shifting to step A23 when N = L. Regulate not to. Further, if the number storage unit 34 is configured to store the value of L−N, the restriction processing unit 50 executes the release of the locked state without shifting to Step A23 when L−N = 0. Regulate not to.

  According to this, when the user releases the locked state by a method other than the input of the password, the number N of cancellations can be limited to the predetermined number L. That is, when the locked state is released many times by a method other than the password input, it is presumed that the person trying to release the locked state is an unauthorized use such as a person who has not set a password. Therefore, by restricting the number of times that the lock state can be released by a method other than the password input to a certain number L, unauthorized use of a special release method is prevented as much as possible, and thereby the security of the inverter device 10 is secured. Can be increased.

(Fifth embodiment)
Next, a fifth embodiment will be described with reference to FIGS. 10 and 11.
In the fifth embodiment, the code calculation information for calculating the contact code is preset and registered by the inverter device manufacturer in addition to the user-set password and the unique information such as the serial number of the inverter device 10. Customer information such as customer number.

  As illustrated in FIG. 10, the inverter device 10 of the fifth embodiment further includes a customer information storage unit 35 in addition to the configuration of the second embodiment. The customer information storage unit 35 is an example of a customer information storage unit. The customer information storage unit 35 is configured by a non-volatile storage medium such as a ROM or a flash memory. The customer information storage unit 35 stores customer information unique to the user. The customer information is assigned a different value for each user by the inverter device manufacturer, and is written in the customer information storage unit 35 before shipment from the factory. A customer number, which is an example of customer information, is composed of, for example, a four-digit number and is notified to the user in advance.

  In this embodiment, as shown in step A12 of FIG. 11, the contact code calculation processing unit 47 makes contact based on customer information such as a customer number in addition to unique information such as a password and manufacturing number set by the user. Calculate the code. Then, as shown in step A21, the verification code calculation processing unit 48 calculates a verification code based on the unique information, the customer number, and the contact code.

  Further, as shown in step B51, the user notifies the inverter manufacturer of customer information such as a customer number in addition to the unique information and the contact code. Then, the inverter device manufacturer calculates a verification code based on the unique information, customer information, and contact code received from the user. The subsequent procedure is the same as that of the second embodiment shown in FIG.

  According to this, a person who intends to release the lock state by a method other than the password input can obtain the verification code if he / she knows the unique information of the inverter device 10 but does not know the customer information. Can not. That is, the manufacturer of the inverter device determines whether the person who intends to release the locked state by a method other than the password input knows the customer information recorded in the inverter device 10, and determines whether or not the inverter device 10 It is possible to determine whether or not the user has the authority to release the lock state. Accordingly, it is possible to prevent the verification code from being obtained by unauthorized means as much as possible, thereby further improving the security safety of the inverter device 10.

  According to the inverter device of the above embodiment, the inverter device creates a contact code from at least a password set by the user and unique information unique to the inverter device. Then, the inverter device manufacturer restores the password or creates a verification code from at least the unique information and the communication code notified by the user, and notifies the user of the restored password or verification code. Then, the inverter device 10 verifies the password or verification code input from the user, and if the password or verification code is appropriate, the lock state is released.

  According to this, even when the set password is lost, the user can easily release the locked state by a password entry or a release method similar to password entry. Furthermore, since the cancellation method differs for each inverter device, the confidentiality of the cancellation method can be maintained at a high level.

In each of the above embodiments, the unique information does not need to use all information such as a manufacturing number and an IP address. That is, for example, a specific number value of a manufacturing number or an IP address can be used as unique information.
The unique information does not necessarily have to be described on the nameplate 14. For example, the content stored in the unique information storage unit 31 may be displayed on the display unit 22 in accordance with a user operation.
Moreover, each said embodiment can be implemented in combination, respectively.

  Further, when the lock state is released by inputting the verification code, the verification code input parameter is not limited to the password input parameter F703 shared as described in the above embodiments. For example, the parameter F703 may be dedicated to password input, and a parameter F704 for inputting a verification code may be newly provided separately from the parameter F703. In this case, the inverter device 10 may switch the input of the parameters F703 and F704 by performing a predetermined operation on the input unit 21. According to this, the lock state is not released by inputting either the password or the verification code in one parameter. That is, even if a verification code is input to the password input parameter F703, the locked state is not released. Similarly, even if a password is input to the verification code input parameter F704, the locked state is not released. Therefore, security safety can be further enhanced.

  As mentioned above, although several embodiment of this invention was described, these embodiment was 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. 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, 10 is an inverter device, 21 is an input unit (input unit), 22 is a display unit (contact unit), 31 is a unique information storage unit (unique information storage unit), 32 is a password storage unit (password storage unit), 34 is a number storage unit (number storage unit), 35 is a customer information storage unit (customer information storage unit), 43 is a password setting processing unit (password setting unit), 45 is a lock processing unit (locking unit), and 46 is unlocked. Processing unit (lock release unit), 47 is a communication code calculation processing unit (contact code calculation unit), 48 is a verification code calculation processing unit (verification code calculation unit), 49 is a verification processing unit (verification unit), Reference numeral 50 denotes a regulation processing unit (regulation means).

Claims (5)

Specific information unique to the inverter device provided in a form visible to the user,
Unique information storage means for storing the unique information in advance;
Input means for receiving input from the user;
Password setting means for setting a value input to the input means as a password;
Password storage means for storing the password set by the password setting means;
Lock means for locking the changeable parameter that can be changed by the user when the password is set;
Unlocking means for releasing the locked state when the input value input to the input means and the password stored in the password storage means are matched and both match,
A contact code calculated from the code calculation information including at least the unique information and the password using a secret code creation algorithm that is not disclosed to the user, and communicated to a predetermined person, together with the specific information and the predetermined code A contact code calculating means for calculating a contact code used to calculate the password using a password restoration algorithm that is private to the user of the person,
Contact means used to contact the predetermined code with the predetermined code;
An inverter device comprising: Specific information unique to the inverter device provided in a form visible to the user,
Unique information storage means for storing the unique information in advance;
Input means for receiving input from the user;
Password setting means for setting a value input to the input means as a password;
Password storage means for storing the password set by the password setting means;
Lock means for locking the changeable parameter that can be changed by the user when the password is set;
Unlocking means for collating the input value input to the input means with the password stored in the password storage means and releasing the locked state when the result satisfies a predetermined condition;
A contact code calculated from the code calculation information including at least the unique information and the password using a secret code creation algorithm that is not disclosed to the user, and communicated to a predetermined person, together with the specific information and the predetermined code A contact code calculation means for calculating a contact code used to calculate a verification code using a verification code creation algorithm that is not disclosed to a user of the person,
Contact means used for contacting the contact code to the predetermined person;
Verification code calculation means for calculating the verification code from the information based on the password and the unique information using the verification code creation algorithm;
Collating means for collating the input value input to the input means with the collating code calculated by the collating code calculating means and executing processing for releasing the lock state when both match,
An inverter device comprising:   The inverter device according to claim 2, wherein the verification unit releases the lock state by initializing the changeable parameter. Number-of-times storage means for storing a numerical value corresponding to the number of times the locked state is released by the verification means;
Restriction means for restricting release of the locked state by the collating means according to the number of times stored by the number of times storage means;
The inverter device according to claim 2 or 3, further comprising:   The inverter device according to any one of claims 1 to 4, wherein the code calculation information includes preset customer information.

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