JP5345115B2 - Electronic lock - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent a product conveying box from being unlocked until the quality test of a sample inspection is completed, for instance. <P>SOLUTION: An electronic lock according to one suitable embodiment includes: key registration means configured to register a plurality of unlocking keys corresponding to intrinsic setting keys, respectively; setting means configured to set one of the setting keys as the present setting key; and locking/unlocking signal generation means configured to generate unlocking signals when an inputted key is suited to the unlocking key corresponding to the present setting key. The key registration means may be configured to register the intrinsic locking keys respectively for the respective unlocking keys. The unlocking signals can be used as signals for actuating an actuator or a motor for operating hardware which performs locking. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to an electronic lock, and preferably relates to a technique that can be used as a lock for preventing the product carrying box from being unlocked until a sample inspection is completed.

Background of the Invention

The applicant has made one of the business fields to manufacture and sell radiopharmaceuticals used for PET (Positron Tomography) and SPECT (Single Photon Emission Tomography). Since the radiotracers contained in these radiopharmaceuticals have a short half-life, it is preferable to deliver them to diagnostic facilities such as hospitals as soon as possible after production. In particular, the tracer for PET has a short half-life and is about 110 minutes at ¹⁸ F, which is one of the typical tracers. For this reason, the range in which the tracer can be delivered from the radiopharmaceutical manufacturing site is not so wide.

  In addition, the tracer cannot be used immediately after it is manufactured, but after it is prepared as a pharmaceutical product, it must be subjected to a quality test to check whether it satisfies a predetermined performance. If this test is not passed, it cannot be used clinically. But of course, quality testing takes some time. For this reason, more time is required from the completion of production to shipment, which causes a further reduction in the deliverable range of the radiopharmaceutical.

  Therefore, the applicant considered the following in order to extend the deliverable distance. That is, when the production of the radiopharmaceutical is completed, several samples for quality test are extracted from it, and the remaining products are shipped immediately, for example, put on a truck and transported to a PET facility. The extracted sample is immediately sent to the quality test. Then, when the test is completed and it is confirmed that the sample satisfies the required performance, the deliveryer or PET facility is contacted by telephone or the like to inform that the shipped product is usable. If the sample does not meet the required performance, of course, the shipped product is not used. In this way, since the time required for the quality test can be used for delivery, it is possible to extend the deliverable distance.

  In this method, it is necessary to reliably prevent the shipped product from being used when it cannot be confirmed that the sample satisfies the required performance. For this purpose, for example, it is preferable not to unlock the box until the product is put in a box and locked, and the result of the quality test becomes clear. However, if a person in charge at the PET facility, a delivery person, etc. can freely unlock, it cannot be denied that the product may be used unintentionally.

  Against this background, the applicant has decided that a means for enabling unlocking is necessary only when the quality test passes without giving the unlocking key to the unlocker at the time of shipment. It was.

  In paragraphs 0001 to 0007 and 0012 to 0013 of JP-A-2002-161657, an electronic lock system is described in which an administrator wirelessly distributes unlocking information to a mobile terminal of an unlocker. In this electronic lock system, the lock also has a wireless communication means, and is configured to be unlocked by wirelessly receiving unlocking information from the unlocker's mobile terminal (0012). Therefore, it is conceivable to use this system and transmit the unlocking information to the unlocker only when the sample quality test passes. However, this system requires infrastructure to provide unlocking information wirelessly. For example, a dedicated management center that manages wireless management is required, and it is necessary to install wireless communication means and dedicated software on locks and mobile terminals. Therefore, it must be a costly solution. Japanese Patent Application Laid-Open No. 2002-161657 assumes that a mobile phone or a PHS is used as a mobile terminal (0013). However, these terminals consume battery relatively quickly and need to be unlocked. In such a case, a situation where the battery has run out can easily occur.

JP 2002-161657 A

  In view of these circumstances, the electronic lock technology disclosed in the application documents of this application was developed for the purpose of obtaining a new technology that prevents the product carrying box from being unlocked until the quality test of the sample is completed. It has been done. However, as is apparent from the description of the present specification, the drawings, and the configuration of the preferred embodiment defined in each claim, the electronic lock technology according to the present invention is limited to use in accordance with the above-mentioned purpose. It is a technology that can be used without limitation in all fields that require locking and unlocking.

  As an example, the present invention provides a key registration unit configured to register a plurality of unlocking keys in association with unique setting keys; and sets any of the setting keys as a current setting key. Setting means configured to be capable of; unlocking signal generation configured to generate an unlocking signal when the input key matches an unlocking key corresponding to the current setting key; And an electronic lock comprising means; This unlocking signal can be used as a signal for operating an actuator or a motor for operating hardware for locking.

  In other words, the electronic lock can use a plurality of unlock keys by switching the current setting key. Therefore, when using the above electronic lock, the administrator switches the setting key before locking, and tells the unlocking key corresponding to the setting key by telephone or the like only when the sample quality test passes. The product carrying box can be unlocked. Therefore, it is possible to remarkably reduce the possibility that the product transport box is unlocked against the intention of the shipper and the product is used. In order to use this electronic lock, the administrator must prepare only a list of combinations of setting keys and unlock keys. Unlike the technique described in Patent Document 1 described above, it is not necessary to introduce infrastructure or equipment for wireless communication. Therefore, the use of the electronic lock can be a simple and inexpensive solution compared to the case where the technique described in Patent Document 1 is used.

  Said electronic lock may be comprised so that locking may be performed by an auto-lock. However, once locked, it cannot be unlocked unless the administrator gives you an unlock key. Locking is preferably performed after sufficiently confirming that locking may be performed. For such purposes, auto-locking is not necessarily the preferred means.

  Therefore, the key registration means is configured to register a unique locking key for each of the unlocking keys, and the unlocking signal generating means is configured such that the input key is the current setting key. Preferably, it is configured to generate a locking signal when it matches a locking key corresponding to.

According to this embodiment, the locker cannot perform the lock without inputting the lock key, and therefore cannot perform the lock easily. Therefore, the locker has sufficient time to perform various confirmations before locking. Can be secured. Before locking, the administrator tells the locker only the lock key corresponding to the setting key currently being set, and only when the product has passed the test, the administrator locks the unlock key to the unlocker. Can be used. All the administrator has to prepare is a list of combinations of setting keys and locking and unlocking keys, again a simple and inexpensive solution.
It should be noted that in the above-described embodiment, a plurality of unlock keys and lock keys can be registered and used. Even if only the administrator manages the unlocking key and the locking key and makes it known only to the administrator, it is a long time if only one key can be used as the unlocking key or the locking key. In the meantime, there may be a risk that various persons other than the administrator can remember the key unintentionally. In that case, the reliability of the distribution system that uses the key, for example, will be significantly impaired. In the above-mentioned embodiment, since it is comprised so that a some unlocking key and locking key can be utilized, this danger is reduced and the safety | security of an electronic lock is raised.
In the above-described embodiment, it should be noted that a plurality of combinations of unlocking keys and locking keys can be registered in association with setting keys. In order to improve safety, a configuration in which a plurality of unlocking keys and locking keys are registered and these are randomly combined is also conceivable. However, if they are simply used in combination at random, management becomes complicated and it may be difficult to use. On the other hand, in the above-described embodiment, since the combination of the unlocking key and the locking key is associated with each individual setting key, it is easily managed simply by preparing a list recording these correspondences. Is possible. That is, the combination of the unlocking key and the locking key can be easily managed and used using the unique setting key.

  For example, the present invention can be implemented as a computer program configured to allow a processor included in an electronic lock to execute the following processing. In this processing, a plurality of unlocking keys are registered in association with respective unique setting keys; one of the setting keys is set as a current setting key; and the input key is the current key Generating an unlocking signal when matching an unlocking key corresponding to the setting key. Preferably, a unique locking key is registered for each of the unlocking keys; and a locking signal is generated when the input key matches a locking key corresponding to the current setting key. May be included.

  In the embodiments introduced below, further technical problems, solving means, and effects related to the above-described electronic lock related technology are disclosed. The scope of claims of the present application defines several technical configurations that the applicant currently seeks for a patent, divided into claims. However, it is noted that the applicant may claim in the future for any new technical features that can be grasped from the present specification and drawings, even if not currently stated in the claims. I want.

1 is a diagram depicting the appearance of an electronic lock 100 that can be an example of an embodiment of the present invention. 3 is a diagram for explaining a locking mechanism in the electronic lock 100. FIG. 3 is a block diagram for explaining elements related to control of the electronic lock 100. FIG. It is an example of a correspondence table of setting keys, locking keys, and unlocking keys. It is a flowchart for demonstrating the flow of the exemplary process which registers a lock key and an unlock key. It is a flowchart for demonstrating the flow of the exemplary process for setting the present setting key. It is a flowchart for demonstrating the flow of the exemplary process for locking. It is a flowchart for demonstrating the flow of the exemplary process for unlocking. It is a flowchart for demonstrating the flow of the exemplary process for displaying the present setting key.

  Hereinafter, an example of a preferred embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram depicting the appearance of an electronic lock 100 that can be an example of an embodiment of the present invention. The electronic lock 100 is configured as a so-called padlock type lock in which a lock body 102 has a push-in U-shaped shackle 202 as a clasp. The lock body 102 includes ten numeric buttons 104 corresponding to the numbers 0 to 9, a decision button 106 for determining an inputted number, a lock button 108 used for locking, and an opening used for unlocking. The lock button 110 includes a setting button 112 that is used to activate the setting means described in the summary of the invention. The lock body 102 is also provided with a display 114 for displaying numbers input through the number buttons 104. The display 114 in the present embodiment is configured to be able to display up to five characters, as indicated by dotted lines in the figure. The lock body 102 may be provided with a connection terminal 116 that can be used for connection to a computer or the like.

  FIG. 2 is a view for explaining a locking mechanism in the electronic lock 100, and is drawn in a form such as a sectional view. As described above, the electronic lock 100 is configured as a so-called padlock type lock in which the lock body 102 has a push-in U-shaped shackle 202 as a clasp. A spring 208 is provided between the one end 204 of the shackle 202 and the lock body 102 via a column 206. In the illustrated locked state, the spring 208 urges the shackle 202 upward. ing. The other end 210 of the shackle 202 is provided with an engagement groove 212 that engages with the latch 214. As shown in the figure, the latch 214 is engaged with the engagement groove 212 in a state where the other end portion 210 of the shackle 202 is accommodated in the lock main body 102, whereby locking is realized. That is, although the spring 208 biases the shackle 202 upward, the shackle 202 cannot move upward due to the latch 214 engaging with the engaging groove 212, and the other of the shackle 202 can be moved. The end 210 cannot be exposed from the lock body. However, when the latch 214 is disengaged from the engagement groove 212, the shackle 202 can move upward, and the shackle 202 is moved to the extent that the other end 210 of the shackle 202 is exposed from the lock body by the elastic force of the spring 208. Pushed up. Thereby, unlocking is realized. The latch 214 can move between at least two positions, such as a position where the latch 214 is engaged with the engagement groove 212 and a position where the latch 214 is received in the latch housing 216 and disengaged from the engagement groove 212 as illustrated. The movement of the latch 214 is controlled by driving means 308 (see FIG. 3) such as an actuator or a motor. In this embodiment, a stepping motor is used as the driving unit 308. The stepping motor 308 is actuated by a signal supplied from the CPU 302, and in accordance with the instruction from the CPU 302, the latch 214 is engaged with the illustrated position and the position accommodated in the latch housing 216 and not engaged with the engagement groove 212. Move to any position between.

  FIG. 3 is a block diagram for explaining elements related to the control of the electronic lock 100. A CPU 302 and a memory 304 are mounted on the lock body. The memory 304 can be a non-volatile memory such as a flash memory. The memory 304 can store a computer program 305 for causing the CPU 302 to execute various functions of the electronic lock 100. At the time of execution, the program 305 may be copied to a faster memory (such as SRAM, not shown) and executed. The memory 304 can also be used as a storage for storing information necessary for the CPU 302 to execute the program 305. In the future, unless otherwise specified, each function of the electronic lock 100 described below may be considered to be realized at least in part by the operation of the CPU 302 in accordance with instructions of the program 305.

  The electronic lock 100 further has a keypad 306. The keypad 306 includes the buttons 104 to 112 described with reference to FIG. 1 and is configured so that when these buttons are pressed, it can be communicated to the CPU 302. A display 114 described with reference to FIG. 1 is also connected to the CPU 302. The program instructions stored in the memory 304 are configured to control the CPU 302 to present predetermined information on the display 114 in response to inputs from the buttons 104 to 112.

  A stepping motor 308 is also connected to the CPU 302. As described with reference to FIG. 2, the stepping motor 308 operates in response to a signal supplied from the CPU 302, and the latch 214 is engaged with the engagement groove of the shackle 202. It is moved between a position that engages with 212 and a position that is accommodated in the latch housing 216 and does not engage with the engagement groove 212. The signal supply to the stepping motor 308 is also performed in accordance with instructions of the program 305.

  The electronic lock 100 is also provided with an interface 310 with an external device. The interface 310 is preferably one that can be connected to, for example, a personal computer, and is preferably of a widespread type. The interface 310 can be, for example, a USB interface.

  The electronic lock 100 is also equipped with a battery 312 for supplying power to each component such as the CPU 302, the motor 308, and the display 114. The battery 312 is preferably a battery having a general-purpose shape and voltage so that it can easily cope with unexpected battery exhaustion.

  The electronic lock 100 can store a combination of a lock key and an unlock key in the memory 304. The electronic lock 100 can store a plurality of combinations, and each combination is associated with a unique setting key. Such a correspondence table is stored in the memory 304, and an example thereof will be described as a table 400 (database 400) with reference to FIG. In the table 400, the leftmost column represents the setting key, the middle column represents the locking key, and the rightmost column represents the unlocking key. According to this table, the lock key 5824 and the unlock key 2286 are associated with the setting key 0001. Further, a lock key 6697 and an unlock key 1877 are associated with the setting key 0002. The lock keys associated with the setting keys 0003 and 0004 are both 1326. However, the corresponding unlocking keys are 7423 and 4895, respectively. Thus, a plurality of setting keys may have the same locking key or unlocking key. What is important is that a specific setting key is assigned to a specific combination of a lock key and an unlock key, and that a plurality of such combinations can be registered. In the present embodiment, 10,000 keys from 0000 to 9999 can be used as setting keys, and therefore a maximum of 10,000 combinations of locking and unlocking keys can be registered. However, this is only an example. For example, more combinations can be registered using a 5-digit setting key, or fewer combinations can be registered using, for example, a 3-digit setting key. . In the present embodiment, only numbers are used as components of the setting key, the locking key, and the unlocking key. However, depending on the embodiment, alphabets, symbols, and other arbitrary characters may be used. Needless to say. Those skilled in the art will be able to configure the keypad 306 appropriately according to the type and number of characters used for the setting key, locking key, and unlocking key.

  As described above, the table 400 is stored in the memory 304 as data. Since the memory 304 is nonvolatile, data is not lost even when power supply is stopped. The table 400 can be stored in the memory 304 by creating it with a computer or the like and transferring it to the electronic lock 100. That is, the computer can be connected to the electronic lock 100 via the connection terminal 116 and the interface circuit 310, and the data transferred from the computer can be sent to the memory 304 under the control of the CPU 302 to be stored. Alternatively, data created by a computer is stored in a USB memory or the like, and the data stored in the USB memory is transferred to the memory 304 under the control of the CPU 302 by connecting the data to the connection terminal 116. It is good. However, the electronic lock 100 is configured so that the lock key and the unlock key can be registered only by the electronic lock 100 main body without a computer. The function is implemented by the program 305. The processing flow will be described with reference to FIG.

  FIG. 5 is a flowchart for explaining processing for registering a lock key and an unlock key using only the electronic lock 100. 500 indicates that the electronic lock 100 is turned on and is in a standby state. In this embodiment, in order to access the key registration function, the user needs to press and hold the setting button 112 for a certain period of time. When the button is pressed for a predetermined time or longer (502), the characters “Toroku” are displayed on the display 114 (504). Therefore, when the enter button 106 is pressed within a predetermined time, the characters “Bangou” are displayed on the display 114 (506). In this state, when a four-digit number used as a setting key is input using the numeric button 104 and the enter button 106 is pressed, the lock key and the unlock key are registered in association with the set number. Will be able to. If the determination button 106 is not pressed within a predetermined time at 504, the process returns to 500, and the electronic lock 100 returns to the standby state.

  When the setting number is entered, “SEI” is displayed on the display 114 next. In this state, when a 4-digit number used as a locking key is input using the numeric buttons 104 and the enter button 106 is pressed, the locking key is registered in relation to the setting key set in step 506 ( 508). When the registration of the lock key is completed, “Caijo” is displayed on the display 114. Therefore, when a 4-digit number used as an unlocking key is input using the numeric button 104 and the enter button 106 is pressed, the unlocking key is registered in relation to the setting key set in step 506 ( 510). The combination of the setting key, the locking key, and the unlocking key may be stored in the memory 304 as data having a format as shown in Table 400, for example. 512 represents the end of the process, and the electronic lock 100 returns to the standby state.

  By these steps, it becomes possible to register the lock key and the unlock key using only the electronic lock 100. Such an implementation is merely an example, and it is needless to say that various modifications can be made to the implementation form of the registration function. For example, in order to access the registration function, in step 502, the setting button is simply pressed for a long time, but this may be switched to a method using a personal identification number. For example, first, a predetermined four-digit password (for example, 9588) may be input using the numeric button 104 and then the setting button 112 may be pressed. Embodiments using a personal identification number for access to the registration function are desirable in terms of preventing easy access to the registration function and increasing security. That is, it is possible to prevent a situation in which a person other than the administrator registers an arbitrary lock / unlock key in association with his / her desired setting key.

  The electronic lock 100 is configured so that any of a plurality of registered setting keys can be set as the current setting key. And when the number input using the number button 104 corresponds to a locking number or an unlocking number, it is comprised so that locking and unlocking are each possible. Next, examples of these processes will be described with reference to the drawings. First, an exemplary process flow for setting the current setting key will be described with reference to FIG.

  Reference numeral 600 indicates that the electronic lock 100 is turned on and is in a standby state. In this embodiment, the user is required to press the setting button 112 shortly in order to access the function for setting the current setting key. Here, if a long time is pressed for a certain period of time, a registration function such as a lock / unlock key is accessed (see step 502 in FIG. 5), so care must be taken. When each button of the electronic lock 100 including the setting button 112 is pressed, it can be instructed to the CPU 302 as an interrupt event. When the CPU 302 is notified of the pressing of the setting button 112 (602), the program 305 controls the CPU 302 to check the pressed time, and if it is within the predetermined time, the display 114 displays “SETTING”. Is displayed (604). In this state, by pressing the enter button 106 within a predetermined time, it is possible to proceed to setting key input. When detecting that the enter button 106 is pressed within a predetermined time, the program 305 controls the CPU 302 to prompt the user to input a setting key. This may be done, for example, by displaying the letters “Bangou” on the display 114. In this state, for example, the user inputs a setting key (for example, 0005) to be used as the current setting key and presses the enter button 106. When detecting that the determination button 106 has been pressed (606), the CPU 302 refers to the database 400, for example, in accordance with an instruction of the program 305, and the key corresponding to the setting key input in step 606 is registered in the database 400. It is checked whether or not (608). If no corresponding key is found, the setting key set fails and the process returns to step 602 after making appropriate notifications. This notification may be, for example, sounding an alarm or displaying characters such as “shipping” and “Failed” on the display 114. In step 608, when a key corresponding to the input setting key is found in the database 400, the program 305 and the CPU 302 set the setting key as the current setting key. Reference numeral 610 represents the end of the process, and the electronic lock 100 returns to the standby state.

  Such an implementation is merely an example, and it goes without saying that various modifications can be made to the implementation form of the function for switching the current setting key. For example, as in the case of access to the registration function of the lock / unlock key, it is preferable to improve the security to use the password for access to the current setting key switching function. For example, in step 602, instead of simply pressing the setting button 112, first, a predetermined four-digit password (for example, 4731) is input using the number button 104 and then the setting button 112 is not pressed. , It may be modified so as not to proceed to step 604. According to such an embodiment, since the current setting key cannot be changed except by an administrator who knows the personal identification number, it becomes more difficult for a person other than the administrator to unlock it illegally. That is, it is possible to prevent a person other than the administrator from changing the setting key for which the release number is known to the user and unlocking it illegally.

  FIG. 7 is a diagram for explaining the flow of an exemplary process for locking. 700 indicates that the electronic lock 100 is turned on and is in a standby state. In order to perform locking, in this embodiment, the user needs to press the locking button 108. As described above, each button of the electronic lock 100 including the lock button 108 can be instructed to the CPU 302 as an interrupt event when pressed. When the CPU 302 is notified that the lock button 108 has been pressed (702), the CPU 302 displays a character “SEJO” on the display 114 in accordance with an instruction of the program 305 (704). At this time, in this embodiment, it is required to move the shackle 202 to the locking position within a predetermined time. That is, it is necessary to push the shackle 202 into the lock body 102. When the movement of the shackle 202 is detected by a sensor or the like, the program 305 (see FIG. 3) causes the CPU 302 to display the characters “Bangou” on the display 114 (706). If the shackle 202 is not moved to the locking position within a predetermined time, the process returns to 700 and the electronic lock 100 returns to the standby state. In that case, the user has to start again by pressing the lock button 108 again.

  In a state (706) where the characters “Bangou” are displayed on the display 114, the user inputs the lock key corresponding to the current setting key using the numeric buttons 104 and presses the enter button 106. In response to pressing of the enter button 106, the program 305 instructs the CPU 302 to check whether or not the input key matches the lock key corresponding to the current setting key (708). If they do not match, after notifying that they do not match, the process returns to step 706 to request the input of the lock key again. The notification may be, for example, sounding an alarm or displaying characters such as “shipping” and “Failed” on the display 114. If it is determined in step 708 that the input key is compatible with the lock key corresponding to the current setting key, the program 305 instructs the CPU 302 to output a signal for operating the stepping motor 308. Output. When the stepping motor 308 is actuated by the signal, the latch 214 moves to the locked position as depicted in FIG. Reference numeral 710 represents the end of the process, and the electronic lock 100 returns to the standby state.

  Such mounting is merely an example, and it goes without saying that various modifications can be made to the locking processing mounting form. For example, in order to perform locking, the step of pressing the locking button (step 702) is eliminated, and it is detected that the shackle 202 has been pushed into the locking position, and the process proceeds to a step for obtaining a number (step 706) May be. In this case, step 704 could also be omitted. The important point is that the locking is performed in response to the input of the locking number corresponding to the current setting key, and the mounting form may vary widely. Furthermore, depending on the embodiment, the locking may be an automatic lock.

  FIG. 8 is a diagram for explaining the flow of an exemplary process for unlocking. 800 indicates that the electronic lock 100 is turned on and is in a standby state. In order to perform unlocking, in this embodiment, the user is required to press the unlocking button 110. When the CPU 302 is notified that the unlock button 110 has been pressed (802), the CPU 302 displays the characters “Kaijo” on the display 114 in accordance with the command of the program 305 (804). At this time, in this embodiment, it is necessary to press the enter button 106 within a predetermined time. If the CPU 302 is not notified of the pressing of the enter button 106 within a predetermined time, the program 305 returns the process to 800 and returns the electronic lock 100 to the standby state. When the pressing of the determination button 106 is notified within a predetermined time, the CPU 302 displays the characters “Bangou” on the display 114 according to the instruction of the program 305 and requests the user to input the unlocking key. The user inputs an unlocking key corresponding to the current setting key using the numeric buttons 104 and presses the enter button 106 again. In response to pressing of the enter button 106, the program 305 instructs the CPU 302 to check whether or not the input key matches the unlocking key corresponding to the current setting key (808). If they do not match, after notifying that they do not match, the process returns to step 806 to request the unlock key again. Although not shown, for example, when the key mismatch continues several times, the process may be returned to step 802. If it is determined in step 808 that the input key matches the lock key corresponding to the current setting key, the program 305 instructs the CPU 302 to send a signal for operating the stepping motor 308. Output. The stepping motor 308 is actuated by the signal to house the latch 214 (see FIG. 2) in the latch housing 216 (see FIG. 2), so that the latch 214 is disengaged from the engagement groove 212 of the shackle 202. As a result, unlocking is realized. Reference numeral 810 represents the end of the process, and the electronic lock 100 returns to the standby state.

  Such an implementation is merely an example, and it goes without saying that various modifications can be made to the implementation form of the unlocking process. For example, a case where the electronic lock 100 is already in the unlocked state when the unlock button 110 is pressed in step 802 can be considered. Whether or not it is in the unlocked state can be detected, for example, by examining the position of the latch 214, the position of the shackle 202, or the like with a sensor or the like. Therefore, the program 305 and the CPU 302 check whether or not the electronic lock 100 is already in the unlocked state when the unlocking button 110 is pressed in step 802. It may be configured to return to step 800 and return to the standby state without proceeding.

  As described above, the electronic lock 100 can change the combination of the lock key and the unlock key by changing the current setting key. Since it is assumed that only the administrator manages the correspondence table between the setting key and the locking / unlocking key, and only the administrator sets the setting key, the unlocking person must know the unlocking key in advance. It is assumed that this is not possible. However, after many uses, the unlocker may remember the unlock key corresponding to a specific setting key.

  In order to prevent such a situation, it is preferable that the unlocker cannot see the current setting key. However, making it impossible to see the current configuration key would be inconvenient when the administrator wants to see what the current configuration key is.

  Therefore, the electronic lock 100 is configured to display the current setting key in response to an input of a specific password. An exemplary process flow relating to this function will be described with reference to FIG.

  900 indicates that the electronic lock 100 is turned on and is in a standby state. In this state, it is assumed that a predetermined password is input using the numeric buttons 104 (902), and the enter button 106 is pressed within a predetermined time (904). Then, the program 305 instructs the CPU 302 to check whether the password information stored in advance in the memory 304 or the like corresponds to the entered password number (906). Are displayed on the display 114 (908). If the input password does not correspond to the stored information, the process returns to step 902 to request input of the password again. At this time, an alarm may be sounded or characters such as “shipping” and “failed” may be displayed on the display 114 in order to indicate to the user that the entered password has not been accepted. 910 represents the end of the process, and the electronic lock 100 returns to the standby state.

  The set current setting key is preferably stored in the memory 304. This is because the memory 304 is non-volatile, so that data is not lost even when power supply is stopped. Therefore, even if the battery runs out during locking, it can be unlocked with the unlocking key corresponding to the stored current setting key by replacing the battery with a new one.

  In steps 708 and 808 of FIG. 7 and FIG. 8, when the input key corresponds to the locking key or unlocking key corresponding to the current setting key, locking or unlocking is performed. There are several possible variations of the method. First, it is necessary to store the set current setting key somewhere. A suitable location is the non-volatile memory 304 as described above, but storing it in another memory not shown, for example, a volatile memory, is not excluded from variations of the embodiments of the present invention. Also, setting the current setting key by a hardware dial or the like is not excluded from variations of the embodiment of the present invention.

  In order to compare the input key with the lock key or unlock key corresponding to the current setting key, the lock key or unlock key must be stored. The program 305 may be configured to cause the CPU 302 to search the data (table) 400 using the current setting key as a search key in order to obtain a lock key or an unlock key corresponding to the current setting key. Each time the program 305 needs a lock key or an unlock key corresponding to the current setting key, that is, whenever it needs to compare with the key input in steps 708 and 808 of FIG. 7 or FIG. The data 400 may be configured to be searched. Alternatively, when the current setting key is set, a corresponding locking key or unlocking key may be retrieved from the data 400 and stored in the memory 304. In the latter case, when comparing with the input key (708, 808), it is not necessary to search again from the data 400, and it is only necessary to read out the stored lock key or unlock key, so the processing is simple. There is an advantage that it is sufficient.

  As described above, the technology related to the electronic lock 100 was developed for the purpose of locking a box for carrying a radiopharmaceutical or the like used for PET imaging, but is limited to use in accordance with this purpose. It will be clear that the technology can be used without limitation in all fields that require unlocking. However, in some embodiments, the electronic lock 100 may be integrated into a box (usually having a radiation shielding function and a shielding box) that carries the radiopharmaceutical. Such a box is also an example of an embodiment of the present invention.

  Manufactured radiopharmaceuticals are not only delivered to a single facility, but may be delivered separately to multiple facilities. In that case, you may set the setting key individually for each delivery destination, but it will be difficult to manage, so you can set the same setting key for all delivery destinations and unlock with the same unlock key If it becomes, it is convenient. For this reason, the electronic lock 100 is not only sold alone, but may be manufactured and sold as a set including a plurality of electronic locks having the same registration information of the setting key, the locking key, and the unlocking key. Such a set is also an example of an embodiment of the present invention.

  Moreover, although it seems that it was understood by the description so far, the main functions of the electronic lock 100 can be implemented by the program 305. Therefore, it is possible to manufacture and sell such a program as a single product. The program can be downloaded and sold through the Internet or stored in a computer-readable storage medium such as a CD-ROM or USB memory. Such a program or storage medium is also an example of an embodiment of the present invention. It should be noted that depending on the embodiment, at least a part of the above functions can be realized by a hardware circuit or a programmable circuit.

  As described with reference to FIGS. 1 and 2, the electronic lock 100 is configured as a padlock. However, the embodiment of the present invention is not limited to mounting on a padlock, and various types of locks may be used. It is possible to implement. In addition, since the detailed structure of the lock part of a padlock is described in Unexamined-Japanese-Patent No. 8-184233 and the special table 2001-516831, please refer if necessary. It goes without saying that embodiments of the present invention can also be implemented in these padlocks.

  As described above, various examples of the embodiment of the present invention have been described through describing various aspects of the electronic lock 100, but these descriptions are not provided for the purpose of limiting the scope of the present invention. Rather, they are provided to assist in a deeper understanding of the invention and are provided to meet legal requirements for patenting. The claims define several preferred embodiments of the present invention, but it should be understood that these embodiments can also be embodied in various specific configurations without departing from the spirit of the invention. Nor. These specific embodiments are included in the scope of the claimed invention.

100 Electronic lock 102 Lock body 104 Numeric button 106 Enter button 108 Lock button 110 Unlock button 112 Setting button 114 Display 116 Connection terminal 202 Shackle 204 One end 206 Strut 208 Spring 212 Engagement groove 214 Latch 216 Latch housing 304 Memory 305 Program 306 Keypad 308 Stepping motor 310 Interface 312 Battery 400 Database

Claims (12)

An electronic lock used to lock a box carrying a radiopharmaceutical,
A key registration means configured to register a plurality of unlocking keys in association with respective unique setting keys;
Setting means configured to be able to set any of the setting keys as a current setting key;
An unlocking signal generating means configured to generate an unlocking signal when an input key matches an unlocking key corresponding to the current setting key;
In addition,
The key registration means is configured to be able to register a unique locking key for each of the unlocking keys,
The unlocking signal generating means is configured to generate a locking signal when an input key matches a locking key corresponding to the current setting key.
Electronic lock. The electronic lock according to claim 1 , wherein the electronic lock is configured so that the current setting key can be set in response to an input of a personal identification number. Configured to display the current setting key in response to input of a personal identification number, electronic lock according to claim 1. Configured to set the current set key is to be stored in non-volatile memory, electronic lock according to any one of claims 1 to 3. The key registration means comprises an external interface, electronic lock according to any one of claims 1 to 4. A box used to transport radiopharmaceuticals ,
The box includes an electronic lock integrated with the box,
A key registration means configured to register a plurality of unlocking keys in association with respective unique setting keys;
Setting means configured to be able to set any of the setting keys as a current setting key;
An unlocking signal generating means configured to generate an unlocking signal when an input key matches an unlocking key corresponding to the current setting key;
In addition,
The key registration means is configured to be able to register a unique locking key for each of the unlocking keys,
The unlocking signal generating means is configured to generate a locking signal when an input key matches a locking key corresponding to the current setting key.
Box . With the lock body, the clasp having at least one open end, and the open end being accommodated in the lock body, the lock body is fixed by engaging with a groove provided in the clasp. A latch that can be moved, and an actuator or a motor that can move the latch between a position engaging with the groove and a position not engaging with the groove,
The locking signal is configured to operate the actuator or motor to engage the latch with the groove, and the unlocking signal is configured to operate the actuator or motor to remove the latch from the groove. The
The electronic lock according to any one of claims 1 to 5 . The electronic lock according to claim 7 , wherein the lock body includes a button for inputting the locking key or the unlocking key, and a setting button related to the operation of the setting means. An electronic lock set comprising a plurality of electronic locks according to any one of claims 1 to 5 , 7 , and 8 . A processor with an electronic lock used to lock a box carrying a radiopharmaceutical ,
Register multiple unlock keys in association with each unique setting key;
Registering a unique locking key for each of the unlocking keys;
Setting one of the setting keys as the current setting key;
Generating an unlock signal when the input key matches an unlock key corresponding to the current setting key;
Generating a lock signal when the input key matches a lock key corresponding to the current setting key;
A computer program configured to be executed. The computer program product of claim 10 , configured to cause the processor to store the current setting key in a non-volatile memory. An electronic lock comprising a processor and a memory storing the computer program according to claim 10 or 11 .

Images