This application is based upon and claims the benefit of priority of the prior Japanese Patent Application No. 2014-095716 filed on May 7, 2014, the entire contents of which are incorporated herein by reference.
The embodiments discussed herein are related to a magnetic tape device and a method for controlling a magnetic tape device.
In an information processing system, a magnetic tape device which backs up data is utilized in order to avoid disappearance of important data or the like.
The related art is disclosed in Japanese Laid-open Patent Publication No. 2003-178501.
According to an aspect of the embodiments, a magnetic tape device, includes: a base member movable in a front-back direction of a cabinet; a tape drive mounted rotatably to the base member at least between a first position facing a front surface of the cabinet and a second position facing a side surface of the cabinet; and a rotation unit configured to rotate the tape drive from the first position to the second position when a magazine detachably containing a magnetic tape cartridge is inserted into the cabinet, and to rotate the tape drive from the second position to the first position when the magazine is removed from the cabinet.
The object and advantages of the invention will be realized and attained by means of the elements and combinations particularly pointed out in the claims.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, as claimed.
Magnetic tape devices include a single-unit magnetic tape device in which a magnetic tape cartridge is manually replaced, and a magnetic tape device with an autoloader function in which plural magnetic tape cartridges contained in a magazine are replaced by the autoloader. In the single-unit magnetic tape device, the magnetic tape cartridge is inserted into a tape drive, and thereafter, data backup is started in a short time. In the magnetic tape device with the autoloader function, data backup is performed without manual operation, while at the start of the data backup, operation is performed in which all magnetic tape cartridges are transported to the tape drive and volumes are read in. Thus, in an information processing system, the single-unit magnetic tape device is utilized for data backup during time periods in which operator's operation is expectable (for example, in the daytime), and the magnetic tape device with the autoloader function is utilized for data backup during time periods in which the operator's operation is not expectable (for example, at night).
For example, in a case where the information processing system including only the magnetic tape device with the autoloader function is operated, a volume reading operation is performed every time the magnetic tape cartridge is manually replaced, and thus, backup efficiency may be reduced.
Thus, a magnetic tape device including the single-unit magnetic tape device integral with the magnetic tape device with the autoloader function may be provided.
The magnetic tape device 100 includes a base member 220 and a tape drive 300. The base member 220 is movable in a front-back direction of a cabinet 200. The tape drive 300 is rotatably mounted between a first position facing a front surface of the cabinet 200 and a second position facing a side surface of the cabinet 200. The magnetic tape device 100 includes a rotation unit 600 configured to rotate the tape drive 300 between the first position and the second position according to the insertion or removal of a magazine 500 in which plural magnetic tape cartridges 400 are detachably contained. The rotation unit 600 rotates the tape drive 300 from the first position to the second position when the magazine 500 is inserted into the cabinet 200, while the rotation unit 600 rotates the tape drive 300 from the second position to the first position when the magazine 500 is removed from the cabinet 200.
A solid or hollow cylindrical rotating shaft 260 is fixed to an upper surface of the base member 220. The tape drive 300 is rotatably fixed to the rotating shaft 260 by a bearing or the like. A configuration given below limits a rotation of the tape drive 300 to between the first position and the second position and allows the tape drive 300 to be held (or fixed) at the first position or the second position.
For example, a proximal end portion of a spring plunger 320 protruding downward toward the upper surface of the base member 220 is fixed to a lower surface of the tape drive 300.
A driving pulley 720 and a driven pulley 740, which are driven by a servomotor 700, are mounted on the bottom surface of the cabinet 200 in order to move the tape drive 300 formed integrally with the base member 220, along the rails 240. A belt 760 including a material having elasticity, for example, is entrained between the driving pulley 720 and the driven pulley 740. The base member 220 is fixed to the belt 760. Thus, the servomotor 700 is actuated to rotate the belt 760 entrained between the driving pulley 720 and the driven pulley 740 and move the tape drive 300 formed integrally with the base member 220, along the rails 240.
A magazine rail 280 extending in the front-back direction of the cabinet 200 and holding the magazine 500 at a certain position is fixed to the left side surface and bottom surface of the cabinet 200. The magazine rail 280 includes a first rail member 282 supporting the left side surface and the left-side bottom surface of the magazine 500 on the left side surface of the cabinet 200, and a second rail member 284 supporting a lower portion of the right side surface and the bottom surface of the magazine 500 on the bottom surface of the cabinet 200. Thus, under a condition where the magazine 500 is placed on the magazine rail 280, the magazine 500 is supported at least at both its side surfaces and its bottom surface by the first rail member 282 and the second rail member 284 and is thus restrained from moving leftward and rightward and moving downward.
The cabinet 200 is mounted with the rotation unit 600 configured to rotate the tape drive 300 toward the first position or the second position according to the insertion or removal of the magazine 500.
In response to rotation of the second gear 624, the tape drive 300 rotates between the first position and the second position. Thus, a fitting hole 624A in which a tip portion of a pin 642 of an actuator 640 is fitted is formed in one end portion of an arc of the second gear 624.
The base member 220 is mounted with a transport unit 800 configured to transport the magnetic tape cartridges 400 between the tape drive 300 and the magazine 500 under a condition where the tape drive 300 directly faces the magazine 500 after rotating to the second position.
The first transport member 820 includes a swinging plate portion 824, and two rollers 826 and 828. The swinging plate portion 824 is swingable around a rotating shaft 822 extending in the front-back direction of the cabinet 200. The two rollers 826 and 828 are spaced apart from each other and fixed to a lower portion of the swinging plate portion 824. At least one of the rollers may be fixed to the lower portion of the swinging plate portion 824. A roller 832 rotatable around a rotating shaft 830 extending in a width direction of the cabinet 200 is fixed to an end portion of the swinging plate portion 824 located on the base member 220 side.
The second transport member 840 includes a swinging plate portion 844, and two rollers 846 and 848. The swinging plate portion 844 is swingable around a cylindrical portion 842 having a substantially cylindrical shape, which functions as a rotating shaft extending in the front-back direction of the cabinet 200. The two rollers 846 and 848 are spaced apart from each other and fixed to an upper portion of the swinging plate portion 844. At least one of the rollers may be fixed to the upper portion of the swinging plate portion 844. The cylindrical portion 842 is rotatably fixed to the swinging plate portion 844, for example by a bearing. A hole having a noncircular shape such as a polygonal shape (for example, an equilateral hexagonal shape) is formed in a center of the cylindrical portion 842. A belt 850 including a material having elasticity is entrained between the cylindrical portion 842 and the two rollers 846 and 848. When the cylindrical portion 842 rotates, its rotating force is transmitted via the belt 850 to the two rollers 846 and 848, so that the rollers 846 and 848 rotate. A roller 854 rotatable around a rotating shaft 852 having a portion extending in the width direction of the cabinet 200 is fixed to an end portion of the swinging plate portion 844 located on the base member 220 side.
The swinging plate portion 824 of the first transport member 820 and the swinging plate portion 844 of the second transport member 840 are biased by tension coil springs 834 and 856 in a direction in which the swinging plate portions 824 and 844 move away from each other. Under a condition where an external force does not act on the swinging plate portions 824 and 844, there is a great distance between the rollers 826 and 828 of the first transport member 820 and the rollers 846 and 848 of the second transport member 840. Thus, the first and second transport members 820 and 840 may not perform the function of transporting the magnetic tape cartridge 400 with it pinched therebetween.
A bottom portion of the cabinet 200 is provided with a rotatable drive shaft 860 extending in the front-back direction of the cabinet 200 in such a way as to pass through the cylindrical portion 842 of the second transport member 840 of the transport unit 800. Both end portions of the rotatable drive shaft 860 are rotatably supported by a pair of bearing members 862 fixed to the bottom surface of the cabinet 200. The rotatable drive shaft 860 is rotatably driven for example by a servomotor 864. The rotatable drive shaft 860 is provided with large diameter portions 860A each having a larger diameter than other portions and having a polygonal shape, for example, a hexagonal shape. A large diameter portion 860A is formed at an intermediate portion of the rotatable drive shaft 860 directly facing each of cells (or shelves for containing the magnetic tape cartridges 400) of the magazine 500 housed in the cabinet 200. The large diameter portions 860A of the rotatable drive shaft 860 may have a shape according to the hole of the cylindrical portion 842, so as to be rotatable integrally with the cylindrical portion 842 of the second transport member 840. The cylindrical portion 842, the belt 850, the rotatable drive shaft 860 or the servomotor 864 is given as an example of a driving unit.
In response to movement of the tape drive 300, the large diameter portion 860A of the rotatable drive shaft 860 is fitted in the hole in the cylindrical portion 842 of the second transport member 840, and thereby, rotation of the rotatable drive shaft 860 is transmitted to the cylindrical portion 842. Thus, the two rollers 846 and 848 rotate. If the large diameter portion 860A of the rotatable drive shaft 860 is not fitted in the hole in the cylindrical portion 842 of the second transport member 840, the two rollers 846 and 848 of the second transport member 840 do not rotate even if the rotatable drive shaft 860 rotates.
The first block 866 is mounted by a first bracket 870 hanging down from the top plate of the cabinet 200, in such a manner that an apex of the first block 866 is located downward. The second block 868 is mounted by a second bracket 872 standing from the bottom surface of the cabinet 200, in such a manner that an apex of the second block 868 is located upward. The first block 866 and the second block 868 are each mounted in an orientation in which a height of each block changes along the front-back direction of the cabinet 200.
In response to movement of the tape drive 300, the roller 832 of the first transport member 820 runs up onto the first block 866, and also, the roller 854 of the second transport member 840 runs up onto the second block 868. Thus, the swinging plate portions 824 and 844 swing against biasing forces of the tension coil springs 834 and 856. The distance between the rollers 826 and 828 of the first transport member 820 and the rollers 846 and 848 of the second transport member 840 is reduced, so that the magnetic tape cartridge 400 is pinched therebetween. Proximal end portions of the first transport member 820 and the second transport member 840, for example, may be made of a spring material so as to be capable of absorbing tolerance of the magnetic tape cartridges 400, or the like.
The back portion of the cabinet 200 is mounted with a stabilizer circuit 900 and a controller board 920 as a control system of the magnetic tape device 100, and the stabilizer circuit 900 stabilizes electric power from an external commercial power source, and the controller board 920 controls the tape drive 300, the actuator 640, the servomotors 700 and 864, and the like. A back portion of the magazine rail 280 is mounted with a sensor 940 which outputs an ON signal for example when the magazine 500 is inserted. The upper surface of the base member 220 is mounted with a sensor 960 which outputs an ON signal when the tape drive 300 rotates to the second position.
The output signals from the sensors 940 and 960 are input through signal lines to the controller board 920. The controller board 920 performs electronic control on the tape drive 300 and the servomotors 700 and 864 in response to a command from a host control device (for example, a server or the like). When the output signals from the sensors 940 and 960 both become ON, the controller board 920 operates the actuator 640 to delink the tape drive 300 from the rotation unit 600.
For example, in an initial state, as illustrated in
In a case where the magnetic tape device 100 is used as the single-unit magnetic tape device, with the magnetic tape device 100 remaining in the state illustrated in
In a case where the magnetic tape device 100 is used as the magnetic tape device with the autoloader function, the operator inserts the magnetic tape cartridges 400 into the cells of the magazine 500, as illustrated in
When the tape drive 300 is moved to the position directly facing the magnetic tape cartridges 400, in the transport unit 800, the roller 832 of the first transport member 820 runs up onto the first block 866, and also, the roller 854 of the second transport member 840 runs up onto the second block 868. As illustrated in
In operation 3, the controller board 920 outputs a volume reading command to the tape drive 300, and the volume is read from the magnetic tape cartridge 400.
In operation 4, the controller board 920 compares the volume read from the magnetic tape cartridge 400 with the volume directed by the command from the host control device, thereby to determine whether or not the magnetic tape cartridge 400 inserted in the tape drive 300 is the magnetic tape cartridge directed by the command. If the controller board 920 determines that the volume read from the magnetic tape cartridge 400 is identical to the volume directed by the command from the host control device, the operation goes to operation 5 (Yes). If the controller board 920 determines that the volume read from the magnetic tape cartridge 400 is different from the volume directed by the command from the host control device, the operation goes to operation 7 (No).
In operation 5, the controller board 920 executes the writing or reading of data to or from the magnetic tape cartridge 400 inserted in the tape drive 300, in response to the command from the host control device.
In operation 7, the controller board 920 outputs the reverse driving signal to the servomotor 864, and the magnetic tape cartridge 400 inserted in the tape drive 300 is transported to the magazine 500, as illustrated in
Thereby, when the magazine 500 is inserted into the cabinet 200, the tape drive 300 rotates to the second position directly facing the magnetic tape cartridges 400, and the data backup operation is executed in response to the command from the host control device. Thus, after the operator has inserted the magazine 500, for example, automated data backup may be performed at night.
A piece of the magnetic tape device 100 is switched to the single-unit magnetic tape device or the magnetic tape device with the autoloader function according to whether or not the magazine 500 is inserted in the cabinet 200. During time periods in which the operator's operation is expectable, the magnetic tape device 100 is used as the single-unit magnetic tape device. Thus, after the insertion of the magnetic tape cartridges 400, the data backup is started in a short time, and a reduction in efficiency of the backup may be suppressed. During time periods in which the operator's operation is not expectable, the magnetic tape device 100 is used as the magnetic tape device with the autoloader function. Thus, the automated data backup is performed on the plural magnetic tape cartridges 400.
All examples and conditional language recited herein are intended for pedagogical purposes to aid the reader in understanding the invention and the concepts contributed by the inventor to furthering the art, and are to be construed as being without limitation to such specifically recited examples and conditions, nor does the organization of such examples in the specification relate to a showing of the superiority and inferiority of the invention. Although the embodiments of the present invention have been described in detail, it should be understood that the various changes, substitutions, and alterations could be made hereto without departing from the spirit and scope of the invention.
Number | Date | Country | Kind |
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2014-095716 | May 2014 | JP | national |