JP2003201790A5 - - Google Patents

Description

[Title of the Invention] Fireproof safe for electronic storage media [Claims]
1. A secondary storage made of a material having latent heat of fusion is installed inside a fireproof safe for general paper, and when the temperature rises above the melting temperature, the latent heat at the time of changing from a solid phase to a liquid phase is used. A fireproof safe for electronic storage media, wherein the temperature in the secondary storage is maintained at a predetermined temperature or lower.
2. A fireproof safe for electronic storage media, wherein a secondary fireplace is fitted in a primary fireproof safe for general paper,
The peripheral wall of the secondary storage is made of a heat insulating material, a heat absorbing material provided inside the heat insulating material, and a metal inner wall plate serving as an inner wall of the secondary storage,
The heat-absorbing material has a melting point or a freezing point in a range of each allowable temperature or each allowable temperature −10 ° C., and when the temperature rises above the temperature, the latent heat at the time of changing from a solid phase to a liquid phase is used in the secondary storage. A fireproof safe for electronic storage media, characterized in that the temperature rise is maintained at or below each allowable temperature.
3. The fire-resistant safe for electronic storage media according to claim 1, wherein the heat-absorbing material is set to a thickness such that a solid phase can be present when heated for a predetermined time.
DETAILED DESCRIPTION OF THE INVENTION
[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an improvement in a fireproof safe for electronic storage media in which a secondary fireplace is fitted in a primary fireproof safe for general paper.
[0002]
[Prior art]
In the applicable standard of "Fireproof safe for magnetic tape" in JIS standard (JIS S1037 fireproof safe), the condition that the internal temperature (permissible temperature) at the time of heating is 66 ° C or less and the humidity 85% or less is defined. In the applicable standards of the "fireproof safe for disk cartridges", the conditions are set such that the internal temperature (allowable temperature) during heating is 52 ° C. or less and the humidity is 80% or less.
On the other hand, the applicable standard of “fireproof safe for general paper” defines a condition that the allowable temperature is 177 ° C. or less.
In addition, the secondary storage means a container which is pre-installed in the fireproof safe for general paper or a container which is additionally installed. In the present invention, the secondary storage stores an electronic storage medium such as a magnetic tape or a flexible disk cartridge.
Therefore, in order to satisfy the fireproof conditions of the "fireproof safe for magnetic tapes" and the "fireproof safe for flexible disk cartridges" using the secondary warehouse, various materials have been studied as heat insulating materials for the secondary warehouse. However, there is still a situation in which anything satisfying the above conditions cannot be found.
For example, if the secondary storage is configured as a secondary storage with a structure in which urethane foam or urethane foam is combined with a particle board, the initial temperature rise time can be delayed, but the temperature inside the secondary storage after heating is completed. It is difficult to keep rising and to keep it below the allowable temperature.
[0003]
[Problems to be solved by the invention]
The present invention has been made in view of the above circumstances, and its main problem is that the peripheral wall of the secondary storage is composed of a heat insulating material and a heat absorbing material having a latent heat of fusion provided inside thereof, and the heat absorbing material is It is an object of the present invention to provide a fireproof safe for electronic storage media that maintains the temperature in a secondary storage at or below an allowable temperature by utilizing latent heat when a temperature rises above a melting temperature and changes from a solid phase to a liquid phase.
[0004]
[Means for Solving the Problems]
In order to achieve the above object, in the invention of claim 1,
A secondary storage made of a material having latent heat of fusion is installed inside a fireproof safe for general paper, and when the temperature rises above the melting temperature, the secondary storage utilizing the latent heat when changing from the solid phase to the liquid phase is used. Technical measures are taken to keep the temperature rise in the inside below a predetermined temperature.
In the invention of claim 2,
A fireproof safe for electronic storage media in which a secondary fireplace is fitted into a primary fireproof safe for general paper,
The peripheral wall of the secondary storage is made of a heat insulating material, a heat absorbing material provided inside the heat insulating material, and a metal inner wall plate serving as an inner wall of the secondary storage, and the heat absorbing material has a melting point or a freezing point. The range is 66 ° C to 56 ° C for a fire-resistant safe for magnetic tapes and 52 ° C to 42 ° C for a fire-resistant safe for flexible disk cartridges. When the temperature rises above the above-mentioned temperature, the latent heat when changing from a solid phase to a liquid phase is used. Then, a technical measure is taken to keep the temperature rise in the secondary storage below the allowable temperature.
In the invention of claim 3,
Technical measures are taken such that the thickness of the heat absorbing material is set to a thickness in which a solid phase can exist upon heating for a predetermined time.
[0005]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of a fireproof safe for electronic storage media of the present invention will be described with reference to the drawings.
According to the JIS standard, a fire-resistant safe for magnetic tapes and a fire-resistant safe for flexible disk cartridges are classified, but it goes without saying that the fire-resistant safes for flexible disk cartridges can be applied to the fire-resistant safes for magnetic tapes if the allowable conditions are satisfied. Therefore, a fireproof safe for a flexible disk cartridge will be described below.
[0006]
The fire-resistant safe 1 for a flexible disk cartridge shown in FIG. 1 has a configuration in which a secondary storage is incorporated in a primary storage having the performance of a general paper fire-resistant safe.
That is, reference numeral 11 denotes an outer wall made of a metal plate of the primary storage, which is filled with foamed concrete exemplified as a heat insulating material 12 of the primary storage between the metal plate and the middle plate 13, and the primary storage peripheral wall and the primary storage door. To form a fireproof safe for general paper.
[0007]
Next, reference numeral 14 denotes a heat insulating material serving as an outer wall of the secondary storage, in which a heat absorbing material 15 formed in a plate shape is overlapped, and a metal plate serving as an inner wall of the secondary storage is provided inside. A secondary storage having a peripheral wall and a door inner wall covered with an inner plate 16 is formed.
[0008]
In the case of the illustrated example, the metal plate 13 is made of a metal plate. It is preferable to reduce the heat conduction from the primary storage by providing an interposing means having a low thermal conductivity such as providing a heat insulating material such as a plywood or providing a space in order to suppress an increase in the internal temperature of the secondary storage.
[0009]
Further, the opening end of the peripheral wall of the secondary storage is turned over from the ends of the middle plate 13 and the inner plate 16 and is covered with an end plate having a U-shaped cross section connecting the two.
The entire periphery of the secondary door is covered with a steel plate.
Here, as the metal plate, a steel material is mainly used, but in order to suppress heat transfer to the inside by heat conduction of the steel plate, a metal having a low thermal conductivity partially so that the steel material is not continuous, such as a stainless steel plate. It is preferable to connect them.
[0010]
In addition, the primary door has a heat insulating mortar portion and a lock mechanism portion independent of each other, and prevents heat and humidity from entering the lock case 19, particularly the through hole of the rotating shaft of the handle 17 into the secondary storage.
[0011]
The secondary door has a structure in which the lock mechanism 19 is pressed against a silicon rubber packing 20 provided on the plywood of the secondary storage main body, and has a high degree of sealing, which also prevents heat and humidity from entering.
In the drawing, reference numeral 18 denotes a hinge for opening and closing the primary door.
[0012]
In the above configuration, in the present embodiment, as the heat insulating material 14 of the secondary storage, for example, urethane foam foam, foamed urethane board, or lightweight silicate calcium board is used. Any heat insulating material that can withstand can be used.
"Modeler 801A" (manufactured by Solar Co., Ltd.) as a urethane foam, "Achilles Board AG" (manufactured by Achilles Corporation) as a urethane foam board, and "Taikalite No. 1" as a lightweight silicate calcium foam board. A thickness of 20 to 30 mm such as [manufactured by Nippon Insulation Co., Ltd.] is used, but is not limited thereto as long as the heat resistance and the heat insulation performance are equivalent.
[0013]
Next, as the heat absorbing material 15, a material having a latent heat of fusion with a melting point in the range of 42 ° C to 52 ° C is used.
In this embodiment, bagged paraffin wax, polyethylene glycol or sodium metasilicate 9 hydrate is used as an example of the heat absorbing material 15.
That is, as the paraffin wax, paraffin wax 115F, melting point 47 ° C. (manufactured by Nippon Seiro Co., Ltd.) was used.
[0014]
As the polyethylene glycol, polyethylene glycol having a molecular weight of 1540 and a freezing point of 43 ° C. to 47 ° C. (manufactured by Lion Corporation) or a molecular weight of 2,000 and a freezing point of 51 ° C. (manufactured by Sanyo Chemical Industries, Ltd.) was used.
The melting point of 48 ° C. (manufactured by Fuji Chemical Industry Co., Ltd.) was used as sodium metasilicate 9 hydrate.
In the case of the illustrated example, these are bagged and used as a thickness of 18 to 20 mm.
[0015]
The heat-absorbing material 15 is used by cooling a liquid packed in a bag such as a polyethylene bag and solidifying it into a board shape using a mold, or a granular or powdered material into a bag and making the thickness uniform. It may be something.
[0016]
Further, the heat absorbing material 15 may be attached without any gap along the inside of the heat insulating material 14 or may be attached partially.
Further, the thickness needs to be such that the solid phase can be present during heating for a predetermined time, and it is desirable that the portion in contact with the inner plate at the time of heating is set to a thickness that does not completely melt.
[0017]
Next, an experimental example will be described.
Since the outside of the secondary storage corresponds to the internal temperature of the “fireproof safe for general paper”, the heating conditions of the secondary storage are set to 100 ° C. for 1 hour, 100 ° C. for 1 hour by referring to the past test examples of the “fireproof safe for general paper”. The temperature was set at １５０150 ° C. for 1 hour, 150 ° C. for 2 hours, and 100 ° C. for 3 hours, and then the mixture was naturally cooled until the internal temperature of the secondary storage was clearly reduced.
[0018]
[Comparative example]
A urethane foam board having a thickness of 30 mm was used as the heat insulating material 14, and a particle board was used as the heat absorbing material 15. As a result, the maximum temperature reached 66.9 ° C. after 6.5 hours.
[0019]
[Experimental example 1]
A 30 mm thick urethane foam board was used as the heat insulating material 14, and a polyethylene glycol molecular weight 1540 having a freezing point of 43 to 47 ° C. was used as the heat absorbing material 15. As a result, the maximum temperature reached 44.7 ° C after 10 to 13 hours.
[0020]
[Experimental example 2]
A 30 mm thick urethane foam board was used as the heat insulating material 14, and paraffin wax F115 having a melting point of 47 ° C. was used as the heat absorbing material 15. As a result, the maximum temperature reached 44.7 ° C. after 14.5 hours.
[0021]
[Experimental example 3]
A 30 mm thick urethane foam board was used as the heat insulating material 14, and sodium metasilicate nonahydrate having a melting point of 48 ° C. was used as the heat absorbing material 15. As a result, the maximum temperature reached 47.7 ° C. after 9 to 11 hours.
[0022]
[Experimental example 4]
A 30 mm thick urethane foam was used as the heat insulating material 14, and a polyethylene glycol molecular weight of 2,000 having a freezing point of 51 ° C. was used as the heat absorbing material 15. As a result, the maximum temperature reached 49.8 ° C. after 9 to 10 hours.
[0023]
[Control example]
A 30 mm thick urethane foam board was used as the heat insulating material 14, and paraffin wax F130 having a melting point of 55 ° C. was used as the heat absorbing material 15. As a result, the maximum temperature reached 52.8 ° C after 11 to 13.5 hours.
[0024]
As described above, the particle board having no latent heat of fusion as shown in the comparative example reaches 66.9 ° C. and cannot be controlled to 52 ° C. or less. In addition, all combinations of heat absorbing materials (Experimental Examples 1 to 4) using a urethane foam material as a heat insulating material and having a melting point or a solidification point of 43 to 51 ° C. and a latent heat of fusion are all within 52 ° C.
[0025]
Even when the same urethane foam board was used as the heat insulating material, the combination of the heat absorbing materials having the melting point or the freezing point of 55 ° C. (control example) exceeded 52 ° C.
Further, when the melting point or freezing point was lower than 43 ° C., the solid phase began to melt at that temperature, and the temperature could be maintained at a lower temperature, but after melting, the temperature rose and was not effective.
[0026]
From these, it was confirmed that the heat absorbing material is preferably a material having a latent heat of fusion in the range of 42 ° C. to 52 ° C., particularly a material having a melting point or freezing point of about 47 ° C. Although this experimental example is sufficiently applicable to a fireproof safe for magnetic tapes, if it is limited to a fireproof safe for magnetic tapes, a material having a melting heat or a latent heat of melting within a range of 56 ° C to 66 ° C is selected. Obviously, it can be maintained at 66 ° C. or lower.
[0027]
In the above embodiment, a case where the present invention is applied to a "fireproof safe for flexible disk cartridges" is illustrated. However, in the present invention, if the present invention is applied to a fireproof safe for electronic storage media including "a fireproof safe for magnetic tape" and the like. Of course, it is needless to say that the present invention is not limited to the above embodiment.
Further, the present invention is not limited to the above embodiment, and various design changes can be made without changing the gist.
[0028]
【The invention's effect】
In the present invention configured as described above, since the heat absorbing material is provided on the peripheral wall of the secondary storage, the material having a latent heat of fusion in the range of, for example, 42 ° C to 52 ° C is selected as the heat absorbing material. It has an excellent effect that the temperature rise in the refrigerator can be maintained at 52 ° C. or lower to satisfy the standard as a fire-resistant safe for a flexible disk cartridge as well as a fire-resistant safe for a magnetic tape.
[Brief description of the drawings]
FIG. 1 is a sectional view showing an embodiment of a fireproof safe for a flexible disk cartridge.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Fire-resistant safe for flexible disk cartridges 11 Outer wall of primary storage 12 Thermal insulation of primary storage 13 Middle plate of primary storage 14 Thermal insulation of secondary storage 15 Heat absorbing material of secondary storage 16 Inner plate 17 Handle 18 Hinge 19 Lock mechanism 20 Silicon Rubber packing