Evaluation of Flame Retardancy of Cardboards Products—Aiming for Application to Cardboard Beds in Shelters

Japan is a country with many disasters such as earthquakes and heavy rains. Disasters cannot be prevented, however, efforts to reduce secondary damage was performed by the nation. Sleeping without beds in a shelter has a high prevalence of economy class syndrome. Due to the living environment of shelter, cots were introduced to each local government. As a result, cots were able to prevent hypothermia and freezing death. Shelters in cold regions use powerful heating devices, which lowers humidity and increases the risk of fire. Cardboard beds were made from paper so that, the user was not com-pletely convinced of the fire risk. In this study, we investigated the combustion behavior and effects of flame-retardants on cardboard by combustion test and thermal analysis. Phosphorus-Nitrogen flame-retardant was possible to suppress the combustion which emitted a large amount of carbon monoxide.


Introduction
Japan is a country with a narrow land area with forests covering about 67%.
Land area is narrow and long with north and south and blessed with rich nature.
However, nature rages and various "disasters" have attack people and torments. shin-Awaji Earthquake and the Great East Japan Earthquake. Comprehensive disaster prevention that predicts major disaster and copes with them to prevent or reduce damage has high-difficulties [1].
Concepts of reduction have been established than disaster prevention in recent years. Although the damage to the disaster occurrence is unavoidable, efforts have been made to reduce secondary damage [2]. Among them, secondary health hazards have been reported at shelters. Especially, the economy class syndrome which caused by victims sleeping in a shelter is often covered by the media since the Mid Niigata Prefecture Earthquake in 2004. Sakuma et al. investigated high morbidity of the serious economy class syndrome caused by blood clots are formed on the feet by long-term miscellaneous life in the shelter as shown in Figure 1 [3].
In April 2016, the recommending statement of a cardboard bed was included in the shelter operation guidelines established by the Cabinet Office disaster prevention department [4]. Immediately after that, on April 14 and 16, two large earthquakes occurred on Kumamoto prefecture as the epicenter and 5,300 cardboard beds were introduced on shelter as shown in Figure 2. Local governments    [6].
Disaster cots such as cardboard bed and pipe bed were an overwhelming shortage of places for storing in Japan which is the small country. Cardboard beds have advantages such as capable of mass production with low-costs and produce in 72 hours. Japan has more than 2500 establishments that can be produced nationwide. Therefore, basically no need for stockpiling as an exception for some users requiring special consideration. Moreover, a cardboard bed can deliver reliably to the shelter by making the disaster prevention agreement with the government in advance [7]. Cardboard beds were made by the paper that has a high danger with the fire owing to a large number of beds are placed in a shelter. Especially, cold region shelter uses the strong heating equipment that makes low-humidity and the risk of fire becomes even higher. Cardboard beds were not having full confidence by users cause of the risk of fire.
Incombustibility of the cardboard is one of the methods to minimize the secondary damage from the fire. Incombustible is to make difficult to burn so as to reduce valuable life and property loss as much as possible and to minimize the social impact. History of incombustibility is old; the beginning is said to be B.C. and vinegar was painted on wood to prevent fire on Roman times [8]. In 1786, Geyrussac works on the incombustibility for French theater records and discovered ammonium sulfate treatment [9]. The United States military worked to make incombustibility the airplane to protect the crew and developed the halogenated paraffin and antimony oxides during World War II. These are groundbreaking flame-retardant and these were improved and are still considered as highly influential flame-retardant systems [10]. Fire is the burning that has passed the human control range and has become a massive spill condition. Combustion is a chemical reaction that involves the generation of light and heat and occurs under low pressure or similar conditions. This is basically a chemical reaction consisting of combustibles and oxygen and the highest temperature range is called the flame [11]. When the combustible substance is ignited for some reason, the temperature of gas-phase rises and the material surface heats by the radiant heat. The heat transferred into the inside of material and decomposition products were generated by reaching the decomposition temperature. The decomposition products are ejected from the material surface into the gas phase and mixed with oxygen in the gas phase so that combustible gas is generated and combustion continues. The idea that combustion can be stopped by breaking this chain process is the basic idea of incombustibility and incombustibility of combustible substances. The idea of incombustibility applies in this study and work on the incombustibility of cardboard [12].
In this study, we investigated the combustion behavior and influence of flameretardant on the cardboard to identify the problems of the cardboards. Combus-Open Journal of Safety Science and Technology a total of eight types of flame-retardants were selected and treated to cardboards.
Optimization of the selection of flame-retardants to prevent secondary damage in shelters.

Materials and Flame-Retardants
The cardboard used W flute type (thickness 8 mm, JPACKS Co. Ltd.) which shape is 3 sheets composition in the 3-layer structure shown in Figure 3. W flute type has the advantages of strong to heavyweights within the commercial product.
Only the W flute type is used for the production of cardboard bed.
Five types of reagent flame-retardants and three types of commercial flameretardants were selected for the treatment of cardboard. Table 1 Table 2 shows the flame-retardants impregnation rate which calculated from the mass of the flame-retardant before and after impregnation.

UL Combustion Test
Multi Calorimeter (Toyo Seiki Seisaku-sho, Ltd.) was used for the combustion test. Multi Calorimeter has the 0.75 m 3 volume draft chamber which is able to measure the heat generation rate and mass loss. UL combustion test was performed both of vertical and horizontal direction according to ASTM D3801 and ASTM D635. This test measure and evaluate the temporal changes of heat quantity with combustion which specimen placed vertically and horizontally ignited and burned with a burner. The cardboard was cut out the size with 150 mm length and 15 mm width for vertical direction combustion test as shown in Figure 4. On the other hands, horizontal direction specimens were cut out 200 mm length and 50 mm width as shown in Figure 5. The

Corn Calorimeter Test
Corn calorimeter test was performed by Corn calorimeter C3 (Toyo Seiki Seisaku-sho Ltd.). This test measures the calorie of burning combustible gas generated by thermal decomposition with the spark which specimen placed horizontally and heated by the corn. Calorie of combustion, combustion time and time until ignition were measured in this study. Specimens were cut out with 100 mm square flat plate. The radiant heat of corn was set up 50 kW/m 2 for the measurement condition. Each specimen was tested with three samples.

Thermal Analysis
Thermogravimetric analysis was performed to investigate the decomposition speed of flame-retardants. Thermogravimetric analysis machine Discovery TGA (TA Instruments) was used. Flame-retardants which are P1, NS, PN, C, B and PNS, and cardboard was used for measurements. Each specimen was tested with a rising temperature of 20 degrees/minutes. Each flame-retardant was tested with three samples. Figure 6 shows the relationship between the heat release rate (HRR) and burning time on vertical combustion test and horizontal combustion test of W-flute cardboard. Vertical combustion has a shaper curve start and higher maximum HRR than horizontal combustion. Vertical combustion was a shorter combustion time than the horizontal combustion from the results of Figure 6. Cardboard combustion on horizontal direction took time after the ignition was observed. On the other hand, combustion of vertical direction was emitted high Open Journal of Safety Science and Technology heat immediately after ignition and burns out in a short time. Figure 7 shows the schematic view of combustion areas in the vertical direction and horizontal direction. Combustion speed on end was faster than the center of cardboard both vertical and horizontal direction was demonstrated by these figures. In addition, combustion was spread with the shape of concentric circles stretched upward to form the fire source was observed in the center of the cardboard.

Thermal Analysis
Results       the other hand, the decomposition temperature of commercial flame-retardants which C, B, and PN were started from 100 degrees or less.
All specimens of residues were within 10%. PN was pyrolyzed with 4 stages and residues was about 9%. P1 started pyrolysis on 200 degrees and weight was Open Journal of Safety Science and Technology decreased to 10% immediately. In the case of NS, pyrolysis occurred with twostages around 300 degrees and almost no residue remained.

Discussion
The compatibility between the cardboard and each flame-retardant were investigated. Regarding the commercial flame-retardants had difficulties to impregnate the cardboard and these effects were low. Pyrolysis of commercial flameretardants and phosphorus flame-retardant occurred at a lower temperature of cardboard. Therefore, these were decomposed until the cardboard combustion. So, the heat of combustion was increased on the combustion test was considered.
On the other hand, comparing the pyrolysis behavior of nitrogen-sulfur flameretardants such as PN, PNH, and the cardboard, pyrolysis occurred during the pyrolysis of the cardboard. In addition, a large amount of carbon monoxide was generated on the combustion that suppressed the combustion by emitted an inert gas from flame-retardants on combustion before and after. Flame-retardants were considered that flame-retardant effects were demonstrated in the combustion test. Form these results, we thought that PN is suitable for flame-retardant cardboard.

Conclusions
In this study, we investigated the combustion behavior and influence of flameretardants on the cardboards. UL combustion test, corn calorimeter test and thermal analysis were performed to clarify the combustion mechanism and optimization of flame-retardants.
Cardboard combusted easily in the vertical direction and combusted into a shape with concentric circle extended upward. Although commercial flame-retardants were pyrolyzed at the temperature on 100 degrees, however, PN was low in both of maximum HRR and THR and emission of carbon monoxide was high. PN is the suitable flame-retardant for cardboard which this emit a large amount of carbon monoxide and suppresses the combustion was clarified by these experiments.
PN impregnated cardboard is expected to prevent secondary damage from the fire in a shelter.