JP2016000928A - Roof structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fire resistant-structured roof superior in fire resistance, heat insulation, noise insulation and workability.SOLUTION: The roof structure includes: a roof board 3; a heat insulation material 4; and a waterproof material 5 which are sequentially laminated on a deck plate 2 fixed to a beam or a main building 1. The roof board 3 is constituted of a hard wood-wool cement board. The heat insulation material 4 has a thickness of 50 mm or more.

Description

  The present invention relates to a roof structure, and particularly to a roof structure using a deck plate that is excellent in fire resistance, heat insulation, sound insulation and workability.

  As shown in FIG. 5, the current roof structure (hereinafter referred to as “example specification”) prescribed in the Ministry of Construction Notification No. 1365 using the deck plate is placed on the beam or purlin 11 as shown in FIG. Insulating material 13 and waterproofing material 14 are arranged on a fixed fire-resistant structure deck plate 12, but it improves sound insulation performance such as measures against rain noise, and eliminates stepping and cracking of the insulating material during construction. There is a demand for improvement in workability. Here, in the example specification, the thickness of the heat insulating material 13 is defined as 50 mm or less.

In addition, through the enforcement of the “Law Concerning Rational Use of Energy” for CO ₂ emission reduction and subsequent revisions, further improvements in energy-saving performance of buildings are required. Under such circumstances, in order to reduce heat loss from a part such as an outer wall, a ceiling or a roof, or an opening of a building, improvement of heat insulation performance is demanded as a trend of the world.

  Here, in order to improve the heat insulating performance, a heat insulating material 13 having a thickness exceeding 50 mm is used, or in order to support the finish of the field plate, that is, the roof, on the deck plate 12 in order to improve sound insulation and workability. In order to use a roof with a base material attached to a fireproof area or a semi-fireproof area, it is stipulated that it must be “approved by the Minister of Land, Infrastructure, Transport and Tourism”. It is necessary to obtain the Minister's certification after obtaining the evaluation.

  In addition, the fire resistance performance related to the Minister's approval of the roof fireproof structure is based on the provisions of Article 2, Item 7 of the Building Standards Act, and the “deflection performance test” of the roof is conducted by the designated performance evaluation organization. It is determined by the presence or absence of flame and other items.

  In Patent Document 1, as shown in FIG. 6, on a deck plate 16 fixed on a beam 15, a base plate 17 made of wood cement board, a heat insulating material 18 made of polyethylene foam, etc., and a waterproofing made of synthetic resin. A roof structure in which a waterproof material 19 made of a sheet or the like is fixed with screws 20 is disclosed. Hereinafter, this roof structure is referred to as a conventional roof structure.

JP-A-8-246609

  According to the above-described conventional roof structure, the base plate 17, the heat insulating material 18, and the waterproof material 19 are sequentially laminated on the deck plate 16, so that the insulating property and the waterproof property can be obtained without placing concrete on the deck plate 16. Although the fire resistance can be improved, there are the following problems.

  In general, the size of the base plate 17 and the heat insulating material 18 is the same (910 mm × 1820 mm), and the roof base plate 17 and the heat insulating material 18 are sequentially laid from the same reference point / reference line during roof construction. The positions of the butt joint of the field plate 17 and the butt joint of the heat insulating material 18 are aligned vertically.

  In addition, the field plate 17 is in close contact with the joint portion as much as possible so as not to transmit the indoor heat at the time of the fire to the upper part of the roof structure as much as possible, but is softened by the heat transmitted from the deck plate 16, It gradually carbonizes and shrinks from the lower surface of the field plate 17 and the butt surface of the field plate 17. As a result, the joint portion is gradually opened and heat is easily transmitted to the upper portion.

  In addition, the joint portion is more easily affected by heat by opening the joint portion, and softening, carbonization, and shrinkage proceed. The same applies to the heat insulating material 18.

  When the base plate 17 and the heat insulating material 18 are softened, carbonized, and contracted in this way and heat is transmitted to the upper part, the surface rigidity is lowered and the deflection of the roof increases, or the heat insulating material 18 reaches the ignition point. Fires and has a problem in terms of fire resistance of the roof.

  The ignition point of the heat insulating material 18 is about 350 ° C. for polyethylene, about 490 ° C. for polystyrene foam, about 410 ° C. for polyurethane foam, and about 510 ° C. for phenol foam.

  In addition, since the conventional roof structure is not an example specification of the Ministry of Construction Notification No. 1365 in 2000, it is necessary to check the fire resistance when using it in a fireproof area or semi-fireproof area. There is also a problem in the performance evaluation because it is a pass judgment item of the roof “fire resistance performance test” of the performance evaluation related to the Minister's approval of the fireproof structure of the roof.

  Therefore, since the object of the present invention is not an example specification of the Ministry of Construction Notification No. 1365 in 2000, it is necessary to check the fire resistance when used in a fire prevention area or a semi-fire prevention area. An object of the present invention is to provide a roof having a fireproof structure excellent in sound insulation and workability.

  The present invention has been made to achieve the above object, and is characterized by the following.

  The invention according to claim 1 is a roof structure in which a field plate, a heat insulating material, and a waterproof material are sequentially laminated on a deck plate fixed on a beam or a main roof, wherein the field plate is a hard wood cement board or It consists of a hard wood piece cement board, and the said heat insulating material is characterized by having thickness more than 50 mm.

  The invention according to claim 2 is characterized in that, in the invention according to claim 1, the positions of the butt joints of the base plate and the butt joints of the heat insulating material are vertically shifted.

  The invention according to claim 3 is characterized in that, in the invention according to claim 1 or 2, the surface of the butt joint of the field plate is lined with a metal tape such as an aluminum tape or a stainless steel tape. .

  The invention according to claim 4 is characterized in that, in the invention according to any one of claims 1 to 3, the "bulk density" of the hard wood wool cement board is 1.0 or more. It is.

  The invention according to claim 5 is the invention according to any one of claims 1 to 4, wherein the heat insulating material comprises an organic heat insulating board such as polyethylene foam, polystyrene foam, polyurethane foam or phenol foam. It has a feature in being.

  The invention according to claim 6 is the invention according to any one of claims 1 to 5, wherein the waterproof material is an asphalt waterproof method, an improved asphalt sheet waterproof method, a vinyl chloride resin sheet waterproof method, a rubber type It is characterized by comprising a sheet waterproof method or a coating film waterproof method.

  According to the present invention, by using a hard wood wool cement board as a field board, it is possible to improve fire resistance, heat insulation, sound insulation and workability, and the performance evaluation roof "fire resistance performance test" It is also effective in pass / fail judgment.

  Moreover, according to this invention, fire resistance, heat insulation, and sound insulation can be further improved by using a heat insulating material having a thickness of more than 50 mm.

  Further, according to the present invention, the fire resistance is improved by shifting the position of the joint joint of the base plate and the joint joint of the heat insulating material up and down, and it is also effective in the pass / fail judgment of the “fire resistance performance test” of the performance evaluation. It is.

It is a fragmentary sectional view which shows the roof structure of this invention. It is a fragmentary perspective view which shows the roof structure of this invention. It is a figure which shows the test result according to the "fireproof performance test" of the roof at the time of using a medium-sized wood wool cement board. It is a figure which shows the test result according to the "fireproof performance test" of the roof at the time of using a hard wood cement board. It is a fragmentary sectional view which shows an example of the present roof structure prescribed | regulated by Ministry of Construction Notification No. 1365 in 2000. It is a fragmentary sectional view which shows the conventional roof structure.

  One embodiment of the roof structure of the present invention will be described with reference to the drawings.

  FIG. 1 is a partial sectional view showing the roof structure of the present invention, and FIG. 2 is a partial perspective view showing the roof structure of the present invention.

  In FIG. 1 and FIG. 2, 1 is a beam or purlin made of steel materials such as shaped steel and steel pipes or wood-based material, 2 is a deck plate fixed on the purlin 1, 3 is on the deck plate 2 A base plate made of hard wood wool cement board, 4 is a heat insulating material provided on the base plate 3, 5 is a waterproof material provided on the heat insulating material 4, and 6 is a base plate 3 and a heat insulating material. 4 is a screw for fixing 4 on the deck plate 2. The screw 6 is screwed in via a fixed plate 7, and a waterproof material 5 is laid on the fixed plate 7.

  The heat insulating material 4 is made of an organic heat insulating board such as polyethylene foam, polystyrene foam, polyurethane foam, or phenol foam.

  The waterproof material 5 is made of an asphalt waterproofing method, an improved asphalt sheet waterproofing method, a vinyl chloride resin sheet waterproofing method, a rubber sheet waterproofing method, or a coating film waterproofing method.

  The effect by using a hard wood cement board as the field board 3 is demonstrated below.

  There are three types of wood wool cement board: ordinary wood wool cement board, medium wood wool cement board, and hard wood wool cement board (JIS A 5404 “woody cement board”). Many manufacturers make it 20% or less (when shipped). For this reason, the moisture content of a hard wood cement board with a large “bulk density” is the maximum among the three types.

  If hard wood wool cement board is used as a roofing base plate, the moisture content is high, so the temperature rise in the roof structure during a fire is delayed and the rate of temperature rise is suppressed. The temperature inside the roof can be lowered as compared with the case of using a medium quality, normal). For this reason, softening, carbonization, and shrinkage of the wood wool cement board can be delayed.

  In addition, the heat resistance of the roof can be suppressed by delaying the heat transfer to the top and suppressing the increase in roof deflection and the heat generation of the heat insulating material due to softening, carbonization, and shrinkage of the heat insulating material, resulting in reduced surface rigidity. Will improve. Furthermore, it is also effective in determining whether or not a fire evaluation test for a roof for performance evaluation is acceptable.

  Conducted tests according to the “fire resistance performance test” of the roof for the examples where the wood wool cement board of the roof structure is medium wood wool cement board and the example of hard wood wool cement board (Note: The temperature of the upper part of the wood wool cement board (interface between the wood wool cement board and the heat insulating material) was investigated. The results are shown in FIG. 3 and FIG.

  FIG. 3 is a diagram showing the results of a test according to the “fire resistance performance test” of a roof when a medium-sized wood wool cement board is used, and FIG. 4 is a diagram of the roof when a hard wood wool cement board is used. It is a figure which shows the result of the test according to a "fire resistance performance test".

  As is clear from FIG. 3 and FIG. 4, the time period (indicated by the arrow in the figure) in which the upper temperature of the wood wool cement board is maintained near 100 ° C. is longer in the roof structure using the hard wood wool cement board. Therefore, compared to the roof structure using medium wood wool cement board, the temperature rise after the time zone to maintain around 100 ° C is small, the maximum temperature is also low, and the risk of fire of the heat insulating material It can be seen that is significantly reduced.

  Here, it is clear that the time period in which the temperature of the upper part of the wood wool cement board is maintained at around 100 ° C. is caused by the dehydration process of the water (free water, combined water) contained in the wood wool cement board. The difference in the length of time seems to be caused by the water content of the wood wool cement board.

  Moreover, as a result of the test, the maximum deflection was 68.4 mm for the medium wood cement board and 21.3 mm for the hard wood cement board. This is 47.5% (= 68.4 mm / 144.4%) for medium wood wool cement board with respect to the judgment standard “maximum deflection amount prescribed value” used in the acceptance judgment of the “fire resistance performance test” of the roof. 0mm), and for hard wood wool cement board, it is 16.1% (= 21.3mm ÷ 132.25mm). By using hard wood wool cement board, the maximum deflection for the "maximum deflection amount specified value" is As can be seen from the figure, it is greatly reduced to about 1/3.

  3 and 4 show the elapsed time of the test according to the “fire resistance performance test”, the standard heating curve, the furnace temperature, and the transition of the temperature on the wood cement board. The temperature on the wood wool cement board is set near the center of the span of the specimen, and the thermocouples are installed at 6 places (3 deck plate mountain parts and 3 valley parts) avoiding the joint joint of the wood wool board. , Measured.

  The structure of the roof structure of FIG. 3 is a deck plate (span 2,400 mm), a wood wool cement board (medium), and a heat insulating material (thickness 60 mm).

  The structure of the roof structure of FIG. 4 is a deck plate (span 2,300 mm), a wood wool cement board (hard), and a heat insulating material (thickness 50 mm).

  Moreover, the sound insulation, workability | operativity, and the heat insulation performance can be aimed at by using the field board 3 as a hard wood wool cement board.

  Since the ability to block sound is higher as the mass (surface density) of the material is higher, the sound insulation performance is improved by increasing the thickness of the heat insulating material. Relatively small. On the other hand, the use of a wood cement board as the field board 3 improves the sound insulation. In addition, the hard wood wool cement board has the largest “bulk density” among the three wood wool cement boards (“bulk density”: hard 1.0 or more, medium quality 0.7 or more and less than 1.0, (Normally 0.4 or more and less than 0.7), the sound insulation performance is the best.

  Regarding the heat insulation performance, the thermal conductivity of the wood wool cement board is 0.13 W / mK for the hard wood wool cement board, 0.11 W / mK for the medium wood wool cement board, and 0. The hard wood wool cement board is inferior to the other two because it is 09 W / mK, but the thermal conductivity of gypsum board is 0.16 W / mK, and the thermal conductivity of ordinary concrete is 1.40 W. / MK, the heat insulation performance of the hard wood cement board is higher than these.

  Moreover, by using a hard wood wool cement board, since the stepping-out and cracking of the heat insulating material at the time of construction are eliminated, the workability can be improved. Instead of the hard wood wool cement board, a hard wood cement board having equivalent performance such as “bulk density” may be used.

  Next, the effect by shifting the position of the joint joint of the field board 3 and the joint joint of the heat insulating material 4 up and down is demonstrated below.

As shown in FIG. 2, when the butt joint of the base plate 3 and the butt joint of the heat insulating material 4 are shifted up and down, moisture such as water vapor (steam) generated in the process of dewatering the wood wool cement board by heat is insulated. It is possible to suppress the passage through the joints 4 and to the upper part. In some cases, the field plate 3 is burned, and even if smoke or flame is generated, they are prevented from blowing through the joints. can do. (Expansion of joint gap due to thermal deformation is considered.)
In addition, since the joint positions are shifted up and down, moisture tends to stay on the lower surface of the heat insulating material 4 (between the heat insulating material 4 and the deck plate 2), and the temperature on the upper surface of the wood wool cement board is 100. The time zone for maintaining the vicinity of ° C. can be made longer.

  Instead of shifting the butt joint of the base plate 3 and the butt joint of the heat insulating material 4 up and down, a highly sensitive metal tape such as aluminum tape or stainless steel tape is used on the butt joint of the base plate 3. In order to suppress water vapor, a weathering method may be used.

  Of course, a more reliable effect can be expected if the positions of the butt joints of the base plate 3 and the butt joints of the heat insulating material 4 are shifted up and down, and then glazed with the metal tape or the like.

  Moreover, although the heat insulating material 4 shown in FIG. 1 is an application example of 1 sheet, it is not limited to this, A plurality of sheets may be piled up and a higher heat insulating property may be given. In this case, it is desirable that the joint positions of the upper and lower heat insulating materials are shifted from each other, but the same positions may be used.

  If the heat insulating material 4 is a heat insulating material with a face material (aluminum foil or the like), it is even better because it further improves the water vapor shielding property.

  Next, on the deck plate, the position where the wood cement plate is joined to the deck plate with screws 6 'alone, both for preventing the wood cement plate from slipping and improving the shrinkage of the wood cement plate due to heat. It may be provided (see FIG. 1).

  Because of this, the heat transfer to the upper part is delayed, and it is possible to suppress an increase in the deflection of the roof and the ignition of the heat insulation board due to softening, carbonization and contraction of the heat insulating material 4 to reduce the surface rigidity. Will improve. Furthermore, it is also effective in the pass / fail judgment of the “fire resistance performance test” of the roof for performance evaluation.

  As described above, according to the present invention, since it is not an example specification of the Ministry of Construction Notification No. 1365 in 2000, when used in a fireproof area or a semi-fireproof area, it is necessary to check the fireproof performance. Since the thickness of the material can exceed 50 mm, fire resistance, heat insulation, sound insulation and workability can be further improved, and it is also effective in pass / fail judgment of the “fire resistance performance test” of the roof for performance evaluation It is.

  Moreover, according to this invention, fire resistance, heat insulation, and sound insulation can be further improved by using the heat insulating material 4 having a thickness of more than 50 mm.

  Further, according to the present invention, the fire resistance is improved by shifting the butt joint of the base plate 3 and the butt joint of the heat insulating material 4 up and down, and the “fire resistance test” of the roof for performance evaluation is accepted or rejected. It is also effective in determination.

1: Beam or purlin 2: Deck plate 3: Field plate 4: Thermal insulation material 5: Waterproof material 6, 6 ': Screw 7: Fixed plate 11: Beam or purlin 12: Deck plate 13: Thermal insulation material 14: Waterproof material 15: Beam or beam 16: Deck plate 17: Base plate 18: Heat insulation material 19: Waterproof material 20: Screw

Claims (6)

In the roof structure where field boards, heat insulating materials and waterproofing materials are sequentially laminated on the deck plate fixed on the beam or main roof,
The roof structure is characterized in that the field board is made of hard wood wool cement board or hard wood piece cement board, and the heat insulating material has a thickness of more than 50 mm.   The roof structure according to claim 1, wherein a position of the butt joint of the field board and the butt joint of the heat insulating material is shifted up and down.   The roof structure according to claim 1, wherein the roof plate is lined with a metal tape such as an aluminum tape or a stainless steel tape on a butt joint of the base plate.   The roof structure according to any one of claims 1 to 3, wherein a bulk density of the hard wood wool cement board is 1.0 or more.   The roof structure according to any one of claims 1 to 4, wherein the heat insulating material is formed of an organic heat insulating board such as polyethylene foam, polystyrene foam, polyurethane foam, or phenol foam.   The waterproof material comprises an asphalt waterproofing method, an improved asphalt sheet waterproofing method, a vinyl chloride resin sheet waterproofing method, a rubber sheet waterproofing method, or a coating film waterproofing method. The roof structure according to any one of 1 to 5.