JP2007056513A - Floor slab structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a floor slab structure capable of exhibiting sufficient floor impact sound cut-off performance without causing structural demerits. <P>SOLUTION: The structure of a floor slab 1 supported by vibration restraining members 11 comprises a non-restrained floor slab part 12 located at a distance exceeding the half wavelength of bending wave in the floor slab to the impact frequency of a predetermined floor impact sound impact source, from the closest vibration restraining member, and a stepped part provided in the non-restrained floor slab part. The stepped part includes the non-restrained floor slab part at a distance within the half wavelength of the bending wave. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a floor slab structure capable of exhibiting sufficient floor impact sound insulation performance without causing structural disadvantages.

  Conventionally, for example, a technique disclosed in Patent Document 1 is known as a technique related to a floor slab structure of a building.

Patent Document 1 is provided with a step portion by a beam portion of a full precast structure integrally on the lower half precast plate at the position of the boundary between the upper half precast plate and the lower half precast plate continuous thereto, The floor slab structure is characterized in that the upper surface of the stepped portion protrudes upward from the upper half precast plate.
Japanese Patent No. 3481190

  By the way, hitherto, importance has been given to the performance of blocking floor impact noise in buildings. Among floor impact sounds, for example, heavy floor impact sound that occurs when a heavy object falls or moves on the floor slab, such as a child jumping or running around, is used as an impact source (input of impact vibration). The blocking performance is influenced by the influence of the vibration restraining member such as. Specifically, when every part in the floor slab is close to a vibration restraining member such as a structural beam or a bearing wall, the floor impact sound blocking performance of the floor slab is relatively good. . However, if there is a part in the floor slab that is located at a distance from the vibration restraining member such as a beam, the part cannot obtain the restraint property of the impact vibration by the vibration restraining member. In many cases, sufficient blocking performance is not obtained. Recently, there are an increasing number of buildings built using relatively large span floor slabs, such as buildings with a center core type or an out-frame construction method. In such buildings, in particular, vibration restraining members such as beams are used. Since there is a portion in the floor slab located at a distance from the floor, the floor impact sound cannot be effectively blocked. Therefore, in the case of such a building, the floor impact sound insulation performance is usually secured by increasing the thickness dimension of the floor slab. However, as the thickness of the floor slab increases, the weight of the floor slab increases. Therefore, it is necessary to increase the size of the pillars to support the weight, resulting in an increase in the load on the entire building. The demerit of was great.

The present invention has been devised in view of the above-described conventional problems, and provides a floor slab structure capable of exhibiting sufficient floor impact sound insulation performance without causing structural disadvantages.
The purpose is to provide.

  The floor slab structure according to the present invention is a structure of a floor slab supported by a vibration restraining member, and a half of a bending wave in the floor slab with respect to an impact frequency of a predetermined floor impact sound impact source from the nearest vibration restraining member. An unconstrained floor slab portion located at a distance exceeding the wavelength, and a step portion provided in the unconstrained floor slab portion, the step portion being located at a distance within half a wavelength of the bending wave. It is characterized by including.

  Moreover, the recessed part dividedly formed in the said floor slab by the said level | step-difference part is utilized as a watering part.

  Further, the stepped portion has at least a stepped portion reinforcing bar for firmly connecting the stepped portion with the unconstrained floor slab portion adjacent to the stepped portion, and for reinforcing the shear rigidity of the stepped portion. A shear reinforcement bar and a connecting bar that connects the shear reinforcement bars are embedded.

  In the floor slab structure according to the present invention, it is possible to exhibit a sufficient floor impact sound blocking performance without causing a structural disadvantage.

  Hereinafter, preferred embodiments of a floor slab structure according to the present invention will be described in detail with reference to the accompanying drawings. A floor slab structure 1 of the present embodiment (hereinafter also simply referred to as a floor slab 1) is a structure of a floor slab supported by a vibration restraining member. The vibration restraint member acts as a fixed end with respect to a floor slab as a medium that transmits vibration, such as structural beams such as large beams and small beams, and bearing walls. A member restrained in the vicinity. The degree to which the vibration generated in the floor slab is restrained by the vibration restraining member (hereinafter referred to as vibration restraining property) is related to the distance from the vibration restraining member, and the vibration restraining property is generally higher in the vicinity of the vibration succeeding member. More specifically, the vibration restraint is related to the wavelength λb of the bending wave (transverse wave) propagating through the floor slab.

The wavelength λb of the bending wave is calculated by the following equation (1). As can be seen from Equation (1), the wavelength λb of the bending wave differs depending on the impact frequency f of the impact vibration input (hereinafter also referred to as excitation force) of the floor impact sound impact source applied to the floor slab. The impact frequency is the reciprocal (unit: Hz) of the numerical value obtained by doubling the impact time. As can be seen from the equation (1), the wavelength λb of the bending wave varies depending on the attributes of the floor slab, such as Young's modulus, density, and equivalent thickness of the floor slab. The equivalent thickness of the floor slab is obtained by converting a void slab or the like into a uniform single plate floor slab based on a uniform single plate floor slab of ordinary concrete.

図１〜図５は、振動拘束部材などの振動拘束性の実際を調べるために発明者が行った実験である。この実験に使用された鉄筋コンクリート構造の実大規模の試験体２は、２階建てであり、図１にその２階部分の平面図を示している。２階部分の床を構成する床版３は、約９５００ｍｍ×２１０００ｍｍの平面寸法、および等価厚さ２７４ｍｍ（実厚３００ｍｍの矩形ボイドスラブ）を有し、長辺方向に沿う両端部にのみ大梁４が形成された一方向版である。各大梁４の下方にはそれぞれ柱５が４箇所設けられており、当該２階部分の床版３を支持している。床版３の梁間方向の約６：４の位置には、長辺方向と平行に設けられた段差部６が設けられている。２階部分には柱などは設けられておらず、床版３のみから構成されている。

1 to 5 are experiments conducted by the inventor in order to examine the actual vibration restraint property of a vibration restraining member or the like. A full-scale specimen 2 of a reinforced concrete structure used in this experiment has a two-story structure, and FIG. 1 shows a plan view of the second-story part. The floor slab 3 constituting the floor of the second floor part has a plane size of about 9500 mm × 21000 mm and an equivalent thickness of 274 mm (rectangular void slab having an actual thickness of 300 mm). It is a formed one-way version. Four pillars 5 are provided below each of the large beams 4 to support the floor slab 3 of the second floor portion. At a position of about 6: 4 in the inter-beam direction of the floor slab 3, a step portion 6 provided in parallel with the long side direction is provided. The second floor portion is not provided with pillars and the like, and is composed only of the floor slab 3.

  By substituting numerical values such as Young's modulus, density, equivalent thickness, etc., of the floor slab 3 used in this experiment into the above equation (1) and determining the wavelength λb of the bending wave, the impact frequency f = 250 Hz. In the case of the excitation force of, the wavelength of the bending wave is λb = 2.63 m, and in the case of the excitation force of the impact frequency f = 25 Hz, which is an example of the “heavy floor impact sound” generated by the drop of the larger mass. The wavelength of the bending wave is λb = 8.18 m. For example, in the case of a bang machine that is an impact source of heavy floor impact sound as defined in JIS A 1418-2000 “Measurement method of floor impact sound insulation performance of buildings Part 2: Method by standard weight impact source” Since the impact frequency is f = 25 Hz, the wavelength of the bending wave is λb = 8.18 m.

In this experiment, an excitation force is input by an impulse hammer 7 having an impact frequency f = 250 Hz, vibrations transmitted to the floor slab 3 are picked up by a vibration pickup 8, and the data is used for analysis via a charge amplifier 9. Sent to the personal computer 10. Such vibration measurement was performed on a plurality of survey lines shown in FIG. The survey lines 1-1 to 1-5 and the survey lines 2-6 to 2-10 are the survey lines having the end of the large beam 4, the survey lines 1-6 to 1-10, and the survey lines 2-1 to 2 Up to −5 is a survey line with the stepped portion 6 as an end. Table 1 shows the distance from the end of the measurement point on each survey line.

本実験においては、振動拘束性を調べるために、インパルスハンマー７で加振したときのハンマー加振力の衝撃力波形Ｆ（ｔ）（単位：Ｎ）と振動速度波形Ｖ（ｔ）（単位：ｍ／ｓ）とから、インピーダンス、具体的にはインパルスハンマー７の衝撃時間（衝撃波形の立ち上がりから最初のゼロクロスまでの時間、単位：ｓ）内の応答に着目した衝撃時間内応答インピーダンス（以下、衝撃インピーダンスという）を求めた。具体的には衝撃インピーダンスＺｂは以下の式（２）で示されるように、インパルスハンマー７の衝撃時間内で、衝撃力Ｆ（ｔ）の二乗を積分した値と、振動速度Ｖ（ｔ）の二乗を積分した値との比をとることにより求めた。さらに、衝撃インピーダンスレベル（単位：ｄＢ）を、１０（ｌｏｇ₁₀Ｚｂ）として求めた。

In this experiment, in order to investigate the vibration restraint property, the impact force waveform F (t) (unit: N) and the vibration velocity waveform V (t) (unit: N) of the hammer excitation force when the impulse hammer 7 is vibrated. m / s), specifically, the impedance within the impact time (hereinafter, referred to as the response within the impact time of the impulse hammer 7 (time from the rise of the impact waveform to the first zero cross, unit: s). Called impact impedance). Specifically, the impact impedance Zb is obtained by integrating the square of the impact force F (t) within the impact time of the impulse hammer 7 and the vibration velocity V (t) as shown by the following equation (2). It was obtained by taking the ratio with the value obtained by integrating the square. Further, the impact impedance level (unit: dB) was determined as 10 (log ₁₀ Zb).

衝撃インピーダンスレベルの計算結果を図３、図４に示している。図３は端部が大梁４の各測線、図４は端部が段差部６の各測線についてまとめたものである。端部からの距離Ｘが、曲げ波の１波長＝１λｂ以上離れると、梁による振動拘束性は得られない、すなわち無限に大きい床版における衝撃インピーダンスと同程度の値となることが既に知られている。この無限大版衝撃インピーダンスは計算により求めることができる。図３、図４における横軸は、端部からの距離Ｘを、インパルスハンマー７の衝撃周波数に対する当該床版３における曲げ波の１波長＝１λｂを単位として（すなわち、Ｘ／λｂの値を）対数座標で示している。図３、図４における縦軸は、１λｂ離れた測定点における衝撃インピーダンスレベルを基準とした相対的な上昇量を示している。ある位置において衝撃インピーダンスレベルが上昇しているということは、その位置において大梁４や段差部６による振動拘束性が得られていることを示している。

The calculation results of the impact impedance level are shown in FIGS. FIG. 3 summarizes each survey line whose end is the beam 4, and FIG. 4 summarizes each survey line whose end is the stepped portion 6. It is already known that if the distance X from the edge is more than 1 wavelength of the bending wave = 1λb or more, vibration restraint by the beam cannot be obtained, that is, the value is equivalent to the impact impedance in an infinitely large slab. ing. This infinite plate impact impedance can be obtained by calculation. 3 and 4, the horizontal axis represents the distance X from the end in units of 1 wavelength = 1λb of the bending wave in the floor slab 3 with respect to the impact frequency of the impulse hammer 7 (that is, the value of X / λb). Logarithmic coordinates are shown. The vertical axis in FIGS. 3 and 4 indicates the relative amount of increase based on the impact impedance level at measurement points separated by 1λb. The fact that the impact impedance level is rising at a certain position indicates that vibration restraint by the large beam 4 or the stepped portion 6 is obtained at that position.

  As a conclusion of this experiment, even in the case where the end is the girder 4 or in the case of the stepped portion 6, the portion in the floor slab 3 up to a distance of about 0.5λb from the end (hereinafter referred to as the floor slab portion). ), Vibration restraint is obtained. This indicates that the stepped portion provided on the floor slab can be handled in the same manner as a vibration restraining member such as a structural beam or a load bearing wall. In both the case of the step portion and the vibration restraining member, the floor slab portion located at a distance exceeding 0.5λb from the step portion or the vibration restraining member is a floor slab portion that cannot obtain sufficient vibration restraint. It is shown that. If there is a floor slab portion in the floor slab where vibration restraint cannot be obtained from either the stepped portion or the vibration restraining member, the floor impact sound is not effectively blocked by the floor slab. Further, according to the result of this experiment, the vibration restraint property by the step portion 6 is smaller than the vibration restraint property by the large beam 4, and is, for example, about 2/3 at a position where the distance from the end portion is 0.1λb. .

  FIG. 5 shows a distribution example of the impact impedance level in the cross section between the beams of the floor slab 3 in this experiment. It is the graph which connected together the survey line 1-4 in FIG. 1, the survey line 1-9, the survey line 2-4, and the survey line 2-9. As can be seen from FIG. 5, in the vicinity of the stepped portion 6, the impact impedance rises if not as much as the large beam 4.

  From the result of the above experiment, the floor slab structure 1 according to the first embodiment has the impact frequency of a predetermined floor impact sound impact source from the large beam 11 which is the nearest vibration restraining member as shown in FIGS. An unconstrained floor slab portion 12 located at a distance exceeding 0.5λb of a bending wave half wavelength (hereinafter simply referred to as a half wavelength of the bending wave) in the floor slab 1 with respect to f, and provided in the unconstrained floor slab portion 12 The step portion 13 includes the unconstrained floor slab portion 12 at a distance within a half wavelength 0.5λb of the bending wave. Here, the “predetermined” floor impact sound impact source is, for example, a floor impact sound impact that is assumed in designing the floor slab structure or in predicting the floor impact sound cutoff performance as a previous step. Refers to the source. Alternatively, a floor impact sound impact source specified in the technical standard, for example, JIS A 1418-2000 “Measurement method of floor impact sound insulation performance of buildings Part 2: Method using standard weight impact source” is described. An impact source such as a bang machine specified as an impact source of the above may be adopted.

  More specifically, in the floor slab structure 1 of the present embodiment, a step portion 13 is formed in the vicinity of the center in the inter-beam direction substantially in parallel with the large beams 11 located at both ends of the floor slab 1. The step portion 13 is formed over the entire dimension of the floor slab 1 in the long side direction. The distance from each large beam 11 to the step portion 13 is longer than the half wavelength 0.5λb of the bending wave and slightly shorter than one wavelength λb. Therefore, the portion where the distance from the large beam 11 exceeds the half wavelength 0.5λb of the bending wave, that is, the unconstrained floor slab portion 12 located on both sides including the step portion 13 is the dimension between the beams (step (Except for the portion 13) is slightly shorter than one wavelength of the bending wave of 1.0λb. Of the floor slab 1, a portion located within a half-wavelength 0.5λb of the bending wave from the stepped portion 13 can obtain vibration restraint by the stepped portion 13, so that the vicinity of the intermediate position between the stepped portion 13 and the two large beams 11 is obtained. In FIG. 4, there are some overlapping portions 14 where vibration restraint by the beam 11 and vibration restraint by the step portion 13 can be obtained. Such an overlapping portion 14 is not necessarily essential, but by providing the overlapping portion 14, a floor slab portion that can obtain vibration restraint by the beam 11 and a floor slab portion that can obtain vibration restraint by the step portion 13 are provided. , It can be reliably overlapped without gaps.

  The floor slab 1 having the structure as described above is divided into an upper floor slab 1a and a lower floor slab 1b with the stepped portion 13 as a boundary, and the lower floor slab 1b is provided at an end portion thereof. A recess 15 surrounded by the large beam 11 and the stepped portion 13 is formed.

  According to the floor slab structure 1 as in the present embodiment, when an impact waveform having a certain impact frequency is input from a predetermined floor impact sound impact source, the vibration is generated from the bending beam of the floor impact sound from each large beam 11. The floor slab portion located within a half wavelength 0.5λb is sufficiently restrained by the vibration restraint property of each large beam 11, and each unconstrained floor slab portion 12 adjacent to both sides except the step portion 13 is Since it is located within the wavelength 0.5λb of the bending wave from the step portion 13, it is effectively restrained by the vibration restraint property of the step portion 13. In addition, with respect to the overlapping portion 14 described above, vibration restraint can be obtained from both the large beam 11 and the stepped portion 13. As a result, the floor impact sound is effectively blocked in the floor slab having the floor slab structure 1 of the present embodiment.

  FIG. 8 shows the stepped portion 13 and the structure in the vicinity thereof. First, the step portion 13 in the floor slab structure 1 of the present embodiment is not a structure in which both ends thereof are joined to a structural member such as a column or a beam to transmit a load to the structural member, and the main beam of the beam is also not included. It is not constructed as a beam because it is not laid.

  More specifically, each unconstrained floor slab portion 12 adjacent to both sides of the stepped portion 13, that is, the upper unconstrained floor slab portion 12 a and the lower unconstrained floor slab portion 12 b are flat at both ends. They are abutted so that they are in contact with each other, and both parts are joined by placing concrete reinforcements on both sides and placing concrete. At that time, at the end of the lower unconstrained floor slab portion 12b, the lower surface coincides with the lower surface of the lower unconstrained floor slab portion 12b, and the upper surface is flush with the upper surface of the upper unconstrained floor slab portion 12a. A stepped portion 13 formed in this way is formed. Both the upper unconstrained floor slab portion 12a and the lower unconstrained floor slab portion 12b are formed using a half precast plate in which truss bars 16 are arranged in the beam-to-beam direction. The truss bar 16 is configured by combining a quadrangular pyramid lattice bar 16c between an upper end force distribution bar 16a and a lower end force distribution bar 16b extending in the inter-beam direction. Moreover, the lower end main reinforcement which makes the lower main reinforcement of each upper and lower floor slab 1a, 1b is arrange | positioned along the said lower end distribution reinforcement 16b in the vicinity of the lower end distribution reinforcement 16b.

  The bar arrangement structure of the stepped portion 13 includes at least stepped portion reinforcing bars 17a and 17b for firmly connecting the unconstrained floor slab portion 12 adjacent to the stepped portion 13 and the stepped portion 13, and the shear rigidity of the stepped portion 13. Shear reinforcing bars 18a and 18b for reinforcing the reinforcing bars and connecting bars 19 that connect the shear reinforcing bars 18a and 18b are embedded.

  The stepped portion reinforcing bars 17a and 17b include a first stepped portion reinforcing bar 17a for firmly connecting the upper unconstrained floor slab portion 12a and the stepped portion 13, and a lower unconstrained floor slab portion 12b and the stepped portion 13 respectively. And a second stepped portion reinforcing bar 17b for firmly connecting the two. The first stepped portion reinforcing bar 17a is obliquely raised from below in the stepped portion 13 and protrudes into the truss bar 16 of the upper unconstrained floor slab portion 12a along the longitudinal direction of the truss bar 16. Is provided. The second stepped portion reinforcing bar 17b is obliquely lowered from above in the stepped portion 13 so as to be along the longitudinal direction of the truss bar 16 just above the truss bar 16 of the lower unconstrained floor slab portion 12b. It is provided to protrude. The bar arrangement of the second stepped portion reinforcing bar 17b along the truss bar 16 is also configured as an upper main bar of the lower unconstrained floor slab portion 12b (lower floor slab 1b).

  The shear reinforcement bars 18a and 18b include an upper shear reinforcement bar 18a and a lower shear reinforcement bar 18b. The upper shear reinforcement 18a extends from the upper unconfined floor slab portion 12a in the vicinity of the upper surface, just above the truss bar 16 and along the longitudinal direction of the truss bar 16 to the inside of the step part 13. The first vertical end surface 13a of the stepped portion 13, that is, the stepped portion 13 is bent and lowered near the vertical end surface far from the upper unconstrained floor slab portion 12a to the vicinity of the upper surface of the lower half precast plate. Has reached. The bar arrangement of the upper shear reinforcing bar 18a along the truss bar 16 of the upper unconstrained floor slab portion 12a is also used as the upper main bar of the upper unconstrained floor slab portion 12a (upper floor slab 1a). It is configured. At the corner where the upper shear reinforcing bar 18a is bent near the first vertical end face 13a, a connecting bar 19 for connecting the upper shear reinforcing bar 18a to each other is disposed. The lower shear reinforcement bar 18b extends the bar arrangement that protrudes along the longitudinal direction of the truss bar 16 into the truss bar 16 of the lower unconstrained floor slab part 12b. The second vertical end surface 13b, that is, the stepped portion 13 is bent and raised near the vertical end surface far from the lower unconstrained floor slab portion 12b and reaches the vicinity of the upper surface of the stepped portion 13. The tip of the upper shear reinforcement 18a reaching the upper surface of the lower half precast plate is joined to the lower shear reinforcement 18b, and both shear reinforcements are integrated.

  In recent housing, etc., in order to provide a horizontal piping space on the floor slab of the water supply area such as a bathroom due to a request for barrier-free, a step between the room side and the water supply part (hereinafter referred to as a water supply step) ) Is often used. In the floor slab structure 1 of the present embodiment, the recess 15 defined by the large beam 11 and the stepped portion 13 is used as it is as the water circulation portion, so that the water circulation level difference is the level difference in the floor slab structure 1 of the present embodiment. It can be used as part 13.

  9 and 10 show an example in which the floor slab structure 1 of this embodiment is applied to an actual building B. FIG. This building B is a so-called center core type building, and vertical structural members such as columns and load-bearing walls are concentrated in the vicinity of the central portion and the outer peripheral portion of the floor. A floor slab 1 having the floor slab structure 1 of the embodiment is annularly arranged along the circumferential direction of the building. FIG. 10 is a longitudinal sectional view showing one of the floor slabs 1 arranged in an annular shape, and shows a sectional view taken along line AA across the room R shown in FIG. The large beams 11 provided at both ends of the floor slab 1 and the step portions 13 provided near the center of the floor slab 1 are arranged so as to be connected in a ring shape along the circumferential direction of the building. Therefore, also in this application example, the stepped portion 13 is not structured to be bonded to a structural member such as a column or a beam to transmit a load to the structural member, and the beam main bar is not arranged. From the point of view, it is not constructed as a beam. Moreover, in this application example, the recess 15 formed on the floor side of the floor slab in each room from the stepped portion 13 to the center portion side can be used as it is as a water supply portion.

  As described above, in the floor slab structure 1 according to the present embodiment, the floor slab structure 1 is supported by the large beam 11 that is a vibration restraining member, and the vibration from the nearest vibration restraining member 11 to the impact frequency of a predetermined floor impact sound impact source. The floor slab 1 includes an unconstrained floor slab portion 12 positioned at a distance exceeding the half wavelength 0.5λb of the bending wave, and a step portion 13 provided in the unconstrained floor slab portion 12, Since the unconstrained floor slab portion 12 is included in a distance within a half wavelength 0.5λb of the bending wave, all portions of the floor slab 1 can obtain vibration restraint by the large beam 11 or the stepped portion 13. As a result, sufficient floor impact sound insulation performance is exhibited without causing structural disadvantages such as increasing the thickness of the floor slab 1.

  Further, if the recess 15 defined in the floor slab by the step portion 13 is used as the water portion, the water step that is frequently provided in modern buildings from the request for barrier-free, etc. It can utilize as the level | step-difference part 13 for obtaining the vibration restraint property in the floor slab structure 1 of this embodiment. In that case, since it is not necessary to construct the step part 13 in particular, the construction cost can be reduced, the work can be omitted, and the design flexibility can be improved.

  Further, at least the unconstrained floor slab portion 12 adjacent to the stepped portion 13 and the stepped portion reinforcing bars 17a and 17b for firmly connecting the stepped portion 13 to the stepped portion 13 and the shear rigidity of the stepped portion 13 are provided. Since the shear reinforcement bars 18a and 18b for reinforcing the reinforcement and the connecting reinforcement 19 connecting the shear reinforcement bars 18a and 18b are embedded and constructed, the step portion 13 is constructed as a beam structure. As a result, construction costs can be reduced and work can be omitted, which is advantageous.

  Below, each modification of the floor slab structure concerning this invention is shown. FIG. 11 shows a second embodiment of the floor slab structure 1 according to the present invention. The same components as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted. In the present embodiment, beams 20 and 21 that are vibration restraining members are provided at the four ends of the floor slab 1. The two beams 20 provided at both ends along the short side direction are referred to as a first beam 20, and the two beams 21 provided at both ends along the long side direction are referred to as a second beam 21. To. Three step portions 22, 23, and 24 are constructed so as to divide the long side direction of the floor slab 1 into four. Each of the step portions 22, 23, 24 is formed in parallel with the short side direction of the floor slab 1. Of the three step portions 22, 23 and 24, the one located at the center is referred to as the first step portion 22, and the one located on both sides thereof is referred to as the second step portion 23 and the third step portion 24. The vertical cross-sectional shape of the floor slab 1 may be, for example, arranged so that the upper floor slab 1a and the lower floor slab 1b are staggered as shown in FIG. As shown in c), the step portions 22, 23, and 24 may be formed so as to descend from one first beam 20 to the other first beam 20.

  In the present embodiment, vibration restraint from each first beam is not obtained in the floor slab portion located at a distance exceeding the half wavelength 0.5λb of the bending wave from each first beam 20. However, the portion of the floor slab located in the vicinity of each second beam 21, that is, at a distance within the half wavelength 0.5λb of the bending wave from each second beam 21, is vibration restraint from each second beam 21. Is obtained. Therefore, the floor slab portion located at a distance exceeding the half wavelength 0.5λb of the bending wave from the central portion of the floor slab 1, each of the first beams 20 and the second beams 21 is an unconstrained floor slab portion 12. . Three step portions 22, 23, and 24 are provided so that the entire area of the unconstrained floor slab portion 12 is included in a distance within one half wavelength 0.5λb of the bending wave from any of the step portions 22, 23, 24. It has been.

  Speaking about the long side direction of the floor slab 1, in short, when the vibration restraining members 20 adjacent to each other are separated from each other by one or more bending waves of one wavelength of 1.0λb as in this embodiment, the vibration restraining members 20 In addition, the distance between the stepped portions 22, 23, 24 adjacent to each other and the distance between the stepped portions 22, 24 at both ends and each vibration restraining member 20 are all within one wavelength of 1.0λb of the bending wave. Step portions 22, 23, and 24 may be provided as appropriate. By doing so, all floor slab portions can obtain vibration restraint by the vibration restraining member 20 or any one of the step portions 22, 23, 24. In the case of the present embodiment, as described above, all the portions of the floor slab 1 have vibration restraint properties by the first beams 20 and the step portions 22, 23, 24. Since each second beam 21 is also provided at the end, the floor slab portion 1c adjacent to both each second beam 21 and each first beam 20, or each step with each second beam 21 The floor slab portions (not shown) that are close to both the portions 22, 23, and 24 are portions where vibration restraints from beams and stepped portions are overlapped.

  Even in the second embodiment, it is needless to say that the same effects as those of the first embodiment can be obtained.

  FIG. 12 shows a third embodiment of a floor slab structure according to the present invention. Constituent elements that are the same as those in the above embodiments are given the same reference numerals, and descriptions thereof are omitted. In this embodiment, two beams provided at both ends along the short side direction of the floor slab 1 are provided at the third beam 25 and at one end thereof along the long side direction. One beam will be referred to as a fourth beam 26. In the vicinity of the center of the floor slab 1, one step portion 27 is constructed along the long side direction. The vertical cross-sectional shape of the floor slab 1 is, for example, as shown in FIG. 12B, the floor slab portion on the side close to the fourth beam 26 with the step portion 27 as a boundary is the upper step portion 1a, and the opposite side is the lower step portion 1b. Alternatively, as shown in FIG. 12 (c), the floor slab part far from the fourth beam 26 may be the upper step part 1a and the opposite side may be the lower step part 1b.

  In the floor slab 1, the floor slab portion located at a distance exceeding the half wavelength 0.5λb of the bending wave from each third beam 25 and the fourth beam 26 is an unconstrained floor slab portion 12. A stepped portion 27 is provided so as to include the entire area of the unconstrained floor slab portion 12 within a distance within a half wavelength 0.5λb of the bending wave. Accordingly, the distance from the stepped portion 27 to the end portion of the floor slab 1 where the beams 25 and 26 are not provided is within a half wavelength 0.5λb of the bending wave. In the case of the present embodiment, the floor slab portion adjacent to both the third beam 25 and the fourth beam 26 and the floor slab portion adjacent to both the third beam 25 and the stepped portion are It is a portion (both not shown) where the vibration restraint properties from both are obtained in an overlapping manner.

  Even in the third embodiment, it is a matter of course that the same effects as those of the above-described embodiments can be obtained.

  FIG. 13 shows a fourth embodiment of a floor slab structure according to the present invention. Constituent elements that are the same as those in the above embodiments are given the same reference numerals, and descriptions thereof are omitted. In the third embodiment, both end portions of the step portion 27 are connected to each third beam 25, and the vicinity of both end portions of the step portion 27 vibrates from both the third beam 25 and the step portion 27. In the present embodiment, both ends of the stepped portion 28 are separated from the third beams 25 so that such overlapping portions can be reduced. The step portion 28 is formed in a U-shape by bending from both ends to the end of the floor slab 1 where the beams 25 and 26 are not provided. Other configurations are the same as those of the third embodiment. Also in this embodiment, the entire area of the unconstrained floor slab portion 12 is located at a distance within a half wavelength 0.5λb of the bending wave from the step portion 28.

  Even in the fourth embodiment, it is a matter of course that the same operational effects as those of the above-described embodiments can be obtained.

  Next, the test conducted by the present inventor in order to verify the vibration restraint property of the step portion will be described in detail. The actual large-scale test body 29 is a two-story reinforced concrete structure similar to the above embodiment, and a plan view thereof is shown in FIG. The floor slab 30 constituting the floor of the second floor portion has a plane size of about 9500 mm × 21000 mm and an equivalent thickness of 274 mm (a rectangular void slab having an actual thickness of 300 mm), and the large beams 31 are formed only at both ends in the long side direction. It is a one way version. Four pillars 32 are provided below each of the large beams 31 to support the floor slab 30 of the second floor portion. A step portion 33 is provided at a position of about 6: 4 in the beam-to-beam direction of the floor slab 30. The second floor portion is not provided with pillars or the like, and is composed only of the floor slab 30.

  The lower floor of the floor slab, that is, the space on the first floor is partitioned as shown in FIG. 14 to form a room A, a room B, and a room C, and floor impact sound using heavy floor impact sound as an impact source in each room. The level (unit: dB) was measured. Specifically, it was performed in accordance with JIS A 1418-2000 “Measurement method of floor impact sound insulation performance of buildings Part 2: Method using standard weight impact source”.

  The A room and the B room are rooms that are in contact with the beam 31 and are rooms in which vibration restraint by the beam 31 can be expected. On the other hand, the C chamber is located away from the beam 31 and close to the stepped portion 33. In the compartments of the A and B chambers, the outer wall portion is sprayed with urethane on an ALC plate of 100 mm, and no gypsum board for finishing is provided. The partition is a double wall of 12.5mm gypsum board. As for C room, all four walls are formed by double walls of 12.5mm gypsum board.

  According to the conventional floor impact sound prediction method that does not consider the vibration restraint due to the stepped portion 33, the room A and the room B have a heavy floor impact sound blocking performance of Lr-50, but the room C is 1 less than that. Lr-55 below the rating. However, the measurement result of this test was Lr-50 in each of the A, B, and C chambers as shown in FIG. In particular, looking at the band of 63 Hz that is the determination frequency of the grade in this test, the room with the highest shut-off performance is room B, but the room with the next highest shut-off performance is room C. It shows that the vibration restraint property of 33 contributes effectively to the floor impact sound insulation performance.

It is a top view of the test body in the experiment for investigating the vibration restraint property of the floor slab structure concerning this invention. It is explanatory drawing which shows the measuring method of the experiment of FIG. It is a graph which shows the result of the experiment of FIG. It is a graph which shows the result in case the edge part of the experiment of FIG. 1 is a level | step difference part. It is a graph which shows distribution of the impact impedance level in a certain cross section of the experiment of FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory plan view showing a first embodiment of a floor slab structure according to the present invention. It is a longitudinal cross-sectional view of the floor slab structure of FIG. It is a principal part expanded sectional view which shows the level | step-difference part vicinity of the floor slab structure of FIG. It is a top view which shows the example of application of the floor slab structure of FIG. It is a longitudinal cross-sectional view by the AA line of the application example of FIG. It is a figure showing (a) a top view showing a 2nd embodiment of a floor slab structure concerning the present invention, (b) an example of a longitudinal section, and (c) another example of a longitudinal section. It is a figure showing (a) a top view showing a 3rd embodiment of a floor slab structure concerning the present invention, (b) an example of a longitudinal section, and (c) another example of a longitudinal section. It is a figure showing (a) a top view showing a 4th embodiment of a floor slab structure concerning the present invention, (b) an example of a longitudinal section, and (c) another example of a longitudinal section. It is a top view of the test body in the Example of the floor slab structure concerning this invention. It is a graph which shows the measurement result of the Example of FIG.

Explanation of symbols

1 Floor slab (floor structure)
11 Vibration restraint member (large beam)
12 Unconstrained floor slab portion 13 Stepped portion 15 Recessed portion 17a, 17b Stepped portion reinforcing bar 18a, 18b Shear reinforcing bar 19 Connecting bar

Claims (3)

A floor slab structure supported by a vibration restraining member,
An unconstrained floor slab portion located at a distance exceeding the half wavelength of the bending wave in the floor slab with respect to the impact frequency of a predetermined floor impact sound impact source from the nearest vibration restraining member;
A step portion provided in the unconstrained floor slab portion,
The step portion includes the unconstrained floor slab portion at a distance within half a wavelength of the bending wave.   The floor slab structure according to claim 1, wherein a recess formed in the floor slab by the stepped portion is used as a water-circulating portion.   The stepped portion includes at least a stepped portion reinforcing bar for firmly connecting the unconstrained floor slab portion adjacent to the stepped portion and the stepped portion, and shear reinforcement for reinforcing the shear rigidity of the stepped portion. The floor slab structure according to claim 1 or 2, wherein a line and a connecting line for connecting the shear reinforcement bars are embedded.

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