JP2010013830A - Method for manufacturing lower section of base-isolated foundation - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily manufacture a lower section of a base-isolated foundation with a high degree of horizontal accuracy of a base plate. <P>SOLUTION: In this manufacturing method, the base plate is positioned in an upper portion in a form by supporting the base plate on a base; concrete for forming a concrete section is placed in the form; and subsequently, mortar for forming a mortar section is infilled between a top surface of the concrete section and an undersurface of the base plate, so as to manufacture the lower section of the base-isolated foundation. A variation in a bleeding amount associated with a lapse of time after the placing of concrete for use in the formation of the concrete section is observed; a mortar placing reference time A, at which the bleeding amount until the time E of the completion of the bleeding retrospectively from the time E of the completion of the bleeding of the concrete is set at 0.03 cm<SP>3</SP>/cm<SP>2</SP>, is predetermined; and in the manufacture of the lower section of the base-isolated foundation, the mortar is placed on the top surface of the concrete until a lapse of predetermined time from the mortar placing reference time A. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a method for producing a base isolation base lower part with good horizontal accuracy of a base plate.

A concrete that assembles the formwork at a predetermined position on the foundation structure of the building, supports the base plate with a gantry and places it in the upper part of the formwork, and forms a concrete part in the formwork through an injection hole formed in the baseplate After placing the mortar, there is a method of creating a seismic isolation base lower part on the building foundation structure by filling the mortar that forms the mortar part between the upper surface of the concrete part and the lower surface of the base plate through the injection hole. Known (see, for example, Patent Document 1).
When manufactured by the method as described above, the seismic isolation base lower part 1 is provided on the concrete part 4 provided on the foundation structure 3 of the building 2 and the upper surface 4a of the concrete part 4 as shown in FIG. The mortar part 5 and the base plate 6 provided on the upper surface 5a of the mortar part 5 are provided. For example, the injection hole 20 penetrating the upper surface 9 and the lower surface 16 of the base plate 6 is formed at the center of the base plate 6 formed in a circular or square shape with a metal flat plate having a thickness of about 10 to 20 mm. A lower mounting plate 8 of a seismic isolation member 7 such as a laminated rubber seismic isolation device is attached to the upper surface 9 of the base plate 6 of the base isolation base lower part 1, and an upper mounting plate 10 of the seismic isolation member 7 is formed at the lower part of the building 2. It is attached to the lower surface 12 of the seismic isolation base upper portion 11. The bottom mounting plate 8 of the seismic isolation member 7 and the base plate of the base isolation base 1 are provided by a cap nut 17 attached to the lower surface 16 of the base plate 6 so as to extend to the bolt hole 15 and a bolt 18 fastened to the cap nut 17. 6 and the top mounting of the seismic isolation member 7 by the cap nut 17 attached to the upper surface 19 of the top mounting plate 10 so as to extend to the bolt hole 15 and the bolt 18 fastened to the cap nut 17. The plate 10 and the seismic isolation base upper part 11 are connected.
JP 11-293933 A

In the lower part of the base isolation base, it is necessary to ensure that the axial force and shear force received by the base isolation member can be transmitted to the foundation structure of the building via the base plate and mortar. For this purpose, at least it is required that latencies and bubbles are not floated under the base plate, and mortar is uniformly filled under the lower surface of the base plate so that the level of the base plate is maintained. However, there was no clear standard on the timing of mortar placement to obtain a base-isolated base that satisfies this requirement. At present, the base isolation base is often produced according to the experience of the installer, and there is a problem that the base isolation base with high horizontal accuracy of the base plate cannot be easily manufactured.
The present invention provides a method for producing a base-isolated base lower part that can easily produce a base plate having a good horizontal accuracy and a base-isolated lower part.

A method for producing a seismic isolation base lower part according to the present invention includes a concrete part provided on a foundation structure of a building, a mortar part provided on an upper surface of the concrete part, and a base plate provided on an upper surface of the mortar part. When making the base isolation base where the base isolation member is mounted on the base, the base plate is supported by the gantry and positioned on the top of the mold, and the concrete that forms the concrete part in the mold is placed and then the concrete In the method of making the base isolated base by filling the mortar forming the mortar part between the upper surface of the part and the lower surface of the base plate, the time lapse after the concrete placement for the concrete used to form the concrete part Observe the change in the amount of bleeding associated with the Back bleeding amount until bleeding end and is to previously obtain a mortar hitting set reference time to be 0.03 cm 3 ^/ cm ^2, in making the seismic isolation foundation bottom is a predetermined time period has elapsed since the mortar hitting set reference point In the meantime, mortar was placed on the top surface of the concrete.
As mortar, 20 cm flow time of flow test is 20 seconds to 60 seconds, 5 minute flow of flow test is 250 ± 25 mm, pH test value is 12.0 or less, air amount is 4.0% or less, and bleeding is 0. It is also characterized by using a mortar that satisfies the above.
As the mortar, a binder composed of cement and an expanding material powder, a first powder composed of a first water-soluble low-molecular compound selected from a cationic surfactant, and a second selected from an anionic aromatic compound. It is formed by mixing a thickener composed of a second powder composed of a water-soluble low molecular weight compound, a fine aggregate, a cement admixture powder, and water, with a unit water amount of 380 to 440 kg / m ³ , The ratio of water to binder is 34.0 to 60.0%, the sum of the amount of the first powder and the amount of the second powder is 2.50 to 4.00 kg / m ³ , cement admixture It is also characterized in that a mortar having a powder amount of 0.90 to 2.00 kg / m ³ is used.

According to the manufacturing method of the base isolation base lower part of this invention, the base isolation base lower part with the sufficient horizontal precision of a baseplate can be manufactured easily.
Moreover, the base isolation | separation base lower part with sufficient performance which can transmit the axial force and shear force which a base isolation member receives to a foundation structure of a building via a baseplate and mortar reliably by the mortar to be used can be produced easily.

  Using the test specimen preparation device, the mortar placement time for forming the mortar part was varied to produce a plurality of test specimens at the bottom of the seismic isolation foundation. While evaluating by visual observation, the adhesion strength of the mortar of each test body was measured.

The concrete used for forming the concrete part of each specimen is three types, 27-21-20N, 33-21-20N, and 49-60-20N, as shown in FIG. 9A as an example. The concrete was used. The numerical values on the left (27, 33, 49) indicating the type of concrete are the nominal strength (N / mm ² ), and the central numerical values (21, 21, 60) indicating the type of concrete are the nominal slump and slump flow (cm ), The right numerical value (20, 20, 20) indicating the type of concrete indicates the diameter of the aggregate (mm), and the right symbol (N, N, N) indicating the type of concrete indicates the type of cement. The material composition of each concrete is as shown in FIG. In FIG. 9A, W / C is the water cement ratio, S / a is the fine aggregate ratio, W is the unit water amount, C is the unit amount of cement (ordinary Portland cement, ρ = 3.16 g / cm ³ ), S1 is the unit amount of land sand (ρ = 2.60 g / cm ³ , FM = 2.40) from Kamisu (Ibaraki Prefecture), S2 is crushed sand (ρ = 2.70 g / cm ³ ) from Sano (Tochigi Prefecture). , FM = 3.10), G1 is a unit quantity of crushed stone (ρ = 2.60 g / cm ³ , actual rate = 60.0) from Ishioka (Ibaraki), G2 is from Sano (Tochigi) Unit amount of crushed stone (ρ = 2.74 g / cm ³ , actual rate = 60.0), Ad1 is a unit amount of AE water reducing agent (manufactured by BASF Pozoris, product name “Pozoris No. 70”), Ad2 is high It is a unit amount of the performance AE water reducing agent (manufactured by BASF Pozzolith Co., Ltd., product name “Leobuild SP-8SV”).

FIG. 9B shows the characteristics of the three types of concrete described above. In FIG. 9B, the temperature indicates the concrete temperature, and the bleeding amount indicates the bleeding amount (total amount) at an ambient temperature of 20 ° C. FIG. 10 shows changes in the amount of bleeding with the passage of time after placing the concrete in each of the three types of concrete. As shown in FIG. 9 (b); FIG. 10, the concrete bleeding amount (total amount) of 49-60-20N is 0.03 cm ³ / cm ² or less, and the other two concrete bleeding amounts (total amount). Is 0.03 cm ³ / cm ² or more.

The mortar used for forming the mortar part of each test specimen is, for example, cement (C), expanding material powder (CSA), thickening admixture powder (Vt), fine aggregate as shown in FIG. A mortar formed by mixing (S), cement admixture powder (SP), antifoam powder (E), and water (W). In addition, as shown in FIG. 6, the used mortar has an amount of cement admixture powder (SP use amount) in an appropriate range of 0.90 to 2.00 kg / m ³ , and the amount of the first powder The sum of the amount of the second powder, that is, the amount of the thickening admixture powder (the amount of Vt used) is an appropriate range of 2.50 to 4.00 kg / m ³ , and the ratio of water to the binder (hereinafter referred to as The water binding material ratio (W / B) is in the appropriate range of 34.0 to 60.0%, and the amount of water per unit volume (hereinafter referred to as the unit water amount (W)) is in the appropriate range of 380 to 440 kg / m ^3. Mortar that satisfies the condition of A mortar that satisfies the above conditions is a mortar that satisfies the evaluation value condition shown in FIG. That is, the 20 cm flow time of the flow test is 20 seconds to 60 seconds, the 5-minute flow of the flow test is 250 ± 25 mm, the result of the pH test is 12.0 or less, and the air amount obtained by the air amount measurement method is 4.0%. Hereinafter, the mortar satisfies the condition that bleeding is 0. Binder (B) = cement (C) + expandant powder (CSA).

Specifically, SP usage is 1.65 kg / m ³ , Vt usage is 3.7 kg / m ³ , unit water amount (W) is 425 kg / m ³ , cement (C) is 1194 kg / m ³ , expansion material Powder (CSA) is 20 kg / m ³ , Binder (B) is 1214 kg / m ³ , Water Binder Ratio (W / B) is 35%, Fine Aggregate (S) is 485 kg / m ³ , Antifoam Powder A specimen was prepared using a mortar having a composition of (E) 0.2 kg / m ³ and aluminum powder 0.02 kg / m ³ .

The thickening admixture powder (Vt) as the thickening material is composed of a first powder and a second powder. The first powder is formed by drying a powder of a first water-soluble low-molecular compound selected from cationic surfactants or a liquid containing the first water-soluble low-molecular compound. The water-soluble low molecular weight compound powder was used. The second powder is formed by drying a powder of a second water-soluble low molecular compound selected from anionic aromatic compounds or a liquid containing the second water-soluble low molecular compound. The water-soluble low molecular weight compound powder was used. As the cement admixture powder (SP), a carboxyl group-containing polyether water reducing agent powder excellent in compatibility with the thickening admixture powder (Vt) was used. The binder (B) is formed by the cement (C) and the expansion material powder (CSA).
As the first water-soluble low molecular weight compound, a quaternary ammonium salt type cationic surfactant is preferable, and an additive mainly composed of an alkyl ammonium salt is particularly preferable. The second water-soluble low molecular weight compound is preferably a sulfonate having an aromatic ring, and particularly preferably an additive having an alkylallyl sulfonate as a main component. Cement (C) includes ordinary Portland cement, early-strength Portland cement, medium-heated Portland cement, white Portland cement such as limestone, clay, and iron oxide, blast furnace cement, fly ash cement, silica cement, etc. Use mixed cement. As the fine aggregate (S), silica sand or the like obtained from river sand is used. The expansion material powder (CSA) uses a lime composite expansion material powder. As the defoamer powder (E), a silicon-based defoamer powder is used. The defoamer powder (E) is preferably used in order to prevent bubbles from being generated during kneading and an increase in the amount of air in the mortar, resulting in a decrease in strength and a decrease in specific gravity.

  As shown in FIG. 4, the specimen preparation device 50 includes a rectangular box-shaped mold 21 having an upper opening, a lid 22, and a hopper 23. The lid 22 includes an injection hole 24 formed by a hole penetrating the lid 22. The hopper 23 is formed by a conical cylindrical body, and is used with the cone upside down. The hopper 23 is installed so that the lower end opening 25 is connected to the injection hole 24, and guides the mortar to the injection hole 24. . The mold 21 and the lid 22 were formed of plywood.

  The test body was produced as follows. After placing concrete in the mold 21 until the top of the concrete reaches a position 2 cm below the upper end of the mold 21, one side edge 26 of the lid 22 and the upper end surfaces of the four side plates of the mold 21 A lid 22 is installed on the upper end surface of the mold 21 so as to close the upper portion of the mold 21 with a gap 28 between the upper end surface 27 and the upper end surface 27. Then, a hopper 23 is installed so as to be connected to the injection hole 24 of the lid 22, and between the concrete upper surface (top end) 29 and the lower surface 30 of the lid 22 through the hopper 23 and the injection hole 24. Mortar was cast and filled. Then, when the mortar overflowed from the gap 28, the mortar casting and filling were finished, and after waiting for the mortar to solidify, the lid 22 was removed to prepare a test specimen.

  Test specimens were prepared for each of the three types of concrete with different time conditions from placing the concrete to placing and filling the mortar. The time condition from the placement of concrete to the start of mortar filling is 30 immediately after placing the concrete (shown as “immediately after placing” in FIGS. 2 and 3) and 30 after placing the concrete. Immediately after the lapse of minutes (shown as “30 minutes later” in FIG. 2; 3), immediately after the end of the concrete bleeding (shown as “after bleeding” in FIG. 2; 3), immediately after the lapse of 24 hours after placing the concrete (see FIG. 2). 2; 3 indicates “after 24 hours”). That is, for each of the three types of concrete, a total of 12 types of test specimens were prepared under four time conditions, and after observing the surface condition of the mortar portion in each test specimen, the adhesion strength of the mortar of each specimen was measured. It was measured. As shown in FIG. 10, the time until the concrete 27-21-20N bleeding ends is 8 hours after the concrete is placed, and the time until the concrete 33-21-20N bleeding ends is It is 6 hours after placing the concrete, and the time until the bleeding of the concrete 49-60-20N is 7 hours after placing the concrete. In this experiment, as shown in FIG. 10, for three concretes, the time from placing the concrete to the end of the concrete bleeding was known, so the time until the end of the concrete bleeding was determined. Immediately after the lapse of time, without removing water floating on the upper surface 4a of the concrete part 4, mortar was cast and filled on the upper surface 4a of the concrete part 4 to prepare a test specimen. In this case, water or the like floating on the upper surface 4a of the concrete portion 4 is pushed out by the mortar filled with filling and discharged from the gap 28.

  The observation evaluation of the surface condition of the mortar part in the test specimen was evaluated by visually observing the surface of the mortar part of the test specimen. Fig. 3 (a) shows the result of the surface condition of the mortar part in each test specimen in which the concrete type and the time condition until the start of mortar filling after concrete placement are different (Fig. 3 (a) shows the surface condition). It is shown as an observation test result). The evaluation criteria for the surface condition are not acceptable when the entire surface of the mortar part has a float such as latency or air (×), and when the surface of the mortar part partially has a float such as latency or air (△ ), When the surface of the mortar part has less float of latency, air, etc., was judged as good (◯).

A Kenken-type adhesive strength tester was used to measure the adhesion strength of the mortar of the specimen. That is, using a core drill, as shown in FIG. 5, a cylindrical groove 43 is formed downward from the surface 42 of the mortar 41 of the test body 40, and the surface of the columnar portion 44 partitioned by the groove 43. The attachment 46 of the adhesion strength tester was bonded to 45, and a tensile load was applied to the attachment 46, and the value of the load when the cylindrical portion 44 was broken was measured as the adhesion strength. FIG. 3 (b) shows the measurement results of the mortar adhesion strength in each test specimen in which the concrete type and the time condition until the start of mortar filling after the concrete is placed are different. Evaluation criteria for adhesion strength, disables less than 1N / mm ² (×), allowed to less than 1N / mm ² or more 1.5N / mm ² (△), was 1.5 N / mm ² or more good (○) .

  FIG. 2 collectively shows the results of the surface condition of the mortar part in each test specimen and the measurement results of the adhesion strength of the mortar, and further shows a comprehensive evaluation evaluating the two results. The overall evaluation is X (impossible) when one or more of the two results are not possible (x), and ○ (one) is acceptable (△) and the other is ○ (good). Yes) When both results were good (good), it was marked good (good).

  As can be seen from FIG. 3 (a), even when any of the three types of concrete is used, the test specimen prepared by placing and filling the mortar immediately after the bleeding is finished is the surface condition of the mortar part. Is good or acceptable. Therefore, in the case of forming the lower part of the seismic isolation foundation, the concrete shown in FIG. 9 and the mortar shown in FIGS. 6 to 8 are used, and the mortar is placed and filled under the base plate immediately after the bleeding is completed, thereby allowing the latency to be set under the base plate. The bottom of the base plate is filled with mortar evenly under the bottom surface of the base plate, and the base plate can be easily manufactured with a high horizontal accuracy.

  As can be seen from FIG. 3 (a), the specimen prepared by placing and filling concrete 49-60-20N and placing mortar immediately after 30 minutes from placing the concrete is the surface condition of the mortar part. Is possible. Therefore, when forming the lower part of the seismic isolation foundation, use concrete 49-60-20N and the mortar shown in FIGS. 6 to 8 to cast and fill the mortar 30 minutes after the concrete is placed. Thus, the lower part of the base plate with high horizontal accuracy can be easily manufactured by filling the mortar evenly under the lower surface of the base plate without floating of latency or bubbles under the base plate.

From FIG. 3A, it can be seen that the surface condition of the mortar portion tends to be better as the mortar is placed and filled later.
Moreover, it can be seen from FIG. 3B that the adhesion strength of the mortar tends to be better as the mortar is placed and filled earlier.
That is, the conditions for improving the surface condition of the mortar part and the conditions for increasing the adhesion strength of the mortar are contradictory to each other.

  As can be seen from the results shown in FIG. 2, a test specimen prepared by using three concretes and placing and filling mortar immediately after the end of bleeding is an overall evaluation ◯. Therefore, the base plate 6 is supported by a base (not shown) and positioned at the upper part in the mold (not shown), and the concrete for forming the concrete portion 4 is placed in the mold through the injection hole 20 formed in the base plate 6. After that, when the mortar for forming the mortar part 5 is filled between the upper surface 4a of the concrete part 4 and the lower surface 16 of the base plate 6 through the injection hole 20, the seismic isolation base lower part 1 is formed (see FIG. 11). In FIG. 11, by using the above three concretes and the mortar shown in FIGS. 6 to 8, and placing and filling the mortar immediately after the concrete bleeding, as shown in FIG. The mortar is uniformly filled under the lower surface 16 of the base plate 6 without floating, and the horizontal accuracy of the base plate 6 is good, and the mortar The seismic isolation base lower part 1 that satisfies the requirement of high adhesion strength, that is, the axial force and shearing force that the seismic isolation member 7 receives can be reliably transmitted to the base structure 3 of the building 2 via the base plate 6 and the mortar part 5. A good seismic isolation base lower part 1 can be easily manufactured.

  As can be seen from the results shown in FIG. 2, a test specimen prepared by placing and filling mortar immediately after 30 minutes from placing concrete using concrete 49-60-20N is is there. Therefore, when forming the lower part of the seismic isolation foundation, use concrete 49-60-20N and the mortar shown in FIGS. 6 to 8 to cast and fill the mortar 30 minutes after the concrete is placed. Thus, the seismic isolation base lower part 1 having the above-described performance can be easily manufactured.

That is, in the case of producing the lower part of the seismic isolation foundation, for example, concrete having the same composition and characteristics as the above three concretes and the mortar shown in FIGS. 6 to 8 are used, and the amount of bleeding of the concrete used is 0. In the case of 03 cm ³ / cm ² or more, after the completion of the bleeding of the concrete until the lapse of a predetermined period (for example, the drying of the concrete after the completion of the bleeding; the bleeding considered that the adhesion strength decreases with the progress of the setting) When the concrete bleed amount is 0.03 cm ³ / cm ² or less, the specified period of time has elapsed since the end of the concrete bleeding. (For example, 30 minutes after placing concrete) The above-mentioned performance is achieved by placing mortar on the top surface of the concrete after the drying of the concrete; the period until about 4 hours have passed after the bleeding is considered to decrease with the progress of setting) It is considered that a good seismic isolation base lower part 1 can be easily produced.

  In addition, as can be seen from FIG. 2, a test specimen prepared by using concrete 49-60-20N and placing and filling mortar immediately after 24 hours from placing the concrete has an overall evaluation ◎. This is considered to be an influence of the high performance AE water reducing agent contained in the concrete 49-60-20N. However, after 24 hours have passed since placing the concrete, there is an adverse effect that the process takes two days. Therefore, in order to produce the seismic isolation base lower part 1 having the above-mentioned performance in the short construction period, the period from the end of the concrete bleeding to the elapse of the predetermined period, or the period from the end of the concrete bleeding to the elapse of the predetermined period. A mortar may be placed between them.

  In addition, when mortar is placed 30 minutes before the concrete is placed, because the concrete maintains fluidity, the surface condition of the mortar part becomes worse due to extrusion of the concrete or air floating. Conceivable.

The present inventor has examined the above results and found the following. As can be seen from FIG. 3 (a), when 49-60-20N concrete is used, the surface condition of the mortar portion remains even if the mortar is placed and filled immediately after 30 minutes from the end of the concrete placement. Yes. As can be seen from FIG. 10, the concrete 49-60-20N has a bleeding amount (total amount) of 0.03 cm ³ / cm ² , and the bleeding amount from the end of placing concrete until 30 minutes have elapsed. Is 0. That is, when mortar is cast and filled immediately after 30 minutes from the end of concrete placement, the amount of concrete bleeding is 0.03 cm ³ / cm ² until the end of bleeding. From this, even if bleeding occurs after the mortar is placed and filled, if the amount of bleeding is 0.03 cm ³ / cm ² or less, the surface condition of the mortar part is considered to be acceptable. That is, it is considered that the surface condition of the mortar part can be made acceptable if the concrete bleeding amount after placing and filling the mortar is 0.03 cm ³ / cm ² or less, regardless of what concrete is used.

Therefore, with regard to the concrete used to form the concrete part at the bottom of the seismic isolation foundation, changes in the amount of bleeding with the passage of time after placing the concrete are observed in advance, and the amount of bleeding as shown in FIG. A graph X showing the change in the above is created. Based on the graph X, the concrete bleeding end point E and the mortar placing reference point A at which the amount of bleeding from the ending point E to the ending point E is 0.03 cm ³ / cm ² are obtained. Keep it. When the mortar is placed on the concrete upper surface 4a of the concrete part 4 to produce the seismic isolation base lower part 1, the mortar is applied to the concrete upper surface 4a during a predetermined period from the mortar placing reference time A. To cast. Thereby, the surface condition of the mortar part 5 can be made, and the base-isolated base lower part 1 with good horizontal accuracy of the base plate 6 can be easily manufactured.

  Further, FIG. 10 shows the following. When using concrete 27-21-20N, the mortar placing reference time A of the concrete 27-21-20N is the time when about 6 hours and 45 minutes have elapsed from the end of placing the concrete. When using concrete 33-21-20N, the mortar placing reference time A of the concrete 33-21-20N is a time when about 5 hours have elapsed from the end of placing the concrete. When concrete 49-60-20N is used, the mortar placement reference time A of the concrete 49-60-20N is a time when about 3 hours have elapsed from the end of the concrete placement.

  Accordingly, the three types of concrete and the mortar shown in FIGS. 6 to 8 are used, and the period from the mortar placing reference time A of the concrete to be used until a predetermined period elapses (for example, from the mortar placing reference time A). Concrete is dried; refers to the period of time until about 4 hours after the completion of bleeding, which is considered to decrease the bond strength as the setting progresses), and mortar is placed on the top surface of the concrete to create the lower part of the base Thus, the seismic isolation base lower part 1 having the above-described performance can be easily manufactured.

According to the present invention, when producing a seismic isolation lower part, even when using concrete or mortar other than the concrete or mortar described above, for example, selecting and using concrete or mortar equivalent to the concrete or mortar described above. When obtaining the mortar placement reference time point A for the concrete used to form the concrete part, and placing the mortar on the upper surface of the concrete of the concrete part to produce the seismic isolation base lower part, If the mortar is placed on the upper surface of the concrete and the lower part of the seismic isolation foundation is produced between the mortar placement reference point A and the predetermined period of time, the lower part 1 of the seismic isolation base having the above-described performance can be easily produced Conceivable.
The present invention can also be applied to the filling and filling of the filler in the so-called reverse casting method.

Explanatory drawing (the best form) of the concrete bleeding end point and the mortar setting reference point used for the production of the seismic base. The figure which shows comprehensive evaluation of a test body (best form). (A) is a figure which shows the surface condition quality result of the mortar part of a test body, (b) is a figure which shows the measurement result of the adhesion strength of the mortar of a test body (best form). The figure which shows a test body preparation apparatus (best form). The figure which shows the outline | summary of the adhesion strength test of the mortar of a test body (best form). The figure which shows the range of the main composition of the mortar used for preparation of a test body (best form). The figure which shows the characteristic of the mortar used for preparation of a test body (best form). The figure which shows the detail of the composition material of the mortar used for preparation of a test body (best form). (A) is a figure which shows the composition of the concrete used for preparation of a test body, (b) is a figure which shows the characteristic of the concrete used for preparation of a test body (best form). The figure which shows the change of the amount of bleeding with the passage of time after placement of the concrete used for preparation of a test body (best form). The figure which shows the seismic isolation base lower part.

Explanation of symbols

1 Lower seismic isolation base 2 Building 3 Foundation structure 4 Concrete part
4a Top surface of concrete part, 5 mortar part, 5a Top surface of mortar part,
6 Base plate, 7 Seismic isolation member, E
A Time point for placing mortar.

Claims (3)

A seismic isolation lower part provided with a concrete part provided on the foundation structure of the building, a mortar part provided on the upper surface of the concrete part, and a base plate provided on the upper surface of the mortar part, and a base isolation member is mounted on the base plate The mortar part is placed between the upper surface of the concrete part and the lower surface of the base plate after placing the concrete that forms the concrete part in the mold frame by placing the base plate on the upper part in the form frame while supporting the base plate with a base. In the method of making the seismic isolation base by filling the mortar forming the concrete, the change of the bleeding amount with the passage of time after the concrete placement is observed for the concrete used for forming the concrete part, and the concrete The bleeding from the end of the bleeding to the end of the bleeding Over loading amount to previously obtain a mortar hitting set reference time to be 0.03 cm 3 ^/ cm ^2, in making the seismic isolation foundation bottom, a top surface of the concrete between the mortar hitting set reference time point until a predetermined period elapses A method for producing the lower part of the seismic isolation foundation, characterized by placing mortar on the base.   As mortar, 20 cm flow time of flow test is 20 seconds to 60 seconds, 5 minute flow of flow test is 250 ± 25 mm, pH test value is 12.0 or less, air amount is 4.0% or less, and bleeding is 0. The method for producing the lower part of a base isolated according to claim 1, wherein a mortar satisfying the above is used. As the mortar, a binder composed of cement and an expanding material powder, a first powder composed of a first water-soluble low-molecular compound selected from a cationic surfactant, and a second selected from an anionic aromatic compound. It is formed by mixing a thickener composed of a second powder composed of a water-soluble low molecular weight compound, a fine aggregate, a cement admixture powder, and water, with a unit water amount of 380 to 440 kg / m ³ , The ratio of water to binder is 34.0 to 60.0%, the sum of the amount of the first powder and the amount of the second powder is 2.50 to 4.00 kg / m ³ , cement admixture The method for producing a lower part of a base isolated according to claim 1, wherein a mortar having a powder amount of 0.90 to 2.00 kg / m ³ is used.

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