JP4864866B2 - Porous concrete and its aggregate - Google Patents

Description

  The present invention relates to porous concrete that can be produced by effectively reusing a large amount of fly ash and an aggregate used for the same.

  Currently, a huge amount of fly ash is generated. The generated fly ash is mainly used by being added to a cement raw material, but there are many fly ashes that are discarded without being effectively used. Furthermore, it is also added to cement as an admixture, but if this addition amount is large, the strength decreases, so the amount of fly ash added is limited due to the required physical properties. Porous concrete has low strength required for its use. A technique for adding fly ash to the raw material of porous concrete has been developed. (See Patent Documents 1 and 2)

  Patent Document 1 describes a building block made of porous concrete using fly ash. This stack block is integrally formed by laminating immediate demolding concrete constituting the base layer and porous concrete constituting the surface layer. Porous concrete consists of cement, coarse aggregate, high-performance water-reducing agent or high-performance AE water-reducing agent, water, fine aggregate mixed as necessary, slag fine powder, fly ash, anhydrous gypsum, and zeolite. One or more types selected from are mixed. This porous concrete describes the addition of fly ash to a binder that binds coarse aggregate.

  Patent Document 2 describes porous concrete composed of coarse aggregate and cement paste or mortar having a volume ratio of 25 to 100% with respect to 100% of the coarse aggregate. This porous concrete is a fired product made from one or more kinds of municipal waste incineration ash or sewage sludge incineration ash, and 10 to 40 mass of one or more kinds of calcium chloroaluminate, calcium fluoroaluminate or calcium aluminate. Eco-cement mainly composed of calcined material and gypsum containing 2% and calcium silicate is used as cement paste or cement for mortar. Furthermore, this porous concrete also describes that the eco-cement or the powder mixture containing eco-cement consists of 50 to 100% by mass of eco-cement and 50 to 0% by mass of blast furnace slag, fly ash or silica fume.

  Patent Documents 1 and 2 describe porous concrete to which fly ash is added, but the amount of fly ash added to this porous concrete is limited to a small amount. A large amount of fly ash cannot be added to make porous concrete with sufficient strength. This is because fly ash is added to the binder that binds the coarse aggregate. In porous concrete in which coarse aggregates are bonded with a binder, the aggregate weight occupies a large weight as a whole. For this reason, the amount of fly ash added to the binder that binds it is small, and a large amount of fly ash cannot be added to obtain sufficient strength.

The amount of fly ash used can be increased by adding fly ash in the process of producing the aggregate. A method for producing an aggregate by adding fly ash has been developed (see Patent Document 3). In this publication, an iron-based material having a density of 3.5 g / cm ³ or more, cement, fine aggregate, and water are blended, concrete-molded, or a concrete solidified body is molded and then pulverized to produce a heavy aggregate. Describes the method. This heavy aggregate describes that crushed sand or fly ash is used as the fine aggregate, and describes an example in which crushed sand is used in the fine aggregate and an example in which fly ash is used.

This publication describes a method for producing heavy aggregate using iron-based material as a main raw material, but does not describe a technique for producing aggregate using fly ash as the main raw material. The technology for producing porous concrete is not described. Therefore, according to the technique of this publication, an aggregate cannot be manufactured using a large amount of fly ash.
JP 2001-347511 A JP 2002-316858 A JP 2007-15880 A

  The present invention was developed for the purpose of realizing sufficient strength as an aggregate of porous concrete while using a large amount of fly ash as a main raw material. Aggregates that use fly ash as the main raw material can improve strength by increasing the amount of cement mixed. However, increasing the amount of cement added increases the raw material cost and cannot be used in practice. Therefore, the present invention was developed for the purpose of realizing sufficient strength as an aggregate of porous concrete while further reducing the amount of cement used in addition to using fly ash as a main raw material. is there. Therefore, an important object of the present invention is to use an aggregate that achieves sufficient strength as an aggregate of porous concrete while using 50% by weight or more fly ash and reducing the amount of cement used. It is to provide porous concrete to be used.

The aggregate of porous concrete described in claim 1 of the present invention is obtained by granulating and solidifying a raw material mixture containing fly ash as a main raw material and cement. Furthermore, this aggregate contains fly ash of 50% by weight or more, and further contains fine aggregate in addition to fly ash and cement, and this fine aggregate is crushed sand obtained by crushing natural stone, and its inclusion The amount is 20 wt% to 40 wt% , the cement content is 15 wt% or less, and the raw material mixture is solidified in an agglomerated state to an average particle diameter of 5 mm to 50 mm.

The aggregate of claim 2 of the present invention contains 0 to 5% by weight of quicklime in addition to the structure of claim 1.

Further, the porous concrete according to claim 3 of the present invention is formed by binding the aggregate in a state having voids with a binder, and the aggregate is composed of a raw material mixture containing main raw material fly ash and cement in a thickness of 5 mm to 5 mm. Includes coarse aggregates granulated and solidified to an average particle size of 50 mm. In addition, the aggregate contains 50% by weight or more of fly ash, and further contains fine aggregate in addition to fly ash and cement. The fine aggregate is crushed sand obtained by crushing natural stone, and its content Is 20 wt% to 40 wt%, and the cement content is 15 wt% or less.

Further, porous concrete of claim 4 of the present invention, the aggregate contains quicklime 5 percent by weight 0. Moreover, the porous concrete of Claim 5 of this invention uses the binder which couple | bonds an aggregate as mortar.

  The present invention uses a large amount of fly ash as 50% by weight or more as a main raw material, and while reducing the amount of cement used to 15% by weight or less, as an aggregate and as a porous concrete using this aggregate Realize sufficient strength. That is, the present invention uses fly ash as the main raw material of the aggregate of the porous concrete, adds fine aggregate in addition to fly ash to this aggregate, and further crushes natural stone in the fine aggregate This is because crushed sand is used, and the raw material mixture in which these are mixed is granulated to a predetermined particle size and solidified in the granulated state to obtain an aggregate. In porous concrete, fly ash can be added to a binder for bonding aggregates. However, this porous concrete cannot be used because the strength is significantly lowered when a large amount of fly ash is used. In the present invention, fly ash is used as a main raw material of aggregate, not a binder. In addition, by mixing unique crushed sand with the main raw material fly ash, the strength of the aggregate itself is remarkably improved with a small amount of cement.

Incidentally, an aggregate produced without adding fine aggregate cannot be used as a porous concrete aggregate because the amount of cement added is 8 parts by weight and the crushing strength is 0.75 N / mm ² . Furthermore, the aggregate of fly ash as the main raw material can be used as an aggregate of porous concrete by increasing the amount of cement added to 16 parts by weight and having a crushing strength of 1.55 N / mm ² . Since this aggregate uses as much as 16% by weight of cement, the raw material cost is high, and in reality it can only be used for special purposes. On the other hand, the porous concrete aggregate of the present invention comprises 70 parts by weight of fly ash and 30 parts by weight of fine aggregate as the main raw materials, while the mixing amount of cement is extremely small at 8 parts by weight. it not 2.33N / mm ² strength can stronger than the aggregate of the amount of 3.51N / mm ² and cement and 16% by weight. In addition, the aggregate using sea sand instead of crushed sand has the same weight ratio of fly ash, fine aggregate and cement, and has a crushing strength of 1.55 N / mm ^2, which is incomparable to the present invention. Lower.

  Embodiments of the present invention will be described below with reference to the drawings. However, the example shown below illustrates the porous concrete and the aggregate for embodying the technical idea of the present invention, and the present invention does not specify the porous concrete and the aggregate as follows. Further, this specification does not limit the members shown in the claims to the members of the embodiments.

Porous concrete is produced by adding a binder to the aggregate and placing it in a mold to cure the binder. Aggregate solidifies fly ash, the main raw material, with cement. Quick lime is preferably added to the cement. The inventor first made a first aggregate by mixing 8 parts by weight of cement and 1.5 parts by weight of quicklime with 100 parts by weight of fly ash. The first aggregate has a crushing strength of 0.75 N / mm ² , and does not achieve a satisfactory strength as an aggregate of porous concrete. The crushing strength is measured from the pressure at which the opposing position of the aggregate is pressed by a cylinder having a diameter of 2 mm and broken. In order to improve the strength of this aggregate, the amount of cement added to 100 parts by weight of fly ash is increased from 8 parts by weight to 12 parts by weight, and the same amount of quicklime is mixed to obtain a second aggregate. As a prototype, the crushing strength of the second aggregate was 1.28 N / mm ² . The 2nd aggregate which has this intensity | strength is used for porous concrete, and does not become sufficient intensity | strength. Further, for the purpose of improving the strength of the aggregate, a third aggregate was produced in the same manner except that the amount of cement added was increased to 16 parts by weight. The crushing strength of the third aggregate was 1.55 N / mm ² , and an almost satisfactory strength was realized as an aggregate of porous concrete. However, this aggregate has a high raw material cost because the amount of cement mixed is as large as 16 parts by weight, and in reality it cannot be used except for special applications.

The present inventor added 30 parts by weight of fine aggregate to 70 parts by weight of fly ash for the purpose of improving the strength of the aggregate while reducing the amount of cement added, and 8 parts by weight thereof. A fourth aggregate was made by mixing the above cement and 1.5 parts by weight of quicklime. This aggregate has a strength of 1.55 N / mm ² and an almost satisfactory strength as an aggregate of porous concrete. In this aggregate, the amount of cement used was 8 parts by weight, which was half that of the third aggregate, and a strength comparable to that of the third aggregate was realized.

As a result of further trial and error, the present inventor further increased the strength of the aggregate, and as a result, by using crushed sand obtained by crushing natural stone in the fine aggregate, the amount of cement was further increased. Succeeded in improving strength. Accordingly, the aggregate of the porous concrete of the present invention contains 50% by weight or more of fly ash, further contains 20% by weight to 40% by weight of fine aggregate made of crushed sand obtained by crushing natural stone, and further contains cement. The content is 15% by weight or less.

  The content of fly ash is preferably 50% by weight to 90% by weight, more preferably 60% by weight to 80% by weight. Although the fly ash content can be increased and the fly ash can be effectively used in a large amount, the strength is reduced as an aggregate. On the contrary, when the content of fly ash is reduced, the strength is improved, but the raw material cost is increased. Therefore, the content of fly ash is set to an optimum value within the above range in consideration of the strength and raw material cost required for the use of porous concrete.

The content of crushed sand is 20 % to 40% by weight. Increasing the content of crushed sand can improve the strength of the aggregate, but increasing this will decrease the content of fly ash and increase the raw material cost, so the content of crushed sand is also required for porous concrete applications Considering strength and raw material cost, the optimum value is set within the above range.

  Further, the cement content is preferably 12% by weight or less, more preferably 10% by weight or less, and more than 5% by weight. The cement content can be increased to improve the strength, but the raw material cost becomes high. Therefore, the cement content is set to the optimum value within the above range in consideration of the strength and raw material cost required for the use of the porous concrete.

  Furthermore, the aggregate for porous concrete of the present invention contains 0 to 5% by weight of quicklime. Aggregates containing quicklime have an effect of suppressing elution of heavy metals and can be used in a state that is friendly to the natural environment.

  The aggregate is manufactured by granulating a raw material mixture containing fly ash, fine aggregate and cement while adding water, and solidifying the granulated state. The average particle size in the granulated state is 5 mm to 50 mm. The raw material mixture is largely formed with a mold to solidify the cement, and then is crushed and processed into an aggregate of a predetermined particle size.

  Porous concrete is bonded to a state where an aggregate is formed with a binder. This porous concrete is produced by mixing an aggregate and a binder, putting them in a mold, and curing the binder. Cement mortar is used for the binder. As the cement mortar, a mixture of cement and fine aggregate can be used. A mortar binder made of cement and fine aggregate is manufactured by mixing 25 parts by weight of cement, 17 parts by weight of fine aggregate and 5 parts by weight of water with respect to 100 parts by weight of aggregate. . However, the mixing ratio of the cement with respect to 100 parts by weight of the aggregate may be 15 parts by weight to 50 parts by weight. Further, it is not always necessary to add fine aggregate to the binder, but preferably 5 to 30 parts by weight of fine aggregate is added to 100 parts by weight of aggregate. In addition, plastic mortar can be used as the binder in place of cement mortar depending on the application of porous concrete.

Aggregates are manufactured in the following process.
70 parts by weight fly ash, 30 parts by weight of fine aggregate made of crushed sand, 8 parts by weight of cement and 1.5 parts by weight of quicklime are mixed, and a particle size of about 9 mm is added thereto while adding water. When the strength after 14 days was measured, the strength after 14 days was 2.97 N / mm ² , which was sufficient as porous concrete.

Except that the granulated particle size is changed from 9 mm to about 12 mm, an aggregate is produced in the same manner as in Example 1, and the strength after 14 days is 2.35 N / mm ² , which is sufficient as porous concrete. It was.

Except that the granulated particle size is changed from 9 mm to about 10 mm, an aggregate is produced in the same manner as in Example 1, and the strength after 14 days is 3.51 N / mm ² , which is sufficient as porous concrete. It was.

Except that the granulated particle size is changed from 9 mm to about 13 mm, an aggregate is produced in the same manner as in Example 1, and the strength after 14 days is 2.33 N / mm ² , which is sufficient for porous concrete. It was.

The strength of the aggregates of the above examples is 2.33 N / mm ² to 3.51 N / mm ² , and the strength is sufficiently excellent as an aggregate of porous concrete while reducing the amount of cement added to 8 parts by weight. Realized.

Comparative Example 1

The aggregate was produced in the same manner as in Example 1 except that the crushed sand used was sea sand, and the crushing strength after 14 days was 1.55 N / mm ^2. It is considerably lower than the aggregate in the example.

To 100 parts by weight of the aggregate obtained in Example 1, 25 parts by weight of cement, 17 parts by weight of fine aggregate made of sea sand and 5 parts by weight of water were added, mixed and tested. When a prototype is made, the compressive strength after 14 days of this test piece is 10-12 N / mm ^2, which is sufficient as porous concrete, and the porosity is about 15%, showing excellent physical properties. In this embodiment, sea sand is used for the fine aggregate, but crushed sand can also be used.

Claims (5)

An aggregate for porous concrete in which a raw material mixture containing fly ash as a main raw material and cement is granulated and solidified,
In addition to fly ash and cement, it contains fine aggregates of 50% by weight or more, and the fine aggregates are crushed sand obtained by crushing natural stone, and the content thereof is 20% by weight to 40 %. An aggregate for porous concrete having a weight percentage of 15 % and a cement content of 15% by weight or less, wherein the raw material mixture is solidified in a granulated state to an average particle diameter of 5 to 50 mm.   The aggregate for porous concrete according to claim 1, comprising 0 to 5% by weight of quicklime. Porous concrete formed by combining aggregates with voids in a state having voids,
The aggregate contains coarse aggregate obtained by granulating and solidifying a raw material mixture containing fly ash as a main raw material and cement to an average particle size of 5 mm to 50 mm,
Furthermore, this aggregate contains fly ash of 50% by weight or more, and further contains fine aggregate in addition to fly ash and cement, and this fine aggregate is crushed sand obtained by crushing natural stone, and its inclusion Porous concrete having an amount of 20 to 40 % by weight and a cement content of 15% by weight or less. The porous concrete according to claim 3 , wherein the aggregate contains 0 to 5% by weight of quicklime. The porous concrete according to claim 3 , wherein the binder for bonding the aggregate is cement mortar.