JP2657399B2 - Improved asphalt mastic - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an improved asphalt mastic used for a barrier layer of various reservoirs including dams.

[Conventional technology]

Irrigation structures in which a water barrier is installed on the slopes of dams and various reservoirs are well known.

For example, the slope of the fill dam may be faced with an asphalt mixture to maintain water tightness, or the reservoir may be faced to maintain the water tightness of the entire reservoir.

By the way, the conventional asphalt mastic used as a surface protective layer of the asphalt mixture for water impermeable is mainly an asphalt mastic obtained by adding limestone powder, that is, a filler, to asphalt or a mixture of straight asphalt and blown asphalt, and asbestos. Was widely used.

Needless to say, the purpose of using asbestos is to prevent dripping of asphalt mastic on slopes.

[Problems to be solved by the invention]

However, asbestos is designated as a carcinogen and its use is strictly regulated. Therefore, as with asbestos, there has been a strong demand for the development of an additive which has a dripping prevention effect and is not a harmful substance.

The present invention has been developed for the purpose of responding to such a demand, and an object of the present invention is to provide an asphalt mastic having improved workability and higher water blocking effect than conventional products.

[Means for solving the problem]

As means for achieving the above object, the present invention relates to wollastonite (scientific name: Wollas), which has been used as a filler for improving the rigidity, dimensional stability, surface smoothness and other functions of a synthetic resin material.
The focus is on tonite wollastonite, CaSiO ₃ ), which has been used in asphalt mastics as an additive in place of the harmful asbestos.

As is well known, wollastonite is classified into granular and granular α-forms and acicular and long pillar-shaped β-forms. Its substances are CaO and SiO ₂
It is a white natural product consisting of almost the same amount as the above and is a chemically stable substance. And it is not as harmful as asbestos. By the way, the harmlessness of wollastonite has already been proved by various research studies.

For example, a research paper (SC) based on an immunological survey of workers working at wollastonite mining sites
AN.J.WORK ENVIRON.HEALTH (FINLAND) 1983.9 / 2,169-1
75, Hunskonen MS et al, Preliminary results from a
cohort of workers exposed to Wollastonite in a Fin
nish limestone quary.) or (Shasby DM. Petersen M. Hodons T, Boehlecke B, Mercha
n J, “Respiratory morbidity of workers exposed to
Wollastonite through mining and miling In: Lemen R.
Dement FM, eds.Dusts and disease.Park Forest South,
Illinois: Pathotox Publisher, Inc. 1979, 251-6) Furthermore, a paper on the shape of crystalline fibers and carcinogenicity (J.NA)
T.CHANCER INST (USA) 1981.67 / 5 1965/975), Stato
n MFet al Relation of particle dimention to carc
inogenicity amphibole asbestoses and other fibrous
minerals.) Others have denied its hazards.

Therefore, the present invention focuses on the fact that wollastonite is harmless as described above, is low in impurities and high in quality, and is inexpensive. This is used for asphalt materials and stone powder (filler) as follows. The resulting mixed asphalt mastic, that is, detoxified improved asphalt mastic was obtained.

Asphalt (Blown, straight) 25-40% Stone powder (filler) 50-70% Wollastonite (Wollastonite) 5-20% [Action] As a result of constructing the impermeable layer on the dam slope using the above asphalt mastic, The workability and the water-shielding property were high, and there was no flow after the work, and the intended purpose was sufficiently satisfied.

〔Example〕

Further, the functionality of the asphalt mastic according to the present invention will be specifically described based on examples.

First, equal amounts of heated straight asphalt and blown asphalt are mixed, and stone powder and wollastonite are added and kneaded at the weight ratios shown in Table 1, and the mixture is heated and kneaded again until the mixture becomes a paste. Made asphalt mastic for Then, a flow-con test was conducted to confirm the viscosity of the improved asphalt mastic during construction, and a slope flow test was conducted to confirm the fluidity after construction.

In the above examples, wollastonite having β structure was used.

FIG. 1 is a graph showing the results of a flow control test of asphalt mastic according to the mixing ratio shown in Table 1 above, and FIG. 2 similarly shows the results of a slope flow test for confirming the fluidity after construction. Things.

For comparison, FIGS. 1 and 2 also show the test results of a conventional asphalt mastic to which asbestos was added.

First, before examining the test results, the workability of asphalt mastics, which are generally used for dams or reservoir surfaces, that is, the impermeable layer on the inclined surface, whether or not a dripping phenomenon occurs during construction, flow values from this viewpoint Will be described.

As is well known, if the viscosity of the asphalt mastic at the time of construction, that is, the flow value is too large, the construction becomes difficult, and if it is too low, the asphalt mastic flows down and the function as a water barrier layer is impaired.

Therefore, empirically, the flow value of asphalt mastic used for impermeable construction on slopes such as dam slopes is 5 to 15
The range of seconds is appropriate.

From this point of view, it is understood from the test results shown in FIG. 1 that the addition amount of wollastonite is optimally in the range of 7 to 10% by weight. Furthermore, when wollastonite is added, the change in flow value is gentle even if the addition amount is increased, and if the addition amount is regulated to 7 to 10% as described above, the so-called drooling during construction is reduced. Don't worry.

Therefore, the present invention is based on the above test results, the weight ratio of asphalt: stone powder: wollastonite is 25-40%: 50-70%, 5
Set to ~ 20%. However, it should be noted that there is a slight variation in the compounding ratio depending on the slope gradient. In any case, according to the asphalt mastic having the above mixing ratio, it was possible to perform the construction without fear of dripping.

By the way, when conventional asbestos, which is a pollutant, is added, the viscosity increases greatly depending on the amount added, as assumed from Fig. 1, making workability extremely difficult. The significance of the stone was established.

Next, the results of the slope flow test, which is an index for stability after construction, are shown in FIG. 2 if the amount of wollastonite is regulated to 7 to 10% (weight ratio) in view of the test conditions shown in FIG. It is apparent that there is no problem, as the addition amount within the range of 5 to 20% by weight of wollastonite set based on the flow-con test is not a problem.

〔The invention's effect〕

If the wollastonite is added in a controlled manner at a weight ratio of 7 to 10%, preferably 5 to 15% as proved by the flow-con test and the slope flow test, the workability is maintained and It can function as an asphalt mastic that maintains stable watertightness without the risk of loss of the water blocking function due to dripping.

Therefore, when the asphalt mastic according to the present invention is used, the pollution problem including the so-called carcinogenic problem can be solved at once, and wollastonite is a natural product, which is extremely inexpensive, and is significantly more significant than conventional asbestos. It is.

[Brief description of the drawings]

FIG. 1 is a graph showing a flow-con test result of the improved asphalt mastic according to the present invention, and FIG. 2 is a graph showing a slope-flow test result.

Claims (2)

(57) [Claims] An asphalt mastic for use as a water barrier layer in a reservoir or the like obtained by mixing heated asphalt, stone powder, and needle-like or long columnar wollastonite, and then heating and kneading the mixture until it becomes a paste. 2. The impermeable layer according to claim 1, wherein the mixing ratio of asphalt: stone powder: wollastonite is 25-40%: 50-70%: 5-20% by weight. Improved asphalt mastic used.