JPH01127705A - Sprinkler for asphalt - Google Patents

Abstract

PURPOSE: To improve sprinkled properties wettability, and stability by providing a nozzle to spray a spray assistant for dropping the viscosity of asphalt on a discharge nozzle part of an asphalt heating and melting furnace. CONSTITUTION: Asphalt is charged from an asphalt charging inlet 8 into a melting container 3 in an oil bath 1 with a thermal oil 2, and melted by a heating device 4. When asphalt is discharged and sprayed from a discharge nozzle part 6 by compressed air introduced through an inlet pipe 9, a spray assistant for dropping the viscosity of asphalt is ejected from a tank 7 with compressed air introduced through an inlet pipe 11. High viscosity asphalt is dropped in viscosity to improve the spraying property, wettability and stability.

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field) The present invention relates to an asphalt spreading device. More specifically, the present invention relates to a high-performance asphalt spreading device in which the viscosity of high-viscosity asphalt is reduced to improve spreadability, wettability, stability, etc.

(Background Art) Conventionally, asphalt has been spread by discharging asphalt melted in a heating melting furnace using compressed air.

For example, as shown in the attached Figure 5, heating medium oil (
Asphalt (1) is charged into the melting furnace (1) in the oil bath (B) containing (A), heated by a gas burner (O), and the asphalt (1) is melted. By feeding compressed air (x) through the nozzle, molten asphalt is discharged and dispersed from the discharge nozzle. The asphalt is charged through the inlet (ge), and the pressure is monitored with a pressure gauge (k) and the oil bath temperature with a bath thermometer (su).

In such a device, at a temperature of 200°C, 140°C
When distributing high viscosity asphalt with a viscosity of 0 to 2000 CDS, 2 kf/
It is necessary to spray at - pressure. Only in this state does the asphalt become atomized.

However, spreading high viscosity asphalt with such conventional equipment is not practical in practice, since the penetration is 10/20, 20/30, 40/6.
This is because heating the above-mentioned high viscosity asphalt such as 0.0 to 200° C. or higher causes thermal deterioration of the asphalt. It is necessary to maintain the temperature at least below 200°C before spraying.

However, to date, no asphalt spreading apparatus has been realized that can meet such demands.

(Object of the Invention) This invention was made in view of the above circumstances, and it improves the shortcomings of conventional spreading equipment, and provides high-efficiency spreading at a lower temperature suitable for spreading high-viscosity asphalt. A new asphalt spreading bag that realizes:

(Disclosure of the Invention) In order to achieve the above object, the asphalt spreading device of the present invention connects a pressurized asphalt viscosity-lowering spreading aid tank to a discharge nozzle connected to an asphalt heating and melting furnace. , asphalt discharge nozzle tip jlii
3! It is characterized in that a nozzle for spouting the auxiliary agent from the tank is inserted into the x fM.

The apparatus of the present invention will be explained along with the attached drawings.

FIG. 1 is a schematic sectional view showing an example of the present invention.

As shown in this example, the asphalt spreading device consists of a melting vessel (2) placed in a heat transfer oil (2) in an oil bath (1).
3) and a heating device consisting of a gas burner, etc. ! (4) An asphalt heating and melting furnace consisting of an on-off valve (
5), and a pressurized asphalt viscosity-lowering spreading aid tank (7) connected thereto.

The melting container (3) is equipped with an asphalt inlet (8), a compressed air supply pipe (9), and a pressure gauge (10), and the asphalt viscosity-lowering spreading agent tank (7) is equipped with:
It is equipped with a compressed air inlet pipe (11) and a pressure gauge (12).

FIG. 2 shows an example of the appearance of the discharge nozzle (6). A branch nozzle is arranged which connects to the tank (7). As shown in Figure 3, this branch nozzle has molten asphalt (A) in the asphalt feed pipe (13).
An auxiliary agent jet nozzle (15) is inserted near the asphalt discharge nozzle tip (14). The auxiliary agent (B) is discharged from this jet nozzle (15). It is also preferable to heat this vicinity.

At the tip of the asphalt discharge nozzle (14), the asphalt (A>) and the asphalt viscosity-lowering spreading aid (B) are rapidly mixed and sprayed.The mixing is uniform and the spread of the spray is wide. , no clogging of the nozzle tip occurs.

FIGS. 4(a) and 4(b) illustrate the front and bottom surfaces of the asphalt discharge nozzle tip (14).

The outlet of the nozzle tip (14) is preferably fan-shaped.

The spraying device of the present invention exhibits excellent effects when spraying not only ordinary asphalt but also high-viscosity asphalt.

High viscosity asphalt has a temperature of 1400 to 200℃.
Products with a viscosity of 2000 CEIS are targeted, and conventionally known viscosity-lowering dispersion aids such as water, hot water, and even light oil can be used, but natural rosin, 05-05 to One of C9 petroleum resin, alkylphenol resin, and coumaron-indene resin
An aqueous emulsion containing one or more of 1a and a diester type nonionic anion activator is used.

This aqueous emulsion has excellent dispersibility, wettability of asphalt to aggregate, stability, etc.

When using this, 1/2 of asphalt
0 to 1/30, an asphalt temperature of 180 to 183°C, and a spraying pressure of 2 to 4 kf/ali. By adding an auxiliary agent such as an aqueous emulsion, asphalt is foamed, and the dispersibility of high-viscosity asphalt is significantly improved.

Next, the present invention will be explained in more detail by showing examples.

Example 1 Using the apparatus illustrated in FIGS. 1, 2, and 3 equipped with a fan-shaped nozzle with a nozzle size of 9.5 wXd shown in FIG. 1800
CDS high viscosity asphalt was spread.

The height from the outlet of the asphalt discharge nozzle to the spraying surface was 350 to 370B. Further, as the viscosity-lowering spreading aid, an aqueous emulsion heated to 70 to 90°C was used. This emulsion contains natural rosin (viscosity 480C).
I) S (20°C), pH 8.5-9.5) approx. 48
% by weight and 0.1% di(polyethylene ether) alkyl phosphate activator.

Asphalt is heated to 180-183℃ and heated to 2-4kI.
Sprayed at r/-.

The dispersion status was evaluated. Table 1 shows the results. For comparison, the spraying situation was also evaluated when no auxiliary agent was used. The spraying area of the device of this invention is large and there is no uneven spraying.

Table 1 Example 2 The asphalt of Example 1 was sprayed at different temperatures, and the expansion ratio and residual moisture in the asphalt (in the asphalt after spraying) were evaluated.

The results are shown in Table 2.

The higher the temperature of the asphalt, the larger the bulk.
Less residual moisture. If there is little residual moisture, interfacial peeling will not occur after spraying.

Table 2 Reference Example The shape of the outlet of an asphalt discharge nozzle was studied using a conventional device. The apparatus shown in FIG. 5 was used.

For comparison, two nozzle exit shapes with 7.5 teeth and 6.5 teeth were used for comparison.
A fan-shaped nozzle exit shape of 5 m x 4 m was used.

The spread of asphalt was evaluated. The fan-shaped one used in Example 1 was also excellent in spreading the spray.

The results are shown in Table 3.

Table 3 (Effects of the Invention) As explained in detail above, with the apparatus of the present invention, the asphalt can be spread over a large area, and a good atomization state can be achieved even in the case of high viscosity asphalt.

There is no uneven distribution.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing an example of the device of the present invention. Figure 2 is a front view showing the appearance of the discharge nozzle section;
The figure is a sectional view showing the tip of the discharge nozzle part, and FIG.
) and (b) respectively show a front view and a bottom view showing the nozzle tip outlet. FIG. 5 is a sectional view showing a conventional device. 1...Oil bath, 2...Hot niece oil, 3...
・Melting container, 4... Heating device, 5... Opening/opening valve, 6... Discharge nozzle section, 7... Spreading aid tank, 8... Asphalt inlet, 9... Feeding
Pipe, 10... Pressure gauge, 11... Feed pipe,
12... Pressure gauge, 13... Asphalt feed piping, 14... Discharge nozzle tip, 15... Auxiliary agent jet nozzle. Agent Patent Attorney Toshi Nishizawa Okiku 3
Figure 4 Figure 5

Claims (2)

[Claims] (1) Connect a pressurized asphalt viscosity-lowering spreading aid tank to the discharge nozzle connected to the asphalt heating and melting furnace, and insert a nozzle to spray the aid from the tank near the tip of the asphalt discharge nozzle. Asphalt spreading equipment characterized by: (2) The asphalt spreading device according to claim 1, wherein the asphalt discharge nozzle has a fan-shaped outlet.