JPH0522831Y2 - - Google Patents

Description

[Detailed Description of the Invention] "Industrial Application Field" The present invention relates to a heat-retaining device for keeping the asphalt in the measuring device warm, in an asphalt measuring device used mainly in an asphalt mixture manufacturing device.

"Conventional technology" Generally, asphalt used in the production of asphalt mixture is heated and kept at around 150 to 160°C in storage equipment (asphalt tanks), and the required amount is transferred during the production of asphalt mixture. The amount is measured in a measuring tank and then injected into an asphalt mixture mixing device (mixer). At this time, if the asphalt put into the measuring tank at the beginning of measurement is cooled by the wall of the measuring tank, the viscosity of the asphalt will increase, leading to deterioration of measurement accuracy, and if the asphalt is injected into the mixer. There is a problem in that the quality of the asphalt mixture deteriorates due to an adverse effect on the injection state of asphalt. For this reason, conventionally, as shown in FIG. The measuring tank 1 is kept warm through the overflow tank 2 by circulating heat medium oil at 160°C, or the area around the funnel part 2a of the overflow tank 2 as shown in FIG. An electric heating cable 4 is disposed in the tank, and the overflow tank 2 is covered with a heat insulating material 5, so that the measuring tank 1 is heated and kept warm via the overflow tank 2 by the electric heating cable 4. .

"Problems to be Solved by the Invention" However, the above-mentioned conventional heat retention devices indirectly keep the measuring tank 1 warm by heating and keeping the overflow tank 2 warm.
Since the air layer A is interposed between the overflow tank 2 and the measuring tank 1, heat transfer efficiency is poor, and it takes time for the measuring tank 1 to reach a predetermined temperature, and heat loss is high. The problem is that it is large and consumes a lot of energy.

This invention was made in view of the above circumstances,
The purpose is to provide a heat-retaining device for an asphalt weighing device that can efficiently and quickly heat and keep a weighing tank warm, has little heat loss, is energy-saving, and can be easily managed.

``Means for Solving the Problems'' In order to achieve the above object, the present invention has a take-out port that can be opened and closed at the lower end, and a measuring tank placed in the overflow tank has a take-out port of the asphalt tank. A supply end of a switching valve, in which a pipe and a return pipe are individually connected to a receiving end and a circulation end, is connected via a supply pipe, and the funnel part of the overflow tank has a
An asphalt metering device in which an injection pump is connected to the injection pump via a connecting pipe, and a spray device is connected to the injection pump via a transfer pipe,
A first electric heating cable is attached to the outer periphery of the measuring tank.
A second electric heating cable is connected to the take-out pipe, the return pipe, and the switching valve, a third electric heating cable is connected to the funnel part of the overflow tank and the connecting pipe, and a fourth electric heating cable and a fifth electric heating cable are connected to the transfer pipe. A sixth electric heating cable and a seventh electric heating cable are respectively attached to the injection pump, and the second, third, fourth, fifth, sixth, and seventh electric heating cable portions and the supply pipe are attached to the injection pump. and an overflow tank is provided with a heat insulating material to cover them, while a first temperature sensor for controlling the first electric heating cable is attached to the first electric heating cable, and the second, third, fourth, The fifth electric heating cables are connected in series with each other, and a second temperature detector is attached to the second, third, fourth, and fifth electric heating cables to control them, and the sixth and seventh electric heating cables are further connected to each other in series. The cables were connected in parallel to each other, and a third temperature detector was attached to the sixth and seventh electric heating cables to control them.

"Function" The first electric heating cable directly heats the measuring tank. The part where the series-connected second to fifth electric heating cables are installed and the measuring tank do not vibrate significantly, so the heating cable is less likely to break, and even in the unlikely event that it breaks and the asphalt hardens. All the extraction pipes, transfer piping, etc. have simple structures and can be quickly restored.

The sixth and seventh electric heating cables connected in parallel are subject to the vibrations of the injection pump, and are therefore relatively susceptible to disconnection. However, because one heating cable continues to heat the injection pump, the asphalt in the injection pump is not completely cured.

"Embodiment" Hereinafter, an embodiment of the present invention will be described based on FIGS. 1 to 3.

In the figure, reference numeral 10 denotes a weighing tank for storing asphalt and measuring its weight.
A switching valve 11 is provided above which connects a supply pipe 12 for supplying asphalt into the measuring tank 10 to a supply end 11a. Further, at the receiving end 11b of this switching valve 11, there is an outlet pipe 13 and an outlet pipe 13.
An asphalt tank 15 is connected to the asphalt tank 15 via a circulation pump 14 installed in the middle of the switching valve 11 , and a return pipe 16 connects the circulation end 11 c of the switching valve 11 to the asphalt tank 15 .

At the lower end of the measuring tank 10, an outlet 10a is formed for discharging the asphalt inside. It is designed to be opened and closed. Further, an overflow tank 18 is installed around the measuring tank 10, and this overflow tank 18 has a
An injection pump 20 is connected via a connecting pipe 19. A transfer pipe transfer piping 21 having a three-way valve 22 at its intermediate portion is connected to the injection pump 20, and a branch pipe transfer pipe 23 is connected to the tip of this transfer pipe 21. Furthermore, branch pipe 2
A spray device 25 for injecting asphalt into a mixer device 24 for manufacturing an asphalt mixture is connected to both ends of the asphalt mixture.

Furthermore, a first
The electric heating cable R ₁ is wound around a plurality of attachment pieces 26, and a middle part of the outer circumference has a
A temperature sensing portion 27a of a first temperature detector (thermostat) 27 is attached. The first electric heating cable R ₁ and the first temperature detector 27 are connected in series to the power source E, and the first temperature detector 27 is connected to the power source E in series.
By opening and closing 7, the measuring tank 10 is maintained at a predetermined temperature (for example, 130° C.). Also, a second electric heating cable is connected from the outlet pipe 13 to the return pipe 16 via the switching valve 11.
R ₂ and a third electric heating cable R ₃ extending from the lower outer periphery of the funnel portion 18a of the overflow tank 18 to the connecting pipe 19;
and a fourth electric heating cable _R4 to the three-way valve 22,
Furthermore, the fifth electric heating cable is connected to the branch pipe 23.
R ₅ are attached by a plurality of attachment pieces 26, respectively. A temperature-sensing section 28a of a second temperature detector (thermostat) 28 is attached near the joint of the branch pipe 23 with the transfer pipe 21, and a temperature-sensing section 28a of a second temperature detector (thermostat) 28 and a third 2nd, 5th, 4th electric heating cables R ₃ , R ₂ ,
R ₅ and R ₄ are connected in series to the power supply E, and the second
By opening and closing the temperature detector 28, the above-mentioned take-out pipe 13, switching valve 11, return pipe 16, overflow tank 18, connecting pipe 19, transfer pipe 21, three-way valve 2
2. The branch pipes 23 are each kept at a predetermined temperature (e.g.
temperature (150℃). moreover,
Sixth and seventh electric heating cables R ₆ and R ₇ are respectively wound around the injection pump 20,
In addition, a temperature sensing portion 29a of a third temperature detector (thermostat) 29 is attached. One end of each electric heating cable R ₆ , R ₇ is connected to one end of the power source E via the third temperature detector 29, and the other end of each electric heating cable R ₆ , R ₇ is connected to the other end of the power source E. By opening and closing the third temperature detector 29, the injection pump 20 is maintained at a predetermined temperature (for example, 150° C.).

In addition, the above-mentioned take-out pipe 13, switching valve 11, return pipe 1
6, supply pipe 12, overflow tank 18, connecting pipe 19, injection pump 20, transfer pipe 21, three-way valve 2
2. A heat insulating material 30 is provided to cover the outer periphery of the branch pipe 23, and each electric heating cable R ₂ ~
A wire mesh 31 is interposed between R ₇ and the heat insulating material 30.

When injecting a required amount of asphalt into the mixer device 24 using the asphalt supply system of the asphalt mixture production apparatus configured as described above, first, the circulation pump 14 is used to inject the extraction pipe 13, The asphalt circulating in the order of the switching valve 11, the return pipe 16, the asphalt tank 15, and the circulation pump 14 is metered through the supply pipe 12 by communicating the receiving end 11b and the supply end 11a of the switching valve 11. It is supplied into the tank 10. and,
When the required amount of asphalt is stored in the measuring tank 10, the switching valve 11 is switched to the circulation side,
The supply of asphalt into the measuring tank 10 is stopped.

Next, the rod 17a of the cylinder 17 is operated to open the outlet 10a of the measuring tank 10, and the asphalt is discharged from the measuring tank 10. In this case, the first electric heating cable R ₁ wrapped around the outer circumference of the measuring tank 10 is controlled on and off by the opening/closing operation of the first temperature detector 27, so that the measuring tank 10 is maintained at a predetermined temperature. Therefore, measuring tank 1
The temperature of the asphalt contained in the measuring tank 10 does not drop, and the viscosity of the asphalt does not increase and adhere to the inside of the measuring tank 10. Therefore, the measured value of asphalt is not adversely affected, and high measurement accuracy can always be obtained. The asphalt discharged from the metering tank 10 is sent to the injection pump 20 via the overflow tank 18 and the connecting pipe 19, and then to the transfer pipe 21 and the branch pipe 23.
through the spray device 2 in the mixer device 24
5, it is injected into the mixer device 24. At this time, each electric heating cable R ₁ , R ₃ to _{R 7}
- The overflow tank 1 is controlled on and off by the opening and closing operations of the third detectors 27, 28, and 29.
8, connecting pipe 19, injection pump 20, transfer pipe 21,
Since the three-way valve 22 and the branch pipe 23 are kept at a predetermined temperature, the asphalt passing through them is always maintained at a predetermined temperature, and the increase in the viscosity of the asphalt can adversely affect the injection pump 20 (overload). ) or deterioration of the spraying condition in the spray device 25.

``Effect of the invention'' As explained above, the present invention has a take-out port that can be opened and closed at the lower end, and connects the take-out pipe and return pipe of the asphalt tank to the receiving end and the measuring tank placed in the overflow tank. Supply ends of the switching valves individually connected to the circulation ends are connected via supply pipes,
An injection pump is connected to the funnel part of the overflow tank by a connecting pipe, and a spray device is connected to the injection pump via a transfer pipe. A first electric heating cable is connected to the outlet pipe, the return pipe and the switching valve, a third electric heating cable is connected to the funnel part and the connecting pipe of the overflow tank, and a third electric heating cable is connected to the transfer pipe. A fourth electric heating cable and a fifth electric heating cable are attached to the injection pump, and a sixth electric heating cable and a seventh electric heating cable are respectively attached to the injection pump. , a heat insulating material is provided to cover the seventh electric heating cable, the supply pipe and the overflow tank, and the first electric heating cable is provided with a first temperature sensor for controlling the first electric heating cable. The second, third, fourth, and fifth electric heating cables are connected in series with each other, and the second, third, fourth, and fifth electric heating cables are provided with a second temperature for controlling them. A detector is attached, and the above-mentioned sixth and seventh detectors are attached.
The electric heating cables are connected in parallel to each other, and the sixth and seventh electric heating cables are provided with a third temperature detector for controlling them, and the measuring tank is controlled by the first electric heating cable. By heating and keeping the asphalt at a predetermined temperature, the control response of the temperature in the weighing tank is good, and the asphalt in the weighing tank can be quickly and reliably maintained at the predetermined temperature without being affected by temperature changes due to seasonal fluctuations. It is possible to prevent the viscosity of asphalt from increasing due to a decrease in asphalt temperature. Therefore,
Asphalt does not adhere to the inner wall of the measuring tank, and measurement accuracy can be maintained at a high level, and there is no problem with the transfer of asphalt after measurement. In addition, since the measuring tank is directly heated, heat loss from the outer periphery of the overflow tank can be kept to an extremely small level due to the air layer between the measuring tank and the overflow tank and the heat insulating material in the overflow tank. It has the excellent effect of reducing power consumption by 60 to 70% compared to conventional methods. Moreover, the second to fifth electric heating cables are connected to each other in series, and if a disconnection occurs at one point, the power supply to these heating cables is stopped, but the outlet tubes provided with the second to fifth electric heating cables The parts such as the pipes and transfer piping do not vibrate significantly, so there is almost no chance of wire breakage, and even if a wire breaks, the asphalt will not harden because the take-out pipes and transfer pipes have simple structures. The disconnection can be repaired and measurement can be resumed quickly without any damage caused by the disconnection.

The sixth and seventh electric heating cables are relatively easily disconnected due to the vibration of the injection pump, but both electric heating cables are connected in parallel to each other,
Even if one wire breaks, the other one continues to heat the injection pump, preventing complete hardening of the asphalt in the injection pump, which has a complex structure. This prevents the injection pump from malfunctioning and makes maintenance management easier overall. It is.

[Brief explanation of the drawing]

Figures 1 to 3 show an embodiment of the present invention, where Figure 1 is a side view, Figure 2 is a schematic diagram of the asphalt supply system, and Figure 3 is an electrical circuit diagram of each part. a is a circuit diagram of the measuring tank section, b is a circuit diagram of each piping section, c is a circuit diagram of the injection pump section, Fig. 4 is a schematic explanatory diagram of a conventional circulation type heat retention device, and Fig. 5 is a conventional electric circuit diagram. FIG. 2 is a schematic explanatory diagram of a heating type heat retention device. R ₁ ...First electric heating cable, 10...Measuring tank, 18...Overflow tank, 27...First
Temperature detector (thermostat), 30...Heat insulation material.

Claims (1)

[Scope of utility model registration request] A take-out port 10a that can be opened and closed is provided at the lower end, and the take-out pipe 13 of the asphalt tank 15 is connected to the measuring tank 10 placed in the overflow tank 18.
The supply end 11a of the switching valve 11, in which the return pipe 16 is connected to the receiving end 11b and the circulation end 11c, is connected via the supply pipe 12, and an injection pump 20 is connected to the funnel part 18a of the overflow tank 18. A spray device 25 is connected to the injection pump 20 via a connecting pipe 19, and a spray device 25 is connected to the transfer pipe 2.
1 and 23, a first electric heating cable R1 is connected to the outer periphery of the measuring tank 10, and a first electric heating cable _R1 is connected to the outlet pipe 13 and the return pipe 1.
6 and the switching valve 11, and a third electric heating cable _R2 is connected to the funnel part 18a of the overflow tank 18 and the connecting pipe 19.
_R3 , a fourth electric heating cable _R4 and a fifth electric heating cable _R5 are connected to the transfer pipes 21 and 23, and a sixth electric heating cable _R6 is connected to the injection pump 20.
and 7th electric heating cable R ₇ are attached respectively,
Heat is maintained in the second, third, fourth, fifth, sixth, and seventh electric heating cables R ₂ , R ₃ , R ₄ , R ₅ , R ₆ , and R ₇ , the supply pipe 12, and the overflow tank 18. Material 1
8 is provided over them, while said first electrical heating cable R ₁ includes said first electrical heating cable R 1 .
A first temperature detector 27 for controlling R ₁ is attached,
Further, the second, third, fourth, and fifth electric heating cables R ₂ , R ₃ , R ₄ , and R ₅ are connected in series with each other, and the second, third, fourth, and fifth electric heating cables are connected to each other in series. A second temperature detector 28 is attached to R ₂ , R ₃ , R ₄ , and R ₅ to control them, and the sixth and seventh electric heating cables R ₆ and R ₇ are connected in parallel to each other. The sixth and seventh electric heating cables R ₆ ,
A heat retention device for an asphalt measuring device, characterized in that _R7 is provided with a third temperature detector 29 for controlling them.