JPH0454411Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a level meter for measuring the level of asphalt stored in an asphalt tank.

[Conventional technology]

In an asphalt plant, the asphalt plant stored in an asphalt tank is supplied to a mixer, and aggregate and asphalt are kneaded in this mixer.

Asphalt tanks include, for example, electrically heated asphalt tanks, in which asphalt is heated and stored in a liquid state with low viscosity.

As a method for externally detecting the amount of asphalt stored in this asphalt tank, a float type level meter as shown in FIG. 3 has conventionally been used. That is, in the figure, an appropriate amount of asphalt 2 is stored in an asphalt tank 1. The asphalt is heated by a heating device (not shown) to become a liquid with low viscosity, and a float 30 is disposed on the liquid surface. And the float 30 has a wire 3
1 is attached to the asphalt tank 1, and the wire 31 is hung on a pulley 32 provided at the top of the asphalt tank 1, and is suspended along the outer peripheral wall of the asphalt tank 1. And this wire 31
A weight 33 is attached to the tip.

In FIG. 3, as the asphalt 2 in the asphalt tank 1 is consumed and the liquid level decreases, the weight 33 moves upwards, and the scale 34 attached to the outer wall of the asphalt tank 1 indicates the amount of asphalt in the asphalt tank 1. The amount of Asphalt 2 stored is made legible.

However, in the conventional structure, since the operation is mechanical, the wire 31 may come off the pulley 32, the asphalt 2 may adhere to the pulley, etc., and maintenance must be performed frequently. Ta.

In addition, since the stored amount of asphalt 2 is determined by directly reading the scale 34 on the outer wall of the asphalt tank 1, there is a problem that the information cannot be used for remote control such as replenishing asphalt. It was hot.

On the other hand, as a device for detecting liquid level,
There are devices using strain gauges (piezoelectric elements) such as those described in Japanese Utility Model Application Publication No. 56-142329 and Japanese Patent Application Publication No. 55-146013. These devices detect changes in the buoyancy force applied to a weight immersed in liquid as changes in stress applied to a strain gauge connected to the weight, and output this as an electrical signal.

[Problem that the invention attempts to solve]

However, when measuring the level in an asphalt tank using such a strain gauge, a new problem arises in that gas in the asphalt tank flows into equipment such as the strain gauge and damages the equipment.

Therefore, the object of the present invention is to provide an asphalt tank level meter that does not damage the strain gauge, does not require maintenance, and can remotely display the asphalt tank level even under the harsh environment of an asphalt tank.

[Means for solving problems]

In order to achieve this purpose, the asphalt tank level meter of the present invention includes a level meter storage box disposed outside the upper part of the asphalt tank, an annular nonflammable liquid tank formed at the bottom of the level meter storage box, and the level meter The upper part of the strain gauge is supported in a storage box, and a downwardly opened cup whose lower peripheral edge is immersed in the nonflammable liquid in the nonflammable liquid tank is connected to the lower part of the strain gauge. Connect the upper part of a corrosion-resistant wire such as a wire for suspending a detection rod that is immersed for a predetermined length in the asphalt in the asphalt tank to the center of the inner bottom, and connect the detection rod to the asphalt in the asphalt tank. Calculate the immersion length x based on the difference between the electrical output of the strain gauge corresponding to the load w of the detection rod applied to the strain gauge and the load w ₀ of the detection rod when not immersed, and calculate the calculated value. The present invention is characterized by providing means for calculating the level of asphalt in the asphalt tank based on the following.

[Effect]

In the present invention, a detection rod suspended from a strain gauge is immersed in asphalt. The detection rod receives buoyancy from the asphalt, and the magnitude of the buoyancy is proportional to the length of the detection rod immersed in the asphalt. The strain gauge is loaded with the difference between the weight of the detection rod and the buoyant force, and the strain gauge emits an electrical output corresponding to the difference. The output signal is converted to the level of the asphalt tank and displayed on the indicator. When the liquid level changes, a display is made according to the change. The output signal of the strain gauge is not only displayed, but also can be used as information for other control systems.

The inside of the asphalt tank and the level meter storage box that houses the strain gauge are sealed with a cup and nonflammable liquid, so the gas in the asphalt tank will flow into the level meter storage box that houses the strain gauge. This prevents damage to equipment such as strain gauges inside the box.

〔Example〕

Hereinafter, the present invention will be specifically explained based on embodiments shown in the drawings.

FIG. 1 is a sectional view showing the main parts of an asphalt tank level meter according to the present invention.

In the figure, 1 is an asphalt tank,
Asphalt 2 is stored inside. A detection rod 3 made of stainless steel or the like with high corrosion resistance is suspended from the asphalt 2 by a wire 4. The upper end of the wire 4 is fixed to a cup 5 that opens downward. A level meter storage box 6 which also serves as a drip-proof rain cover is fixed to the upper wall of the asphalt tank 1 via a seal packing 7. In the level meter storage box 6, the strain gauge 8 is attached to a fixture 9.
The strain gauge 8 and the cup 5 are connected by a connector 10.
An annular nonflammable liquid tank is formed at the bottom of the level meter storage box 6, and a nonflammable liquid 11 is placed in the annular tank.
is filled to the required depth, and this non-flammable liquid 1
First, the opening of the cup 5 is immersed, thereby preventing vaporized substances in the asphalt tank 1 from entering the level meter storage box 6 and adversely affecting the strain gauge 8. Note that in order to keep the level of the nonflammable liquid 11 constant, the asphalt tank 1 is provided with an air vent 12. Further, an extruded portion 6a that also serves as a rain shield is formed around the level meter storage box 6 to prevent the pressure and temperature inside the level meter storage box 6 from rising.

In Fig. 1, the detection rod 3 is suspended by a wire 4 so as not to move up and down, and covers at least the lowest liquid level H _L of asphalt 2 in the asphalt tank 1 to the highest liquid level H _H. Leave it at the desired length. Now, let w ₀ be the total load applied to the strain gauge 8 when the detection rod 3 is not immersed in the asphalt 2.
Next, considering a state in which the detection rod 3 is immersed x cm into the asphalt 2 from below, the buoyant force F is expressed by the following formula.

F=S×x×ρ However, S is the cross-sectional area of the detection rod 3, and ρ is the specific gravity of asphalt.

Therefore, the load w applied to the strain gauge 8 is w=w ₀ −F=w ₀ −S×x×ρ. From this, by determining the change in the load applied to the strain gauge 8, it is possible to calculate the position from the tip of the detection rod 3 that the liquid level of the asphalt 2 has reached.

x=(w ₀ −w)/(S×ρ) As shown in FIG. 2, the output of the strain gauge is amplified by an amplifier. From the output signal, a load corresponding to the initial load is subtracted, and the level at which the lower end of the detection rod 3 is located in the asphalt tank is added, and this is given as a reference value. The correction signal is given to a display and displayed as the liquid level in the asphalt tank. Note that the signal can also be output to the servo system. By correcting the asphalt level in the asphalt tank based on the shape of the asphalt tank, it is also possible to calculate the amount (volume) of asphalt stored in the asphalt tank.

[Effect of idea]

As explained above, in the present invention, changes in buoyancy applied to a detection rod suspended in an asphalt tank without vertical movement are detected using a strain gauge, and this is extracted as an electrical signal. ing. As there are no mechanically contacting or moving parts, there are fewer failures and the asphalt level in the asphalt tank can be measured with high accuracy. Furthermore, since it is easy to create an explosion-proof structure, it is safe even when installed in a flammable tank. Since the asphalt level signal can be extracted as an electrical signal, it can be displayed on a remote display and used as data recorded by a recorder or the like. Because the inside of the asphalt tank and the outside of the tank where the strain gauge is installed are isolated with a cup and non-flammable liquid, the gas inside the asphalt tank will not liquefy or solidify, contaminating the area around the level gauge or causing malfunction. , high precision measurements can be maintained over a long period of time.

[Brief explanation of drawings]

FIG. 1 is a schematic explanatory diagram of an embodiment of the present invention, FIG. 2 is a block diagram of an electrical system, and FIG. 3 is a sectional view showing an example of a conventional level meter. 1... Asphalt tank, 2... Asphalt, 3... Detection rod, 4... Wire, 5... Cup, 6... Level meter storage box, 6a... Extrusion part, 7... Seal packing, 8... Strain gauge, 9... Fixture, 10... Connector, 11...
Non-flammable liquid, 12... Air bleed.

Claims (1)

[Scope of utility model registration request] A level meter storage box 6 is arranged above and outside the asphalt tank 1, an annular nonflammable liquid tank is formed at the bottom of the level meter storage box 6, and the upper part of the strain gauge 8 is supported within the level meter storage box 6. At the bottom of the strain gauge 8,
The lower peripheral portion is the nonflammable liquid 1 in the nonflammable liquid tank.
The cup 5 immersed in the asphalt tank 1 and opening downward is connected to the bottom center of the cup 5, and a wire or the like is attached to hang the detection rod 3 which is immersed for a predetermined length in the asphalt 2 in the asphalt tank 1. The upper part of the corrosive wire 4 is connected, and the immersion length x of the detection rod 3 in the asphalt 2 in the asphalt tank 1 is calculated by the load w of the detection rod 3 applied to the strain gauge 8 and the immersion length x of the detection rod 3 in the asphalt 2 in the asphalt tank 1. Load when not immersed
The asphalt is characterized by being provided with means for calculating the level of asphalt 2 in the asphalt tank 1 based on the calculated value based on the difference in the electrical output of the strain gauge 8 corresponding to w ₀ respectively. Tank level meter.