KR20010007187A - Measuring apparatus for tank fluid - Google Patents

Abstract

PURPOSE: To make a float to react speedily to variations in the liquid level irrelevantly to freezing. CONSTITUTION: A float 8 for oil level detection has a through hole for a stem 5 in its center shaft and a magnet 36 for detection is fixed near the upper end, and projections 8c are formed on the same level below the draft line of the float of the through hole and the float is positioned below the liquid level H and reacts to the liquid level by the projection with small friction and slides responding to the liquid level without being frozen.

Description

Measuring apparatus for tank fluid

The present invention relates to an apparatus for measuring the liquid level or liquid level of a liquid contained in a tank or the like by the movement of a float.

The liquid level detector which measures the liquid level of the tank buried underground to the level of 1/50 milliliter or less and can detect the liquid level of fuel oil and the amount of water accumulated in the bottom by the same liquid level detecting means As can be seen in Korean Patent Publication No. 7-63595, the oil level detection unit has a transmission coil at one end of the magnetostriction line and a detection coil at the measurement area, and a magnet at the stem is accommodated in a stem sealed at the lower end. The water detection float which has a float for float and a magnet and whose specific gravity is smaller than water and set larger than oil is floated, and it is comprised so that it may move following the oil surface.

According to this apparatus, the oil level float moves in accordance with the liquid level of the fuel oil, and the water detection float moves in accordance with the liquid level of water accumulated under the fuel oil.

However, when the temperature decreases and freezing occurs in the stem, there is a problem in that the oil detection float is subjected to friction due to freezing and does not move in line with the liquid level, thereby greatly reducing the detection accuracy.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object thereof is to provide a liquid level detection apparatus capable of detecting oil level to a high degree by reliably rotating the oil surface detection float regardless of ice.

Another object of the present invention is to provide a liquid level detecting apparatus capable of reliably detecting water accumulated in the bottom of a tank.

Another object of the present invention is to provide a structure suitable for attaching to a tank.

In order to solve such a problem, in the present invention, a magnetostriction line and a detection coil are extended and embedded in the stem in the axial direction, and a float is provided on the stem so as to be able to slide and move along the liquid surface, and the float A tank liquid level detecting device provided with a detecting magnet in the present invention, wherein a through hole through which the stem penetrates is provided in the center axis of the float, and the detecting magnet is fixed near an upper end of the float. The projections are formed to be located on the same surface below than the draft line (the depth where the lower part of the ship is submerged in water, which is the line corresponding to the oil surface).

The float is located below the oil level and is driven by the non-freezing projection to slide the stem in response to the liquid level with a small friction.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the installation example of the liquid level detection apparatus of this invention.

2 is a view showing the structure of the fixing part of the in-phase liquid level detection device.

3 is a diagram illustrating a mounting structure of the in-phase liquid level detecting device.

4 is a plan view showing an example of the head of the in-phase device.

5 is a cross-sectional view showing an embodiment of the base of the in-phase liquid level detection device.

6 is a cross-sectional view showing an embodiment of a water detection float constituting the in-phase liquid level detection device.

7 is a cross-sectional view showing an embodiment of an oil level detecting float constituting the in-phase liquid level detecting apparatus.

8 is a diagram illustrating a state in which the in-phase liquid level detection device detects water.

※ Explanation of code for main part of drawing

1: underground tank 2: feet

3: riser pipe 4: liquid level detector

5: stem 6: base

7: Float for water detection 8: Float for oil detection

8c: projection 10: relay

13: head portion 30: magnetostrictive line

32,34,36: Magnet

EMBODIMENT OF THE INVENTION Below, the detail of this invention is shown and it demonstrates based on an Example.

Fig. 1 shows the attached state of the liquid level detecting device according to the present invention. The riser pipe 3 is connected to the underground tank 1 between the pit 2 provided on the ground, and the liquid level detecting feature of the present invention. The apparatus 4 is installed in the tank 1.

The liquid level detecting device 4 is inserted into the riser pipe 3 so as to press the base 6 of the stem 5 formed by a metal tube serving as a magnetostriction line or a receptor for the detection coil to the bottom of the tank 1, thereby being almost vertical. At the lower end, the water detection float 7 is almost surrounded by the base 6 and the oil detection area 8 is floated along the axial direction of the stem 5 so as to be movable. It is inserted. The stem 5 is made of a non-magnetic metal having rigidity to the extent that it can withstand the tension and external force of the magnetostriction 30 housed therein, and is made of a stainless steel pipe in this embodiment.

FIG. 2 shows an embodiment of the attaching structure of the stem, in which a relay tube 10 is connected to the upper portion 9 of the liquid level detection apparatus 4, one end of which is connected to the spring receiver 11. The head part 13 which serves as a fixed part slides in between the spring 12 supported by the sliding part, and is slidably fitted.

The head portion 13 has a through hole 14 having an outer diameter such that the relay tube 10 can be slid and moved in the center thereof, and a flange 15, and is provided with a spring receiving portion 16 formed on the outer circumference thereof. (12) is supporting the top.

When the head 13 is pressed into the pit 2 in this state, the base 6 of the liquid level detection device abuts on the bottom of the tank 1. In this state, when the spring 12 is pressed against the elasticity of the spring 12, the head portion 13 slides the outer circumference of the relay tube 10 so that the flange 15 moves to the fixed surface of the pit 2 as shown in FIG. 2a), the flange 15 is fixed to the pit 2 by screws 17 in this state.

As a result, the lower surface of the liquid level detecting device 4 is pressed by the elasticity of the spring 12 at the bottom of the tank 1, and the upper end thereof is positioned at the pit 2 such that the movement in the horizontal plane is impossible. . As a result, if the fluctuation of the dimensions of the tank 1 and the detection device 4 due to the temperature change is within the interval Δg, the liquid level detector 4 is fixed to the bottom and is not tilted. The liquid level can be detected to a high degree with reference to the bottom of the tank 1.

In the stage where the fixing is completed, as shown in FIG. 4, the signal cable 18 drawn out from the relay tube 10 and the cable 20 connected to the liquid level management device 19 are fixed to the terminal 21. do. Then, the temperature detection means 22 for detecting the temperature based on the signal from the temperature sensor 26 disposed in the stem, and the circuit board 24 mounted with the serial transmission means 23 are incorporated into the lid 25. Seal.

By accommodating the temperature sensor 26 in the pit 2 in this manner, it is possible to detect a temperature close to the liquid temperature of the tank 1 as much as possible, and can be easily replaced even when the temperature detecting means 22 is broken. The maintenance of the maintenance can be simplified.

According to the above attaching structure, the liquid level detection device 4 of the standard product can be installed irrespective of the diameter of the tank or the length of the riser pipe 3 only by adjusting the length of the relay pipe 10. In addition, by providing the packing material 26 (27) such as a zero ring in the outer circumferential surface of the head portion 15 and the through hole 14, intrusion of water can be prevented.

Next, the structure of the base part 6 and the float 7 and 8 is demonstrated.

Fig. 5 shows an embodiment near the base portion, in which a magnetostriction wire 30 made of nickel alloy is wound around the wire with a close-up winding over almost the entire length thereof covered with a tubing of synthetic resin serving as an insulator. The detection coils are stacked, one end fixed to the base 6 and the other end fixed to the upper part 9 with a constant tension, and the reflection wave absorbing material 31 is fitted to the outer periphery of the lower end.

The base 6 fixed to the lower end of the stem 5 has tapered portions 6a and 6b at the top and bottom, and is formed as a cylinder in which a ring-shaped reference magnet 32 is buried in the center. After inserting the stem 5 into the stem 5, the stem 33 is fixed to the outer circumference of the stem 5.

As shown in Fig. 6, the water detection float 7 has a taper hole 7a almost identical to the taper 6b at the bottom of the base 6, and the air capable of accommodating almost the entire base. It consists of a cylindrical body provided with the seal | sticker 7b, and is comprised by providing the normal extension part 7d with the guide hole 7c which tightens to the extent that the stem 5 can slide in an axial direction on the upper side, and is comprised. . The upper end of the water detection float 7, in this embodiment, the ring-shaped detection magnet 34 is located near the guide hole 7c, and at the lower end, the bulk density as the entirety of the float is stored in the tank 1. In this embodiment, a ballast 35 is provided which is set slightly larger than the density of fuel oil and smaller than water.

By forming the extension portion 7d in this way, the detection magnet 34 can be positioned above the reference magnet 32 at the upper end side, that is, in the direction in which the ultrasonic wave comes, and to the minimum water level ΔL. By allowing the water detection float 7 to float, the movement of the water detection float 7 can be detected irrespective of the dead zone distance caused by the reflected wave absorbing material 31.

The oil-level detection float 8 is comprised as a cylinder with the air chamber 8b which has a through-hole 8a of the diameter slightly larger than the outline of the stem 5 on a center line, as shown in FIG. At least three protrusions 8c are formed on the inner surface of 8a) in a horizontal plane in contact with the outer circumference of the stem 5. In this embodiment, the projections 8c are formed in two places at a distance in the axial direction. In this embodiment, the projection 8c is formed as a fabric so as to be located on the same plane, but the same shape is achieved even when the cross section is formed to form a substantially triangular convex portion.

In the vicinity of the upper end of the through hole 8a, a ring-shaped detection magnet 36 is provided, and at the lower end, a large diameter convex portion 8d capable of accommodating the extension portion 7d of the water detection float 7 is provided. It is formed, and the detection magnet 36 is almost coincident with the oil surface H, and the projection 8c is positioned slightly below (△ H) than the oil surface H, so as to be deposited on the oil bottom 8d. The ballast 37 is fixed.

Since the ballasts 35 and 37 of the above-described water detection float 7 and the oil level detection float 8 are located at the lower portions, the respective floats 7 and 8 are moved along the vertical direction. Friction with the stem 5 can be reduced.

In this embodiment, when a magnetic field is generated in the transmission coil based on the measurement period and mechanical distortion occurs in the magnetostriction 30 instantaneously, ultrasonic vibration occurs and the magnetostriction 30 propagates toward the other end.

When the ultrasonic vibration reaches the oil level detecting float 8, the magnetic field is received by the magnet 36 for detecting the float 8 and the electromotive force is generated in the detection coil by the inverse magnetostrictive effect. Ultrasonic vibration propagates downward along the magnetostriction 30 again and receives a magnetic field from the detection magnet 34 of the oil surface detection float 7 to generate an electromotive force in the detection coil, and again propagate downward to the base part 6. The reference magnet 32 also receives a magnetic field and generates electromotive force in the detection coil.

Therefore, each float is measured by measuring the time at which the mechanical acoustic waves generated at the positions of these three magnets 36, 34, 32 reach the detection coil from the time when the current is applied to the magnetostriction 30 by a counter. The position of (8) (7) can be detected, and the propagation speed of the magnetostriction due to temperature can be ensured by the arrival time of the mechanical acoustic wave of the reference magnet 32.

That is, when water enters the bottom of the tank, as shown in FIG. 8, the water detection float 7 has its taper portion 7a guided to the taper portion 6b of the base portion 6 and the base portion 6 on the center line. Up by a little (ΔL). As a result, since the position of the magnet 34 changes, the intrusion of water can be detected.

In addition, since the water detection float 7 is located as if the base 6 is covered, the water detection float 7 is blocked by the water detection float 7 and attached to the reference magnet 32 even when the rust of the tank 1 falls. This prevents the reference position from being accurately detected.

In addition, since the projection 8c for guiding this is always located below oil level H and is deposited in oil, even when the stem freezes due to a decrease in temperature, the float detection float 8 does not freeze on the stem. As a result, the frictional force is so small that it can quickly follow the change of the oil level, so that the oil level can be detected to a high degree.

In addition, the stem 5 is always suppressed by the spring 12 at the upper end, and the base 6 is pressed against the bottom of the tank 1 so that the vertical state at the time of installation against the wave caused by the supply of fuel oil by the Rowley is maintained. As a result, the oil level can be detected to a high degree.

As described above, in the present invention, the magnetostriction and the coil for detection are extended in the stem in the axial direction, and a float is installed in the stem to allow the slide to move along the liquid level, and the detection magnet is mounted on the float. In the provided tank liquid level detection device, the float has a through hole of the stem in the central axis, the magnet for detection is fixed near the upper end of the float, and the projection is located on the same plane below the draft line of the float in the through hole. Since the float is located below the oil surface and does not receive icing, the float can slide on the liquid surface and slide the stem with a small friction, so that it can quickly follow the change in the liquid level, The liquid level can be detected.

Claims (12)

In a tank liquid level detection device comprising a magnetostriction and a coil for detection extending in the stem in an axial direction, a float that can slide and move on the stem, and a magnet for detection provided in the float. The float has a through hole of the stem on a central axis, and the detection magnet is fixed near the upper end of the float, and projections are formed so as to be located on the same plane below the draft line of the float of the through hole. Tank liquid level measurement apparatus characterized in that there is. The method of claim 1, The tank liquid level measuring device, characterized in that the projection is formed as a fabric. The method of claim 1, A tank liquid level measuring device characterized in that the float is adjusting its draft line by a ballast provided at the bottom. In a tank liquid level detection device comprising a magnetostriction and a coil for detection extending in the stem in an axial direction, a float that is slidably movable on the surface of the stem, and a magnet for detection is provided in the float. A tank having a tapered base formed at least at the upper end side of the stem, providing a reference magnet at the base, and a water detection float inserted into the stem, such as surrounding the base. Liquid level detection device. The method of claim 4, wherein And a detection magnet is provided so that the water detection float has an extension portion at an upper end thereof, and a detection magnet is provided above the reference magnet. The method of claim 4, wherein A tank liquid level detection apparatus, characterized in that a tapered portion is formed below the base portion. The method of claim 5, A tank liquid level detection device, characterized in that the extension portion is formed into a cylinder that is capable of sliding along the stem in an axial direction. The method of claim 6, A lower end of the water detection float is tapered in a tapered manner so as to substantially coincide with the tapered portion of the lower portion of the base portion. The method of claim 5, The oil surface detection float slides in the axial direction so as to be movable in the stem, and a lower portion having a large diameter enough to accommodate the extension portion of the water detection float is formed in the lower portion of the oil surface detection float. Tank liquid level detection device characterized in that. In the tank liquid level detection device having a magnetostriction line and a detection coil in the stem extending in the axial direction, the float is provided in the stem so as to be able to slide and move, and the detection magnet is provided in the float. The upper end of the stem is provided with a head having a through hole for axially movable, one end is supported in the middle of the stem and the other end is supported by the head portion between the spring and the stem is connected to the spring A tank liquid level detection device, characterized in that the bottom of the stem is elastically contacted to the bottom of the tank by a spring by being fixed to the pit so as to be compressed. The method of claim 10, A tank liquid level detection device, characterized in that the upper portion for connecting a relay pipe is formed at an upper end of the stem. The method of claim 10, A tank liquid level detecting device, characterized in that a circuit board on which a temperature detecting means for detecting a temperature of an aqueous solution in a tank is mounted is accommodated in said pit.