KR200230259Y1 - Apparatus for Measuring of a fluid remains - Google Patents

Abstract

The present invention relates to a flow measuring device, and more particularly to a flow measuring device for measuring the residual amount of oil through the current value measured by using a variable resistor.

The present invention is installed vertically on the lower portion of the cover fixed to the oil tank and the coil shaft wound around the resistance wire inserted into the oil tank; A lifting shaft disposed below the cover in parallel with the coil shaft; A lifting hole mounted to the lifting shaft to be freely lifted and sliding to the coil shaft to electrically connect the lifting shaft and the coil shaft; And a buckle formed of a hollow rod body axially coupled to the lifting hole.

The present invention has the advantage that the resistance line is formed vertically to the depth of the oil tank, it is possible to measure the change in the flow rate linearly, it is possible to measure the residual amount of oil more precisely and to reduce the measurement error . In addition, there is an advantage that it is easy to install, but can provide a buoy structure having a sufficient buoyancy enough to ignore the frictional resistance of the hatch.

Description

Apparatus for Measuring of a Fluid remains

The present invention relates to a flow measuring device, and more particularly to a flow measuring device for measuring the residual amount of oil through the current value measured by using a variable resistor.

Oil tanks storing oil are enclosed with the outside and there are various techniques for measuring the amount of oil stored therein. By simply forming a separate passage on one side of the oil tank and checking the oil level, it is possible to install the variable resistor in the oil tank and apply the power to the position of the float floating in the oil tank. There are various methods to measure the amount of oil remaining by measuring the current value that changes accordingly.

3 is a view for explaining a conventional flow measurement device using a variable resistor. As shown in the drawing, a conventional flow measuring device using a variable resistor has a variable resistor 70 installed on one side of an oil tank 100 by using a coil, and detects a position of a float 50 floating in oil. Measure the residual current of oil by measuring the current flowing through).

However, the conventional oil residual amount measuring device rotates about an axis installed near the variable resistor 70 to detect the position of the float 50, thereby moving the float 50 moving up and down the oil tank 100. Since it is formed to detect, it is difficult to precisely measure the residual amount of oil by using a small variable resistor (70).

In addition, when the capacity of the oil tank 100 for storing oil is large, since the above-described floats 50 are moved in a large distance, the variable resistor 70 should also be divided into many levels. The variable resistor 70 is installed. Due to the small size of, precise measurement was not possible.

In addition, since the movement of the floats 50 is sensed by positional movement by rotation, when the float 50 is located at the bottom or the top of the oil tank 100, when the float 50 is located at an intermediate point and the float There is a problem that the measured value according to the movement of the (50) is wrong. That is, because the non-linear detection of the movement of the float 50 is a fine position of the float 50 to move linearly up and down in the oil tank 100 There was a difficult problem to measure.

In addition, in order for the float 50 floating in oil to have sufficient buoyancy, the size of the float 50 in contact with the oil surface should be large. However, since the inlet for injecting the flow measuring device is narrow, it is difficult to install the flow measuring device. Accordingly, there was a problem that the size of the ball 50 is limited.

The present invention is to solve the above-mentioned problems, it is possible to measure the residual amount of oil in detail by linearly detecting the movement of the mouth, and to provide a flow measuring device suitable for large oil tanks.

In addition, the present invention aims to provide a flow measuring device having a float structure having a sufficient buoyancy while being easily inserted through the narrow insertion hole of the oil tank.

1 is a view schematically showing a flow rate measuring device according to a preferred embodiment of the present invention.

2 is a cross-sectional view showing a flow rate measuring device is installed in the oil tank according to a preferred embodiment of the present invention.

3 is a view schematically showing a conventional flow measurement device.

<Description of Major Symbols in Drawing>

10 cover 20 coil shaft

30: lifting shaft 40: hatch

41: first elastic piece 42: second elastic piece

50: float 60: electrical wiring

70: variable resistance 100: oil tank

According to a preferred aspect of the present invention, the present invention is installed vertically on the lower portion of the cover fixed to the oil tank and the coil shaft wound around the resistance wire inserted into the oil tank; A lifting shaft disposed below the cover in parallel with the coil shaft; A lifting hole mounted to the lifting shaft to be freely lifted and sliding to the coil shaft to electrically connect the lifting shaft and the coil shaft; And a buckle formed of a hollow rod body axially coupled to the lifting hole.

According to a further aspect of the present invention, the present invention, the above-described hatch, at least one first elastic piece having a conductivity in the longitudinal direction of the lifting shaft for electrical connection with the lifting shaft; And at least one second elastic piece having conductivity to contact the coil shaft for electrical connection with the coil shaft.

According to another aspect of the present invention, the present invention is characterized in that the above-described coil shaft has at least one flat surface to facilitate contact with the second elastic piece.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

1 is a schematic perspective view of a flow measuring device according to a preferred embodiment of the present invention. As shown, the present invention includes a cover 10, a coil shaft 20, the lifting shaft 30, the lifting hole 40 and the float 50.

The cover 10 is a means for fixing the oil measuring device to the insertion port of the oil tank 100, the coil shaft 20 and the lifting shaft 30 is fixed. In the cover 10, the electrical wiring 60 connected to the power supply unit not shown in the drawing is distributed and connected to the aforementioned coil shaft 20 and the lifting shaft 30.

The coil shaft 20 is vertically fixed to the lower portion of the cover 10 described above, and a resistance wire is wound around the shaft. One end of the above-described electrical wiring 60 is connected to this resistance line to pass electricity. The inside of the shaft and the resistance wire are preferably insulated by an insulator.

In addition, the coil shaft 20 preferably has at least one flat surface in order to facilitate contact with the above-described hatch 40. That is, it is preferable that the shape of the coil shaft 20 is polygonal rather than circular.

The lifting shaft 30 is vertically fixed to the lower portion of the cover 10 described above in parallel with the coil shaft 20 described above. The lifting shaft 30 is a means for connecting the other end of the above-described electrical wiring 60 to allow the current applied from the power supply unit to pass through the above-described coil shaft 20 and to guide the movement of the above-described lifting hole 40. . Therefore, according to another aspect of the present invention, when the above-described hoist 40 is mounted to be elevated on the coil shaft 20, the hoist shaft 30 is replaced by an electric wire 60 whose length is adjusted. It is possible.

Hatch 40 is a means for electrically connecting the above-described coil shaft 20 and the lifting shaft 30 is inserted into the lifting shaft 30 and coupled to the buckle 50 in accordance with the movement of the ball 50 Move up and down along both axes. Since the lifting hole 40 moves up and down, it is preferable that the lifting hole 40 is inserted to move freely when inserting the lifting shaft 30.

Hatch 40 preferably has a first elastic piece 41 having a conductivity in the longitudinal direction of the lifting shaft 30 for the electrical connection with the lifting shaft 30. Hatch 40 is also electrically connected through the portion to be inserted into the lifting shaft 30. The first elastic piece 41 is preferably in close contact with the lifting shaft 30 to the extent that it does not interfere with the movement of the lifting hole 40, it is preferable to electrically connect the lifting hole 40 and the lifting shaft 30.

The hatch 40 preferably has at least one second elastic piece 42 in contact with the coil shaft 20 for electrical connection with the coil shaft 20. Like the first elastic piece 41 described above, the second elastic piece 42 is in close contact with the coil shaft 20 to the extent that it does not interfere with the movement of the hatch 40. It is preferable to connect electrically.

The float 50 is axially coupled to the lifting hole 40 so as to float on the upper portion of the oil. Since the float 50 is coupled to the lifting hole 40 so as to rotate, the flow rate measuring device can be easily inserted into the narrow inlet of the oil tank 100. That is, when it is mounted on the oil tank 100, the mouth 50 is erected in the same manner as the two axes described above and inserted into the oil tank 100, and inserted into the oil tank 100, when floating in the oil horizontally to the oil Be rich and have sufficient buoyancy.

Since the buoy 50 floats horizontally in the oil, the area in contact with the oil is widened to reduce the error of the flow measurement, so that fine flow rate measurement is possible and may have sufficient buoyancy. Buoy 50 preferably has the shape of a rod so that the oil tank 100 can be easily inserted and have sufficient buoyancy. In addition, the float 50 is applied to the load at both ends of the float 50, the float 50 is preferably inserted into the oil tank 100 vertically so that it is easy to rotate horizontally when floating in the oil.

Means for measuring the current value flowing through the contact point of the hatch 40 that changes according to the height of the mouth 50 and converting it to the residual amount of oil and the means for displaying the residual amount of the converted oil are described in this document. Since it is known, a description thereof will be omitted.

2 is a cross-sectional view schematically showing that the flow rate measuring device is installed in the oil tank 100 according to a preferred embodiment of the present invention. As shown, the flow rate measuring device is installed to be inserted vertically into the oil tank 100.

As described above, when the flow measuring device is inserted into the oil tank 100, the insertion port of the oil tank 100 is narrow, so that the mouth port 50 is vertically parallel to the coil shaft 20 and the lifting shaft 30 described above. Insert it upright. When the float 50 reaches the upper portion of the oil, there is a load on both ends of the float 50, so that it rotates horizontally and floats on the oil.

When power is applied from the power applying unit, current flows through the above-described coil shaft 20 and the lifting shaft 30 through the lifting hole 40 at the point where the float 50 floats. Since the current value changes along the length of the resistance wire wound on the coil shaft 20, the residual amount of oil can be measured by measuring the current value.

That is, when there is a large amount of oil remaining, the float 50 is located at the upper portion of the oil tank 100, and the current resistance is large because the length of the resistance line through which current flows is short. ) Is located at the lower part of the oil tank 100, so the current value is measured to be small because the length of the resistance wire through which the current flows is long.

According to the above-described configuration, the present invention has an advantage in that the resistance wire is formed vertically to the depth of the oil tank so that the change in flow rate can be linearly measured. Therefore, the remaining amount of oil can be measured more precisely, and there is an advantage of reducing the measurement error.

In addition, since the length of the resistance wire is installed compared to the prior art has a measurable unit is fine, there is an advantage suitable for large oil tanks.

In addition, since the float can be freely rotated, it is easy to install through the narrow insertion hole of the oil tank, and there is an advantage of providing a float structure having sufficient buoyancy enough to ignore the frictional resistance of the lifting hole.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many different and obvious modifications are possible without departing from the scope of the present invention from this description. Therefore, the scope of the present invention should be construed by the utility model registration claims described to include many such variations.

Claims (3)

A coil shaft 20 vertically installed at a lower portion of the cover 10 fixed to the oil tank 100 and wound with a resistance wire inserted into the oil tank 100; A lifting shaft 30 disposed below the cover 10 in parallel with the coil shaft 20; A lifting hole (40) mounted to the lifting shaft (30) to be freely lifted and sliding to the coil shaft (20) to electrically connect the lifting shaft (30) and the coil shaft (20); A float 50 formed of a hollow rod axially coupled to the lifting hole 40 to be rotatable; Flow rate measuring apparatus comprising a. The method according to claim 1, wherein the hatch 40, At least one first elastic piece (41) having conductivity in the longitudinal direction of the lifting shaft (30) for electrical connection with the lifting shaft (30); At least one second elastic piece 42 having conductivity to be in contact with the coil shaft 20 for electrical connection with the coil shaft 20; Flow rate measuring apparatus comprising a. The method according to claim 1, wherein the coil shaft 20, Flow rate measuring apparatus characterized in that it has at least one flat surface to facilitate contact with the second elastic piece (42).