KR20140066537A - Fluid monitoring equipment combined with fluid storing tank of ship - Google Patents

Abstract

A fluid monitoring device joined to a fluid storage tank of a vessel is provided. The fluid monitoring device includes a lock tool communicated with a guide pipe of the fluid storage tank and a gauging tool joined to the lock tool. The lock tool includes a lock structure, and the gauging tool includes a reel structure.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a fluid monitoring apparatus for a fluid storage tank,

Embodiments of the present invention relate to a fluid monitoring device coupled to a fluid storage tank of a ship.

Generally, the vessel is dried with a fluid storage tank. The fluid storage tank stores fluid comprising fuel oil, oil, oil or liquid chemicals. In this case, since the fluid storage tank is mostly formed of steel, the storage depth of the fluid can not be clearly identified outside the fluid storage tank. Further, the temperature of the fluid can not be confirmed at all outside the fluid storage tank.

In order to easily ascertain the storage depth and temperature of the fluid in the fluid storage tank, the fluid storage tank has recently been dried with a guide tube. The induction tube is disposed on the fluid storage tank so as to be positioned perpendicular to the bottom of the fluid storage tank. In addition, the guide tube can be combined with a specific measuring instrument for measuring the depth of the fluid in the fluid storage tank, or a special measuring instrument for measuring the storage depth and temperature of the fluid.

That is, when the specific measuring instrument corresponds to the induction tube, the special measuring instrument is incompatible with the specific measuring instrument with respect to the induction tube and can not be directly coupled to the induction tube. Therefore, the special measuring instrument is regarded as a useless because it is not used for checking the storage depth and temperature of the fluid in the fluid storage tank.

SUMMARY OF THE INVENTION The present invention provides a fluid monitoring apparatus suitable for appropriately combining one of the metrology instruments incompatible with each other in a guide tube of a fluid storage tank at the time of monitoring the storage depth and temperature of the fluid in the fluid storage tank have.

Still another object to be solved by the present invention is not limited to the above-mentioned problems, and another problem not mentioned here will be fully understood by those skilled in the art from the following description.

There is provided a fluid monitor device coupled to a fluid storage tank of a vessel in accordance with embodiments of the present invention. The fluid monitoring device includes a lock tool in communication with the induction tube of the fluid storage tank so as to be positioned perpendicular to the bottom surface of the fluid storage tank in the vessel and a gauging tool ). Wherein the locking mechanism includes a lock structure, the metering mechanism includes a reel structure, and the reel structure is coupled to the locking structure through the locking mechanism and the metrology mechanism, And to the bottom surface of the storage tank.

The fluid storage tank includes one of water, oil, and a chemical substance.

The induction pipe is configured to protrude from the fluid storage tank to expose the interior of the fluid storage tank.

The locking mechanism is flanged to the guide tube.

The locking mechanism includes a locking body. The locking structure includes a lock within the lock body, and the lock is configured to be freely movable with respect to the lock body with an opening.

The locking structure includes a rotation axis and a rotation axis on the outside of the lock body. Wherein the rotation shaft is fixed to the lock and is configured to penetrate the lock body, and the rotation axis is fixed to the rotation shaft so as to rotate the lock and the rotation axis to open and close the internal passage of the lock body using the opening of the lock, .

The measurement mechanism includes a fastening member. And the locking mechanism and the measuring mechanism are configured to be screwed with the fastening member using the fastening member.

The measuring mechanism includes the reel structure in the measuring body. Wherein the reel structure includes a bobbin, a suspending bar, and a sensor inside the bobbin, and the bobbin is configured to freely rotate in the measuring body to wind or loosen the suspending rope, And the sensor is configured to contact the fluid in the fluid storage tank to generate sound, and wherein the suspension cord and the sensor are configured to receive the fluid through the opening of the lock Lt; / RTI >

The reel structure further includes a rotating plate and a rotating bar on the outside of the measuring body. The rotating plate is disposed on the measuring body and is configured to engage with the bobbin through the measuring body, and the rotating bar is configured to project rotational force from the rotating plate to transmit the rotational force to the rotating plate and the bobbin.

The reel structure further includes a rotation induction unit, a rotation transmission unit, and a rotation operation unit on the outside of the measurement body. Wherein the rotation guide portion is configured to project from the measurement body to expose the inside of the measurement body, the rotation transmission portion is fixed to the bobbin through the rotation guide portion, and the rotation operation portion projects from the rotation transmission portion, The rotation transmitting portion and the bobbin.

The measurement instrument further includes a measurement port on the measurement body. Wherein the metering port communicates with the metering body and penetrates a central region of the turntable and is electrically connected to at least one of the turntable, the suspension line, and the sensor to provide at least one of the storage depth and temperature of the fluid in the fluid storage tank To display one.

As described above, the fluid monitoring device according to embodiments of the present invention includes a locking mechanism on the induction tube of the fluid storage tank to securely couple the induction tube and one of the incompatible metering devices through the locking mechanism .

The fluid monitoring apparatus can always easily monitor the storage depth and / or the temperature of the fluid in the fluid storage tank using a combination of a guide tube, a locking mechanism and a metering mechanism which are stacked in sequence on the fluid storage tank.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a fluid monitoring apparatus according to a first embodiment of the present invention, schematically coupled to a fluid storage tank. FIG.
2 is a schematic diagram of a fluid monitoring device according to a second embodiment of the present invention, schematically coupled to a fluid storage tank.
3 is a schematic view showing fluid storage tanks of a vessel associated with the fluid monitoring apparatus of FIG. 1 or FIG. 2;

A fluid monitor apparatus according to embodiments of the present invention will be described in more detail with reference to Figs.

FIG. 1 is a schematic view of a fluid monitoring apparatus according to a first embodiment of the present invention schematically coupled to a fluid storage tank, and FIG. 3 shows a fluid storage tank of a vessel associated with the fluid monitoring apparatus of FIG. 1 or FIG. Fig.

Referring to FIG. 1, a fluid monitoring apparatus 50 according to a first embodiment of the present invention includes a lock tool 30 and a gauging tool 40, which are coupled to each other. The lock mechanism 30 includes a second flange 33 on the lower side, a lock body 34 on the middle side, a rotation shaft 35, a rotation base 36, a cap strap 37 and a cap 38, And a connecting pipe (39). The second flange 33 is configured to secure the locking mechanism 30 to the fluid storage tank 10 in the vessel 80 of FIG.

The second flange 33 has a through hole (not shown in the figure) in a central region. The locking body 34 is positioned along the rim of the through-hole of the second flange 33 and extends from the rim of the through-hole toward the connecting pipe 39. The lock body 34 has a tube shape. The lock body 34 includes a lock (not shown in the figure) inside, and a rotation shaft 35 and a rotation shaft 36 on the outside. The lock, the rotary shaft 35 and the rotary table 36 constitute a lock structure in the lock body 34.

The lock includes one of a spherical shape, a polyhedral shape, and a combination thereof. The lock is freely movable with respect to the lock body 34 with an opening. The rotary shaft 35 is fixed to the lock so as to penetrate the lock body 34. The rotating table 36 is fixed to the rotating shaft 35 and transmits rotational force to the lock and the rotating table 35 to open and close the internal passage of the lock body 34 using the opening of the lock.

The cap strap 37 is connected to the support protrusion on the side of the lock body 34 through one end. The cap 38 is connected to the other end of the cap strap 37. The coupling tube 39 is positioned on the lock body 34. The connection pipe 39 is connected to the lock body 34 through one end. When the locking mechanism 30 and the first measuring instrument 40 are separated from each other, the other end of the connecting pipe 39 is covered with the cap 38. [ The first measuring instrument (40) is located on the locking mechanism (30).

The first measuring instrument 40 includes a fastening member 41, a measuring body 43, a first suspending bar 45, a first sensor 46, a rotating plate 47, a rotating rod 47A, And a display window 49A. The fastening member 41 surrounds the contact surfaces of the connecting pipe 39 of the lock mechanism 30 and the measuring body 43 of the first measuring instrument 40 to connect the connecting pipe 39 and the measuring body 43 As shown in FIG. The measuring body 43 extends vertically upward from the connection pipe 39 and extends in a diagonal direction with respect to the vertical direction.

The measuring body 43 has an internal passage. The measuring body 43 includes a reel (not shown in the figure) inside. The bobbin is configured to freely rotate in the measuring body (43) to wind or loosen the first suspending rope (45). The first suspension line 45 and the first sensor 46 are located inside the metering body 43. The first hanging string 45 is fixed to the bobbin through one end and fixed to the first sensor 46 through the other end. The first hanging string 45 may have graduations at regular intervals. The first sensor 46 is configured to generate sound by contact with an external object, e.g., fluid.

The first hanger string 45 and the first sensor 46 are configured to pass through the opening of the lock in the lock body 34. The rotating plate 47 and the swinging rod 47A are located outside the measuring body 43. The rotating plate 47 is disposed on the measuring body 43 and is configured to be coupled with the bobbin through the measuring body 43. The rotation bar 47A is configured to project from the rotation plate 47 and transmit rotational force to the rotation plate 47 and the bobbin. The rotating plate 47 and the swinging rod 47A constitute a reel structure in the measuring body 43 together with the lure, the first suspending bar 45 and the first sensor 46.

The measuring instrument 49 communicates with the measuring body 43 and penetrates the central region of the rotating plate 47 and is connected to at least one of the first suspending line 45, the first sensor 46 and the rotating plate 47 And are electrically connected to each other. The measurement tool 49 includes a memory device and / or a microcomputer for storing measurement data generated from at least one of the first suspension line 45, the first sensor 46, and the rotation plate 47, An arithmetic function, and / or a digital display function. The display window 49 is located at the measurement port 49 to expose the inside of the measurement port 49 to the outside.

Next, a method of using the fluid monitor device 50 according to the first embodiment of the present invention will be described.

Referring again to FIGS. 1 and 3, the first fluid monitoring device 50 is provided in the vessel 80 of FIG. The vessel 80 includes a plurality of fluid storage tanks 10, 13, 16, 19. Each of the fluid storage tanks (10, 13, 16, 19) has a fluid comprising fuel oil, refueling oil, crude oil or liquid chemical. In this case, only one of the fluid storage tanks 10, 13, 16, 19 will be selected in order to simplify the present invention.

Further, it is assumed that the fluid storage tank 10 has crude oil. In this case, the crude oil is naturally separated from the fluid storage tank 10 into the water 14 and the oil 18. The crude oil in turn has a first side S1 between the water 14 and the oil 18 on the bottom side of the fluid storage tank 10 and a second side S2 defining the oil in turn. The first fluid monitoring device 50 is connected to the induction pipe 20 of the fluid storage tank 10 to monitor the storage depth and / or temperature of the water 14 and oil 18 in the fluid storage tank 10. [ ).

The induction pipe 20 may protrude from the fluid storage tank 10 so as to be positioned perpendicular to the bottom surface of the fluid storage tank 10. The induction pipe 20 is configured to expose the interior of the fluid storage tank 10. The fluid storage tank 10 and the first fluid monitoring device 50 may be coupled through the first flange 25 of the induction tube 20 and the second flange 33 of the locking mechanism 30. The induction tube 20 and the lock body 34 can communicate with each other. Subsequently, the reel structure of the first measuring instrument 40 is operated.

The reel structure can transmit the rotational force of the rotation bar 47A from the outside of the measuring body 43 to the inside. More specifically, the rotational force of the swinging rod 47A is converted into a vertical motion of the first sensor 46 in the measuring body 43 through the swinging plate 47, the lure and the first suspension line 45 . The first hanger string 45 and the first sensor 46 are configured to pass through the opening of the lock in the lock body 34. The reel structure can be extended to the bottom surface of the fluid storage tank 10 in combination with the locking structure of the lock mechanism 30 through the lock mechanism 30 and the first metering mechanism 40.

When the first sensor 46 contacts the second surface S2, the first sensor 46 generates a first sound. The measurement tool 49 can display the distance between the second surface S2 and the tank deck 12 in a digital value through the display window 49A together with the first sound of the first sensor 46. [ When the first sensor 46 is located between the first surface S1 and the second surface S2 the metering aperture 49 allows the temperature of the oil 18 to flow through the display window 49A to the digital It can be displayed in numerical value.

When the first sensor 46 contacts the first surface S1, the first sensor 46 generates a second sound. The measuring instrument 49 can display the distance between the first surface S1 and the tank deck 12 in a digital value through the display window 49A together with the second sound of the first sensor 46. [ The second sound may have a frequency different from the first sound. When the distance between the bottom surface of the fluid storage tank 10 and the tank deck 12 is previously entered into the microcomputer of the metering hole 49, the metering hole 49 is connected to the fluid storage tank 10, The storage depth and temperature of the crude oil can be easily displayed.

FIG. 2 is a schematic view of a fluid monitoring apparatus according to a second embodiment of the present invention schematically coupled to a fluid storage tank, and FIG. 3 is a schematic view of fluid storage tanks of a vessel associated with the fluid monitoring apparatus of FIG. 1 or FIG. Fig. In this case, the same reference numerals are used for the same members in Fig. 2 as those in Fig.

Referring to FIG. 2, a second fluid monitoring device 70 according to a second embodiment of the present invention includes a locking mechanism 30 and a second metering mechanism 60 that are coupled to each other. Since the lock mechanism 30 is disclosed in Fig. 1, only the second measuring mechanism 60 will be described. The second measuring mechanism 60 includes a fastening member 61, a measuring body 63, a rotation induction unit 63A, a second suspension line 65, a second sensor 66, a rotation transmission unit 67, And includes an operating portion 67A and a handle 69.

The fastening member 61 surrounds the contact surfaces of the connection pipe 39 of the lock mechanism 30 and the measurement body 63 of the second measurement mechanism 60 to connect the connection pipe 39 and the measurement body 63 As shown in FIG. The measuring body 63 is configured to extend vertically from the coupling pipe 39 toward the upper side. The measuring body 63 has an internal passage. The measuring body 63 includes a reel (not shown in the figure) inside. The bobbin is configured to freely rotate in the measuring body (63) to wind or loosen the second suspending rope (65).

The second suspension line 65 and the second sensor 66 are located inside the measurement body 63. The second suspension line 65 is fixed to the bobbin through one end and fixed to the second sensor 66 via the other end. The second suspending rods 65 may have graduations at regular intervals. The first sensor 66 is configured to generate sound by contact with an external object, e.g., fluid. The second row of suspensions 65 and the second sensor 66 are configured to pass through the opening of the lock in the lock body 34. The rotation inducing portion 63A, the rotation transmitting portion 67 and the rotation operating portion 67A are located outside the measuring body 63. [

The rotation inducing unit 63A is configured to project from the measuring body 63 and expose the inside of the measuring body 63. [ The rotation transmitting portion 67 is fixed to the bobbin through the rotation inducing portion 63A. The rotation operating portion 67A is configured to project from the rotation transmitting portion 67 and transmit rotational force to the rotation transmitting portion 67 and the bobbin. The rotation induction unit 63A, the rotation transmission unit 67 and the rotation operation unit 67A constitute a reel structure in the measuring body 63 together with the bobbin, the second suspension cord 65 and the second sensor 66. [

The knob 69 is used when moving the second measuring mechanism 60 and is used for aligning the locking mechanism 30 and the second measuring mechanism 60. [

Next, a method of using the fluid monitor device 70 according to the second embodiment of the present invention will be described.

Referring again to FIGS. 2 and 3, the second fluid monitor device 70 is provided in the vessel 80 of FIG. The vessel 80 includes a plurality of fluid storage tanks 10, 13, 16, 19. Each of the fluid storage tanks (10, 13, 16, 19) has a fluid comprising fuel oil, refueling oil, crude oil or liquid chemical. In this case, only one of the fluid storage tanks 10, 13, 16, 19 will be selected in order to simplify the present invention.

Further, it is assumed that the fluid storage tank 10 has crude oil. In this case, the crude oil is naturally separated from the fluid storage tank 10 into the water 14 and the oil 18. The crude oil has a first surface S1 between the water 14 and the oil 18 on the bottom surface of the fluid storage tank 10 and a second surface S2 defining the oil. The second fluid monitoring device 70 is coupled to the induction tube 20 of the fluid storage tank 10 to monitor the storage depth of the water 14 and oil 18 in the fluid storage tank 10 .

The induction pipe 20 may protrude from the fluid storage tank 10 so as to be positioned perpendicular to the bottom surface of the fluid storage tank 10. The induction pipe 20 is configured to expose the interior of the fluid storage tank 10. The fluid storage tank 10 and the second fluid monitoring device 70 may be coupled through the first flange 25 of the guide tube 20 and the second flange 33 of the locking mechanism 30. [ The induction tube 20 and the lock body 34 can communicate with each other. Subsequently, the reel structure of the second measuring instrument 60 is operated.

The reel structure can transmit the rotational force of the rotating operation portion 67A from the outside of the measuring body 63 to the inside. More specifically, the rotational force of the rotary operation portion 67A is transmitted to the vertical movement of the second sensor 66 in the measurement body 63 via the rotation transmitting portion 67, the bobbin and the second suspending rope 65, . ≪ / RTI > The second row of suspensions 65 and the second sensor 66 are configured to pass through the opening of the lock in the lock body 34. The reel structure can be extended to the bottom surface of the fluid storage tank 10 by engaging with the locking structure of the locking mechanism 30 through the locking mechanism 30 and the second measuring mechanism 60.

When the second sensor 66 contacts the second surface S2, the second sensor 66 generates a first sound. The distance between the second surface S2 and the tank deck 12 can be monitored through the monitor window 63B of the metering body 63. [ When the first sensor 46 contacts the first surface S1, the first sensor 46 generates a second sound. The second sound may have a frequency different from the first sound. The distance between the first surface S1 and the tank deck 12 can be continuously monitored through the monitor window 63B of the metering body 63. [

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10, 13, 16, 19; Fluid storage tank, 12; Tank deck
14; Water, 18; oil
20; Induction tube, 25, 33; flange
30; Locking mechanism, 34; Lock body
35; A rotary shaft, 36; Swivel
37; Cap strap, 38; cap
39; Connector, 40, 60; Fastening mechanism
41, 61; A fastening member, 43, 63; Measuring body
45, 65; Suspension line, 46, 66; sensor
47; A rotating plate, 47A; Rotation bar
49; Measuring instrument, 49A; Display window
50, 70; Fluid monitor device, 63A; Rotation induction portion
63B; Monitor window, 67; The rotation transmitting portion
67A; A rotation operating portion, 69; handle
80; Ship, S1, S2; if

Claims (11)

So as to be positioned perpendicular to the bottom surface of the fluid storage tank in the ship,
A lock tool in communication with the induction pipe of the fluid storage tank; And
And a gauging tool coupled to the locking mechanism,
Wherein the locking mechanism includes a lock structure, the metering mechanism includes a reel structure, and the reel structure is coupled to the locking structure through the locking mechanism and the metrology mechanism, And is configured to extend to the bottom surface of the storage tank. The method according to claim 1,
Wherein the fluid storage tank comprises a fluid of one of water, oil, and a chemical substance. The method according to claim 1,
And the induction pipe is configured to protrude from the fluid storage tank to expose the interior of the fluid storage tank. The method according to claim 1,
And said lock mechanism is flange-coupled to said guide tube. The method according to claim 1,
Wherein the lock mechanism includes a lock body,
Wherein the locking structure comprises a lock within the lock body, and
Wherein the lock is configured to be freely movable with respect to the lock body while having an opening. 6. The method of claim 5,
Wherein the lock structure includes a rotation axis and a rotation axis outside the lock body,
The rotation axis being fixed to the lock and configured to penetrate the lock body, and
Wherein the rotating shaft is fixed to the rotating shaft and transmits rotational force to the lock and the rotating table to open and close the inner passage of the lock body by using the opening of the lock. The method according to claim 1,
Wherein the measuring mechanism includes a fastening member,
Wherein the locking mechanism and the measuring mechanism are configured to be screwed with the fastening member using the fastening member. 6. The method of claim 5,
Wherein the metrology tool comprises the reel structure in a metering body,
Wherein the reel structure includes an anchor, a suspension cord and a sensor inside the measurement body,
Wherein the bobbin is configured to freely rotate in the measuring body to wind or loosen the suspension string,
The hanging string is fixed to the bobbin through one end and fixed to the sensor through the other end,
Wherein the sensor is configured to contact the fluid in the fluid storage tank to generate sound, and
Wherein the suspension line and the sensor are configured to pass through the opening of the lock. 9. The method of claim 8,
Wherein the reel structure further comprises a rotating plate and a rotating bar on the outside of the measuring body,
The rotating plate being positioned on the metering body and configured to engage with the bobbin through the metering body, and
And the rotation bar projects from the rotation plate to transmit rotational force to the rotation plate and the bobbin. 9. The method of claim 8,
The reel structure further includes a rotation induction unit, a rotation transmission unit, and a rotation operation unit on the outside of the measurement body,
Wherein the rotation inducing portion is configured to project from the measuring body to expose the inside of the measuring body,
Wherein the rotation transmitting portion is fixed to the bobbin through the rotation inducing portion, and
And the rotation operating portion is configured to project rotational force from the rotation transmitting portion to the rotation transmitting portion and the bobbin. 9. The method of claim 8,
Wherein the measuring instrument further includes a measurement port in the measurement port,
Wherein the metering port communicates with the metering body and penetrates a central region of the turntable and is electrically connected to at least one of the turntable, the suspension line, and the sensor to provide at least one of the storage depth and temperature of the fluid in the fluid storage tank Wherein the fluid monitor device is configured to display one.

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