KR20130025509A - Pressure adjusting valve for reducing voc in the tanker - Google Patents

Abstract

PURPOSE: A pressure control valve for a volatile organic compound(VOC) reducing apparatus in an oil carrier is provided to effectively control the generation of the VOC inside ships. CONSTITUTION: A pressure control valve for a VOC reducing apparatus in an oil carrier includes an inlet body(410), an outlet body(420), an inner container, a jack bracket(430), an operation cylinder, a disk, and a trim member(460). The outlet body is flange-connected to the inlet body. The inner container is installed inside the outlet body, and forms a discharging path by being separated from the outlet body through forming a gap using a connection piece. The jack bracket penetrates the bottom center of the inner container. The operation cylinder is fixed to the jack bracket. The disk has the tip-end in a cone shape, and is inserted into the inner container. The disk includes through-holes, and the cone-shaped tip-end is fixed to a cylinder rod of the operation cylinder.

Description

PRESSURE ADJUSTING VALVE FOR REDUCING VOC IN THE TANKER}

The present invention relates to a pressure regulating valve for a VOC abatement device in an oil carrier, and more particularly, to a VOC abatement device mounted inside an oil carrier so as to reduce VOC generated from a liquid cargo in an oil carrier. The present invention relates to a pressure regulating valve for a VOC abatement device in an oil carrier that further improves the function of the pressure regulating valve.

Recently, in order to protect the environment, various regulations on harmful gases emitted from ships are implemented at sea.

This is intensified as ships become a major source of pollution at sea as the volume of sea traffic increases.

For example, with the adoption of the revised MARPOL Annex VI and the NOx Technical Code 2008 from the Marine Environment Protection Committee (MEPC), this movement has been compulsory in accordance with international regulations.

Ozone Depleting Substances

Nitrogen oxides (NOx)

Sulfur oxides (SOx)

VOCs (VOLATILE ORGANIC COMPOUNDS)

Since these substances are the main factors affecting the marine environment and global warming, their emissions must be strictly regulated and the same movement is taking place worldwide.

In particular, ships carrying large amounts of oil have a very high probability of VOC generation, since the cargo carried has a low saturated vapor pressure that can volatilize even under conditions of room temperature and pressure.

In addition, since the volume of the tank in the ship is fixed, the pressure inside the tank increases when the cargo is continuously volatilized, and when it reaches the pressure higher than the set pressure of the relief valve installed in the tank, Is released.

Therefore, the VOC generated in the ship acts as a marine pollutant.

Accordingly, in order to solve these problems, the present applicant has developed a "VOC reduction apparatus in an oil carrier" and applied for a patent application No. 2009-0116518 (2009.11.30.).

Subsequently, further studies to further improve the content of the previous application were continuously conducted, and in the process, it was confirmed that the function improvement of the VOC abatement device is closely related to the pressure regulating valve and focused on improving its structure.

The present invention was created due to the necessity of the above-described improvement technique, and in view of the fact that the VOC generated in the ship is released as the pressure rises inside the tank, temperature and pressure can be easily controlled, and the installation and operation Its main purpose is to provide pressure control valves for VOC abatement devices in oil carriers that increase efficiency by improving the convenience, reduce VOC generation, prevent marine pollution, and respond to international regulations.

The present invention is a means for achieving the above object, is installed on the conduit of the fluid to be transferred to the tank by the pump to transfer the pumped fluid to the tank, the eductor is installed to suction and discharge the inert gas for adjusting the oxygen concentration together A pressure regulating valve provided between the discharge side of the tank and the tank and supplied to the tank while maintaining a constant pressure of the fluid discharged through the eductor at the VOC condensation pressure; Inlet body; An outlet body flanged to the inlet body; It is provided in the interior of the outlet body, the space between the gaps while maintaining the gap through the connecting piece is an inner cylinder to form an outlet passage; A jack bracket fixed through the center of the bottom surface of the inner cylinder; An operating cylinder fixed to the jack bracket; The front end is conical, has a cylindrical shape going to the rear end, is inserted into the inner cylinder, the conical portion is formed with a plurality of through holes along the circumference, the center of the conical portion fixed to the cylinder rod of the working cylinder; A trim member inserted into the inlet body and having a rear end fitted to a boundary line between a conical portion and a cylindrical portion of the disk, the trim member having a plurality of holes in a circumferential direction; It provides a pressure control valve for the VOC abatement device in the oil carrier, characterized in that comprising a.

At this time, the cylinder rod is bolted to the center of the conical portion, which is the front end of the disk by the rod bolt, the bolted portion is characterized in that the disk cap is covered and protected.

In addition, the boundary between the conical portion and the cylindrical portion of the disk is characterized in that the oval-shaped outflow guide groove is further formed at a predetermined interval in the circumferential direction.

In addition, the trim member is composed of an inner trim and an outer dream fixed to the outer circumferential surface of the inner end of the inner trim at intervals from the outer circumference, wherein a plurality of first small holes are formed along the circumferential direction at the distal end of the inner trim, Larger pores are formed than the first small pores, and the outer dream is characterized in that a plurality of second small pores smaller than the first small pores are formed along the circumferential direction.

According to the present invention, it is possible to effectively suppress the generation of VOC in the vessel, improve the treatment efficiency, prevent marine pollution, eliminate the health hazards of the crew who stay in the vessel, and actively respond to the increasingly tightened international regulations. It can achieve the effect of securing the competitiveness. In addition, the loss of cargo caused by VOC emissions can be reduced, so there is an economic benefit.

1 is a structural diagram of the tank piping in the vessel for explaining the apparatus according to the present invention,
Figure 2 is an exemplary cross-sectional view of the eductor applied to the present invention,
3 is a cross-sectional view showing the main structure of the pressure control valve according to the present invention;
Figure 4 is a partially cutaway perspective view of the pressure control valve according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, in the ship, in particular, an oil carrier, IG (inert gas) is injected through an IG line (INERT GAS LINE) 200 to prevent explosion in the tank 100 to control the concentration of oxygen. Doing.

At this time, IG, VOC & AIR coexist in the IG line 200, and are connected to all the tanks 100 and the pipes in the vessel.

Therefore, the present invention is configured to reduce the generation of VOC by condensing the VOC in all the tanks 100 above the saturated vapor pressure in a manner to introduce / pressurize the gas mixture of the IG line 200.

Conventionally, the EDUCTOR using the Venturi effect has been used a lot.

The general use of the EDUCTOR (300) is to move the liquid / gas on the suction side more than a certain height or to smoothly discharge the liquid / gas located on the suction side by using the vacuum phenomenon generated by the high speed It was for.

In the present invention, the eductor 300 by using the eductor 300 to condense the VOC by implementing the two functions to pressurize and transfer the IG and VOC mixed gas to the base of the tank 100 It is.

To this end, the present invention further comprises a pressure control valve 400 in the discharge end of the eductor 300.

The pressure adjusting valve (PRESSURE ADJUSTING VALVE) is to maintain the pressure above the saturated steam pressure of the cargo by generating a pressure at the inlet side, for this purpose by measuring the pressure of the front end and receiving this signal from the controller (CONTROLLER) 500 The stroke of the pressure control valve 400 is configured to be adjusted.

In addition, since the discharge side of the pressure control valve 400 is connected to the base of the tank 100, if only the head is formed in the tank 100, it is possible to sufficiently condense the vaporized VOC through the head.

On the other hand, the amount of cargo in the tank 100 may vary depending on the situation, so if the pressure control valve 400 is not installed unstable cargo from the discharge portion of the eductor (EDUCTOR) 300 inside the tank 100 Can generate VOC continuously.

However, in the present invention, since the pressure is kept constant at the front end of the pressure control valve 400, the amount of cargo in the tank 100 can sufficiently condense the VOC if the inlet and outlet lines can be locked.

That is, the eductor 300 utilized in the present invention, as illustrated in Figure 2, the left end is connected to the oil pump, the other end opposite to the one connected to the oil pump is the inlet side of the pressure control valve 400 Connected with

At this time, the IG line 200 is inclinedly connected so as to be separated from one end connected to the oil pump in the radial direction of the eductor 300 and joined at the final discharge end.

Therefore, a vacuum is formed directly above the point joined by the oil discharged at high speed during operation of the eductor 300, that is, the point “A” in the city, and the cargo discharged from the inlet line connected to the oil pump. The IG and VOC mixture introduced into the vacuum can be mixed and moved to the discharge side, thereby maintaining a sufficiently high pressure so that the pressure on the discharge side can be maintained above the saturated vapor pressure of the cargo.

On the other hand, since the discharge pressure of the eductor 200 is variable according to the situation of the rear end (BACK PRESSURE, etc.), it is practically difficult to maintain a certain pressure using only the eductor 200. By installing a pressure control valve 400 as shown in 3 to maintain a constant pressure on the discharge side of the eductor 200.

The pressure control valve 400 for implementing this includes an inlet body 410 and an outlet body 420, as shown in FIGS. 3 and 4.

In addition, the inlet body 410 and the outlet body 420 are assembled to each other in a bolted form with a flange therebetween to form one housing.

In particular, the inner cylinder 422 is further provided inside the outlet body 420, and the inner cylinder 422 is fixed to the outlet body 420 by the connecting piece 424.

In this case, the connecting piece 424 is installed in several places with a predetermined interval in the radial direction of the inner cylinder 422, the rest of the portion except the connection piece 424 is installed, that is, between the outlet body 420 and the inner cylinder 422 The space of the oil becomes the outflow passage 426 through which the oil, that is, the fluid, can pass.

In addition, a hole is drilled in the center of the bottom surface of the inner cylinder 422, and a jack bracket 430 is installed in the hole.

The jack bracket 430 is a means for stably supporting and fixing the operation cylinder 440 to be described later while blocking the perforated hole.

The operation cylinder 440 is a hydraulic actuator. Although not shown in detail, the hydraulic cylinder 440 may be disposed through the inside of the jack bracket 430 to minimize interference with other members and to easily leak out. Ease and stability can be secured.

In particular, the common actuator provided in the art is mainly provided in the form of protruding or exposed to the outside, so the problem of interference occurs frequently during installation, but in the present invention has a built-in form has a large feature that eliminates this problem Have

In addition, a disk 450 is fixed to an upper end of the working cylinder 440. The disk 450 is disposed to be moved by the working cylinder 440 in a state of being fitted inside the inner cylinder 422, and in a longitudinal direction. It is cylindrical in shape and its tip has a conical shape.

Therefore, the disk 450 has a shape that is fixed to the operating cylinder 440 as the inner central axis, the center of the tip portion having a conical shape of the cylinder rod 442 and the rod bolt (440) of the working cylinder 440 444 is firmly fixed, and a disk cap 446 for hermetically protecting the rod bolt 444 is covered on the outer side of the portion where the rod bolt 444 is fixed, that is, the outer surface of the tip of the cone.

In addition, a plurality of through holes 452 are formed in a conical shape, which is a tip portion of the disk 450, to reduce the force of oil introduced through the inlet body 410 on the disk 450. It is designed so that the introduced oil flows toward the radial edge by the disk 450, and the flowed oil moves on the outflow passage 426, which is a space between the inner cylinder 422 and the outlet body 420 described above. Will be.

In this case, the disk 450 is able to adjust the pressure of the oil flowing through the inlet body 410 by adjusting the stroke of the operation cylinder 440 operated under the control of the controller 500, through which the oil It can be maintained above the pressure that can be volatilized.

In addition, at the boundary where the conical portion and the cylindrical portion of the disk 450 meet, a plurality of elliptical outflow guide grooves 454 are formed along the rim at regular intervals so that the oil guided to the outside of the disk 450 It is better to configure so that it can be more smoothly passed to the outflow passage (426).

On the other hand, the inside of the inlet body 410 is provided with a trim member 460, the trim member 460 is made of a cylindrical shape, the inner trim (Inner Trim) 462 and the outer trim (Outer Trim) ( 464).

Here, the trim member 460 prevents a sudden pressure change that may occur between the front and rear ends of the valve when the fluid moves, and when such a phenomenon occurs, the fluid is discharged through an outlet hole formed in the trim member 460. Relief of part prevents sudden pressure change.

That is, in a conventional valve, a cavitation phenomenon occurs at the rear end of the valve due to a sudden pressure difference, and this cavitation phenomenon is the same as that in which the vacuum is generated, which causes the internal fluid to be vaporized by the vacuum and thus is included in the fluid. It will promote the generation of VOC.

However, in the present invention, the fluid passes through the trim member 460 to maintain a constant pressure at the front end of the valve.

In addition, the first hole 463 formed in the inner trim 462, the second hole formed in the outer trim 464, and the gap therebetween form a low pressure drop to prevent cavitation.

These pores continually impinge on the fluid to prevent cavitation and disperse the flow of fluid, increasing energy loss, thereby preventing the pressure in all sections from suddenly dropping below the saturated vapor pressure of the fluid.

The bubbles generated in this process can be liquefied in a shorter time than the larger bubbles under the same pressure inside the tank, and the rise time of the bubbles inside the tank becomes longer compared to the larger bubbles, so the possibility of liquefaction Further increase.

Thus, when the pressure at the front end of the valve is lower than the set pressure, the disk 450 is blocked and when the pressure is higher, the disk 450 is opened and controlled, and the driving is performed by the operation cylinder 440.

In this case, a pressure measuring sensor (not shown) may be further installed at the front end of the valve, and connected to the controller 500 so that the controller 500 controls the disk 450 according to the measured pressure to open the flow path. Can be adjusted automatically.

As such, the pressure control valve for the VOC reducing device according to the present invention is installed on the discharge side of the eductor 300 to suppress the evaporation of the VOC as much as possible by maintaining the pressure supplied to the tank 100, that is to condense This makes it possible to reduce the generation of VOCs in the vessel.

In addition, since the operation cylinder 450 as a driving source can be provided in a built-in type, it is possible to obtain effects such as ease of installation, stability of operation and interference elimination with other members, and ease of control.

100 tank 200 IG line
300: Eductor 400: pressure control valve
410: Inlet Body 420: Outlet Body
430: Jack Bracket 440: wkrehdtlfflsej
450: disk 460: trim member
500: controller

Claims (4)

It is installed between the discharge side of the eductor and the tank which is installed on the pipeline of the fluid transferred to the tank by the pump to transfer the pumped fluid to the tank, and suction and discharge the inert gas for adjusting the oxygen concentration through the eductor A pressure regulating valve provided to supply the tank while maintaining a constant pressure of the discharged fluid at the VOC condensation pressure;
Inlet body;
An outlet body flanged to the inlet body;
It is provided in the interior of the outlet body, the space between the gaps while maintaining the gap through the connecting piece is an inner cylinder to form an outlet passage;
A jack bracket fixed through the center of the bottom surface of the inner cylinder;
An operating cylinder fixed to the jack bracket;
The front end is conical, has a cylindrical shape going to the rear end, is inserted into the inner cylinder, the conical portion is formed with a plurality of through holes along the circumference, the center of the conical portion fixed to the cylinder rod of the working cylinder;
A trim member inserted into the inlet body and having a rear end fitted to a boundary line between a conical portion and a cylindrical portion of the disk, the trim member having a plurality of holes in a circumferential direction; Pressure control valve for VOC reduction device in the oil carrier, characterized in that comprising a.
The method according to claim 1;
The cylinder rod is bolted to the center of the conical portion, which is the front end of the disk by the rod bolt, the bolted portion is a pressure control valve for VOC reduction device in the oil carrier, characterized in that the disk cap is covered with protection.
The method according to claim 1;
Pressure control valve for the VOC reduction device in the oil carrier, characterized in that the boundary between the conical portion and the cylindrical portion of the disk is further formed with an elliptical outflow guide groove recessed at regular intervals in the circumferential direction.
The method according to claim 1;
The trim member is composed of an inner trim and an outer dream fixed to an outer circumferential surface at an outer circumferential surface of the distal end of the inner trim, and a plurality of first small holes are formed at the distal end of the inner trim along the circumferential direction, and the first small holes are disposed on the remaining portions. The larger air hole is formed, the pressure control valve for the VOC reduction device in the oil carrier, characterized in that the outer dream is formed with a plurality of second holes smaller than the first hole in the circumferential direction.

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