KR101516169B1 - Voc recovery system - Google Patents

Abstract

A volatile organic compound recovery system is disclosed. A volatile organic compound recovery system according to an embodiment of the present invention includes a crude oil storage tank; A compressor connected to the crude oil storage tank to compress VOC (volatile organic compound) gas generated in the crude oil storage tank; A first condenser connected to the compressor for condensing the compressed VOC gas; A first separator connected to the first condenser and the crude oil storage tank for recovering the condensed VOC gas to the crude oil storage tank and supplying the non-condensed VOC gas to the steam boiler; A steam boiler connected to the first separator and using the uncondensed VOC gas as fuel; And an absorption chiller connected to the steam boiler so that steam generated from the steam boiler is used as a heat source. The working fluid cooled in the absorption chiller is supplied to a channel provided between the crude oil storage tank and the compressor to generate VOC gas .

Description

[0001] VOC RECOVERY SYSTEM [0002]

The present invention relates to a volatile organic compound recovery system, and more particularly, to a volatile organic compound (VOC) recovery system generated from an oil storage tank or the like.

In crude oil storage tanks (crude oil storage tanks), a considerable amount of volatile organic compounds (VOCs) are generated. Since the release of such volatile organic compounds into the air poses a problem of causing air pollution, in order to protect the environment, the emission of volatile organic compounds is legally regulated, and in industries that emit volatile organic compounds (such as the petrochemical industry) An attempt has been made to continuously reduce the discharge concentration of the volatile organic compound.

On the other hand, since the volatile organic compound contains a large amount of useful components of the crude oil, efforts to recover the volatile organic compound are performed in parallel with efforts to reduce the discharge concentration of the volatile organic compound. Particularly, in the latter case, the emission of volatile organic compounds can be largely reduced, but the energy efficiency is advantageous.

In connection with this, U.S. Patent No. 7032390 discloses an apparatus for collecting volatile organic compounds.

Patent Document 1: United States Patent No. 7032390 (published on October 10, 2004)

Embodiments of the present invention provide a volatile organic compound recovery system that improves recovery efficiency of volatile organic compounds and improves usability.

According to an aspect of the present invention, there is provided an oil storage tank comprising: a crude oil storage tank; A compressor connected to the crude oil storage tank for compressing VOC (VOC) gas generated in the crude oil storage tank; A first condenser connected to the compressor to condense the compressed VOC gas; A first separator connected to the first condenser and the crude oil storage tank for recovering the condensed VOC gas to the crude oil storage tank and supplying the non-condensed VOC gas to the following steam boiler; A steam boiler connected to the first separator and using the non-condensed VOC gas as fuel; And an absorption type refrigerator connected to the steam boiler and serving as a heat source for the steam generated in the steam boiler, wherein a working fluid cooled in the absorption type refrigerator is supplied to a flow path provided between the crude oil storage tank and the compressor, A volatile organic compound recovery system for cooling the VOC gas generated in the system can be provided.

A second condenser connected to the first separator for secondarily condensing the non-condensed VOC gas; And a second separator interconnected with the second condenser and the crude oil storage tank for recovering the secondarily condensed VOC gas to the crude oil storage tank and supplying the second non-condensed VOC gas to the steam boiler .

Further, the working fluid cooled in the absorption chiller can be supplied to the first condenser and / or the second condenser.

The apparatus may further include an auxiliary tank connected to one side of the first separator and / or the second separator and connected to the other side of the crude oil storage tank and / or the steam boiler to receive the condensed VOC gas.

According to another aspect of the present invention, a vessel including a volatile organic compound recovery system according to an aspect of the present invention can be provided.

The embodiments of the present invention use the uncompensated volatile organic compound gas for driving the steam boiler and the absorption type refrigerator and supply the working fluid cooled in the absorption type refrigerator to the volatile organic compound gas at the upstream side of the compressor to increase the compression efficiency , The recovery efficiency of the volatile organic compound can be improved.

1 is a schematic view of a volatile organic compound recovery system according to a first embodiment of the present invention.
2 is a view schematically showing a volatile organic compound recovery system according to a second embodiment of the present invention.
3 is a schematic view of a volatile organic compound recovery system according to a third embodiment of the present invention.

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

1 is a schematic view of a volatile organic compound recovery system according to a first embodiment of the present invention.

Referring to FIG. 1, the volatile organic compound recovery system includes a crude oil storage tank 110, a compressor 120, a first condenser 130, a first separator 140, a steam boiler 150, and an absorption refrigerator 160 And are connected in series. One side of the first separator 140 is connected to the crude oil storage tank 110 and one side of the absorption type refrigerator 160 is connected to a flow path provided between the crude oil storage tank 110 and the compressor 120.

The connection of each of the configurations described above may be performed using at least one transfer line for transferring the fluid, and the transfer line may include at least one control valve (not shown) for controlling the amount of fluid flowing in the transfer line Can be installed. In addition, at least one pump (for example, an intake pump or an exhaust pump) may be provided on the transfer line to control the amount and flow rate of the fluid flowing in the transfer line.

The crude oil storage tank 110 receives crude oil and accommodates volatile organic compounds (hereinafter, VOC) gas generated from the crude oil. The VOC gas is generated from the crude oil and is distributed on the upper side of the crude oil.

One side of the compressor 120 is connected to the crude oil storage tank 110, and the other side is connected to the first condenser 130. The compressor 120 compresses the VOC gas generated from the crude oil storage tank 110 to a high temperature and a high pressure, and then transfers the compressed VOC gas to the first condenser 130. Since the compressor 120 is a general mechanical device, a detailed description thereof will be omitted.

The first condenser 130 has one side connected to the compressor 120 and the other side connected to the first separator 140. The first condenser 130 compresses and transfers the VOC gas compressed and transferred by the compressor 120 to the first separator 140. Since the first condenser 130 is a general mechanical device, a detailed description thereof will be omitted.

On the other hand, not all of the VOC gas passing through the compressor 120 and the first condenser 130 is condensed and liquefied. Therefore, in this specification, condensed VOC gas and non-condensed VOC gas are described separately. Hereinafter, the condensed VOC gas A in the VOC gas passed through the first condenser 130 will be referred to as a "condensed VOC gas A" and the non-condensed VOC gas B as the "non-condensed VOC gas B" Quot;

One side of the first separator 140 is connected to the first condenser 130 and the other side is connected to the steam boiler 150 and the crude oil storage tank 110 respectively. The first separator 140 receives both the condensed VOC gas A and the non-condensed VOC gas B discharged from the first condenser 130 and the condensed VOC gas A and the non-condensed VOC gas B Separate and discharge. The first separator 140 may be a two phase separator since the condensed VOC gas A is in a liquid state and the non-condensed VOC gas B is in a gaseous state. Since the first separator 140 is a general mechanical device, a detailed description thereof will be omitted.

The condensed VOC gas A discharged from the first separator 140 is supplied to the crude oil storage tank 110 again. Accordingly, the VOC gas generated in the crude oil storage tank 110 can be recovered in the crude oil storage tank 110 after being liquefied through the compressor 120, the first condenser 130 and the first separator 140. The non-condensed VOC gas B discharged from the first separator 140 is supplied to the steam boiler 150 and used as fuel for the steam boiler 150.

The steam boiler 150 is connected to the first separator 140 at one side and the absorption refrigerator 160 at the other side. The steam boiler 150 functions to generate high-pressure steam by using the non-condensed VOC gas B transferred from the first separator 140 as a heat source. The generated steam is supplied to the absorption chiller 160 in whole or in part. The steam supplied to the absorption type refrigerator 160 acts as a driving heat source for the absorption type refrigerator 160. Since the steam boiler 150 corresponds to a general steam boiler, a detailed description thereof will be omitted.

One end of the absorption refrigerator 160 is connected to the steam boiler 150, and all or part of the steam generated from the steam boiler 150 is supplied and used as a driving heat source. The absorption type refrigerator 160 has no compressor for compressing the refrigerant vapor, so that it has an advantage that the required power is small and the noise is small. Accordingly, when the steam boiler 150 is driven through the non-condensed VOC gas B and the steam generated through the steam boiler 150 is used as a heat source for the absorption type refrigerator 160, , And non-condensing VOC gas (B), which is advantageous in terms of energy efficiency.

The absorption type refrigerator 160 may use water as a refrigerant and an LiBr aqueous solution as an absorption liquid. In addition, the absorption type refrigerator 160 may be constructed by connecting an evaporator, an absorber, a heat exchanger, a regenerator, a condenser, and the like, and the structure of the absorption type refrigerator 160 is general in nature, and thus a detailed description thereof will be omitted.

The cooled working fluid from the driving of the absorption type refrigerator 160 can be supplied to the flow path provided between the crude oil storage tank 110 and the compressor 120. Accordingly, it is possible to improve the compression efficiency of the compressor 120 by cooling the VOC gas when the VOC gas flows from the crude oil storage tank 110 to the compressor 120. Therefore, the recovery efficiency of the VOC gas generated in the crude oil storage tank 110 can be improved.

2 is a view schematically showing a volatile organic compound recovery system according to a second embodiment of the present invention. The VOC recovery system according to the second embodiment of the present invention can be configured to be substantially the same as or similar to the configuration of the first embodiment described above, and therefore, the following description focuses on the differences from the first embodiment. For the same reason, in FIG. 2, the same or similar components as those of the first embodiment described above are denoted by the same reference numerals.

Referring to FIG. 2, in the volatile organic compound recovery system according to the second embodiment of the present invention, the second condenser 132 and the second separator 142 are additionally provided in the first embodiment. have.

In the volatile organic compound recovery system, the crude oil storage tank 110, the compressor 120, the first condenser 130, the first separator 140, the second condenser 132, the second separator 142, the steam boiler 150 And an absorption refrigerator 160 are connected in series. One side of the first separator 140 and the second separator 142 are connected to the crude oil storage tank 110. The other side of the first separator 140 is connected to the second condenser 132, 142 are connected to the steam boiler 150. In the first embodiment, the other side of the first separator 140 is connected to the steam boiler 150. In the second embodiment, the other side of the first separator 140 is connected to the second condenser 132, The difference is that the separator is composed of multiple stages.

Since the crude oil storage tank 110, the compressor 120, the first condenser 130, the first separator 140, the steam boiler 150 and the absorption refrigerator 160 are the same as or similar to those described above, It will be omitted.

The second condenser 132 has one side connected to the first separator 140 and the other side connected to the second separator 142. The first separator 140 receives the condensed VOC gas A1 and the noncondensed VOC gas B1 through the first condenser 130. The condensed VOC gas A1 is stored in the crude oil storage tank 110, While the non-condensed VOC gas B1 is supplied to the second condenser 132 to be secondarily condensed. The second condenser 132 may be the same as or similar to the first condenser 130 and in some cases it is possible to configure the first condenser 130 and the second condenser 132 as different types of condensers .

All the VOC gas through the second condenser 132 may not be condensed. Therefore, in the present specification, the secondarily condensed VOC gas and the non-condensed VOC are separately described. Hereinafter, the condensed VOC gas A2 in the VOC gas passed through the second condenser 132 will be referred to as a "second condensed VOC gas (A2)" and the condensed VOC gas B2 will be referred to as "second noncondensed VOC gas (B2) ".

One side of the second separator 142 is connected to the second condenser 130 and the other side is connected to the crude oil storage tank 110 and the steam boiler 150, respectively. The second separator 142 receives both the secondary condensed VOC gas A2 and the second uncondensed VOC gas B2 discharged from the second condenser 132 and the secondary condensed VOC gas A2 and the secondary Separate and discharge non-condensing VOC gas (B2). The second separator 142 may be a two-phase separator as well as the first separator 140, and in some cases, the first separator 140 and the second separator 142 may be constructed of different kinds of separators Do.

The secondary condensed VOC gas (A2) discharged from the second separator (142) may be supplied to the crude oil storage tank (110) and recovered. The second uncondensed VOC gas B2 discharged from the second separator 142 is supplied to the steam boiler 150 and can be used as fuel for the steam boiler 150. [ That is, the VOC gas initially discharged from the crude oil storage tank 110 is primarily separated through the first condenser 130 and the first separator 140, and then the second condenser 132 and the second separator 142 are separated from each other. Lt; / RTI > Therefore, the condensing efficiency of the VOC gas can be further increased, and the recovery efficiency can be improved.

The absorption refrigerating machine 160 uses all or part of steam generated from the steam boiler 150 as a driving heat source and the cooled working fluid from the driving of the absorption type refrigerator 160 is supplied to the crude oil storage tank 110, And the compressor (120).

In addition, the working fluid may be supplied to the first condenser 130 and / or the second condenser 132. What is described herein as "and / or" means that the working fluid is supplied both to the first condenser 130 and the second condenser 132, or is selectively supplied from the first condenser 130 or the second condenser 132 It is meant to include both cases.

Further, when the place where the volatile organic compound recovery system is installed is a vessel such as a crude oil carrier, it is possible to supply the working fluid to an air conditioner or the like disposed in the vessel. For example, as shown in FIG. 2, the working fluid discharged from the absorption type refrigerator 160 may be supplied to an air conditioner or the like disposed at another place through a separate flow path S.

As described above, the cooled working fluid from driving the absorption refrigerator 160 can be used to enhance the condensing efficiency of the first condenser 130 and / or the second condenser 132, or to drive other air conditioning devices The energy efficiency of the entire system can be improved.

3 is a schematic view of a volatile organic compound recovery system according to a third embodiment of the present invention. The VOC recovery system according to the third embodiment of the present invention is the same as the VOC recovery system according to the third embodiment of the present invention except for the auxiliary tank 170 and the other components are the same or similar. Explain it. For the same reason, in FIG. 3, the same or similar components as those of the second embodiment described above are denoted by the same reference numerals.

Referring to FIG. 3, in the volatile organic compound recovery system according to the third embodiment of the present invention, the auxiliary tank 170 is additionally provided in the second embodiment.

In the volatile organic compound recovery system, the crude oil storage tank 110, the compressor 120, the first condenser 130, the first separator 140, the second condenser 132, the second separator 142, the steam boiler 150 And an absorption refrigerator 160 are connected in series. One side of the first separator 140 and the second separator 142 are connected to the crude oil storage tank 110. The other side of the first separator 140 is connected to the second condenser 132, 142 are connected to the steam boiler 150.

At this time, an auxiliary tank 170 connected to one side of the first separator 140 and / or the second separator 142 and connected to the other side of the crude oil storage tank 110 and / or the steam boiler 150 is installed . A control valve (not shown), a pump, and the like may be installed in the connection line between the auxiliary tank 170 and the above-described components.

It should be noted that the term "and / or" in the above description includes both the case where one side of the auxiliary tank 170 is connected to the first separator 140 and the second separator 142, It means. The other side of the auxiliary tank 170 is connected to the crude oil storage tank 110 and the steam boiler 150 or both of them are connected to either one of them.

The auxiliary tank 170 functions to temporarily accommodate the condensed VOC gases A1 and A2 supplied from the first separator 140 and / or the second separator 142. [ The condensed VOC gases A1 and A2 stored in the auxiliary tank 170 may be regenerated as needed and used as a driving heat source for the steam boiler 150 or may be recovered to the crude oil storage tank 110. [ Accordingly, since the utilization of the condensed VOC gas (A1, A2) can be selected as needed, there is an advantage that a more efficient system operation is possible.

The present invention can additionally provide a vessel including the volatile organic compound recovery system according to the above-described embodiments of the present invention. The vessel may be an oil tanker, but is not limited thereto.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, many modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

110: Crude oil storage tank 120: Compressor
130: first condenser 132: second condenser
140: first separator 142: second separator
150: Steam boiler 160: Absorption refrigerator
170: auxiliary tank
A, A1, A2: condensing VOC gas B, B1, B2: non-condensing VOC gas

Claims (5)

Crude oil storage tanks;
A compressor connected to the crude oil storage tank for compressing VOC (VOC) gas generated in the crude oil storage tank;
A first condenser connected to the compressor to condense the compressed VOC gas;
A first separator connected to the first condenser and the crude oil storage tank for recovering the condensed VOC gas to the crude oil storage tank and supplying the non-condensed VOC gas to the following steam boiler;
A steam boiler connected to the first separator and using the non-condensed VOC gas as fuel;
Wherein at least one of the crude oil storage tank and the steam boiler is connected to the other of the crude oil storage tank and the steam boiler so as to receive the condensed VOC gas and use the condensed VOC gas as a driving heat source for the steam boiler, An auxiliary tank for returning to the storage tank; And
And an absorption refrigerator connected to the steam boiler to convert the steam generated from the steam boiler into a heat source,
And a VOC gas generated in the crude oil storage tank is cooled by supplying a working fluid cooled in the absorption type refrigerator to a flow path provided between the crude oil storage tank and the compressor. The method according to claim 1,
A second condenser connected to the first separator to secondarily condense the non-condensed VOC gas; And
And a second separator interconnected with the second condenser and the crude oil storage tank for recovering the secondarily condensed VOC gas to the crude oil storage tank and supplying the second non-condensed VOC gas to the steam boiler Volatile organic compound recovery system. The method of claim 2,
And a working fluid cooled in the absorption chiller is supplied to the first condenser and / or the second condenser. The method of claim 2,
And the auxiliary tank is connected to one side of the second separator. A ship comprising the volatile organic compound recovery system according to any one of claims 1 to 4.

Images