KR101086817B1 - Hybrid vapor recovery unit including condensation method and absorption method - Google Patents

Abstract

PURPOSE: An oil mist collecting method based on a condensing mode and an absorbing mode is provided to prevent environmental pollution by primarily condensing oil mist and secondarily absorbing non-condensed oil mist. CONSTITUTION: A condensed oil separator(12) is installed on the path of a collecting pipe(11) supplying oil mist. The condensed oil separator separates condensed oil and oil mist while the oil mist is supplied. An absorbing tower is installed on the path of the collecting pipe and absorbs the oil mist from the condensed oil separator. A vacuum pump(14) is installed on the path of the collecting pipe and compulsively transfers the absorbed oil mist from the absorbing tower. A chiller(16) circulates coolant to condense the oil mist in a condenser(15).

Description

Hybrid vapor recovery unit including condensation and absorption methods {Hybrid vapor recovery unit including condensation method and absorption method}

The present invention relates to a recovery apparatus for recovering oil, especially gasoline generated during storage and shipping of gasoline, and more particularly, condensing and recovering the steam by using a chiller cooled by cooling water, which is not condensed in this process. The present invention relates to an oil vapor recovery apparatus using a condensation method and an absorption method capable of efficiently recovering oil vapor by absorbing and recovering hydrocarbon-based uncondensed oil vapor such as butane and octane from the absorption chamber.

In the case of gasoline, the vapor component consists of a trace amount of hydrocarbon components from butane (C ₄ H ₁₀ ) and pentane (C ₅ H ₁₂ ) to octane (C ₈ H ₁₈ ). Among them, materials capable of liquefying at room temperature are C ₅ It is the above hydrocarbon. Therefore, hydrocarbons composed of C ₄ can be liquefied only at sub-zero temperatures, so that their recovery is difficult, and thus they are not recovered and are released into the atmosphere.

Therefore, there is a demand for an apparatus for reducing environmental pollution by recovering oil vapor as much as possible when dropping or shipping various oils including gasoline.

The general vapor recovery method is divided into three processes, namely, adsorption, desorption, and absorption / recovery processes.

More specifically, the adsorption process of adsorbing oil vapor using an adsorbent (activated carbon, hydrophobic zeolite, silica gel) in an adsorption tower, a desorption process of forcibly separating oil vapor adsorbed inside pores of the adsorbent using a vacuum pump, And an absorption process of supplying the desorbed vapor to the absorption tower to absorb the gas / liquid contact.

However, such a recovery process may be performed at a distance long enough to use the material of the storage tank 1 as an absorbent in the absorption tower 2 when the storage tank 1 is far from the shipping place as shown in FIG. 1. ) And a recovery pipe (4) for recovering the oil vapor absorbed from the absorption tower (2) back to the storage tank (1) has a problem that requires a lot of equipment investment cost, and also far away It was difficult to safely maintain and manage the facilities.

Conventional Utility Model No. 20-0448063 is disclosed as another method for recovering conventional steam. This technology includes a tank having an oil supply pipe to which oil is supplied, an oil vapor recovery pipe from which oil vapor is recovered, and an oil vapor discharge pipe from which oil vapor is discharged;

A control valve is connected to the compressor and at the same time the control tank is opened and closed by a signal of a sensor for operating the cooler when the oil vapor of the buffer tank reaches the set pressure, one end is connected to the vapor discharge pipe, the other end is connected to the tank ;

A buffer tank installed at the recovery pipe and having a detection sensor; And a condenser configured to condense the oil vapor passed through the buffer tank to change into a liquid phase, a compressor configured to compress the refrigerant, a condenser condensing and liquefying the compressed refrigerant, and an evaporator configured to evaporate and cool the oil vapor.

The evaporator is partitioned by a refrigerant circulation tube through which a refrigerant is circulated, and a plurality of chambers attached to the refrigerant circulation tube and including one or more baffles, wherein any one chamber has a plurality of cooling fins having the same arrangement interval. And, baffles for guiding the oil vapor to move up and down alternately and a liquid flow path for guiding the oil vapor changed into the liquid phase, the gap between the cooling fins to reduce the direction of the chamber from the rear chamber to the forward chamber along the direction of the steam transport Configured.

By the way, the conventional vapor recovery apparatus as described above is condensing and recovering the vapor by using a cooler, but because the cooler must circulate the refrigerant must be equipped with a compressor, a condenser, and an evaporator, so the structure of the cooler is large, manufacturing and construction costs This takes a lot, and in particular, the evaporator structure is very complicated, but the function is only a function to evaporate the vapor, so there was an inefficient problem in recovering the vapor compared to the complicated function.

And, above all, the biggest problem of the vapor recovery device is to condense both the vapor and the air flowing through the recovery pipe to improve the recovery efficiency, for this purpose, a lot of energy is consumed in the vapor condensation, and the high cost of recovery.

The present invention is to solve all the problems of the conventional vapor recovery apparatus as described above, the purpose is to condensate and recover the vapor by using the cooling water cooled by the chiller, but not condensed in this process butane, pentane, hexane, The present invention provides an oil vapor recovery apparatus using a condensation method and an absorption method capable of efficiently recovering vapor by absorbing hydrocarbon-based uncondensed oil vapor such as heptane and octane from the absorption chamber.

The oil vapor recovery apparatus applying the condensation method and the absorption method according to the present invention for achieving the above object is installed on the recovery pipe path through which the oil vapor is supplied, the condensed oil separating the condensed oil condensed in advance in the process of supplying with the oil vapor Separator;

An adsorption tower installed on the recovery pipe path and configured to adsorb and desorb oil vapor passing through the condensing oil separator;

A vacuum pump installed on the recovery pipe path and forcibly transferring oil vapor adsorbed in the adsorption tower;

A condenser installed on the recovery pipe path and desorbed to condense oil vapor flowing through the recovery pipe into a liquid phase;

A chiller circulating and supplying cooling water to the condenser to condense the vapor;

A recovery tank connected to the recovery pipe and storing the condensed oil transferred from the condenser;

A gas-liquid separator installed on the recovery pipe path and separating oil vapor contained in condensed oil transferred from the condenser to a recovery tank;

A first absorption chamber connected to the gas-liquid separator and the guide tube, and supplying the oil vapor separated from the gas-liquid separator to the liquid absorbing liquid filled therein through the guide tube to contact the gas-liquid and absorb it in a liquid state; And

Controlling the flow of oil vapor so that the oil vapor flowing through the recovery pipe is absorbed and desorbed in the adsorption tower and condensed in the condenser and recovered in a liquid state in the recovery tank and the first absorption chamber, and the vacuum pump, the condenser, and the chiller It includes; a controller for controlling the driving of.

An oil vapor recovery apparatus using the condensation method and the absorption method according to another embodiment of the present invention includes: a condensing oil separator installed on a recovery pipe path through which oil vapor is supplied and separating condensed oil, which is condensed beforehand, from the oil vapor;

An adsorption tower installed on the recovery pipe path and configured to adsorb and desorb oil vapor passing through the condensing oil separator;

A vacuum pump installed on the recovery pipe path and forcibly transferring oil vapor adsorbed in the adsorption tower;

A condenser installed on the recovery pipe path and desorbed to condense oil vapor flowing through the recovery pipe into a liquid phase;

A chiller circulating and supplying cooling water to the condenser to condense the vapor;

A recovery tank connected to the recovery pipe and storing the condensed oil transferred from the condenser;

A gas-liquid separator installed on the recovery pipe path and separating the oil vapor contained in the condensed oil transferred from the condenser to the recovery tank and supplying the vapor to the recovery tank through a guide tube connected to the recovery tank;

A second absorption chamber installed in an upper portion of the recovery tank so as to communicate with the recovery tank and spraying a separately supplied absorbing liquid to a mesh member installed therein to absorb oil vapor in the recovery tank in a liquid state; And

Controlling the flow of the vapor so that the oil vapor flowing through the recovery pipe is absorbed and desorbed in the adsorption tower and condensed in the condenser and then recovered in a liquid state to the recovery tank and the second absorption chamber, and the vacuum pump, the condenser, and the chiller It includes; a controller for controlling the driving of.

The present invention configured as described above is recovered by first condensing the steam flowing through the recovery pipe in the condenser under the control of the controller, and the non-condensed vapor not condensed in the first condensation process is pre-filled or stored in the recovery tank (oil vapor By recovering by secondary absorption for a long time to the same material as), there is an advantage that can be recovered even from the material, such as butane which is released without being recovered under normal pressure to pollute the environment to prevent environmental pollution.

In addition, the present invention uses the material recovered in the recovery tank as the absorbent liquid, so that the supply pipe to the storage tank far away to use the material of the conventional storage tank as the absorbent liquid, and also the recovery pipe for recovering the recovered oil vapor to the storage tank There is a remarkable effect that can reduce the construction difficulties and the high cost associated with the piping.

In addition, the present invention can be configured in a compact structure of the oil vapor recovery apparatus as described above has the effect of miniaturizing the installation site and reduce the maintenance and management costs.

1 is a steam system piping system diagram according to the conventional invention
2 is a system diagram of the oil vapor recovery apparatus according to the present invention
3 is a view showing a state in which oil vapor is supplied to the first adsorption tower of the present invention;
4 is a view showing a process in which oil is supplied to a second adsorption tower of the present invention and at the same time the oil vapor is desorbed from the first adsorption tower and then condensed through a condenser and a gas-liquid separator and then recovered to a recovery tank.
5 is a view illustrating a process of recovering a recovery tank after condensing while passing through a condenser and a gas-liquid separator after desorption of oil vapor from the second adsorption tower of the present invention;
6 is a view illustrating a process in which oil vapor is gas-liquid separated and supplied to a recovery tank in a gas-liquid separator according to the present invention.
7 is a view showing a process of absorbing oil vapor in the absorption chamber according to the present invention.
8 is a system diagram of another embodiment of the oil vapor recovery apparatus according to the present invention
9 is a view illustrating a state in which oil vapor is supplied to the first adsorption tower of FIG. 8;
FIG. 10 is a view illustrating a process in which oil vapor is supplied to the second adsorption tower of FIG. 8 and at the same time the oil vapor is desorbed from the first adsorption tower and then condensed through a condenser and a gas-liquid separator, and then recovered to a recovery tank.
FIG. 11 is a view illustrating a process in which the vapor is desorbed in the second adsorption tower of FIG. 8 and then recovered through a condenser and a gas-liquid separator and then recovered to a recovery tank.
12 is a view illustrating a process in which oil vapor is gas-liquid separated and supplied to a recovery tank in the gas-liquid separator of FIG. 8.
13 is a view illustrating a process of absorbing oil vapor in the absorption chamber of FIG. 8.
14 is a piping system diagram of the steam treatment system according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the oil vapor recovery apparatus applying the condensation method and the absorption method according to the present invention.

As shown in the figure, the oil vapor recovery apparatus applying the condensation method and the absorption method according to the present invention is composed of two embodiments.

First, FIGS. 2 to 7 show an oil vapor recovery apparatus 10 to which a condensation method and an absorption method are applied according to an embodiment of the present invention. The recovery device 10 has a structure in which the first absorption chamber 19a is about 1/20 smaller than the conventional one, and is suitable for small scale steam treatment.

The exemplary embodiment of the vapor recovery device 10 is installed on a recovery pipe 11 through which oil vapor flows and a path of the recovery pipe 11 to adsorb / desorb oil vapor flowing through the recovery pipe 11 and then condensate. And absorbing components through the absorption process, which is controlled by a controller (not shown).

The components include a condensed oil separator 12 for separating condensed oil condensed in advance in the supply process, an adsorption tower 13 for absorbing and desorbing oil vapor, a vacuum pump 14 for vacuum desorption of oil vapor, and a desorbed oil vapor. A condenser 15 for condensing, a chiller 16 for cooling the condenser 15 so that the condenser 15 can condense oil vapor, and a recovery tank 17 for recovering and storing the condensed oil condensed in the condenser 15. And a gas-liquid separator 18 for separating the oil vapor contained in the condensed oil, and a first absorption chamber 19a for supplying the oil vapor separated from the gas-liquid separator 18 to the liquid absorbing liquid filled therein and absorbing it in a liquid state. And a controller that controls the components that operate to recover the oil vapor into the liquid phase.

The recovery pipe 11 is appropriately piped according to the user's convenience so that the oil vapor may go through a condensation and absorption process, and it is made of a material that is not corroded and has a strong strength in consideration of the oil vapor being supplied.

The condensed oil separator 12 is installed on the recovery pipe 11 path, and when the oil vapor flowing through the recovery pipe 11 is condensed in advance by the influence of the external temperature, the condensed oil separator 12 is transferred to the recovery tank 17. Even if a small amount of oil vapor is condensed in the supply process, the condensed oil is introduced into the adsorption column 13, the vacuum pump 14, the condenser 15, and so on, thereby preventing or causing such devices to be damaged. To use a condensate separator 12.

The condensed oil separator 12 is connected to the recovery tank 17 and the supply pipe (P-1) so that the condensed oil condensed at the bottom is transferred to the recovery tank 17 through the supply pipe (P-1), and also It is connected to the recovery tank 17 and the bypass pipe (P-2) so that the oil vapor in the recovery tank 17 can be bypassed.

The adsorption tower 13 is installed on the recovery pipe 11 path and serves to adsorb and desorb oil vapor passing through the condensing oil separator 12, and the adsorbent 13c is housed inside the vessel. Various kinds of the adsorbent 13c may be used, and activated carbon and hydrophobic zeolite may be used as one example.

Therefore, the oil vapor flowing through the recovery pipe 11 flows into the fine pores of the adsorbent 13c and is adsorbed. When the adsorption state is continued and saturated, the saturated organic vapor is forced by the vacuum pump 14 to force the adsorption tower 13. Exit and detach.

One adsorption tower 13 may be used, but preferably, a plurality of adsorption towers 13 are installed in parallel on a path of the recovery pipes 11 as shown in the drawing, and controllers are installed in the recovery pipes 11 connected to the respective adsorption towers 13. By controlling the valve, oil vapor may be alternately supplied to the adsorption tower 13 so as to sequentially adsorb and desorb the valve.

The parallel arrangement of the adsorption tower 13 will be described in more detail. As shown in the drawing, the first and second flow paths 11a and 11b are piped on both sides of the recovery pipe 11, and these first and second flow paths 11a are provided. On one side of the 11b, the first and second adsorption towers 13a and 13b are connected to each other and the first and second air access pipes A and B are connected to each other so that air can enter and exit. . First and second valves V1 and V2 are installed in the first and second flow paths 11a and 11b to control the flow of oil vapor supplied for adsorption under the control of a controller. The flow path pipes 11a and 11b are connected with third and fourth flow pipes 11c and 11d which provide a path through which the oil vapor adsorbed by the first and second adsorption towers 13a and 13b is desorbed. First and second valves V3 and V4 for controlling the flow of oil vapor desorbed by the control of the controller are provided in the 3 and 4 channel pipes 11c and 11d.

As described above, a process of absorbing and detaching the first and second adsorption towers 13a and 13b by opening and closing the valves V1, V2, V3, and V4 will be described in detail later.

The vacuum pump 14 is installed on the recovery pipe 11 path to forcibly discharge the oil vapor adsorbed in a saturated state inside the adsorption tower 13 to supply the force to the recovery tank 17. This vacuum pump 14 uses a well-known thing.

The condenser 15 is a kind of heat exchanger installed on the path of the recovery pipe 11 and condensing the oil vapor passed through the inside by being cooled by low temperature cooling water supplied from the chiller 16. Since the condenser 15 is a well-known technique, detailed description of the configuration is omitted.

The chiller 16 functions to circulate and supply low-temperature cooling water to the condenser 15 so that the condenser 15 can condense oil vapor. Therefore, the chiller 16 and the condenser 15 are connected to a separate coolant pipe D through which coolant is circulated, and a coolant tank T is installed in the coolant pipe D. The chiller 16 is known in the art and is configured in various forms according to the cooling method. In the case of a small size, the chiller 16 cools the cooling water by using a thermoelectric semiconductor element at which one side becomes a low temperature state by power supply. Cooling water is cooled by using a conventional cooling system using a refrigerant.

Cooling water supplied by the chiller 16 of the present invention is supplied to 5 degrees Celsius to exchange heat with the oil in the condenser 15, discharged about 10 degrees Celsius is introduced into the chiller 16 again. The role of the chiller 16 serves to lower the cooling water temperature of 10 degrees Celsius to 5 degrees Celsius and to supply the condenser 15.

Thus, the oil vapor passing through the condenser 15 is condensed in the condenser 15, while most of the components phase change into a liquid state, but hydrocarbon components such as butane (C ₄ H ₁₀ ) are not condensed under the above conditions.

The recovery tank 17 is connected in communication with the recovery pipe 11 to store the condensed oil transferred from the condenser 15. The recovery tank 17 is connected to the condensed oil separator 12 and the supply pipe (P-1) to receive and store the condensed oil stored in the condensed oil separator 12, and also the via condensed oil separator 12 It is preferable to be connected to the pass pipe (P-2) so that the oil vapor in the recovery tank 17 can be bypassed to the condensation oil separator (12).

The gas-liquid separator 18 is installed on the recovery pipe 11 path to separate oil vapor contained in the condensed oil transferred from the condenser 15 to the recovery tank 17. The condensed oil condensed in the condenser 15 is separated from the gas-liquid separator 18 because components such as butane, which are not condensed at room temperature, exist in an oil vapor state.

The gas-liquid separator 18 is supplied to the recovery tank 17 through the condensed oil stored in the lower portion as shown in the drawing, the oil vapor located in the upper portion is supplied to the absorption chamber (19a) (19b) to be described later It is absorbed there and stored in the recovery tank 17.

Accordingly, the gas-liquid separator 18 extends to the absorption chambers 19a and 19b by extending the guide tube P-3 on the side surface to guide the supply of oil vapor to the absorption chambers 19a and 19b.

The absorption chambers 19a and 19b are connected to the guide tube P-3 so that the oil vapor separated from the gas-liquid separator 18 is supplied, and the oil vapor supplied from the gas-liquid separator 18 is filled therein. It is supplied to the liquid absorbing liquid to make gas-liquid contact to absorb the liquid.

The absorption chambers 19a and 19b are divided into two embodiments. The first absorption chamber 19a of one embodiment may increase the gas-liquid contact area by colliding with oil vapor discharged from the guide tube P-3. The mesh member 19a-1 is installed to be immersed in the absorbent liquid, and a nozzle N formed at the lower end of the guide tube P-3 is disposed below the mesh member 19a-1.

Therefore, the oil vapor supplied from the gas-liquid separator 18 is discharged to the first absorption chamber 19a through the nozzle N, causes bubbles to pass through the absorption liquid, and passes gas / liquid while passing through the mesh member 19a-1 layer. Contact occurs and absorption occurs.

The first absorption chamber 19a is installed inside the recovery tank 17 as shown in FIG. 6, and the absorption liquid is filled therein. Here, the absorbent liquid uses the same type of condensed oil stored in the recovery tank 17. For example, when absorbing gasoline of gasoline, gasoline is used as the absorbent liquid filled in the first absorption chamber 19a.

The controller is a liquid vapor in the recovery tank 17 and the first absorption chamber (19a) after the oil vapor flowing through the recovery pipe (11) is absorbed and desorbed in the adsorption tower (13) and condensed in the condenser (15). The flow of oil vapor is controlled to be recovered and the driving of the valves mounted on the vacuum pump 14, the condenser 15, the chiller 16, and the recovery pipe 11 is controlled. Such a controller is a technique that can be easily implemented by those skilled in the art with a conventional electronic control system.

The following describes another embodiment of the present invention. 7 to 12 are shown.

The oil vapor recovery apparatus applying the condensation and absorption methods of the other embodiments is the same as or similar to the above-described embodiment, except that the second absorption chamber 19b is installed above the recovery tank 17, and is chilled by the chiller 16. It is characterized by using the condensed oil recovered by condensation as an absorbent liquid.

As such, when the second absorption chamber 19b is installed and used above the recovery tank 17, the second absorption chamber 19b is applied to a facility for recovering a large amount of oil vapor.

That is, the second absorption chamber 19b installed above the recovery tank 17 is enlarged to increase the mesh member 19b-1 housed therein so that oil vapor can pass for a long time to increase absorption efficiency.

The second absorption chamber 19b of the other embodiment is installed above the recovery tank 17 so as to communicate with the recovery tank 17, and recovered by spraying the separately supplied absorption liquid to the mesh member 19b-1 installed therein. Absorbs oil vapor inside the tank 17 in a liquid state.

The recovery tank 17 and the second absorption chamber 19b are condensed oil supply pipes P-4 to supply the condensed oil stored in the recovery tank 17 to the second absorption chamber 19b to be used as an absorption liquid. Is connected to, the condensed oil supply pipe (P-4) is provided with a circulation pump (E) to circulate the absorbing liquid.

The following describes a process of recovering oil vapor by the oil vapor recovery apparatus applying the condensation method and the absorption method according to the present invention.

When gas is supplied to the tank roll TK from the pipe connected with the reservoir H, the oil vapor stored in the tank roll TK moves to the recovery pipe 11 as shown in FIG. 3 by the pressure generated as the gas is supplied. By the condensed oil separator 12 is transferred to the first and second adsorption tower (13a) (13b).

In this process, when the temperature is low, such as winter, small amounts of oil vapor may be condensed. The condensed condensed oil is separated from the condensed oil separator 12 and recovered to the recovery tank 17 through the supply pipe P-1. , The non-condensed oil vapor is transferred to the adsorption tower 13 along the recovery pipe 11.

The conveyed oil vapor is supplied to the first and second adsorption towers 13a and 13b to be adsorbed / desorbed. The first and second valves V1 and V2 are opened and the third and fourth valves are controlled by the controller. As V3) V4 is blocked, the oil vapor is supplied to the first and second adsorption towers 13a and 13b through the opened first and second flow paths 11a and 11b to the adsorbent 13c filled therein. Begins to be adsorbed.

When adsorption of oil vapor is completed in the first and second adsorption towers 13a and 13b, the removal and removal of oil vapor is performed, and the desorption proceeds sequentially. That is, if the third valve V3 is opened and the first, second, and fourth valves V1, V2, and V4 are blocked while the vacuum pump 14 is driven by the controller, as shown in FIG. In the first adsorption tower (13) (13a), the adsorption of the oil vapor in the saturation state is completed is desorbed to the recovery pipe (11) through the first and third flow channels (11a) (11c) and transferred to the condenser (15).

Subsequently, when the second and third valves V2 and V3 are shut off and the first and fourth valves V1 and V4 are opened, the oil vapor in which adsorption is completed in the second adsorption tower 13b as shown in FIG. The oil vapor supplied to and removed from the recovery pipe 11 through the pipe 11d, and at the same time, the oil vapor supplied from the tank lorry TK is emptied through the opened first valve V1 and the first flow path 11a. It is supplied to and adsorbed to the adsorption tower 13a.

In this way, the first and second adsorption towers 13a and 13b alternately alternately adsorb and desorb the steam, and the desorption is completed by the pressure of the vacuum pump 14 to condenser 15. Condensed as it passes through).

The condensed oil is introduced into the gas-liquid separator 18, and the pure condensed oil having a heavy gravity is stored below and recovered to the recovery tank 17 through the recovery pipe 11, and the light oil that is not condensed is guide tube (P-). 3) is supplied to the first absorption chamber 19a mounted in the recovery tank 17.

The first absorption chamber 19a is pre-filled with the absorbent liquid, and the mesh member 19a-1 is installed in the absorbent liquid so that the oil vapor discharged from the guide tube P-3 is absorbed by the absorbent liquid. It is introduced into the micropores of the mesh member (19a-1) and the contact area is rapidly increased, so that the absorption proceeds smoothly. Therefore, the oil vapor supplied to the first absorption chamber 19a is absorbed by the absorption liquid and is naturally recovered in the recovery tank 17 when overflowed.

Here, it is preferable to use gasoline as the absorbent liquid when the absorbent liquid used is the same substance as that of the component of the vapor, for example, the oil vapor is gasoline.

As described above, most of the oil vapor flowing through the recovery pipe 11 is recovered in a condensed state in the condenser 15, and non-condensed oil vapor, such as butane, moves to the first absorption chamber 19a and is absorbed by the absorbing liquid. Is recovered in a manner.

Since the recovery tank 17 in which the oil vapor is recovered as described above is connected to the condensing oil separator 12 and the bypass pipe P-2, the oil vapor generated in the recovery tank 17 is bypass pipe (P-2). ) Is returned to the condensed oil separator 12 and is recovered to the recovery tank 17 while again undergoing the previously described process.

This series of vapor recovery process is performed by the control of the controller, the controller measures the vapor pressure and when the pressure reaches the set pressure, the various valves, vacuum pump 14, condenser 15, chiller installed on the recovery pipe (11) Properly control (16) to recover oil vapor.

On the other hand, in another embodiment of the present invention, the second absorption chamber (19b) is installed on the recovery tank 17, the side of the second absorption chamber (19b) is the absorption tank (4) to the recovery tank (17) ), And also the guide pipe (P-3) of the gas-liquid separator 18 is connected to the recovery tank (17).

Therefore, the condensed oil separated from the gas-liquid separator 18 is recovered to the recovery tank 17, and the oil vapor which is not condensed is recovered to the recovery tank 17 separately through the guide pipe P-3. The oil vapor thus recovered is passed through the second absorption chamber 19b installed at the upper side by the pressure of the recovery tank 17. In this process, the nozzle N-1 passes through the mesh member 19b-1. Absorbed by the absorbed liquid in the for a long time is recovered to the recovery tank 17 again.

Thus, in the present invention, since the oil vapor is condensed in the condenser 15 while flowing through the recovery pipe 11, it is recovered to the recovery tank 17 by the condensation method, and the first and second absorption chambers 19a and 19b are secondary. ) Is blocked by the mesh members (19a-1) (19b-1) there, and is slowly filled with the absorbent liquid supplied from the nozzle (N-1) while being filled in advance, or recovered in an absorbing manner.

The recovery method of the oil vapor is different from the method of recovering it immediately after the adsorption / desorption applied until now, or by the condensation method by the cooler, and is a useful invention that is excellent in recovering oil vapor and reducing environmental pollution.

Furthermore, when comparing the schematic diagram of Fig. 1 and Fig. 14, the piping configuration of the steam treatment apparatus of the present invention is significantly simpler than the conventional, so that the size of the equipment can be miniaturized and the maintenance and management costs are reduced accordingly, the inventor will be.

10: vapor recovery device 11: recovery pipe
12 condensing oil separator 13 adsorption tower
14 vacuum pump 15 condenser
16: chiller 17: recovery tank
18: gas-liquid separator 19: absorption chamber

Claims (12)

A condensing oil separator (12) installed on a recovery pipe (11) path through which oil vapor is supplied and separating condensed oil condensed in advance from the oil vapor during supply;
An adsorption tower (13) installed on a path of the recovery pipe (11), for adsorbing and desorbing oil vapor passing through the condensing oil separator (12);
A vacuum pump 14 installed on a path of the recovery pipe 11 and forcibly transferring oil vapor adsorbed by the adsorption column 13;
A condenser (15) installed on a path of the recovery pipe (11) and desorbed to condense oil vapor flowing through the recovery pipe (11) in a liquid state;
A chiller 16 circulating and supplying cooling water to the condenser 15 so that the condenser 15 can condense oil vapor;
A recovery tank 17 connected to the recovery pipe 11 and storing the condensed oil transferred from the condenser 15;
A gas-liquid separator (18) installed on a path of the recovery pipe (11) and separating oil vapor contained in condensed oil transferred from the condenser (15) to the recovery tank (17);
Connected to the gas-liquid separator 18 and the guide tube (P-3), the oil vapor separated from the gas-liquid separator 18 is supplied to the liquid absorbing liquid filled inside through the guide tube (P-3) to contact the gas-liquid A first absorption chamber 19a for absorbing the liquid in a liquid state; And
The oil vapor flowing through the recovery pipe 11 may be absorbed or desorbed in the adsorption tower 13, condensed in the condenser 15, and then recovered in a liquid state in the recovery tank 17 and the first absorption chamber 19a. A controller for controlling the flow of the oil vapor so as to control the driving of the valves mounted on the vacuum pump 14, the condenser 15, the chiller 16, and the recovery pipe 11. Oil vapor recovery system applying the method and the absorption method.
The condensed oil separator 12 stores the condensed oil separated by being connected to the recovery tank 17 and the supply pipe P-1 in the recovery tank 17 through the supply pipe P-1. Oil vapor recovery system applying the condensation method and absorption method, characterized in that.
The method of claim 1, wherein the plurality of adsorption tower 13 is installed in parallel on the path of the recovery pipe 11, the controller controls the valve installed in the recovery pipe (11) connected to each adsorption tower (13), so that the oil vapor is absorbed ( 13) alternately supplied to the oil vapor recovery system applying the condensation method and absorption method characterized in that the sequentially adsorbed, desorbed.
The method according to claim 1, wherein the first absorption chamber (19a) is connected to the gas-liquid separator 18 and the guide tube (P-3) to receive the oil vapor separated from the gas-liquid separator 18, the guide tube (P) -3) A vapor recovery apparatus using the condensation method and the absorption method, characterized in that the mesh member (19a-1) is installed so as to immerse the oil vapor discharged in -3) to increase the gas-liquid contact area.
The oil vapor recovery apparatus using the condensation method and the absorption method according to claim 1 or 4, wherein the first absorption chamber (19a) is installed in the recovery tank (17).
The method of claim 1, wherein the recovery tank 17 and the condensing oil separator 12 is connected to the bypass pipe (P-2) so that the oil vapor in the recovery tank 17 can be bypassed to the condensing oil separator (12). Oil vapor recovery system applying the condensation method and absorption method, characterized in that.
The oil vapor recovery apparatus using the condensation method and the absorption method according to claim 1, wherein the absorbent liquid is the same as the condensed oil stored in the recovery tank.
A condensing oil separator (12) installed on a recovery pipe (11) path through which oil vapor is supplied and separating condensed oil condensed in advance from the oil vapor during supply;
An adsorption tower (13) installed on a path of the recovery pipe (11), for adsorbing and desorbing oil vapor passing through the condensing oil separator (12);
A vacuum pump 14 installed on a path of the recovery pipe 11 and forcibly transferring oil vapor adsorbed by the adsorption column 13;
A condenser (15) installed on a path of the recovery pipe (11) and desorbed to condense oil vapor flowing through the recovery pipe (11) in a liquid state;
A chiller 16 circulating and supplying cooling water to the condenser 15 so that the condenser 15 can condense oil vapor;
A recovery tank 17 connected to the recovery pipe 11 and storing the condensed oil transferred from the condenser 15;
Is installed on the path of the recovery pipe (11), through the guide pipe (P-3) connected to the recovery tank 17 by separating the oil vapor contained in the condensed oil transferred from the condenser 15 to the recovery tank 17 A gas-liquid separator 18 for supplying the recovery tank 17;
The second absorption chamber is installed in the upper part of the recovery tank 17 in communication with the recovery tank 17, the second absorption chamber for spraying the separately supplied absorbing liquid to the mesh member installed therein to absorb the vapor in the recovery tank 17 in the liquid state (19b); And
Oil vapor flowing through the recovery pipe 11 may be absorbed or desorbed in the adsorption tower 13, condensed in the condenser 15, and then recovered in a liquid state in the recovery tank 17 and the second absorption chamber 19b. A controller for controlling the flow of the oil vapor so as to control the driving of the valves mounted on the vacuum pump 14, the condenser 15, the chiller 16, and the recovery pipe 11. Oil vapor recovery system applying the method and the absorption method.
The method of claim 8, wherein the condensed oil separator 12 is connected to the recovery tank 17 and the supply pipe (P-1) to store the separated condensed oil in the recovery tank 17 through the supply pipe (P-1). Oil vapor recovery system applying the condensation method and absorption method, characterized in that.
The method according to claim 8, wherein the plurality of adsorption tower 13 is installed in parallel on the path of the recovery pipe 11, the controller controls the valve installed in the recovery pipe 11 connected to each adsorption tower 13, so that the oil vapor is absorbed ( 13) alternately supplied to the oil vapor recovery system applying the condensation method and absorption method characterized in that the sequentially adsorbed, desorbed.
The method according to claim 8, wherein the second absorption chamber 19b and the condensing oil separator 12 is bypass tube (P) so that the oil vapor passing through the second absorption chamber (19b) can be bypassed to the condensing oil separator (12). -2) vapor recovery system applying condensation and absorption method characterized in that connected to.
The method of claim 8, wherein the recovery tank 17 and the second absorption chamber (19b) is a condensed oil supply pipe (20) to supply the condensed oil stored in the recovery tank 17 to the second absorption chamber (19b) to be used as the absorption liquid. P-4) is connected to the condensed oil supply pipe (P-4), the condensation and absorption method, characterized in that the circulation pump (E) is installed to circulate the absorbing liquid.

Images