KR20230130879A - Crude oil shipment pump cooling system for underground oil storage base using fresh water in construction tunnel - Google Patents

Abstract

The purpose of the present invention is to enable continuous operation of the crude oil shipping pump without emergency operation stoppage, to build a system with a very simple structure using low-cost equipment that is easy to purchase, and to prevent oil leakage due to damage to the heat exchanger. A crude oil shipping pump cooling system for an underground oil storage base using fresh water in a construction tunnel, which can fundamentally prevent the phenomenon of a large amount of low-temperature fresh water in a construction tunnel being contaminated by oil even if it occurs, is being disclosed. The cooling system for the crude oil shipment pump for the underground oil storage base using fresh water in the construction tunnel includes a first heat exchanger connected to the cooling/lubrication oil line of the oil circulation unit of the crude oil shipment pump, and coolant flowing through a closed loop cooling water circulation line. A closed cooling unit that circulates through the first heat exchanger and exchanges heat with the cooling/lubricating oil line to cool the cooling/lubricating oil circulating through the cooling/lubricating oil line, and a second heat exchanger connected to the closed loop coolant circulation line. And, the fresh water in the construction tunnel is taken, supplied to the second heat exchanger, exchanged heat with the cooling water circulating through the closed loop cooling water circulation line, and then the process of discharging the water again as fresh water in the construction tunnel is repeated, thereby circulating the closed loop cooling water. It may include an open cooling unit that cools the cooling water circulating through the line.

Description

Crude oil shipping pump cooling system for underground oil storage base using fresh water in construction tunnel {CRUDE OIL SHIPMENT PUMP COOLING SYSTEM FOR UNDERGROUND OIL STORAGE BASE USING FRESH WATER IN CONSTRUCTION TUNNEL}

The present invention relates to a cooling system for a crude oil shipping pump for an underground oil storage base using fresh water in a construction tunnel. More specifically, it relates to cooling and lubrication of the driving part of the crude oil shipping pump that operates when transferring oil stored in an underground oil storage base to the ground. This relates to a crude oil shipping pump cooling system for an underground oil storage base using fresh water in a construction tunnel to prevent temperature rise in the oil circulation unit.

A large-scale underground oil storage base refers to a facility that stores oil by excavating a cavity in the underground bedrock, taking advantage of the fact that oil does not mix with water and also has a light water content. Such an underground oil storage base can store oil on a large scale. This method not only consumes less operating and maintenance costs, but is also environmentally preferable as there is less risk of oil leakage.

Figure 1 is a schematic diagram of an underground oil storage base. As shown in Figure 1, the underground oil storage base 100 generally includes a construction tunnel 110, a plurality of oil storage tunnels 120, and a water wall tunnel to maintain water pressure. It may include (130).

Meanwhile, the oil reservoir tunnel 120 is connected to the ground by a vertical shaft 140 in order to ship oil to the ground, and a water wall hole 150 branching from the water wall tunnel 130 may be further installed.

In this general underground oil storage base 100, different oil types are stored in a plurality of oil storage tunnels 120, and since each oil has different physical characteristics depending on the production area, it must be stored to prevent the different oil types stored in the oil storage tunnels from mixing. do.

Accordingly, each plug 170 is installed to maintain a certain distance at the entrance of each unit of the oil storage tunnel 120, that is, on both sides of the connection tunnel 160, and the water film separation surface is formed by filling the construction tunnel 110 with water. A method of forming is used to prevent different oil types stored in each oil storage tunnel 120 from being mixed.

Meanwhile, in order to pump and transport the oil stored in the underground oil storage base to the ground, a crude oil delivery pump system is installed and operated in the pump pit 180 provided at the bottom of the vertical shaft 140.

However, since a reliable cooling water supply system has not been developed to prevent the temperature of the oil circulation unit from increasing when the crude oil delivery pump is in operation, continuous delivery for a long time is not possible, resulting in problems such as reducing the amount of delivery.

In other words, if the temperature of the oil circulation unit of the crude oil delivery pump is above 60℃, emergency operation is stopped by an automatic stop system to prevent performance degradation of the crude oil delivery pump, and for restart, motor protection is required due to the nature of the large-capacity crude oil delivery pump. There is a problem that a protection time of at least 30 minutes is required for this purpose.

In order to solve this problem, a method of cooling the cooling oil using fresh water in a construction tunnel using a closed-circuit cooling method, or a method of cooling by operating a chiller using electric power, is currently being used.

Figure 2 is a diagram to explain a crude oil shipping pump cooling system configured in a closed loop using fresh water in a construction tunnel.

Referring to FIG. 2, a general crude oil shipping pump cooling system includes a cooling/lubrication oil line (210) of the oil circulation unit for cooling and lubricating the driving part of the crude oil shipping pump (230) such as the electric motor, bearing, and mechanical room of the crude oil shipping pump. ) is connected to the heat exchanger 220, and the cooling water stored in the make-up water tank 240 is inside the freshwater inside the construction tunnel 270 through the cooling water circulation line 260 as the cooling water circulation pump 250 operates. After flowing into the water and indirectly exchanging heat with low-temperature fresh water in the construction tunnel 270, it is again supplied to the heat exchanger 220 through the cooling water circulation line 260 and the heat exchanger through the cooling/lubrication oil line 210. Heat is exchanged with the cooling/lubricating oil circulating in (220) to cool the cooling/lubricating oil in the oil circulation unit, and then the cooling water is returned to the make-up water tank (240) through the cooling water circulation line (260). The cooling/lubricating oil circulating through the cooling/lubricating oil line 210 of the oil circulation unit is cooled.

In the case of such a conventional crude oil shipping pump cooling system, only one heat exchanger 220 is installed, but the coolant whose temperature is increased by heat exchange with the cooling/lubricating oil through the heat exchanger 220 is cooled through the coolant circulation line ( Since it is cooled by indirectly exchanging heat with fresh water in the construction tunnel 270 while circulating through 260), the cooling water circulation line 260 must be constructed with copper pipes with high heat transfer efficiency, which not only incurs excessive facility costs but also requires cooling. There is a problem with low efficiency.

To solve this problem, recently, a chiller cooling method using electric power or a closed-circuit cooling method using fresh water in a construction tunnel has been used to cool the cooling oil to maintain the temperature of the oil circulation unit within 60℃. It is currently being ordered.

Among the methods for cooling the cooling oil of the oil circulation unit as described above, in the case of the cooling method using a chiller, operation is somewhat complicated due to the operation of the chiller, and not only does it require a large energy source due to the use of power, but also requires a large energy source, such as a chiller, relay equipment, etc. Not only does it require excessive installation costs, but there is a problem that maintainability is reduced due to the increase in maintenance points.

Republic of Korea Patent Publication No. 10-0167083 (1998.09.25.) Republic of Korea Patent Publication No. 10-2090744 (2020.03.12.) Republic of Korea Patent Publication No. 10-1337719 (2013.11.29.) Republic of Korea Patent Publication No. 10-1483524 (January 12, 2015)

The purpose of the present invention is to provide a cooling system for a crude oil shipment pump for an underground oil storage base using fresh water in a construction tunnel that enables continuous operation of the crude oil shipment pump without emergency operation stoppage.

Another object of the present invention is to provide a crude oil shipping pump cooling system for an underground oil storage base using fresh water in a construction tunnel that can be constructed with a very simple structure using low-cost equipment that is easy to purchase.

Another object of the present invention is to store underground oil using fresh water in a construction tunnel, which can fundamentally prevent a large amount of low-temperature fresh water in the construction tunnel from being contaminated by oil even if oil leakage occurs due to damage to the heat exchanger. It provides a cooling system for crude oil shipment pumps for bases.

In order to achieve the above object, the present invention includes a first heat exchanger connected to the cooling/lubrication oil line of the oil circulation unit of the crude oil shipping pump, and cooling water while circulating through the first heat exchanger along a closed loop cooling water circulation line. /A closed cooling unit that exchanges heat with the lubricating oil line and cools the cooling/lubricating oil circulating through the cooling/lubricating oil line, a second heat exchanger connected to the closed loop cooling water circulation line, and fresh water in the construction tunnel The water is taken in and supplied to the second heat exchanger to exchange heat with the coolant circulating through the closed-loop coolant circulation line, and then the process of discharging the water back into fresh water in the construction tunnel is repeated to cool the coolant circulating through the closed-loop coolant circulation line. Shiki presents a crude oil shipping pump cooling system for an underground oil storage base using fresh water in a construction tunnel including an open cooling unit.

For example, the closed cooling unit is installed on a closed loop coolant circulation line connected to the first and second heat exchangers in a closed loop, and the closed loop coolant circulation line to cool the coolant in the closed loop coolant circulation line. It is moved to the first heat exchanger side to exchange heat with the cooling/lubricating oil flowing into the first heat exchanger through the cooling/lubricating oil line, and the cooling water discharged from the first heat exchanger is transferred to the cooling water circulation line through a closed loop type cooling water circulation line. 2 It may include a cooling water circulation pump that moves the water to the heat exchanger side, exchanges heat with fresh water in the construction tunnel taken to the second heat exchanger side, and then circulates it back to the first heat exchanger side.

In addition, the closed cooling unit includes a closed make-up water tank connected to the closed-loop coolant circulation line and capable of replenishing coolant in the closed-loop coolant circulation line, and a make-up water tank connected to the closed-loop coolant circulation line. It may further include a tank and a make-up water pump that supplies make-up water from the make-up water tank to the closed-loop cooling water circulation line.

For example, the open cooling unit may have a water intake line connected to the second heat exchanger to supply fresh water in the construction tunnel to the second heat exchanger, and supply fresh water in the construction tunnel to the second heat exchanger through the water intake line. A low-temperature fresh water supply pump installed on the water intake line, and as the low-temperature fresh water supply pump operates, the cooling water and heat are supplied to the second heat exchanger through the water intake line and flow into the second heat exchanger through the closed loop cooling water circulation line. It may include a water outlet line that discharges the exchanged fresh water back into the fresh water in the construction tunnel.

Meanwhile, at least two low-temperature fresh water supply pumps may be connected in parallel to the water intake line.

Here, it is preferable that the water intake port is disposed below the fresh water surface in the construction tunnel so that the water intake line can take in low-temperature fresh water from the fresh water surface in the construction tunnel and supply it to the second heat exchanger, and the water outlet line is provided from the second heat exchanger. It is desirable for the water outlet to be placed at the bottom of the construction tunnel so that the discharged high-temperature water is discharged to the bottom of the construction tunnel and mixes with a large amount of low-temperature fresh water in the construction tunnel to exchange heat.

As described above, the crude oil shipment pump cooling system for an underground oil storage base using fresh water in a construction tunnel according to an embodiment of the present invention is cooled by primary heat exchange using cooling water through a first heat exchanger, and then the cooling water is cooled. In order to secure the watertightness of the construction tunnel and prevent the different oil types stored in each oil storage tunnel from mixing through the second heat exchanger, it is cooled by secondary heat exchange with low-temperature fresh water that is always stored in the construction tunnel over tens of thousands of tons.

Accordingly, the crude oil shipping pump cooling system for an underground oil storage base using fresh water in a construction tunnel according to an embodiment of the present invention is not only easy to purchase and can be used with low-cost equipment, but also economical because the system construction is simple. It has the effect of excellent constructability.

In addition, compared to systems that use equipment such as chillers that require high-cost equipment and require large amounts of power, power consumption is greatly reduced and continuous operation is possible without emergency stoppage of the crude oil delivery pump, thereby improving the performance of the crude oil delivery pump. There is an effect of reducing operating costs and even operating labor costs due to reduced operating time.

In addition, the system is very simple and easy to operate, so regular maintenance materials are limited and purchasing consumable parts is simple. In addition, the performance of the crude oil delivery pump can be improved and the service life of the crude oil delivery pump can be significantly increased by optimal operation of the crude oil delivery pump. This has the effect of enabling stable driving.

In addition, the cooling system for the crude oil shipment pump for an underground oil storage base using fresh water in a construction tunnel according to an embodiment of the present invention is supplied to the first heat exchanger through a cooling/lubrication oil line, exchanges heat, and then circulates to the crude oil shipment pump. Even if the cooling/lubricating oil leaks and gets mixed into the coolant due to damage such as aging of the first heat exchanger, the coolant in the closed cooling unit where the cooling/lubricating oil can get mixed in when the first heat exchanger is damaged is circulated. The cooling water circulation line is formed in a closed loop connected to the first and second heat exchangers, so even if cooling/lubricating oil is mixed into the cooling water, it is possible to fundamentally prevent the contamination of a large amount of fresh water in the construction tunnel by cooling/lubricating oil. It works.

Ultimately, the cooling system for the crude oil delivery pump for an underground oil storage base using fresh water in a construction tunnel according to an embodiment of the present invention is not only economical and constructible and easy to maintain, but also enables stable operation of the crude oil delivery pump. As a result, it is possible to significantly reduce the construction costs of underground oil storage bases as well as operation and maintenance costs, and even prevent environmental pollution caused by oil leaks.

Other effects of the present invention will be readily apparent and understood by experts or researchers in the technical field through the specific details described below or during the process of implementing the present invention.

Figure 1 is a schematic diagram of an underground oil storage base
Figure 2 is a diagram illustrating a crude oil shipping pump cooling system using fresh water in a general construction tunnel.
Figure 3 is a conceptual diagram illustrating the crude oil shipping pump cooling system according to the present invention.

Since the present invention can be subject to various changes and have various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific disclosed form, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Terms such as first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component without departing from the scope of the present invention.

The terms used in this application are merely used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features or It should be understood that this does not exclude in advance the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains.

Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless clearly defined in the present application, should not be interpreted as having an ideal or excessively formal meaning. No.

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

Figure 3 is a conceptual diagram illustrating a crude oil shipping pump cooling system according to an embodiment of the present invention.

Referring to Figure 3, the crude oil shipping pump cooling system 100 according to an embodiment of the present invention includes a first heat exchanger 110, a closed cooling unit 120, a second heat exchanger 130, and an open cooling unit. It may include (140).

The first heat exchanger 110 is a cooling/lubrication oil line (220) of the oil circulation unit that circulates cooling/lubrication oil for cooling and lubricating driving parts such as the electric motor, bearing, and mechanical room of the crude oil shipping pump 210. ) can be connected to.

The closed cooling unit 120 exchanges heat with the cooling/lubricating oil line 220 while coolant circulates through the first heat exchanger 110 along the closed loop cooling water circulation line 121, thereby exchanging heat with the cooling/lubricating oil line 220. The cooling/lubricating oil circulating through (220) can be cooled.

Here, the closed cooling unit 120 includes cooling/lubricating oil circulated through the cooling/lubricating oil line 220 while the coolant circulates through the first heat exchanger 110 along the closed loop cooling water circulation line 121. By allowing heat exchange, oil is prevented from leaking into fresh water in the construction tunnel 310 even if oil leakage occurs due to damage to the first heat exchanger 110.

For example, the sealed cooling unit 120 may include a closed loop coolant circulation line 121 and a coolant circulation pump 122.

The closed loop type coolant circulation line 121 is connected to the first and second heat exchangers 110 and 130 in a closed loop form and circulates the coolant filled therein to the first and second heat exchangers 110 and 130. Allows for sequential circulation.

The coolant circulation pump 122 is installed on the closed loop type coolant circulation line 121 and moves the coolant in the closed loop type coolant circulation line 121 to the first heat exchanger 110 to cool the cooling/lubrication oil line. After cooling the cooling/lubricating oil by heat exchange with the cooling/lubricating oil introduced into the first heat exchanger 110 through (220), the cooling water discharged from the first heat exchanger 110 is transferred into a closed loop type It is moved to the second heat exchanger (130) through the cooling water circulation line (121) to exchange heat with the fresh water in the construction tunnel (310) taken to the second heat exchanger (130) through the open cooling unit (140). After cooling, it can be circulated back to the first heat exchanger (110) through the closed loop type cooling water circulation line (121).

In addition, the sealed cooling unit 120 may further include a sealed make-up water tank 123, a make-up water tank 124, and a make-up water pump 125.

The sealed replenishment water tank 123 is connected to the closed loop coolant circulation line 121 to replenish coolant in the closed loop coolant circulation line 121.

The make-up water tank 124 may be connected to the closed loop cooling water circulation line 121.

The make-up water pump 125 operates when the coolant in the sealed make-up water tank 123 is insufficient and supplies make-up water from the make-up water tank 124 to the closed loop coolant circulation line 121 to replenish it. make it possible

In addition, the sealed cooling unit 121 may further include an oil detection sensor 126.

The oil detection sensor 126 is installed on the closed-loop coolant circulation line 121 so that oil due to damage due to aging of the first heat exchanger 110, etc., flows into the coolant in the closed-loop coolant circulation line 121. If mixed, it can be detected and transmitted to the control unit 127. When the oil detection signal is transmitted to the control unit 127, the control unit 127 can generate a failure signal through the notification unit 128.

The second heat exchanger 130 is connected to the closed loop cooling water circulation line 121, and is connected to the water intake line 141 and the water outlet line 143 of the open cooling unit 140, which will be described later, and is connected to the closed loop type cooling water circulation line 121. The cooling water circulating through the cooling water circulation line 121 can be cooled by heat exchange with low-temperature fresh water taken in from the construction tunnel 310 through the water intake line 141.

The open cooling unit 140 takes in fresh water from the construction tunnel 310 and supplies it to the second heat exchanger 130, thereby exchanging heat with the cooling water circulating through the closed loop cooling water circulation line 121 and then exchanging heat with the cooling water circulating through the construction tunnel. (310) The cooling water circulating through the closed loop cooling water circulation line (121) can be cooled by repeating the process of draining the water again with fresh water.

For example, the open cooling unit 140 may include a water intake line 141, a low-temperature fresh water supply pump 142, and a water outlet line 143.

The water intake line 141 may be connected to the second heat exchanger 130 to supply fresh water in the construction tunnel 310 to the second heat exchanger 130.

Here, the water intake line 141 simply takes in low-temperature fresh water from the fresh water in the construction tunnel 310 and supplies it to the second heat exchanger 130, so the length from the second heat exchanger 130 is kept as short as possible. It is most desirable to do so.

Accordingly, the water intake line 141 is connected to the second heat exchanger 130 so that the water intake port is located below the fresh water surface in the construction tunnel 310, and intakes low-temperature fresh water from the fresh water surface in the construction tunnel 310. It is desirable to enable supply to the second heat exchanger 130.

The low-temperature fresh water supply pump 142 can be installed on the water intake line 141 to intake fresh water in the construction tunnel 130 through the water intake line 141 and supply it to the second heat exchanger 130. there is.

Here, it is preferable that at least two of the low-temperature fresh water supply pumps 142 are installed on the water intake line 141 so that they can be connected in parallel to prepare for operation in case of an emergency such as a malfunction.

As the low-temperature fresh water supply pump 142 operates, the water outlet line 143 is supplied to the second heat exchanger 130 through the water intake line 141 and the second heat exchanger 130 through the closed loop cooling water circulation line 121. The relatively high temperature fresh water that has exchanged heat with the cooling water introduced into the heat exchanger 130 can be discharged back into the construction tunnel 310 as fresh water.

Here, the water outlet line 143 is connected to the second heat exchanger 130 so that the water outlet can be placed in the lower part of the construction tunnel 310, so that the high-temperature fresh water discharged from the second heat exchanger 130 can be used in the construction tunnel 310. (310) As it is discharged to the bottom and rises, it gradually mixes with a large amount of low-temperature fresh water in the construction tunnel 310 and is preferably disposed at the bottom of the construction tunnel 310 so that heat can be exchanged by convection.

Meanwhile, the open cooling unit (140) takes fresh water from the construction tunnel (310) through the water intake line (141) and supplies it to the second heat exchanger (130), and fresh water discharged from the second heat exchanger (130) Since the main purpose is water intake and discharge of water back into fresh water within the construction tunnel 310 through the water outlet line 143, low-cost PE pipes can be used without the need to use expensive copper pipes for the water intake line 141 and the water outlet line 143. Therefore, facility costs can be significantly reduced.

Referring to FIG. 3, the operating process and effects of the crude oil shipping pump cooling system for an underground oil storage base according to an embodiment of the present invention will be described.

Referring to FIG. 3, the crude oil shipment pump cooling system 100 for an underground oil storage base according to an embodiment of the present invention is used to circulate through the cooling/lubrication oil line 220 of the oil circulation unit of the crude oil shipment pump. In order to cool the cooling/lubricating oil, first, cooling and lubricating the driving parts such as the electric motor, bearing, and mechanical room of the crude oil delivery pump 210 are performed, and the cooling/lubricating oil with an increased temperature is operated by operating the oil circulation unit. It is supplied to the first heat exchanger (110) through the cooling/lubrication oil line (220).

Meanwhile, the coolant 120 of the closed cooling unit 120 is supplied to the first heat exchanger 110 through the closed loop coolant circulation line 121 as the coolant circulation pump 122 operates.

Therefore, the cooling/lubrication oil supplied through the cooling/lubrication supply line 220 to the first heat exchanger 110 and the coolant supplied through the closed loop type coolant circulation line 121 of the sealed cooling unit 120 are By exchanging heat with each other, the temperature of the cooling/lubricating oil decreases and the temperature of the coolant increases.

As described above, the cooling/lubricating oil, whose temperature has been reduced by heat exchange with the cooling water through the first heat exchanger 110, is moved back to the crude oil shipping pump 210 through the cooling/lubricating oil line 220 of the oil circulation unit. After cooling and lubricating the driving part of the crude oil shipping pump 210, the cooling/lubricating oil line 220 is supplied to the first heat exchanger 110 through the cooling/lubricating oil line 220. Therefore, circulation occurs while repeating the process of supplying to the first heat exchanger 110.

In addition, the coolant in the closed-loop coolant circulation line 121 whose temperature has been raised by heat exchange with the cooling/lubrication oil through the first heat exchanger 110 is transferred to the second coolant circulation line 121 through the closed-loop coolant circulation line 121. It is supplied to the heat exchanger (130).

At this time, the oil detection sensor 126 connected to the closed loop coolant circulation line 121 detects whether oil is mixed in the closed loop coolant circulation line 121, and is sealed by the oil detection sensor 126. When oil is detected in the loop-type coolant circulation line 121 and an oil detection signal is transmitted to the control unit 127, the control unit 127 generates a failure signal through the notification unit 128 so that the manager can operate the first heat exchanger 110. ) to quickly identify and respond to malfunctions.

At the same time, the low-temperature fresh water supply pump 142 of the open cooling unit 140 operates, and as the low-temperature fresh water supply pump 142 operates, low-temperature fresh water in the construction tunnel 310 flows through the water intake line 141. The water is taken in and supplied to the second heat exchanger (130).

Here, at least two of the low-temperature fresh water supply pumps 142 are connected in parallel to the water intake line 141, so that even if one of the low-temperature fresh water supply pumps 142 fails, the low-temperature fresh water supply pump 142 is prevented from malfunctioning. This prevents the supply of low-temperature fresh water in the construction tunnel 310 from being interrupted to the second heat exchanger 130 through the water intake line 141 from occurring.

Therefore, the coolant with an increased temperature supplied through the closed-loop coolant circulation line 121 to the second heat exchanger 130 and the low-temperature fresh water in the construction tunnel 310 supplied through the water intake line 141 are each other. As heat is exchanged, the temperature of the cooling water decreases and the temperature of the low-temperature fresh water increases.

As described above, the coolant whose temperature has been lowered by heat exchange with the low-temperature fresh water in the construction tunnel 310 through the second heat exchanger 130 is returned to the first heat exchanger 110 through the closed loop coolant circulation line 121. After the cooling/lubricating oil is cooled by heat exchange with the cooling/lubricating oil supplied to the first heat exchanger 110 through the cooling/lubricating oil line 220, the closed-loop coolant circulation line 121 It circulates by repeating the process of being supplied to the second heat exchanger 130.

Meanwhile, the fresh water in the construction tunnel 310 supplied to the second heat exchanger 130 through the water intake line 141, whose temperature is increased by heat exchange with the cooling water through the second heat exchanger 130, is supplied to the water outlet line 143. ) and is discharged to the lower part of the construction tunnel.

Here, the fresh water with an increased temperature discharged to the lower part of the construction tunnel 310 through the water outlet line 143 rises from the lower part of the construction tunnel 310 and mixes with a large amount of low-temperature fresh water in the construction tunnel 310, resulting in a convection phenomenon. Heat exchange occurs gradually.

Therefore, even if heat exchange is performed by discharging the fresh water in the tunnel, whose temperature has increased by heat exchange with the cooling water through the second heat exchanger 130, into fresh water in the construction tunnel 310 through the water outlet line 143, the temperature is less than 0.5°C. Only a slight increase in the temperature of the fresh water in the construction tunnel 310 occurs, making it possible to continue operating the crude oil delivery pump 210 in an efficient and optimal condition.

At this time, the open cooling unit 140 continuously supplies low-temperature fresh water in the construction tunnel 310 to the second heat exchanger 130 through the water intake line 141 as the low-temperature fresh water supply pump 142 operates. The process of continuously cooling the cooling water supplied to the second heat exchanger (130) through the closed loop cooling water circulation line (121) and then discharging it to the lower part of the construction tunnel (310) through the water outlet line (143) is repeated. It will run.

Meanwhile, if the amount of coolant that is heat exchanged while circulating through the first and second heat exchangers (110) and (130) through the closed loop coolant circulation line 121 is insufficient, the coolant stored in the sealed supplementary water tank 123 is used. It ensures that the insufficient amount can be replenished through the closed loop coolant circulation line 121, and when the coolant charged in the sealed supplementary water tank 123 becomes insufficient, the supplementary water pump 125 is operated to fill the supplementary water tank. Make-up water is supplied from (124) to the closed loop cooling water circulation line (121) so that it can be filled.

As described above, the crude oil shipping pump cooling system 100 for an underground oil storage base using fresh water in a construction tunnel according to an embodiment of the present invention uses cooling/lubricating oil for cooling and lubricating the driving part of the crude oil shipping pump 210. Rather than cooling using equipment that requires a large amount of power, such as a chiller, cooling is performed by primary heat exchange using coolant through the first heat exchanger 110, and then the coolant is transferred to the second heat exchanger 130. In order to secure the watertightness of the construction tunnel 310 and prevent the different oil types stored in each oil storage tunnel from mixing, tens of thousands of tons or more of low-temperature oil, which has an almost constant temperature regardless of the temperature of the outside air, is always stored in the construction tunnel 310. It can be cooled by secondary heat exchange with fresh water.

Therefore, the crude oil shipping pump cooling system 100 for an underground oil storage base using fresh water in a construction tunnel according to an embodiment of the present invention is not only easy to purchase and uses low-cost equipment, but also simple to construct the system. Therefore, it has the advantage of being economical and constructible.

In addition, compared to systems that use equipment such as chillers that require high-cost equipment and require large amounts of power, power consumption is greatly reduced while continuous operation is possible without emergency stoppage of the crude oil shipping pump 210. By reducing the operating time of the shipping pump 210, operating costs and operating labor costs can be reduced.

In addition, the system is very simple and easy to operate, regular maintenance elements are limited, and purchasing consumable parts is simple. In addition, the optimal operation of the crude oil delivery pump 210 improves the performance of the crude oil delivery pump 210 and extends its service life. Since it can be increased significantly, it has the advantage of enabling stable operation.

In addition, the crude oil shipment pump cooling system 100 for an underground oil storage base using fresh water in a construction tunnel according to an embodiment of the present invention is a crude oil shipment pump (100) through the cooling/lubrication oil line 220 of the oil circulation unit. The cooling/lubricating oil circulating through 210) and the first heat exchanger 110 circulates through the first and second heat exchangers 110 and 130 through the closed loop coolant circulation line 121 of the sealed cooling unit 120. The coolant that is cooled by the coolant and circulates through the first and second heat exchangers (110) and (130) through the closed loop type coolant circulation line (121) is discharged through the water intake line (141) of the open cooling unit (140). 2 It is composed of a double cooling unit structure that is cooled by low-temperature fresh water in the construction tunnel 310 that is supplied to the heat exchanger 130 and then discharged as fresh water in the construction tunnel 310 through the water outlet line 143.

Therefore, the cooling/lubricating oil that is supplied to the first heat exchanger 110 through the cooling/lubricating oil line 220, exchanges heat, and then circulates to the crude oil shipping pump 210 causes the aging of the first heat exchanger 110, etc. Even if the cooling water leaks due to damage and is mixed into the coolant, the coolant circulation line through which the coolant of the sealed cooling unit 120, which can be mixed with the cooling/lubricating oil when the first heat exchanger 110 is damaged, is circulated is the first, 2 It is formed in a closed loop type connected to the heat exchanger (110) (130) to fundamentally prevent a large amount of fresh water in the construction tunnel (310) from being contaminated by the cooling/lubricating oil even if cooling/lubricating oil is mixed into the cooling water. make it possible

Although the detailed description of the present invention described above has been described with reference to preferred embodiments of the present invention, those skilled in the art or those skilled in the art will understand the spirit of the present invention as described in the patent claims to be described later. It will be understood that the present invention can be modified and changed in various ways without departing from the technical scope.

(110): First heat exchanger (120): Closed cooling unit
(121): Closed loop coolant circulation line (122): Coolant circulation pump
(123): Closed make-up water tank (124): Make-up water tank
(125): Make-up water pump (130): Second heat exchanger
(120): Drive motor (140): Open cooling unit
(141): Water intake line (142): Low-temperature fresh water supply pump
(143): Water outlet line

Claims (6)

A first heat exchanger connected to the cooling/lubrication oil line of the oil circulation unit of the crude oil shipping pump;
A closed cooling unit in which cooling water circulates through the first heat exchanger along a closed-loop cooling water circulation line and exchanges heat with the cooling/lubricating oil line to cool the cooling/lubricating oil circulating through the cooling/lubricating oil line;
A second heat exchanger connected to the closed loop cooling water circulation line; and
The fresh water in the construction tunnel is taken, supplied to the second heat exchanger, exchanged heat with the cooling water circulating through the closed loop cooling water circulation line, and then the process of discharging the fresh water again in the construction tunnel is repeated through the closed loop cooling water circulation line. A crude oil shipping pump cooling system for an underground oil storage base using fresh water in a construction tunnel that includes an open cooling unit that cools the circulating cooling water. According to claim 1,
The sealed cooling unit,
a closed-loop cooling water circulation line connected to the first and second heat exchangers in a closed loop; and
It is installed on the closed-loop coolant circulation line and moves the coolant in the closed-loop coolant circulation line to the first heat exchanger to exchange heat with the cooling/lubrication oil flowing into the first heat exchanger through the cooling/lubrication oil line. , the cooling water discharged from the first heat exchanger is moved to the second heat exchanger through a closed loop cooling water circulation line, exchanges heat with fresh water in the construction tunnel taken into the second heat exchanger, and then circulates back to the first heat exchanger. A crude oil shipping pump cooling system for an underground oil storage base using fresh water in a construction tunnel including a cooling water circulation pump. According to clause 2,
The sealed cooling unit,
A sealed supplementary water tank connected to the closed loop coolant circulation line and capable of replenishing coolant in the closed loop coolant circulation line;
A supplementary water tank connected to the closed loop cooling water circulation line; and
A crude oil shipping pump cooling system for an underground oil storage base using fresh water in a construction tunnel, further comprising a make-up water pump that supplies make-up water from the make-up water tank to the closed-loop cooling water circulation line. According to claim 1,
The open cooling unit,
A water intake line connected to the second heat exchanger to supply fresh water in the construction tunnel to the second heat exchanger;
a low-temperature fresh water supply pump installed on the water intake line to supply fresh water in the construction tunnel to a second heat exchanger through the water intake line; and
As the low-temperature fresh water supply pump operates, the fresh water supplied to the second heat exchanger through the water intake line and heat-exchanged with the cooling water flowing into the second heat exchanger through the closed loop cooling water circulation line is discharged again as fresh water in the construction tunnel. Cooling system for crude oil shipping pumps for underground oil storage bases using fresh water in construction tunnels containing lines. According to clause 4,
The low-temperature fresh water supply pump,
A crude oil shipment pump cooling system for an underground oil storage base using fresh water in a construction tunnel, characterized in that at least two are connected in parallel to the water intake line. According to clause 4,
The water intake line has a water intake port disposed below the fresh water surface in the construction tunnel so that low-temperature fresh water can be taken in from the fresh water surface in the construction tunnel and supplied to the second heat exchanger,
The water outlet line is a construction tunnel, characterized in that the hot water discharged from the second heat exchanger is discharged to the lower part of the construction tunnel and rises, mixing with a large amount of low-temperature fresh water in the construction tunnel to exchange heat. Crude oil shipping pump cooling system for underground oil storage base using fresh water in tunnel.