KR20240140845A - Liquefactor and method for liquefying a gas - Google Patents

Abstract

A gas liquefaction device comprises a frame (O) accommodating at least one plate-fin heat exchanger (E) at one end, each plate having a length and a width, the plates being arranged such that their lengths are parallel to the length of the frame, and a turbine (M) accommodating at the other end for providing cooling to the at least one heat exchanger, the frame being oriented such that the turbine is positioned beneath the at least one exchanger.

Description

LIQUEFACTOR AND METHOD FOR LIQUEFYING A GAS

The present invention relates to a liquefactor and a method for liquefying gases that are liquefied at cryogenic temperatures, such as, for example, nitrogen, hydrogen and natural gas.

FR2706025 describes an apparatus for separating air by cryogenic distillation, comprising a frame housing heat exchangers, subcoolers, valves, cryogenic pumps, turbines and piping connecting them together. A distillation column is positioned outside this frame.

A nitrogen liquefier is known from US20220404094.

The literature ["Marinized Liquefaction and Gas Conditioning for Floating LNG" by Bryan Trocquet, GasTech 2009] discloses a framework having a heat exchanger at one end.

One object of the present invention is to reduce the installation footprint of the liquefier and to facilitate late installation of any equipment within the skeleton, e.g. a turbine, even if the turbine is delivered late.

In practice, turbines are often delivered after the arrival of other elements, and it is desirable to find a means for installing turbines with a reduced number of required operations, and especially without the need for a crane; on the job site, an overhead crane or a simple material lift can be used for on-site installation of the equipment.

It is advantageous to use a support means for the heat exchanger of the liquefier, which also acts as a framework for the modular assembly. As a result, this framework accommodates other elements of the liquefier, which allows the assembly to be mounted in the workshop by qualified personnel, and connections between the exchanger and other elements of the framework, such as connection boxes, pipes, measuring instruments and electrical equipment, are also made in the manufacturing workshop.

In addition to reducing the installation footprint, locating the exchanger at least 4 m above ground level allows the liquid to be generated, thereby generating hydrostatic pressure, which can be used to reduce the size of the pumps used to transport the gas or pressurize the liquid.

According to one aspect of the present invention, a liquefier for a gas liquefied at a cryogenic temperature is provided, comprising an assembly including a skeleton, the skeleton having a substantially elongated parallelepiped shape and having a main axis corresponding to a length thereof and two ends, the skeleton does not accommodate a distillation column, and inside the skeleton:

i) at least one plate-fin heat exchanger is provided at one end of the skeleton, each plate having a length and a width, and the plates are arranged such that their lengths are parallel to the axis of the skeleton;

ii) there is a line for sending the gas to be liquefied to at least one heat exchanger,

iii) a line for removing cooled or liquefied gas from at least one heat exchanger;

iv) has a support member mounted inside the skeleton,

v) at least one turbine, the turbine being arranged to drive a compressor which is fastened to the support and arranged outside the skeleton, the turbine being connected to at least one exchanger to direct gas cooled or heated within the at least one heat exchanger to be expanded within the turbine and/or to direct gas expanded within the turbine from the turbine to the at least one heat exchanger,

vi) at least one cooler connected to the compressed refrigerant gas within the compressor,

vii) there is a means for transporting the refrigerant to the cooler,

viii) a) the turbine is located at another end of the frame and the cooler is located between the turbine and at least one heat exchanger, or b) the cooler is located at another end of the frame and the turbine is located between the cooler and at least one heat exchanger,

The skeleton is positioned with its main axis vertical, at least one heat exchanger is positioned above the at least one turbine and the at least one cooler, means for sending gas to be liquefied to the heat exchanger within the skeleton, and means connected to the heat exchanger for removing the liquefied gas from the skeleton.

According to other optional aspects that can be combined together in any way compatible with science and logic:

· The skeleton comprises at least one baffle dividing the skeleton into at least two parts, the baffle having the shape of a rectangular plate arranged perpendicularly to the axis of the skeleton, the baffle acting as a support for the turbine if the cooler is at the other end of the skeleton or as a support for the cooler if the turbine is at the other end of the skeleton, the turbine and the cooler being separated from each other by the baffle,

· The skeleton comprises at least two baffles dividing the skeleton into at least three parts, the baffles having the shape of rectangular plates arranged perpendicularly to the axis of the skeleton, one of the baffles acting as a support for the turbine if the cooler is at the other end of the skeleton or as a support for the cooler if the turbine is at the other end of the skeleton, the turbine and the cooler are separated from each other by the baffles acting as supports,

· The skeleton includes fastening feet that are connected to other ends of the skeleton and position the skeleton on a foundation;

· The skeleton includes means for fluidly connecting the exchanger to the compressor to convey cooled gas within the exchanger to the compressor,

· The skeleton includes means for fluidly connecting the exchanger to the turbine to convey the expanded gas within the turbine to at least one exchanger,

· The skeleton is divided into at least three compartments, each compartment having a dimension that is a portion of the length of the skeleton, at least one heat exchanger is within one of the at least three compartments, the turbine is within another of the at least three compartments, and at least one cooler is within another of the at least three compartments.

· The skeleton does not accommodate a heat exchanger or a turbine, but includes a fourth compartment that accommodates connecting lines between the heat exchanger and other elements, which may be at least one turbine;

· The turbine is located at the other end of the skeleton and is connected to the fourth compartment through a compartment arranged parallel to the compartment housing the cooler,

· The skeleton is at least 10 m long, and the cooler and turbine occupy a portion of the skeleton's length of at least 4 m;

· The turbine is connected to provide cold air to at least one heat exchanger,

· The skeleton is formed as a single fragment,

· At least one heat exchanger is insulated.

According to another aspect of the present invention, a method for liquefying a gas at cryogenic temperatures is provided, the method comprising: using an assembly comprising a skeleton, the skeleton having a substantially elongated parallelepiped shape and having a main axis corresponding to its length and two end portions, the skeleton not accommodating a distillation column, the skeleton comprising:

i) at least one plate-fin heat exchanger (E) is provided at one end of the skeleton, each plate having a length and a width, and the plates are arranged such that their lengths are parallel to the axis of the skeleton;

ii) there is a line (C) for sending the gas to be liquefied to at least one heat exchanger,

iii) a line for removing cooled or liquefied gas from at least one heat exchanger;

iv) has a support member mounted inside the skeleton,

v) at least one turbine (M), the turbine being arranged to drive a compressor which is fastened to the support and arranged outside the skeleton, the turbine being connected to at least one exchanger to send gas cooled or heated within the at least one heat exchanger to be expanded within the turbine and/or to send gas expanded within the turbine from the turbine to the at least one heat exchanger,

vi) at least one cooler (R) connected to the compressed cooling gas within the compressor,

a) the turbine is located at another end of the frame and the cooler is located between the turbine and at least one heat exchanger, or b) the cooler is located at another end of the frame and the turbine is located between the cooler and at least one heat exchanger,

viii) the skeleton is positioned with its main axis vertical, and at least one heat exchanger (E) is positioned above at least one turbine (M) and at least one cooler (R),

The gas to be liquefied is sent to a heat exchanger within the skeleton and the liquefied gas is removed from the heat exchanger, the refrigerant is conveyed to a cooler and the cold is provided for liquefaction by expanding the gas within at least one turbine, the gas is cooled or heated within the at least one heat exchanger and/or the gas expanded within the turbine is sent to at least one heat exchanger.

According to another aspect of the present invention, an assembly comprising a skeleton is provided, the skeleton has a substantially elongated parallelepiped shape and has a main axis corresponding to its length and two ends, the skeleton does not accommodate a distillation column, and inside the skeleton:

i) at least one plate-fin heat exchanger is provided at one end of the skeleton, each plate having a length and a width, and the plates are arranged such that their lengths are parallel to the axis of the skeleton;

ii) there is a line for sending the gas to be liquefied to at least one heat exchanger,

iii) a line for removing cooled or liquefied gas from at least one heat exchanger;

iv) has a support member mounted inside the skeleton,

v) at least one turbine, the turbine being arranged to drive a compressor which is fastened to the support and arranged outside the skeleton, the turbine being connected to at least one exchanger to direct gas cooled or heated within the at least one heat exchanger to be expanded within the turbine and/or to direct gas expanded within the turbine from the turbine to the at least one heat exchanger,

vi) at least one cooler connected to the compressed refrigerant gas within the compressor,

vii) there is a means for transporting the refrigerant to the cooler,

a) the turbine is located at another end of the frame and the cooler is located between the turbine and at least one heat exchanger, or b) the cooler is located at another end of the frame and the turbine is located between the cooler and at least one heat exchanger,

At least one turbine and at least one cooler are supported within the frame so as to be operable when the frame is positioned with its major axis along its length being vertical, and at least one heat exchanger is supported within the frame so as to be operable when positioned above the at least one turbine and the at least one cooler.

The support may be a flat surface, particularly one positioned perpendicular to the length of the bone, between two ends of the bone.

The support may be a skeletal bulkhead.

According to another aspect of the present invention, an apparatus for separating air by cryogenic distillation is provided, comprising a system of columns, a liquefier as described above, and means for sending nitrogen-rich gas from the system of the column to the liquefier as gas to be liquefied, and possibly means for sending gas liquefied in the liquefier to the system of the column.

The present invention will be described in more detail with reference to the drawings, in which:

Figure 1 is a longitudinal cross-sectional view of a skeleton according to the present invention in a vertical position.
Figure 2 is a longitudinal cross-sectional view of a modified example skeleton according to the present invention during manufacturing and transportation in a horizontal position.
Figure 3 is a longitudinal cross-sectional view of a modified example skeleton according to Figure 2 illustrating field installation.

Figure 1 illustrates an assembly including a nitrogen liquefaction frame (1) installed with its main axis being vertical, and equipment accommodated within the frame. One end of the frame is positioned several meters above the ground or a flat surface, while the opposite end is fixed to the ground or a flat surface.

The skeleton (O) has a substantially parallelepiped shape having length, width and height. The cross section of the skeleton is rectangular or square.

As illustrated here, the parallelepiped framework actually comprises two parallelepipeds which may have different widths and are preferably joined to one another by welding or bolting, the compartments (1, 4) forming one parallelepiped and the compartments (2, 3) forming another parallelepiped. For reasons of stability it is preferred that the wider parallelepiped (in this case the parallelepiped comprising the compartments (2, 3)) is arranged beneath the other parallelepiped.

At the top of the frame of the first compartment (1), there is at least one heat exchanger (E) used to cool the gas to be liquefied to a temperature close to or at the liquefaction temperature. When the frame is installed vertically, the exchanger is oriented with its hot end upward and its bottom end downward. A line (C) carries the gas to be liquefied to the hot end of the heat exchanger, and this line (C) is connected to an air separation device that potentially produces nitrogen gas.

The first compartment (1) is insulated using a powder insulator such as perlite.

Below the first compartment (1) there may be an auxiliary compartment (4), also called a connection box, separated from the first compartment by a wall and comprising essentially a powder insulation or rock wool. The auxiliary compartment (4) does not accommodate either a heat exchanger or a turbine. It mainly accommodates connection lines passing through the bulkhead via openings in its interior. These lines connect the heat exchangers (E) to the turbines located in the third compartment (3) located at the ends of the frame (O). The turbines are connected to at least one exchanger so as to send gas cooled or heated in the at least one heat exchanger to be expanded in the turbine and/or to send gas expanded in the turbine from the turbine to the at least one heat exchanger.

The heat exchanger (E) is a plate-fin exchanger comprising a stack of plates, each plate being separated from at least one adjacent plate by fins, each plate having a length and a width, and the plates being arranged such that their lengths are parallel to the axis of the skeleton.

The drawing shows a heat exchanger comprising two bodies, each body being considered a heat exchanger and each comprising a stack of plates, each plate having a length and a width, the plates being arranged such that their lengths are parallel to the axis of the frame.

The turbine drives the compressor of the liquefier via a shaft, the compressor being located outside the skeleton (O). The compressor is used to compress gas that has been cooled or heated within at least one heat exchanger.

Depending on the method, at least a portion of the gas compressed within the compressor may be expanded within the turbine.

Within the second compartment (2) located between the third compartment (3) and the auxiliary compartment (4), there is a cooler (R) supplied with a refrigerant such as water to cool the gas compressed in the compressor driven by the turbine of the third compartment (3). Therefore, there is a line passing through the bulkhead between the second and third compartments (2, 3). This bulkhead may need to be reinforced to withstand the weight of the cooler (R). Since the cooler (R) operates at ambient temperature or at a temperature exceeding 20° C., it does not need to be insulated, or it may have protective elements to prevent personnel from touching the hot parts. The frame is preferably not clad with metal sheets around the cooler, which is therefore preferable, and is therefore located outdoors.

To allow direct access for the fluid to exit from at least one exchanger (E) to the turbine (T) and to pass from the turbine (T) to at least one exchanger, the compartment (5) extends on one side of the framework, next to the second compartment (2), between the second and fourth compartments. Thus the fluid does not have to pass through the second compartment (2), the line passes only through the compartment (5). Since the line of the compartment is L-shaped, this provides greater flexibility when the exchanger is heated and cooled, causing expansion and contraction.

This compartment (5) must be insulated using particulate insulation or rock wool and therefore sealed, as must the compartments (1, 4) (if present).

Since the liquefier itself does not contain these elements, the skeleton does not accommodate a scrubbing or distillation column.

The feed gas is sent into the skeleton (O), cooled in at least one exchanger (E), in one variant at least a portion of the feed gas is compressed in a compressor driven by a turbine (T) and subsequently cooled in a cooler (R), and at least a portion of the feed gas is expanded in the turbine (T). The gas sent to the turbine (T) preferably comes from the cooler (R).

A portion of the feed gas is liquefied within the exchanger or downstream of the exchanger to form the product of the process.

The feed gas may be nitrogen, hydrogen or natural gas.

In this case, this type of liquefier is generally associated with a device for separating air by cryogenic distillation comprising a system of columns (S), the nitrogen gas from the device for separating air comprises the feed gas of the liquefier, and at least a part of the formed liquid nitrogen is possibly returned to the device for separating air.

It is noted that the exchangers are arranged at a height such that their length extends in the direction of the main axis of the frame, thereby allowing a wise use of the space beneath the exchangers. Furthermore, if the frame is at least 10 m long and the cooler and turbine occupying a part of the length of the frame are at least 4 m, then when the frame is arranged vertically, the cold end of at least one exchanger is at least 6 m above the ground. Therefore, the liquefied gas coming out of the cold end has a non-negligible hydrostatic pressure, which makes it easier to send it to another location and allows the size of the pump, if any, to be reduced.

Since the compartments (1, 4) (if present) are insulated using perlite, the skeleton is clad with metal sheets. In the case of the compartments (2, 3), where the insulation is typically rock wool, it is possible for the skeleton not to be clad with metal sheets.

In case the turbine arrives late on site, it is advisable to leave an opening in the frame large enough to allow the turbine to be inserted. Since the chamber (5) of the turbine (T) is at ground level, this insertion is particularly easy and does not require the use of a crane.

A turbine (T) is connected to provide cooling air to at least one heat exchanger (E).

The assembly including the skeleton (O) of Fig. 2 differs from the assembly of Fig. 1 in that the compartments (2, 3) are inverted, the cooler (R) is located at the end of the skeleton of the compartment (2) and the turbine (M) is located between the compartment (4) of the cooler (R) and the compartment (2). Since the compartment (3) of the turbine (T) is at a height of more than 2 m, this insertion does not require the use of a crane.

During manufacturing and transportation (Fig. 2), the frame is arranged with its main axis horizontal. Lifting lugs (L) can be seen at the end portion of the frame where the exchanger (E) is located. These lugs (L) can be located at both ends of the frame (O).

During field installation (Fig. 3), these lugs or attachments (L) enable the crane (G) to lift the frame and install it with its main axis vertical. The feet (P) enable the frame to be fastened to the ground or foundation.

The skeleton (O) may take the form of a standardized container to facilitate transport.

The skeleton (O) comprises means for directing flushing gas to the compartments (1, 4, 5) (if present for the latter two compartments).

The turbine may be transported within the skeleton or integrated into the skeleton on site. In the second case, the dimensions and stiffness values of the skeleton must be calculated both with and without the turbine.

The skeleton may be lifted in a single operation, preferably formed as a single piece.

At least one turbine and at least one cooler are supported within the frame so as to be operable when the frame is positioned with its major axis along its length being vertical. At least one heat exchanger is supported within the frame so as to be operable when positioned above the at least one turbine and the at least one cooler.

If the skeleton is to be transported, it is understood that the equipment contained within it must be secured horizontally for transport, even if the equipment must ultimately operate vertically with the skeleton.

The gas to be expanded within at least one turbine may be the gas to be liquefied or another gas, for example a mixed refrigerant.

Claims (14)

A liquefier for a gas liquefied at a cryogenic temperature, comprising an assembly including a skeleton (O), the skeleton having a substantially elongated parallelepiped shape and having a main axis corresponding to its length and two ends, the skeleton does not accommodate a distillation column, and inside the skeleton:
i) at least one plate-fin heat exchanger (E) is provided at one end of the skeleton, each plate having a length and a width, and the plates are arranged such that their lengths are parallel to the axis of the skeleton;
ii) there is a line (C) for sending the gas to be liquefied to at least one heat exchanger,
iii) a line for removing cooled or liquefied gas from at least one heat exchanger;
iv) has a support member mounted inside the skeleton,
v) at least one turbine (M), the turbine being arranged to drive a compressor which is fastened to the support and arranged outside the skeleton, the turbine being connected to at least one exchanger to send gas cooled or heated within the at least one heat exchanger to be expanded within the turbine and/or to send gas expanded within the turbine from the turbine to the at least one heat exchanger,
vi) at least one cooler (R) connected to the compressed cooling gas within the compressor,
vii) there is a means for transporting the refrigerant to the cooler,
a) the turbine is located at another end of the frame and the cooler is located between the turbine and at least one heat exchanger, or b) the cooler is located at another end of the frame and the turbine is located between the cooler and at least one heat exchanger,
A liquefier, wherein the frame is positioned with its main axis vertical, at least one heat exchanger (E) is positioned above at least one turbine (M) and at least one cooler (R), and there is means (C) for sending gas to be liquefied to the heat exchanger within the frame and means connected to the heat exchanger for removing the liquefied gas from the frame. A liquefier, comprising in the first paragraph at least one baffle dividing the skeleton into at least two parts (1, 2, 3, 4, 5), the baffle having a shape of a rectangular plate arranged perpendicularly to the axis (O) of the skeleton, the baffle acting as a support for the turbine (M) when the cooler (R) is at the other end of the skeleton or as a support for the cooler when the turbine is at the other end of the skeleton, the turbine and the cooler being separated from each other by the baffle. A liquefier, comprising a fastening foot (P) connected to the other end of the skeleton (O) and positioning the skeleton on a foundation, in claim 1 or 2. A liquefier according to any one of claims 1 to 3, comprising means for fluidly connecting the exchanger to the compressor for conveying the cooled gas within the exchanger to the compressor. A liquefier according to any one of claims 1 to 4, comprising means for fluidly connecting the exchanger to the turbine for conveying gas expanded within the turbine to the exchanger. A liquefier according to any one of claims 1 to 5, wherein the skeleton is divided into at least three compartments (1, 2, 3), each compartment having a dimension which is a fraction of the length of the skeleton, at least one heat exchanger (E) is in one of the at least three compartments (1), a turbine (M) is in another of the at least three compartments (3), and at least one condenser (R) is in another of the at least three compartments (2), the compartments housing the turbine and the at least one condenser forming a parallelepiped which is wider than the parallelepiped formed by the compartments housing the heat exchangers. A liquefier, in the sixth paragraph, comprising a fourth compartment (4) which accommodates a connecting line between at least one heat exchanger (E) and another element which may be at least one turbine (M), but which does not accommodate a heat exchanger or a turbine. In the seventh paragraph, the turbine (M) is positioned at the other end of the frame (O) and is connected to the fourth compartment (4) through a compartment (5) arranged parallel to the compartment (2) accommodating the cooler (R). A liquefier according to any one of claims 1 to 8, wherein the skeleton (O) is at least 10 m long, and the cooler (R) and the turbine (M) occupy a portion of the length of the skeleton of at least 4 m. A liquefier according to any one of claims 1 to 9, wherein at least one heat exchanger is insulated. A method for liquefying a gas at cryogenic temperatures, the method comprising: using an assembly comprising a skeleton (O), the skeleton having a substantially elongated parallelepiped shape and having a main axis corresponding to its length and two ends, the skeleton not accommodating a distillation column, and inside the skeleton:
i) at least one plate-fin heat exchanger (E) is provided at one end of the skeleton, each plate having a length and a width, and the plates are arranged such that their lengths are parallel to the axis of the skeleton;
ii) there is a line (C) for sending the gas to be liquefied to at least one heat exchanger,
iii) a line for removing cooled or liquefied gas from at least one heat exchanger;
iv) has a support member mounted inside the skeleton,
v) at least one turbine (M), the turbine being arranged to drive a compressor which is fastened to the support and arranged outside the skeleton, the turbine being connected to at least one exchanger to send gas cooled or heated within the at least one heat exchanger to be expanded within the turbine and/or to send gas expanded within the turbine from the turbine to the at least one heat exchanger,
vi) at least one cooler (R) connected to the compressed cooling gas within the compressor,
vii) a) the turbine is located at another end of the frame and the cooler is located between the turbine and at least one heat exchanger, or b) the cooler is located at another end of the frame and the turbine is located between the cooler and at least one heat exchanger,
viii) the skeleton is positioned with its main axis vertical, and at least one heat exchanger (E) is positioned above at least one turbine (M) and at least one cooler (R),
A method wherein the gas to be liquefied is sent to a heat exchanger within the skeleton and the liquefied gas is removed from the heat exchanger, the refrigerant is conveyed to a cooler and the cold is provided for liquefaction by expanding the gas within at least one turbine, the gas is cooled or heated within the at least one heat exchanger and/or the gas expanded within the turbine is sent to the at least one heat exchanger. An assembly comprising a skeleton (O), wherein the skeleton has a substantially elongated parallelepiped shape and has a main axis corresponding to its length and two ends, the skeleton does not accommodate a distillation column, and within the skeleton:
i) at least one plate-fin heat exchanger (E) is provided at one end of the skeleton, each plate having a length and a width, and the plates are arranged such that their lengths are parallel to the axis of the skeleton;
ii) there is a line (C) for sending the gas to be liquefied to at least one heat exchanger,
iii) a line for removing cooled or liquefied gas from at least one heat exchanger;
iv) has a support member mounted inside the skeleton,
v) at least one turbine (M), the turbine being arranged to drive a compressor which is fastened to the support and arranged outside the skeleton, the turbine being connected to at least one exchanger to send gas cooled or heated within the at least one heat exchanger to be expanded within the turbine and/or to send gas expanded within the turbine from the turbine to the at least one heat exchanger,
vi) at least one cooler (R) connected to the compressed cooling gas within the compressor,
vii) there is a means for transporting the refrigerant to the cooler,
viii) a) the turbine is located at another end of the frame and the cooler is located between the turbine and at least one heat exchanger, or b) the cooler is located at another end of the frame and the turbine is located between the cooler and at least one heat exchanger,
An assembly wherein at least one turbine (M) and at least one cooler (R) are supported within the frame so as to be operable when the frame is positioned with its major axis along its length being vertical, and at least one heat exchanger (E) is supported within the frame so as to be operable when positioned above the at least one turbine (M) and the at least one cooler (R). An apparatus for separating air by cryogenic distillation, comprising a system of columns, a liquefier according to any one of claims 1 to 10, and means (C) for sending nitrogen-rich gas from the column system to the liquefier as gas to be liquefied. A device comprising means for sending liquefied gas within a liquefier to a system of a column, in accordance with claim 13.

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