Technical Field
[0001] The present invention relates to a cold box structure for a plate-fin heat exchanger
and an installation method therefor, which are particularly suitable for a high-pressure
aluminum plate-fin heat exchanger.
Background Art
[0002] The plate-fin heat exchanger has the characteristics of compact structure, light
weight, high heat transfer efficiency, etc., and so is widely used in industrial sectors
such as refrigeration, petrochemical, air separation, aerospace, power machinery and
superconducting, and is generally recognized as one of the new efficient heat exchangers.
Due to the low-temperature ductility and good tensile properties of aluminum alloy,
plate-fin heat exchangers made of aluminum alloy are particularly suitable for low-temperature
and ultra-low-temperature applications, and are also widely used in air separation
processes in modern industries. At present, almost all the heat exchangers of air
separation apparatuses use plate-fin heat exchangers. Due to operating at a temperature
below -150°C, the air separation apparatus needs to be placed inside a cold box, and
the cold box is filled with perlite sand to provide heat insulation.
[0003] Generally, the cold box is in the shape of a rectangular hexahedron, comprising a
base, a cold box support frame, four cold box panels and a cold box top plate. In
the prior art, the cold box panels are welded to the outer side the cold box support
frame. The cold box can be made of carbon steel or stainless steel, but due to the
high price of stainless steel, carbon steel is usually used in practice. However,
the carbon steel material is prone to brittle fracture at low temperatures. In the
process of air separation, if leakage occurs at a plate-fin heat exchanger and low-temperature
steam is ejected, the perlite sand inside the cold box becomes damp and hardened,
and the cold box panels or the cold box support frame of carbon steel is easily damaged.
Failure to timely discover leakage may result in other serious consequences.
[0004] In traditional cold box structures, the cold box panels are placed outside the cold
box support frame structure. In the process of air separation, cryogenic steam is
ejected if leakage occurs at the plate-fin heat exchanger. If the leaked steam is
directly ejected to the cold box support frame, since the cold box panels are located
outside the cold box support frame and shield the cold box support frame, the damage
caused by the leakage is not easily discovered in a timely manner, which may result
in the failure to timely discover leakage in the plate-fin heat exchanger. This is
not conducive to the safe operation of air separation systems, resulting in degraded
quality of air separation products, which also may cause serious safety accidents;
in addition, the repair work for the damaged cold box support frame is huge and the
cost is high.
Summary of the Invention
[0005] The present invention provides a cold box structure with cold box panels partly built-in,
which is applicable to a plate-fin heat exchanger, and in particular to a high-pressure
aluminum plate-fin heat exchanger for use in an air separation process. The cold box
of a carbon steel material in the present invention is especially applicable to brazed
aluminum plate-fin heat exchangers with the working pressure higher than 20 bar. Since
leakage easily occurs on the sides of the high-pressure plate-fin heat exchanger where
seals are located, and the temperature at the cold end of the heat exchanger is -196°C,
cryogenic steam ejected due to leakage seriously damages the carbon steel structure,
and brittle fracture, etc. may occur. In the present invention, cold box panels facing
sides of the plate-fin heat exchanger where the seals are located are placed inside
the cold box support frame, so that the leakage can be timely discovered from the
frost and icing conditions of the cold box panels upon occurring, which has the function
of protecting the cold box support frame.
[0006] The technical solution adopted by the present invention to solve the above technical
problems is:
a cold box structure comprising a base, a cold box support frame, four cold box panels
and a cold box top plate, a plate-fin heat exchanger being fixed inside the cold box,
wherein the cold box panels facing sides of the plate-fin heat exchanger where seals
are located are placed inside the cold box support frame, and perlite sand is filled
between the cold box and the plate-fin heat exchanger.
[0007] In the present invention, the cold box support frame, the cold box panels, and the
cold box top plate may be made of carbon steel or stainless steel.
[0008] In the present invention, the cold box panels facing sides of the plate-fin heat
exchanger where lateral plates are located are placed outside the cold box support
frame, and may also be placed inside the cold box support frame.
[0009] An installation method for the cold box structure comprises the steps of:
- 1) fixing a cold box base, installing a cold box support frame, and installing a plate-fin
heat exchanger inside the cold box support frame;
- 2) installing four cold box panels, wherein the cold box panels facing seals of the
plate-fin heat exchanger are installed inside the cold box support frame, and the
cold box panels facing lateral plates of the plate-fin heat exchanger are installed
inside or outside the cold box support frame;
- 3) installing a cold box top plate at the top of the cold box support frame; and
- 4) welding the parts of the cold box in a sealed manner, filling the cold box with
perlite sand, and, if necessary, charging nitrogen.
[0010] In step 2) of the installation method, the cold box panels facing the seals of the
plate-fin heat exchanger are installed in advance inside the cold box support frame,
or are installed on-site inside the cold box support frame, depending on the on-site
installation size.
[0011] The positive effects produced by the technical solution of the present invention
are as follows:
- 1) The cold box support frame is protected. When leakage occurs at the plate-fin heat
exchanger, the leaked steam is prevented from being directly ejected to the cold box
support frame, thereby protecting the cold box support frame from being damaged.
- 2) The leakage situation is timely discovered. The cold box panels facing the sides
of the plate-fin heat exchanger where leakage easily occurs, that is, the sides where
the seals are located, are placed inside the cold box support frame. When leakage
occurs at the plate-fin heat exchanger, cryogenic steam is directly ejected to the
inside cold box panels. Since the cold box panels are thin, air is condensed due to
cooling, and frozen or frost conditions of the cold box panels can also be seen from
outside of the cold box, so as to timely discover the leakage for maintenance. If
the cold box panels are placed outside the cold box support frame, when the ejected
cryogenic steam is exactly on the inside cold box support frame, the heat transfer
is slower due to the thicker support frame, and the air is not easily condensed; in
addition, due to the shielding of the outside cold box panels, it is difficult to
discover the leakage situation of the plate-fin heat exchanger.
Brief Description of the Drawings
[0012]
Fig. 1 is a schematic view of a plate-fin heat exchanger;
Fig. 2 is a schematic structural view of a cold box support frame;
Fig. 3 is a schematic view of the appearance of a first embodiment of the present
invention; and
Fig. 4 is a schematic view of the appearance of a second embodiment of the present
invention.
Detailed Description
[0013] The specific embodiments of the present invention will be further described below
in conjunction with the accompanying drawings.
[0014] Fig. 1 is a schematic view of a plate-fin heat exchanger, wherein the sides on which
seals of the heat exchanger are located are faces b, b', and the sides on which lateral
plates are located are faces a, a'. A plate heat exchanger (in particular a brazed
aluminum plate heat exchanger) has a heat exchange portion inside which a plurality
of heat exchange passages are disposed. The heat exchange passages are formed by alternately
stacking partition plates and profiled plates (for example, ribbed plates or corrugated
plates, finned plates) or distribution devices, and the heat exchange portion is formed
by heating and brazing the stack in a suitable brazing furnace. Under high pressure,
leakage easily occurs at the brazed joint, that is, leakage easily occurs at the faces
b, b' on which the seals of the plate-fin heat exchanger are located.
[0015] Fig. 2 shows a schematic view of a cold box support frame 2, the four sides of which
are A, A', B, B', respectively. The oblique line areas in the figure represent the
interior of the cold box support frame on the side A' and the interior of the cold
box support frame on the side B', respectively, and 1 represents a base. The sides
B, B' of the cold box frame are opposite the sides of the plate-fin heat exchanger
where seals are located, and sides A, A' are opposite the sides of the plate-fin heat
exchanger where cover plates are located (the plate-fin heat exchanger is not shown
in the figure). In the process of installing the cold box panels, the cold box panels
3b, 3b' are installed inside the cold box support frames on the sides B and B', and
the cold box panels 3a, 3a' are installed outside or inside the cold box support frames
on the sides A and A'.
[0016] Fig. 3 is a first embodiment of the present invention, comprising a base 1, a cold
box support frame 2, a cold box top plate 4, and four cold box panels 3a, 3a', 3b,
3b', wherein the oblique line areas in the figure respectively represent the cold
box panel 3a and the cold box panel 3b (3a', 3b' are not visible in the figure). The
cold box panels 3b, 3b' are placed inside the cold box support frame 2, and the cold
box panels 3a, 3a' are placed outside the cold box support frame 2.
[0017] Faces a and a' of the plate-fin heat exchanger are symmetrical faces of the plate-fin
heat exchanger, and faces b and b' are further symmetrical faces of the plate-fin
heat exchanger. The sides A and A' of the cold box frame are symmetrical to each other,
and the sides B and B' are symmetrical to each other. The cold box panels 3a and 3a'
are symmetrical to each other, and 3b and 3b' are symmetrical to each other.
[0018] In the present invention, the interior of the cold box support frame refers to the
side of the cold box support frame facing the heat exchanger; and the exterior of
the cold box support frame refers to the side of the cold box support frame facing
the outside air.
[0019] In the present invention, the cold box panels 3a, 3a', 3b, 3b' refer to the panels
on four sides of the cold box, the cold box top plate 4 refers to the panel located
at the top of the cold box, the base 1 refers to a structure located at the bottom
of the cold box for supporting the cold box, the cold box support frame 2 refers to
a structure that supports the cold box panels to fix the cold box panels.
[0020] In the first embodiment, the cold box panels 3b, 3b' facing the faces b, b' of the
plate-fin heat exchanger are located inside the cold box support frames on the sides
B, B'. Since leakage easily occurs at the faces b, b' of the plate-fin heat exchanger,
the cold box panels 3b, 3b' facing the faces b, b' are built inside the cold box support
frame, which can prevent leaked steam from being directly ejected to the cold box
support frame, thereby having a protection function. In addition, the leakage can
be discovered timely. If the cold box panels 3b, 3b' are placed outside the support
frame, and if the cryogenic steam ejected due to leakage is directly ejected to the
support frame, the leakage is not easily discovered due to the shielding of the cold
box panels.
[0021] In the first embodiment, the cold box panels 3a, 3a' facing the faces a, a' of the
plate-fin heat exchanger are located outside the cold box support frame on the sides
A, A'. Since leakage doesn't easily occur at the faces a, a' of the plate-fin heat
exchanger, in order to reduce installation difficulty, the cold box panels 3a, 3a'
are installed outside the cold box support frame.
[0022] Fig. 4 is a second embodiment of the present invention, comprising a base 1, a cold
box support frame 2, a cold box top plate 4, and four cold box panels 3a, 3a', 3b,
3b', wherein the oblique line areas in the figure respectively represent the cold
box panel 3a and the cold box panel 3b (3a', 3b' are not visible in the figure). The
four cold box panels 3a, 3a', 3b, 3b' are all placed inside the cold box support frame
2.
[0023] In the second embodiment, the cold box structure comprises the cold box panels 3a,
3a', 3b, 3b' placed inside the cold box support frame, wherein the cold box panels
3a, 3a' are placed inside the cold box support frame on sides A, A', and the cold
box panels 3b, 3b' are placed inside the cold box support frame on sides B, B'.
[0024] In the first and second embodiments, the cold box support frame and the cold box
panels are made of carbon steel or stainless steel.
[0025] An installation method of the cold box structure of the first and second embodiments
is as follows:
- 1) fixing a cold box base 1, installing a cold box support frame 2, and installing
a plate-fin heat exchanger inside the cold box support frame 2;
- 2) installing four cold box panels 3a, 3a', 3b, 3b', wherein the cold box panels 3b,
3b' facing seals of the plate-fin heat exchanger are installed inside the cold box
support frame on sides B, B'. In the first embodiment, the cold box panels 3a, 3a'
facing lateral plates of the plate-fin heat exchanger are installed outside the cold
box support frame on sides A, A'; and in the second embodiment, the cold box panels
3a, 3a' facing the lateral plates of the plate-fin heat exchanger are installed inside
the cold box support frame on the sides A, A';
- 3) installing a cold box top plate 4 at the top of the cold box support frame 2; and
- 4) welding joints in a sealed manner, filling the cold box with perlite sand, and,
if necessary, charging nitrogen.
[0026] In step 2) of the foregoing installation method, when the installation size is limited,
the cold box panels 3b, 3b' facing the seals of the plate-fin heat exchanger may be
installed in advance inside the cold box support frame on the sides B, B'; and if
the installation size is not limited on-site, the cold box panels 3b, 3b' may be installed
on-site inside the cold box support frame on the sides B, B'.
[0027] Of course, some equipment components or attachments, such as pipes, cable shafts,
valves or observation facilities and supports, may be installed during factory prefabrication.
[0028] The present invention is applicable not only to rectangular parallelepiped cold boxes
but also to cylindrical cold boxes. The present invention is also not limited to be
applicable to plate-fin heat exchangers, but to all cases where leakage can be judged
by means of the surface of the cold box, or where the cold box support frame needs
to be protected.
[0029] The above embodiments are only preferred embodiments of the present invention, and
the scope of protection of the present invention is not limited to the embodiments.
All the technical solutions under the inventive concept are within the scope of protection
of the present invention. It should be noted that, to those of ordinary skill in the
art, several modifications and variations without departing from the principles of
the present invention should be considered to be within the scope of protection of
the present invention.
1. A cold box structure comprising a cold box support frame (2), four cold box panels
(3a, 3a', 3b, 3b'), a base (1) and a cold box top plate (4), a plate-fin heat exchanger
being placed inside the cold box support frame (2), and perlite sand being filled
between the cold box and the plate-fin heat exchanger, characterized in that the cold box panels (3b, 3b') facing seals of the plate-fin heat exchanger are located
inside the cold box support frame (2).
2. The cold box structure as claimed in to claim 1, characterized in that the cold box support frame and the cold box panels are made of carbon steel or stainless
steel.
3. The cold box structure as claimed in claim 1, characterized in that the cold box panels (3a, 3a') facing lateral plates of the plate-fin heat exchanger
are located outside the cold box support frame on sides (A, A').
4. The cold box structure as claimed in claim 1, characterized in that the cold box panels (3a, 3a') facing lateral plates of the plate-fin heat exchanger
are located inside the cold box support frame on sides (A, A').
5. An installation method applicable to the cold box structure of claim 1,
characterized by comprising the steps of:
1) fixing a cold box base (1), installing a cold box support frame (2), and installing
a plate-fin heat exchanger inside the cold box support frame (2);
2) installing four cold box panels (3a, 3a', 3b, 3b'), wherein the cold box panels
(3b, 3b') facing seals of the plate-fin heat exchanger are installed inside the cold
box support frame on sides (B, B'), and the cold box panels (3a, 3a') facing lateral
plates of the plate-fin heat exchanger are installed inside or outside the cold box
support frame on sides (A, A');
3) installing a cold box top plate (4) at the top of the cold box support frame (2);
and
4) welding the parts of the cold box in a sealed manner, filling the cold box with
perlite sand, and, if necessary, charging nitrogen.
6. The installation method as claimed in claim 5, characterized in that the cold box panels (3b, 3b') facing the seals of the plate-fin heat exchanger are
installed in advance inside the cold box support frame on the sides (B, B'), or are
installed on-site inside the cold box support frame on the sides (B, B').