Technical Field
[0001] The present invention relates to a heat exchanger evaluating device, a heat exchanger
evaluating method, a heat exchanger manufacturing method, and a heat exchanger designing
method.
Background Art
[0002] A known heat exchanger is provided with a plurality of multistage refrigerant flow
paths arranged independently in a vertical direction, and a refrigerant distributor
to which a first end side of each of the plurality of refrigerant flow paths is connected
via a capillary tube (refer to Patent Document 1, for example).
[0003] Patent Document 1 discloses a method of adjusting a height from a bottom edge of
a lowermost refrigerant flow path to a top edge of a lowermost capillary tube to prevent
a liquid refrigerant from accumulating in the lowermost refrigerant flow path and
causing an excessive increase in the degree of subcooling when the heat exchanger
functions as a condenser.
Citation List
Patent Document
Summary of Invention
Problem to be Solved by the Invention
[0005] In Patent Document 1, the connecting positions of the plurality of refrigerant flow
paths and the capillary tubes connected thereto are spaced apart at a constant interval
across an entire region of the overall height of the heat exchanger in the vertical
direction. As a result, a distance in the vertical direction between the connecting
position of the uppermost refrigerant flow path and the capillary tube, and the connecting
position of the lowermost refrigerant flow path and the capillary tube substantially
matches the overall height of the heat exchanger.
[0006] Thus, a large difference exists between the pressure of the liquid refrigerant from
the connecting position of the uppermost refrigerant flow path to the refrigerant
distributor caused by its own weight, and the pressure of the liquid refrigerant from
the connecting position of the lowermost refrigerant flow path to the refrigerant
distributor caused by its own weight. In consequence, the equalized pressure achieved
after the liquid refrigerants from the plurality of capillary tubes join together
in the refrigerant distributor increases, making it difficult for the liquid refrigerant
to discharge from the lowermost refrigerant flow path to the capillary tube and resulting
in problematic accumulation of liquid refrigerant in the interior of the refrigerant
flow path.
[0007] In light of the foregoing, an object of the present invention is to provide a heat
exchanger evaluating device, a heat exchanger evaluating method, a heat exchanger
manufacturing method, and a heat exchanger designing method capable of significantly
preventing a refrigerant from accumulating in a refrigerant flow path of a heat exchanger.
Solution to Problem
[0008] A first aspect of the present invention is a heat exchanger evaluating device for
a heat exchanger including a heat exchanging unit that causes a refrigerant to circulate
through a plurality of multistage refrigerant flow paths arranged in a vertical direction,
and performs heat exchange between the refrigerant and air, a refrigerant header that
allows the refrigerant in a gas phase to circulate therethrough and is connected to
a first end side of each of the plurality of refrigerant flow paths, a plurality of
refrigerant distribution tubes connected to respective second end sides of the plurality
of refrigerant flow paths, and a refrigerant distributor that joins the plurality
of refrigerant distribution tubes at a joining position. The heat exchanger evaluating
device is provided with a determination unit that determines, for each of the refrigerant
flow paths, whether the refrigerant has accumulated in the heat exchanging unit on
the basis of a relationship between a vertical height of the refrigerant flow path
at an outlet of the heat exchanging unit, a first pressure loss of the refrigerant
in the refrigerant flow path of the heat exchanging unit, a second pressure loss of
the refrigerant in the corresponding refrigerant distribution tube, and a vertical
height from a bottom edge of the heat exchanging unit to the vertically lowermost
refrigerant flow path.
[0009] According to the first aspect of the present invention, it is determined, for each
of the plurality of multistage refrigerant flow paths arranged in the vertical direction,
whether the refrigerant has accumulated in the heat exchanging unit on the basis of
a relationship between the vertical height of the refrigerant flow path at the outlet
of the heat exchanging unit, the first pressure loss of the refrigerant in the refrigerant
flow path of the heat exchanging unit that performs heat exchange between the air
and the refrigerant, the second pressure loss of the refrigerant in the refrigerant
distribution tube, and the vertical height from the bottom edge of the heat exchanging
unit to the vertically lowermost multistage refrigerant flow path.
[0010] Thus, whether the refrigerant has accumulated in the heat exchanging unit can be
simply determined using the information of each location through which the refrigerant
passes.
[0011] When the heat exchanging unit is made to function as a condenser and subcooled liquid
is determined to have accumulated in the heat exchanging unit, the accumulation in
the heat exchanging unit can be eliminated and a decrease in a condensing capacity
of the condenser can be prevented by adjusting the relationship between the height
of the refrigerant flow path of the heat exchanging unit, the pressure loss of the
refrigerant in the heat exchanging unit, the pressure loss of the refrigerant in the
refrigerant distribution tubes, and the height of the lowermost refrigerant flow path.
[0012] The determination unit of the heat exchanger evaluating device according to the first
aspect of the present invention may determine whether the refrigerant has accumulated
in the heat exchanging unit on the basis of an expression below, given hi as the vertical
height at the outlet of the heat exchanging unit, Pri as the first pressure loss,
Pci as the second pressure loss, h
bottom as the vertical height from the bottom edge of the heat exchanging unit to the vertically
lowermost refrigerant flow path, p as a refrigerant density, and g as a gravitational
acceleration.

[0013] This determination is simply made on the basis of the conditional expression.
[0014] A second aspect of the present invention is a heat exchanger evaluating method of
a heat exchanger including a heat exchanging unit that causes a refrigerant to circulate
through a plurality of multistage refrigerant flow paths arranged in a vertical direction,
and performs heat exchange between the refrigerant and air, a refrigerant header that
allows the refrigerant in a gas phase to circulate therethrough and is connected to
a first end side of each of the plurality of refrigerant flow paths, a plurality of
refrigerant distribution tubes connected to respective second end sides of the plurality
of refrigerant flow paths, and a refrigerant distributor that joins the plurality
of refrigerant distribution tubes at a joining position. The heat exchanger evaluating
method includes a first step of acquiring information on a vertical height of each
of the refrigerant flow paths at an outlet of the heat exchanging unit of the heat
exchanger to be evaluated, a first pressure loss of the refrigerant in the refrigerant
flow paths of the heat exchanging unit, and a second pressure loss of the refrigerant
in the refrigerant distribution tubes; and a second step of determining, for each
of the refrigerant flow paths, whether the refrigerant has accumulated in the heat
exchanging unit on the basis of a relationship between the vertical height of the
refrigerant flow path of the heat exchanging unit, the first pressure loss, the second
pressure loss, and a vertical height from a bottom edge of the heat exchanging unit
to the vertically lowermost refrigerant flow path.
[0015] The heat exchanger evaluating method may determine whether the refrigerant has accumulated
in the heat exchanging unit on the basis of an expression below, given hi as the vertical
height at the outlet of the heat exchanging unit, Pri as the first pressure loss,
Pci as the second pressure loss, h
bottom as the vertical height from the bottom edge of the heat exchanging unit to the vertically
lowermost refrigerant flow path, p as a refrigerant density, and g as a gravitational
acceleration.

[0016] A third aspect of the present invention is a heat exchanger manufacturing method
for a heat exchanger including a heat exchanging unit that causes a refrigerant to
circulate through a plurality of multistage refrigerant flow paths arranged in a vertical
direction, and performs heat exchange between the refrigerant and air, a refrigerant
header that allows the refrigerant in a gas phase to circulate therethrough and is
connected to a first end side of each of the plurality of refrigerant flow paths,
a plurality of refrigerant distribution tubes connected to respective second end sides
of the plurality of refrigerant flow paths, and a refrigerant distributor that joins
the plurality of refrigerant distribution tubes at a joining position. The heat exchanger
manufacturing method includes manufacturing the heat exchanger that satisfies an expression
below, given hi as a vertical height of the refrigerant flow path at an outlet of
the heat exchanging unit, Pri as a first pressure loss of the refrigerant in the refrigerant
flow paths of the heat exchanging unit, Pci as a second pressure loss of the refrigerant
in the refrigerant distribution tubes, h
bottom as a vertical height from a bottom edge of the heat exchanging unit to the vertically
lowermost refrigerant flow path, ρ as a refrigerant density, and g as a gravitational
acceleration.

[0017] A fourth aspect of the present invention is a heat exchanger designing method for
a heat exchanger including a heat exchanging unit that causes a refrigerant to circulate
through a plurality of multistage refrigerant flow paths arranged in a vertical direction,
and performs heat exchange between the refrigerant and air, a refrigerant header that
allows the refrigerant in a gas phase to circulate therethrough and is connected to
a first end side of each of the plurality of refrigerant flow paths, a plurality of
refrigerant distribution tubes connected to respective second end sides of the plurality
of refrigerant flow paths, and a refrigerant distributor that joins the plurality
of refrigerant distribution tubes at a joining position. The heat exchanger designing
method includes designing the heat exchanger that satisfies an expression below, given
hi as a vertical height of the refrigerant flow path at the outlet of the heat exchanging
unit, Pri as a first pressure loss of the refrigerant in the refrigerant flow paths
of the heat exchanging unit, Pci as a second pressure loss of the refrigerant in the
refrigerant distribution tubes, h
bottom as a vertical height from the bottom edge of the heat exchanging unit to the vertically
lowermost refrigerant flow path, ρ as a refrigerant density, and g as a gravitational
acceleration.

Advantageous Effects of Invention
[0018] The present invention achieves the effect of preventing a refrigerant from accumulating
in a refrigerant flow path of a heat exchanger to the extent possible.
Brief Description of Drawings
[0019]
FIG. 1 is a system configuration diagram of a heat exchanging system according to
the present invention.
FIG. 2 is a function block diagram of an evaluating device according to the present
invention.
FIG. 3 illustrates an example of a heat exchange model during use as a condenser in
a case where a distributer is below a bottom surface of a heat exchanger.
FIG. 4 illustrates an example of a heat exchange model during use as a condenser in
a case where the distributer is above the bottom surface of the heat exchanger.
Description of Embodiments
[0020] A heat exchanger evaluating device, a heat exchanger evaluating method, a heat exchanger
manufacturing method, and a heat exchanger designing method according to the present
invention is described below with reference to the drawings.
[0021] FIG. 1 illustrates a system configuration diagram of an evaluation system 3 of the
present embodiment. The evaluation system 3 includes a heat exchanging system 1 and
an evaluating device 30. While the evaluating device 30 according to the present embodiment
may be used to evaluate an outdoor heat exchanger (heat exchanger) 100 or an indoor
heat exchanger (heat exchanger) 200, the example described below is for evaluation
of the outdoor heat exchanger 100.
[0022] The heat exchanging system 1 is a system that connects the outdoor heat exchanger
100 and the indoor heat exchanger 200 by a refrigerant system to circulate the refrigerant.
[0023] Examples of the heat exchanging system 1 include an air conditioning system in which
one or a plurality of indoor heat exchangers are connected to a single outdoor heat
exchanger. Other examples of the heat exchanging system 1 include a heat pump type
hot water supply system that uses a CO2 refrigerant.
[0024] As illustrated in the system configuration diagram in FIG. 1, the heat exchanging
system 1 includes the outdoor heat exchanger 100, the indoor heat exchanger 200, a
compressor 210 that compresses a refrigerant, an accumulator 220 that removes liquid
components contained in a high-temperature, high-pressure refrigerant gas, a four-way
valve 230, and an expansion valve 240, with these being connected by refrigerant piping.
[0025] The heat exchanging system 1 illustrated in FIG. 1 allows selective execution of
a cooling operation that cools an indoor area and a heating operation that heats an
indoor area by switching a circulation direction of the refrigerant by the four-way
valve 230.
[0026] When the heating operation is performed, the four-way valve 230 sets the circulation
direction of the refrigerant so that the refrigerant compressed by the compressor
210 is introduced into the indoor heat exchanger 200, causing the indoor heat exchanger
200 to function as a condenser, and the refrigerant heat-blocked and expanded by the
expansion valve 240 is introduced into the outdoor heat exchanger 100, causing the
outdoor heat exchanger 100 to function as an evaporator (the direction indicated by
the solid arrows in FIG. 1).
[0027] On the other hand, when the cooling operation is performed, the four-way valve 230
sets the circulation direction of the refrigerant so that the refrigerant compressed
by the compressor 210 is introduced into the outdoor heat exchanger 100, causing the
outdoor heat exchanger 100 to function as a condenser, and the refrigerant heat-blocked
and expanded by the expansion valve 240 is introduced into the indoor heat exchanger
200, causing the indoor heat exchanger 200 to function as an evaporator (the direction
indicated by the dashed arrows in FIG. 1).
[0028] As illustrated in FIG. 2, the evaluating device 30 includes an acquiring unit 31
and a determination unit 32. FIG. 3 illustrates a refrigerant system of the outdoor
heat exchanger 100 as viewed from the side.
[0029] The acquiring unit 31 acquires information on vertical heights h
1, h
2, h
i, h
bottom of refrigerant flow paths 11, 12, 13, 14 at an outlet of the heat exchanging unit
10 of the heat exchanger (outdoor heat exchanger or indoor heat exchanger) to be evaluated
from a bottom edge of a heat exchanging unit 10, a first pressure loss of the refrigerant
in the refrigerant flow paths 11, 12, 13, 14 of the heat exchanging unit 10, and a
second pressure loss of the refrigerant in capillary tubes 21
c1, 21
c2, 21
c1 ... 21
cbottom.
[0030] The determination unit 32 determines, for each of the refrigerant flow paths 11,
12, 13, 14, whether refrigerant has accumulated in the heat exchanging unit 10 on
the basis of the relationship of the vertical heights of the refrigerant flow paths
11, 12, 13, 14 at the outlet of the heat exchanging unit 10 from the bottom edge of
the heat exchanging unit 10, the first pressure loss, the second pressure loss, and
a vertical height from the bottom edge of the heat exchanging unit 10 to the vertically
lowermost refrigerant flow path 14. Specifically, the determination unit 32 determines
whether refrigerant has accumulated in the heat exchanging unit on the basis of an
expression below, given Pri as the first pressure loss, Pci as the second pressure
loss, h
bottom as the vertical height from the bottom edge of the heat exchanging unit 10 to the
vertically lowermost refrigerant flow path 14, p as a refrigerant density, and g as
a gravitational acceleration.

[0031] The basis for use of the formula above is explained below.
[0032] When the Distributer is Below the Bottom Surface of the Heat Exchanging Unit:
As illustrated in FIG. 3, the outdoor heat exchanger 100 includes the heat exchanging
unit 10, the refrigerant distribution tubes 21, a refrigerant header 40, and a distributor
(refrigerant distributor) 50.
[0033] The heat exchanging unit 10 causes the refrigerant to circulate through the plurality
of refrigerant flow paths (circuits) 11, 12, 13, 14 arranged in a vertical direction,
and performs heat exchange with air blown by a blowing fan (not illustrated) provided
to the outdoor heat exchanger 100.
[0034] The refrigerant flow paths 11, 12, 13, 14 are tubular members formed by a metal member
made of copper for example, and flow paths that circulate the refrigerant are formed
in the interiors thereof.
[0035] The heat exchanging unit 10 can be, for example, configured as a fin and tube type
heat exchanger in which the plurality of refrigerant flow paths 11, 12, 13, 14 are
inserted through insertion holes in a plurality of fins (not illustrated) having plate-like
shapes, being made from aluminum, and being disposed consecutively in the horizontal
direction.
[0036] The refrigerant header 40 is piping that allows the refrigerant in a gas phase to
circulate therethrough and is connected to a first end side of each of the plurality
of refrigerant flow paths 11, 12, 13, 14 at a first connecting position C1.
[0037] When the outdoor heat exchanger 100 functions as a condenser, the refrigerant header
40 supplies the refrigerant in a gas phase to each of the plurality of refrigerant
flow paths 11, 12, 13, 14. On the other hand, when the outdoor heat exchanger 100
functions as an evaporator, the refrigerant in a gas phase is supplied from each of
the plurality of refrigerant flow paths 11, 12, 13, 14 to the refrigerant header 40.
[0038] The refrigerant distribution tubes 21 include capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom, each being connected to a second end side of the plurality of refrigerant flow paths
11, 12, 13, 14 at a second connecting position C2.
[0039] The distributor 50 is a device that joins the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom at a joining position C3. The joining position C3 is disposed below the bottom edge
of the heat exchanging unit 10 in a vertical direction (that is, up-down direction
in FIG. 3) orthogonal to a mounting surface of the outdoor heat exchanger 100.
[0040] When the outdoor heat exchanger 100 functions as a condenser, subcooled liquid discharged
from the second connecting positions C2 of the plurality of refrigerant flow paths
11, 12, 13, 14 is supplied to the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom, and guided to the joining position C3 of the distributor 50.
[0041] On the other hand, when the outdoor heat exchanger 100 functions as an evaporator,
subcooled liquid discharged from the joining position C3 of the distributor 50 is
guided to the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom, and supplied to the second connecting positions C2 of the plurality of refrigerant
flow paths 11, 12, 13, 14.
[0042] As illustrated in FIG. 3, the vertical heights of each of the refrigerant flow paths
11, 12, 13, 14 at the outlets of the heat exchanging unit 10 from the bottom surface
of the heat exchanging unit 10 in the vertical direction (up-down direction in FIG.
3) orthogonal to the mounting surface of the outdoor heat exchanger 100 are set as
heights h
1, h
2, h
i, h
bottom.
[0043] FIG. 3 illustrates an example of a heat exchange model when the heat exchanger is
used as a condenser. The up-down direction in FIG. 3 matches the vertical direction
given the mounting surface on which the outdoor heat exchanger 100 is mounted as a
reference.
[0044] In the present embodiment, the heat exchanger is used as a condenser and therefore
the refrigerant flows from left to right as viewed on the paper surface of FIG. 3.
The refrigerant passes through the refrigerant header 40 in a gas state, subsequently
passes through the heat exchanging unit 10 in a two-phase state, and lastly passes
through the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom in a liquid state, with the refrigerant from each of the refrigerant flow paths joining
at the joining position C3 of the distributor 50.
[0045] In FIG. 3, each subscript represents the number of refrigerant flow paths (circuits),
and "bottom" refers to the lowermost refrigerant flow path. Here, Pri denotes the
pressure loss (Pa) in each of the refrigerant flow paths, Pci denotes the pressure
loss (Pa) in each of the capillary tubes, h denotes the height (m) from the outlet
of each of the refrigerant flow paths to the bottom edge of the heat exchanging unit
10, h
D denotes the height (m) from the bottom edge of the heat exchanging unit 10 to the
bottom edge of the distributor 50, Pin denotes the inlet pressure (Pa), and Pout denotes
the outlet pressure (Pa).
[0046] In the refrigerant header 40, the refrigerant is in a gas state and therefore has
low density. As a result, a position head pressure ρgh is negligibly small compared
to the pressure loss Pri in the refrigerant flow paths 11, 12, 13, 14 and the pressure
loss Pci in the capillary tubes. Further, upon comparison with the refrigerant flow
paths 11, 12, 13, 14, the refrigerant header 40 has a shorter piping length and a
larger inner diameter than those of the refrigerant flow paths 11, 12, 13, 14, making
the pressure loss in the refrigerant header 40 also negligibly small. Thus, the inlet
pressures Pin of each of the refrigerant flow paths 11, 12, 13, 14 can be assumed
as equal.
[0047] Further, the outlet pressures Pout of each of the refrigerant flow paths 11, 12,
13, 14 are designed as equal, and therefore the outlet pressures Pout can also be
assumed as equal for the refrigerant flow paths 11, 12, 13, 14. Furthermore, as long
as heat is suitably exchanged in the heat exchanging unit 10, the refrigerant in the
capillary tubes 21
c1, 21
c2, 21
ci,..., 21
cbottom, is in a liquid state, and thus the refrigerant density ρ can be assumed as equal
in the refrigerant flow paths 11, 12, 13, 14.
[0048] From the above assumed conditions, the relationship between the inlet pressure Pin
and the outlet pressure Pout is expressed as Formula (2) below from Formula (1). Here,
ρ is the refrigerant density (kg/m
3), and g is gravitational acceleration (m/s
2).
[0049] [Expression 6]

[0050] Here, the relationship between the uppermost refrigerant flow path 11 and the lowermost
refrigerant flow path 14 will be examined. Because the outlet outputs Pout are equal
for each of the refrigerant flow paths, Formulas (1) and (2) above are equal. Thus,
Formula (3) below holds.
[Expression 7]

[0051] Here, the pressure loss is a function proportionate to the square of the refrigerant
flow path Gr (kg/h) as shown below. Note that λ is a friction coefficient, L is a
piping length (m), d is a piping inner diameter (m), A is a piping cross-sectional
area (m
2), ϕ
L is a two-phase multiplier coefficient, and x is a dryness.

[0052] Thus, the refrigerant flows to the lowermost refrigerant flow path 14 as long as
P
rbottom > 0, and to the lowermost capillary tube 21
cbottom as long as P
cbottom > 0. As a result, the conditional expression for the flow of refrigerant without
liquid accumulation in the lowermost refrigerant flow path 14 is Formula (4) below.
[Expression 9]

[0053] When Formula (3) is substituted into Formula (4) described above, Formula (5) below
is achieved.
[Expression 10]

[0054] From Formula (5) above, it is understood that a flow of refrigerant will exist in
the lowermost refrigerant flow path 14 and liquid accumulation will not occur as long
as the sum of the pressure loss of the uppermost refrigerant flow path 11 and the
pressure loss of the capillary tube 21
c1 is greater than a liquid head pressure differential of the uppermost refrigerant
flow path 11 and the lowermost refrigerant flow path 14. The relationships between
the second and subsequent refrigerant flow paths 12, 13 from the uppermost stage and
the lowermost refrigerant flow path 14 can also each be found using a similar procedure.
From this, it is understood that liquid accumulation will not occur in the lowermost
refrigerant flow path 14 as long as Formula (6) below (Formula (7) upon conversion)
is satisfied in all of the refrigerant flow paths 11, 12, 13.
[Expression 11]

[0055] When the Distributer is Above the Bottom Surface of the Heat Exchanging Unit:
[0056] FIG. 4 illustrates an example of a heat exchange model when the heat exchanger is
used as a condenser. Unlike FIG. 3, the distributor 50 is disposed in a position above
the bottom edge of the heat exchanging unit 10 in a vertical direction (that is, up-down
direction in FIG. 4) orthogonal to the mounting surface of the outdoor heat exchanger
100. In the following, descriptions of locations having the same configuration as
that in FIG. 3 will be omitted, and differences therebetween will be mainly described.
[0057] Here, the liquid head of the refrigerant at the capillary tube 21
cbottom of the lowermost refrigerant flow path 14 will be examined. In the lowermost refrigerant
flow path 14, the refrigerant moves upward and thus the liquid head works to decrease
pressure. While the refrigerant is positioned higher than a top edge of the distributor
50 at this time, the position decreases to the top edge of the distributor 50, causing
the pressure to eventually increase by h
D - h
bottom. Thus, the relationship between the inlet pressure Pin and the outlet pressure Pout
is expressed as follows.
[0058] [Expression 12]

[0059] Similar to the case where the distributor 50 is below the bottom edge of the heat
exchanging unit 10, the outlet pressure Pout are equal for each of the refrigerant
flow paths 11, 12, 13, 14, and thus Formulas (8) and (9) above are equal. As a result,
Formula (10) below holds.
[Expression 13]

[0060] Here, Formula (10) is equal to Formula (3) above. Accordingly, the exact same procedure
as the process for deriving Formula (6) is used. When Formula (10) is substituted
into Formula (4), the formula becomes Formula (11) below, and Formula (11) and Formula
(5) are exactly the same.
[Expression 14]

[0061] When the second and subsequent refrigerant flow paths 12, 13 from the uppermost stage
and the lowermost refrigerant flow path 14 are treated in the same manner, Formula
(12) is found, and Formulas (12) and (6) are the same. It is then understood that
liquid accumulation will not occur in the lowermost refrigerant flow path 14 as long
as Formula (12) (Formula (13) upon conversion) is satisfied in all of the refrigerant
flow paths 11, 12, 13.
[Expression 15]

[0062] Neither Formula (6) derived when the distributor 50 is assumed to be below the bottom
edge of the heat exchanging unit 10 nor Formula (12) derived when the distributor
50 is assumed to be above the bottom edge of the heat exchanging unit 10 includes
ho which represents the height from bottom edge of the heat exchanging unit 10 to
the top edge of the distributor 50.
[0063] This indicates that liquid accumulation is not related to the height position of
the distributor 50 when the heat exchanger is used as a condenser, and liquid accumulation
will not occur as long as the sum of the pressure loss of each of the refrigerant
flow paths 11, 12, 13, 14 and the pressure loss of each of the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom is greater than a liquid head pressure differential of each of the refrigerant flow
paths 11, 12, 13, 14 and the lowermost refrigerant flow path 14.
[0064] The action of the evaluating device 30 of an air-conditioning device according to
the present embodiment will be described below with reference to FIGS. 1 to 4.
[0065] A heat exchanger already manufactured serves as the evaluation target, and the information
acquired include the vertical height of the refrigerant flow paths 11, 12, 13, 14
at the outlets of the heat exchanging unit 10 of the heat exchanger to be evaluated,
from the bottom edge of the heat exchanging unit 10, as well as the first pressure
loss of the refrigerant in the refrigerant flow paths of the heat exchanging unit,
and the second pressure loss of the refrigerant in the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom.
[0066] Whether refrigerant has accumulated in the heat exchanging unit 10 is determined
in accordance with whether Formula (7) (Formula (13)) holds on the basis of the acquired
information.
[0067] When Formula (7) holds, it is determined that refrigerant has not accumulated in
the heat exchanging unit 10. When Formula (7) does not hold, it is determined that
refrigerant has accumulated in the heat exchanging unit 10.
[0068] When it has been determined that refrigerant has accumulated in the heat exchanging
unit 10, the value of each location may be adjusted so that Formula (7) holds. Examples
of ways for remedying accumulation include changing the path assembly method of the
refrigerant flow paths 11, 12, 13 of the heat exchanging unit 10 (that is, changing
the circuit lengths of the heat exchanging unit 10), and adjusting the lengths of
the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom.
[0069] As described above, according to the heat exchanger (outdoor heat exchanger 100 and
indoor heat exchanger 200) evaluating device, the heat exchanger evaluating method,
the heat exchanging manufacturing method, and the heat exchanger designing method
according to the present embodiment, whether refrigerant has accumulated in the heat
exchanging unit 10 is determined on the basis of the relationship between the vertical
heights h
1, h
2, h
i of the plurality of multistage refrigerant flow paths 11, 12, 13, arranged in the
vertical direction, at the outlets of the heat exchanging unit 10, the first pressure
loss of the refrigerant in the refrigerant flow paths 11, 12, 13, 14 in the heat exchanging
unit 10 that performs heat exchange between the air and the refrigerant, the second
pressure loss of the refrigerant in the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom, and the vertical height from the bottom edge of the heat exchanging unit 10 to the
vertically lowermost multistage refrigerant flow path 14.
[0070] Thus, whether refrigerant has accumulated in the heat exchanging unit 10 can be simply
determined using the information of each location through which the refrigerant passes.
[0071] Further, the outlet heights of the heat exchanging unit 10 for the refrigerant flow
paths 11, 12, 13 above the refrigerant flow path 14 can be simply determined on the
basis of the lowermost refrigerant flow path 14 using the expression for determining
refrigerant accumulation.
[0072] When the heat exchanger is made to function as a condenser and subcooled liquid is
determined to have accumulated in the heat exchanging unit 10, the accumulation in
the heat exchanging unit can be eliminated and a decrease in a condensing capacity
of the condenser can be prevented by adjusting the relationship between the heights
of the refrigerant flow paths 11, 12, 13 of the heat exchanging unit 10, the pressure
loss of the refrigerant in the heat exchanging unit 10, the pressure loss of the refrigerant
in the refrigerant distribution tubes (capillary tubes) 21, and the height h
cbottom of the lowermost refrigerant flow path 14.
[0073] While the evaluating device in the above embodiment has been described as a device
that evaluates whether refrigerant has accumulated in the heat exchanging unit 10
for a heat exchanger that has already been manufactured, the present invention is
not limited thereto. For example, the evaluating device may be used in the stage of
designing the heat exchanger.
[0074] Specifically, when the information on the height h
i of each of the refrigerant flow paths 11, 12, 13, 14, the first pressure loss in
the refrigerant flow paths 11, 12, 13, 14, the second pressure loss in the capillary
tubes 21
c1, 21
c2, 21
ci... 21
cbottom, and the height h
cbottom of the lowermost refrigerant flow path 14 from the heat exchanging unit 10 derived
in the design stage is substituted into Formula (7) above and Formula (7) holds, no
refrigerant accumulation is assumed, and the design process transitions to another
design process or the like. When Formula (7) above does not hold, refrigerant accumulation
is assumed to have occurred, and the accumulation can be remedied by returning to
the design procedure, adjusting the heights h
1, h
2, h
i, h
bottom of each of the refrigerant flow paths 11, 12, 13, 14 at the outlets of the heat exchanging
unit 10, adjusting the circuit lengths, and reselecting the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom.
[0075] Additionally, as another example, the evaluating device may be used in the stage
of manufacturing the heat exchanger.
[0076] Specifically, when the information on the height h
i of each of the refrigerant flow paths 11, 12, 13, 14, the first pressure loss in
each of the refrigerant flow paths 11, 12, 13, 14, the second pressure loss in the
capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom, and the height h
cbottom of the lowermost refrigerant flow path 14 from the heat exchanging unit 10 obtained
in the manufacturing stage is substituted into Formula (7) above and Formula (7) holds,
no refrigerant accumulation is assumed and the manufacturing process proceeds.
[0077] When Formula (7) above does not hold, it is determined that refrigerant accumulation
has occurred. The heat exchanger can then be manufactured so that Formula (7) above
holds by adjusting the heights h
1, h
2, h
i, h
bottom of each of the refrigerant flow paths 11, 12, 13, 14 at the outlets of the heat exchanging
unit 10, adjusting the circuit lengths, and reselecting the capillary tubes 21
c1, 21
c2, 21
ci... 21
cbottom.
[0078] The embodiment of the present invention has been described above in detail with
reference to the drawings, but the specific configurations are not limited to the
embodiment, and design changes and the like that do not depart from the scope of the
present invention are also included.
Reference Signs List
[0079]
1 Heat exchanging system
10 Heat exchanging unit
11, 12, 13, 14 Refrigerant flow path
21c1, 21c2, 21ci... 21cbottom Capillary tube
40 Refrigerant header
50 Distributor (refrigerant distributor)
100 Outdoor heat exchanger (heat exchanger)
200 Indoor heat exchanger (heat exchanger)