CROSS-REFERENCE TO RELATED APPLICATIONS
FIELD
[0002] This application relates to the field of air conditioning equipment, and more particularly
to a compressor assembly, an air conditioner outdoor unit, and an air conditioning
system.
BACKGROUND
[0003] With social development and technological progress, multi-unit heat pump air conditioning
systems have increasing capacity. However, with the increase in the capacity, the
multi-unit heat pump air conditioning systems also face problems such as insufficient
volume for gas separation and difficulty in recovering refrigeration oil, which limit
the development of the multi-unit heat pump air conditioning systems. In the related
art, parallel connection is adopted for gas separation to expand the capacity of the
air conditioning system, which solves the problem of insufficient gas separation volume,
but leads to poor reliability of compressor operation.
SUMMARY
[0004] The present invention aims to solve at least one of the technical problems existing
in the related art to a certain extent.
[0005] Accordingly, embodiments of the present invention propose a compressor assembly to
improve operational reliability of a compressor.
[0006] Embodiments of the present invention also propose an air conditioner outdoor unit
to improve operational reliability of the air conditioner outdoor unit.
[0007] Embodiments of the present invention also propose an air conditioning system to improve
operational reliability of the air conditioning system.
[0008] The compressor assembly according to embodiments of the present invention comprises:
a first compressor comprising a first exhaust port and a first gas return port; a
second compressor comprising a second exhaust port and a second gas return port; a
first oil separator comprising a first oil outlet and a first oil separator inlet,
the first oil separator inlet being communicated to the first exhaust port; a second
oil separator comprising a second oil outlet and a second oil separator inlet, the
second oil separator inlet being communicated to the second exhaust port; a first
gas-liquid separator comprising a first separation chamber, a first gas separator
inlet, a first oil return hole and a first gas separator outlet, wherein the first
gas separator inlet, the first oil return hole and the first gas separator outlet
are communicated to the first separation chamber, and wherein the first oil outlet
is communicated to the first gas separator inlet, and the first gas separator outlet
and the first oil return hole are each communicated to the first gas return port;
a second gas-liquid separator comprising a second separation chamber, a second gas
separator inlet, a second oil return hole and a second gas separator outlet, wherein
the second gas separator inlet, the second oil return hole and the second gas separator
outlet are communicated to the second separation chamber, and wherein the second oil
outlet is communicated to the second gas separator inlet, and the second gas separator
outlet and the second oil return hole are each communicated to the second gas return
port; and a liquid balance pipe and a gas balance pipe above the liquid balance pipe.
An end of the liquid balance pipe and an end of the gas balance pipe are both communicated
to the first separation chamber, while an other end of the liquid balance pipe and
an other end of the gas balance pipe are both communicated to the second separation
chamber.
[0009] The compressor assembly according to embodiments of the present invention has advantages
such as high operational reliability.
[0010] In some embodiments, the first gas-liquid separator comprises: a first cylinder,
the first separation chamber being defined in the first cylinder; and a first gas
outlet pipe, a portion of the first gas outlet pipe extending into the first separation
chamber, the first oil return hole being in the portion of the first gas outlet pipe,
and the first gas separator outlet being in an other portion of the first gas outlet
pipe. The second gas-liquid separator comprises: a second cylinder, the second separation
chamber being defined in the second cylinder; and a second gas outlet pipe, a portion
of the second gas outlet pipe extending into the second separation chamber, the second
oil return hole being in the portion of the second gas outlet pipe, and the second
gas separator outlet being in an other portion of the second gas outlet pipe. The
end of the liquid balance pipe is above the first oil return hole or at a same height
as the first oil return hole; and the other end of the liquid balance pipe is above
the second oil return hole or at a same height as the second oil return hole.
[0011] In some embodiments, the portion of the first gas outlet pipe comprises a third oil
return hole communicated to the first separation chamber, and the portion of the second
gas outlet pipe comprises a fourth oil return hole communicated to the second separation
chamber. The third oil return hole is above the first oil return hole or at a same
height as the first oil return hole; and the fourth oil return hole is above the second
oil return hole or at a same height as the second oil return hole.
[0012] In some embodiments, the end of the liquid balance pipe is between the first oil
return hole and the third oil return hole in an up-down direction, and the other end
of the liquid balance pipe is between the second oil return hole and the fourth oil
return hole in the up-down direction.
[0013] In some embodiments, the end of the gas balance pipe is above the third oil return
hole or at a same height as the third oil return hole, and the other end of the gas
balance pipe is above the fourth oil return hole or at a same height as the fourth
oil return hole.
[0014] In some embodiments, the third oil return hole is between the end of the gas balance
pipe and the end of the liquid balance pipe in an up-down direction; and the fourth
oil return hole is between the other end of the gas balance pipe and the other end
of the liquid balance pipe in the up-down direction.
[0015] In some embodiments, the first oil return hole and the second oil return hole are
at a same height; and/or a bottom wall surface of the first separation chamber and
a bottom wall surface of the second separation chamber are at a same height, the end
of the liquid balance pipe and the other end of the liquid balance pipe are at a same
height, and the end of the gas balance pipe and the other end of the gas balance pipe
are at a same height.
[0016] In some embodiments, the third oil return hole and the fourth oil return hole are
at a same height.
[0017] In some embodiments, the portion of the first gas outlet pipe and the portion of
the second gas outlet pipe each comprise a U-shaped portion. The U-shaped portion
comprises: a first segment and a second segment, the first segment and the second
segment extending in an up-down direction; and an intermediate segment, comprising
an end connected to a lower end of the first segment, and an other end connected to
a lower end of the second segment. The first oil return hole is in the intermediate
segment of the first gas outlet pipe; the third oil return hole is in the first segment
of the first gas outlet pipe; the second oil return hole is in the intermediate segment
of the second gas outlet pipe; and the fourth oil return hole is in the first segment
of the second gas outlet pipe.
[0018] The air conditioner outdoor unit according to embodiments of the present invention
comprises: a four-way valve, comprising a first interface, a second interface, a third
interface, and a fourth interface; an outdoor heat exchanger, a first port of the
outdoor heat exchanger being connected to the first interface; and the compressor
assembly according to any one of the above embodiments. The first oil separator comprises
a first oil separator outlet, and the second oil separator comprises a second oil
separator outlet; the first oil separator outlet and the second oil separator outlet
are each connected to the second interface; and the first gas separator inlet and
the second gas separator inlet are each connected to the fourth interface.
[0019] The air conditioner outdoor unit according to embodiments of the present invention
has advantages such as high operational reliability.
[0020] The air conditioning system according to embodiments of the present invention comprises:
the air conditioner outdoor unit according to any one of the above embodiments; and
an air conditioner indoor unit comprising an indoor heat exchanger. A second port
of the outdoor heat exchanger is connected to a first port of the indoor heat exchanger,
and a second port of the indoor heat exchanger is connected to the third interface.
[0021] The air conditioning system according to embodiments of the present invention has
advantages such as high operational reliability.
BRIEF DESCRIPTION OF DRAWINGS
[0022]
FIG. 1 is a schematic view of an air conditioner outdoor unit according to an embodiment
of the present invention.
FIG. 2 is an enlarged view of part A in FIG. 1.
FIG. 3 is a schematic view of an air conditioner outdoor unit according to another
embodiment of the present invention.
FIG. 4 is a schematic view of a first gas inlet pipe and a second gas inlet pipe according
to an embodiment of the present invention.
FIG. 5 is a schematic view of a first gas inlet pipe and a second gas inlet pipe according
to an embodiment of the present invention.
FIG. 6 is a schematic view of a first gas inlet pipe and a second gas inlet pipe according
to an embodiment of the present invention.
Reference numerals:
[0023]
air conditioner outdoor unit 100;
first compressor 1; first exhaust port 101; first gas return port 102;
second compressor 2; second exhaust port 201; second gas return port 202;
first oil separator 3; first oil separator inlet 301; first oil outlet 302; first
oil separator outlet 303;
second oil separator 4; second oil separator inlet 401; second oil outlet 402; second
oil separator outlet 403;
first gas-liquid separator 5; first cylinder 501; first separation chamber 5011; first
gas outlet pipe 502; first gas separator outlet 5021; first oil return hole 5022;
third oil return hole 5023; first gas inlet pipe 503; first gas separator inlet 5031;
second gas-liquid separator 6; second cylinder 601; second separation chamber 6011;
second gas outlet pipe 602; second gas separator outlet 6021; second oil return hole
6022; fourth oil return hole 6023; second gas inlet pipe 603; second gas separator
inlet 6031;
liquid balance pipe 7; first end 701; second end 702; first pipe segment 703; second
pipe segment 704; third pipe segment 705;
gas balance pipe 8; third end 801; fourth end 802;
four-way valve 9; first interface 901; second interface 902; third interface 903;
fourth interface 904;
outdoor heat exchanger 10; first port 1001; second port 1002;
first pipe 11; second pipe 12; third pipe 13; fourth pipe 14; fifth pipe 15; sixth
pipe 16; seventh pipe 17; eighth pipe 18; ninth pipe 19; tenth pipe 20; eleventh pipe
21; twelfth pipe 22; thirteenth pipe 23.
DETAILED DESCRIPTION
[0024] Embodiments of the present invention will be described in detail below, and examples
of the embodiments will be shown in the accompanying drawings. The embodiments described
below are exemplary and are intended to explain the present invention rather than
limit the present invention.
[0025] A compressor assembly according to embodiments of the present invention will be described
below with reference to the accompanying drawings.
[0026] As shown in FIGS. 1 to 3, the compressor assembly according to embodiments of the
present invention comprise a first compressor 1, a second compressor 2, a first oil
separator 3, a second oil separator 4, a first gas-liquid separator 5, a second gas-liquid
separator 6, a liquid balance pipe 7, and a gas balance pipe 8.
[0027] The first compressor 1 has a first exhaust port 101 and a first gas return port 102.
The second compressor 2 has a second exhaust port 201 and a second gas return port
202. The first oil separator 3 has a first oil outlet 302 and a first oil separator
inlet 301 that is communicated to the first exhaust port 101. The second oil separator
4 has a second oil outlet 402 and a second oil separator inlet 401 that is communicated
to the second exhaust port 201.
[0028] The first gas-liquid separator 5 has a first separation chamber 5011 and comprises
a first gas separator inlet 5031, a first oil return hole 5022 and a first gas separator
outlet 5021, all of which are communicated to the first separation chamber 5011. The
second gas-liquid separator 6 has a second separation chamber 6011 and comprises a
second gas separator inlet 6031, a second oil return hole 6022 and a second gas separator
outlet 6021, all of which are communicated to the second separation chamber 6011.
The first oil outlet 302 is communicated to the first gas separator inlet 5031, and
the second oil outlet 402 is communicated to the second gas separator inlet 6031.
The first gas separator outlet 5021 and the first oil return hole 5022 are each communicated
to the first gas return port 102. The second gas separator outlet 6021 and the second
oil return hole 6022 are each communicated to the second gas return port 202.
[0029] The gas balance pipe 8 is above the liquid balance pipe 7. It can be understood by
those skilled in the art that the gas balance pipe 8 being above the liquid balance
pipe 7 means that when the first gas-liquid separator 5 and the second gas-liquid
separator 6 are in use, the gas balance pipe 8 is above the liquid balance pipe 7.
[0030] One end of the liquid balance pipe 7 and one end of the gas balance pipe 8 are both
communicated to the first separation chamber 5011, while the other end of the liquid
balance pipe 7 and the other end of the gas balance pipe 8 are both communicated to
the second separation chamber 6011. For example, as shown in FIGS. 1 to 3, the liquid
balance pipe 7 has a first end 701 and a second end 702 opposite to each other in
its length direction; the gas balance pipe 8 has a third end 801 and a fourth end
802 opposite to each other in its length direction; the first end 701 and the third
end 801 are each communicated to the first separation chamber 5011; and the second
end 702 and the fourth end 802 are each communicated to the second separation chamber
6011.
[0031] Consequently, the use of the liquid balance pipe 7 and the gas balance pipe 8 can
achieve connection between the first separation chamber 5011 and the second separation
chamber 6011, thereby achieving liquid balance and gas balance between the first separation
chamber 5011 and the second separation chamber 6011.
[0032] During operation of the compressor assembly according to embodiments of the present
invention, refrigerant vapor containing refrigeration oil (first oil-containing refrigerant
vapor) flowing out of the first exhaust port 101 of the first compressor 1 enters
the first oil separator 3 through the first oil separator inlet 301, and the first
oil-containing refrigerant vapor is separated into first refrigerant vapor and first
refrigeration oil in the first oil separator 3. The first refrigeration oil enters
the first separation chamber 5011 of the first gas-liquid separator 5 through the
first oil outlet 302 and the first gas separator inlet 5031, and the first refrigerant
vapor enters an indoor heat exchanger for heat exchange. Meanwhile, refrigerant vapor
containing refrigeration oil (second oil-containing refrigerant vapor) flowing out
of the second exhaust port 201 of the second compressor 2 enters the second oil separator
4 through the second oil separator inlet 401, and the second oil-containing refrigerant
vapor is separated into second refrigerant vapor and second refrigeration oil in the
second oil separator 4. The second refrigeration oil enters the second separation
chamber 6011 of the second gas-liquid separator 6 through the second oil outlet 402
and the second gas separator inlet 6031, and the second refrigerant vapor enters the
indoor heat exchanger for heat exchange.
[0033] In addition, a part of the refrigerant (a third refrigerant), which flows out of
the indoor heat exchanger and needs to return to the first compressor 1 and the second
compressor 2, enters the first separation chamber 5011 of the first gas-liquid separator
5 through the first gas separator inlet 5031; and another part of the refrigerant
(a fourth refrigerant), which flows out of the indoor heat exchanger and needs to
return to the first compressor 1 and the second compressor 2, enters the second separation
chamber 6011 of the second gas-liquid separator 6 through the second gas separator
inlet 6031.
[0034] Next, in a suction process of the first compressor 1 (the third refrigerant and the
fourth refrigerant), the refrigeration oil in the first separation chamber 5011 can
return, along with the refrigerant vapor, to the first compressor 1 through the first
oil return hole 5022, the first gas separator outlet 5021 and the first gas return
port 102; in a suction process of the second compressor 2 (the third refrigerant and
the fourth refrigerant), the refrigeration oil in the second separation chamber 6011
can return, along with the refrigerant vapor, to the second compressor 2 through the
second oil return hole 6022, the second gas separator outlet 6021 and the second gas
return port 202. Thus, recovery of refrigeration oil in the first compressor 1 and
the second compressor 2 can be realized.
[0035] For the compressor assembly that returns oil through the gas-liquid separator, there
is a relationship between the return oil volume of the compressor and the suction
volume of the compressor - the return oil volume of the compressor increases with
an increase in the suction volume of the compressor, while the return oil volume of
the compressor decreases with a decrease in the suction volume of the compressor.
Accordingly, when compressors with different capacities are used in a common system,
if a deviation among suction volumes of compressors with different capacities is too
large (exceeding a design deviation), a deviation in the amount of refrigeration oil
returned to the compressor along with refrigerant vapor during the suction process
of the compressor will also be large, cause some compressors (usually small-capacity
compressors) to suffer from insufficient return oil or inability to return oil.
[0036] In the related art, parallel connection is adopted for gas separation to expand the
capacity of the air conditioning system, which solves the problem of insufficient
gas separation volume, but cannot solve the problem concerning refrigeration oil recovery,
and there is a significant risk of delay or inability of oil return, resulting in
poor reliability of compressor operation.
[0037] For the compressor assembly according to embodiments of the present invention, since
the first separation chamber 5011 of the first gas-liquid separator 5 and the second
separation chamber 6011 of the second gas-liquid separator 6 are connected through
the liquid balance pipe 7 and the gas balance pipe 8, it can be ensured that the first
separation chamber 5011 of the first gas-liquid separator 5 and the second separation
chamber 6011 of the second gas-liquid separator 6 both have refrigeration oil and
refrigerant therein, which can reduce or even avoid a large refrigerant distribution
deviation (i.e., there is a large amount of refrigerant at the gas separator inlet
of the gas-liquid separator corresponding to the large capacity compressor, while
there is very little refrigerant at the gas separator inlet of the gas-liquid separator
corresponding to the small capacity compressor) at the first gas separator inlet 5031
of the first gas-liquid separator 5 and the second gas separator inlet 6031 of the
second gas-liquid separator 6 caused by different capacities of the first compressor
1 and the second compressor 2. Furthermore, the problem of insufficient return oil
or even inability to return oil for small capacity compressors due to the different
capacities of the first compressor 1 and the second compressor 2 can be relieved or
even avoided, thereby preventing compressor wear for lack of lubrication caused by
untimely oil return or inability to return oil, and greatly improving the reliability
of the compressor assembly.
[0038] Therefore, the compressor assembly according to embodiments of the present invention
has advantages such as high reliability.
[0039] In addition, each compressor according to embodiments of the present invention has
its corresponding oil separator and gas-liquid separator, allowing each compressor
to form a relatively independent refrigeration oil circulation system.
[0040] In some embodiments of the present invention, as shown in FIGS. 1 and 2, the compressor
assembly comprises a first pipe 11, a second pipe 12, a third pipe 13, a fourth pipe
14, a fifth pipe 15, and a sixth pipe 16. The first exhaust port 101 is connected
to the first oil separator inlet 301 through the first pipe 11, and the second exhaust
port 201 is connected to the second oil separator inlet 401 through the second pipe
12. The first oil outlet 302 is communicated to the first gas separator inlet 5031
through the fifth pipe 15, and the second oil outlet 402 is communicated to the second
gas separator inlet 6031 through the sixth pipe 16. The first gas separator outlet
5021 is connected to the first return gas outlet 102 through the third pipe 13, and
the second gas separator outlet 6021 is connected to the second return gas outlet
202 through the fourth pipe 14.
[0041] In some embodiments, as shown in FIGS. 1 to 3, the first gas-liquid separator 5 comprises
a first cylinder 501 and a first gas outlet pipe 502. The first separation chamber
5011 is defined in first cylinder 501, and a part of the first gas outlet pipe 502
extends into the first separation chamber 5011. The first oil return hole 5022 is
in the part of the first gas outlet pipe 502, and the first gas separator outlet 5021
is in another part of the first gas outlet pipe 502.
[0042] For example, the first gas outlet pipe 502 comprises a first portion and a second
portion, the first portion extends into the first separation chamber 5011, and the
second portion is outside the first separation chamber 5011. The first oil return
hole 5022 is in the first portion of the first gas outlet pipe 502, and the first
gas separator outlet 5021 is in the second portion of the first gas outlet pipe 502.
[0043] The second gas-liquid separator 6 comprises a second cylinder 601 and a second gas
outlet pipe 602. The second separation chamber 6011 is defined in the second cylinder
601, and a part of the second gas outlet pipe 602 extends into the second separation
chamber 6011. The second oil return hole 6022 is in the part of the second gas outlet
pipe 602, and the second gas separator outlet 6021 is in another part of the second
gas outlet pipe 602.
[0044] For example, the second gas outlet pipe 602 comprises a first portion and a second
portion, the first portion extends into the second separation chamber 6011, and the
second portion is outside the second separation chamber 6011. The second oil return
hole 6022 is in the first portion of the second gas outlet pipe 602, and the second
gas separator outlet 6021 is in the second portion of the second gas outlet pipe 602.
[0045] One end of the liquid balance pipe 7 is above the first oil return hole 5022 or at
a same height as the first oil return hole 5022; the other end of the liquid balance
pipe 7 is above the second oil return hole 6022 or at a same height as the second
oil return hole 6022.
[0046] It can be understood by those skilled in the art that when the first gas-liquid separator
5 and the second gas-liquid separator 6 are in use, one end of the liquid balance
pipe 7 is above the first oil return hole 5022 or at the same height as the first
oil return hole 5022, and the other end of the liquid balance pipe 7 is above the
second oil return hole 6022 or at the same height as the second oil return hole 6022.
[0047] For example, as shown in FIGS. 1 and 2, a bottom wall surface of the first separation
chamber 5011 and a bottom wall surface of the second separation chamber 6011 are at
the same height. A distance between the first end 701 (e) of the liquid balance pipe
7 and the bottom wall surface of the first separation chamber 5011 is denoted as L1;
a distance between the first oil return hole 5022 (a) and the bottom wall surface
of the first separation chamber 5011 is denoted as L2; a distance between the second
end 702 (f) of the liquid balance pipe 7 and the bottom wall surface of the second
separation chamber 6011 is denoted as L3; and a distance between the second oil return
hole 6022 (c) and the bottom wall surface of the second separation chamber 6011 is
L4, in which L1 ≥ L2 and L3 ≥ L4.
[0048] Therefore, the refrigeration oil in the first separation chamber 5011 can enter the
second separation chamber 6011 through the liquid balance pipe 7 only when a liquid
level of the refrigeration oil in the first separation chamber 5011 is not lower than
the first oil return hole 5022; the refrigeration oil in the second separation chamber
6011 can enter the first separation chamber 5011 through the liquid balance pipe 7
only when a liquid level of the refrigeration oil in the second separation chamber
6011 is not lower than the second oil return hole 6022. Hence, the refrigeration oil
in the first separation chamber 5011 first return to the first compressor 1, and only
on the premise that the first compressor 1 has returned oil, the refrigeration oil
in the first separation chamber 5011 can enter the second separation chamber 6011
to provide refrigeration oil for the second compressor 2; and the refrigeration oil
in the second separation chamber 6011 first return to the second compressor 2, and
only on the premise that the second compressor 2 has returned oil, the refrigeration
oil in the second separation chamber 6011 can enter the first separation chamber 5011
to provide refrigeration oil for the first compressor 1. In such a way, the reliability
of the compressor assembly can be further enhanced.
[0049] In some embodiments of the present invention, the first gas-liquid separator 5 comprises
a first gas inlet pipe 503, and a part of the first gas inlet pipe 503 extends into
the first separation chamber 5011, the first gas separator inlet 5031 being in the
part of the first gas inlet pipe 503. The second gas-liquid separator 6 comprises
a second gas inlet pipe 603 that extends into the second separation chamber 6011.
A part of the second gas inlet pipe 603 extends into the second separation chamber
6011, and the second gas separator inlet 6031 is in the part of the second gas inlet
pipe 603.
[0050] The first gas inlet pipe 503 and the first oil outlet 302 are connected through the
fifth pipe 15, and the second gas inlet pipe 603 and the second oil outlet 402 are
connected through the sixth pipe 16.
[0051] In some embodiments of the present invention, one end of the liquid balance pipe
7 extends into an interior of the first cylinder 501, so that one end of the liquid
balance pipe 7 is communicated to the first separation chamber 5011; the other end
of the liquid balance pipe 7 extends into an interior of the second cylinder 601,
so that the other end of the liquid balance pipe 7 is communicated to the second separation
chamber 6011.
[0052] For example, as shown in FIGS. 1 to 3, the first end 701 of the liquid balance pipe
7 extends into the interior of the first cylinder 501, and the second end 702 of the
liquid balance pipe 7 extends into the interior of the second cylinder 601.
[0053] In some embodiments, the first oil return hole 5022 and the second oil return hole
6022 are at the same height.
[0054] For example, when the bottom wall surface of the first separation chamber 5011 and
the bottom wall surface of the second separation chamber 6011 are at the same height,
L2=L4.
[0055] Consequently, the problem of large refrigerant distribution deviation caused by the
different capacities of the first compressor 1 and the second compressor 2 can be
relieved or even avoided, which is conducive to further improving the reliability
of the compressor assembly.
[0056] In some embodiments of the present invention, each of the liquid balance pipe 7 and
the gas balance pipe 8 is a straight pipe.
[0057] For example, as shown in FIGS. 1 and 2, the liquid balance pipe 7 is a straight pipe,
a connection port between the liquid balance pipe 7 and the first gas-liquid separator
5 is denoted as e, and a connection port between the liquid balance pipe 7 and the
second gas-liquid separator 6 is denoted as f, in which e and f are at the same height.
The first end 701 of the liquid balance pipe 7 and the second end 702 of the liquid
balance pipe 7 are both at the same height as the connection port e (the connection
port f).
[0058] In some embodiments of the present invention, at least one of the liquid balance
pipe 7 and the gas balance pipe 8 is a bent pipe.
[0059] For example, as shown in FIG. 3, the liquid balance pipe 7 comprises a first pipe
segment 703, a second pipe segment 704, and a third pipe segment 705. The second pipe
segment 704 is horizontally arranged, and the first and third pipe segments 703 and
705 are both obliquely arranged. One end of the second pipe segment 704 is connected
to a lower end of the first pipe segment 703, and the other end of the second pipe
segment 704 is connected to a lower end of the third pipe segment 705.
[0060] The two ends of the second pipe segment 704 are connected to the first gas-liquid
separator 5 and the second gas-liquid separator 6, respectively. A connection port
between the second pipe segment 704 and the first gas-liquid separator 5 is denoted
as e2; and a connection port between the second pipe segment 704 and the second gas-liquid
separator 6 is denoted as f2. The first pipe segment 703 extends into the first separation
chamber 5011, and the third pipe segment 705 extends into the second separation chamber
6011. An end e1 of the first pipe segment 703 away from the second pipe segment 704
is the first end 701 of the liquid balance pipe 7, and an end f1 of the third pipe
segment 705 away from the second pipe segment 704 is the second end 702 of the liquid
balance pipe 7. In such a case, the connection port e2 and the end e1 are at different
heights, and the connection port f2 and the end f1 are at different heights.
[0061] In some embodiments, a part of the first gas outlet pipe 502 has a third oil return
hole 5023 communicated to the first separation chamber 5011, and a part of the second
gas outlet pipe 602 has a fourth oil return hole 6023 communicated to the second separation
chamber 6011. The third oil return hole 5023 is above the first oil return hole 5022,
or the third oil return hole 5023 and the first oil return hole 5022 are at a same
height. The fourth oil return hole 6023 is above the second oil return hole 6022,
or the fourth oil return hole 6023 and the second oil return hole 6022 are at a same
height.
[0062] For example, as shown in FIGS. 1 to 3, when the bottom wall surface of the first
separation chamber 5011 and the bottom wall surface of the second separation chamber
6011 are at the same height, a distance between the third oil return hole 5023 (b)
and the bottom wall surface of the first separation chamber 5011 is L5, and a distance
between the fourth oil return hole 6023 (d) and the bottom wall surface of the second
separation chamber 6011 is L6, in which L5 ≥ L2 and L6 ≥ L4.
[0063] As a result, when the first compressor 1 fails to return oil in time through the
first oil return hole 5022 or when oil cannot return through the first oil return
hole 5022 for some reason, the first compressor 1 can achieve oil return through the
third oil return hole 5023; and when the second compressor 2 fails to return oil in
time through the second oil return hole 6022 or when oil cannot return through the
second oil return hole 6022 for some reason, the second compressor 2 can achieve oil
return through the fourth oil return hole 6023. It is possible to further prevent
the compressor from being worn out for lack of lubrication due to untimely oil return
or inability to return oil, thereby further improving the reliability of the compressor
assembly.
[0064] In some embodiments, one end of the liquid balance pipe 7 is between the first oil
return hole 5022 and the third oil return hole 5023 in an up-down direction, and the
other end of the liquid balance pipe 7 is between the second oil return hole 6022
and the fourth oil return hole 6023 in the up-down direction.
[0065] For example, as shown in FIGS. 1 to 3, when the bottom wall surface of the first
separation chamber 5011 and the bottom wall surface of the second separation chamber
6011 are at the same height, L5 ≥ L1 ≥ L2, and L6 ≥ L3 ≥ L4.
[0066] Hence, it is beneficial to further improving the reliability of the compressor assembly.
[0067] In some embodiments, the third oil return hole 5023 and the fourth oil return hole
6023 are at the same height.
[0068] For example, when the bottom wall surface of the first separation chamber 5011 and
the bottom wall surface of the second separation chamber 6011 are at the same height,
L5=L6.
[0069] Hence, it is possible to further relieve or even avoid the problem of the large refrigerant
distribution deviation caused by the different capacities of the first compressor
1 and the second compressor 2, which is conducive to further improving the reliability
of the compressor assembly.
[0070] In some embodiments, one end of the gas balance pipe 8 is above the third oil return
hole 5023 or at the same height as the third oil return hole 5023, while the other
end of the gas balance pipe 8 is above the fourth oil return hole 6023 or at the same
height as the fourth oil return hole 6023.
[0071] For example, as shown in FIGS. 1 to 3, when the bottom wall surface of the first
separation chamber 5011 and the bottom wall surface of the second separation chamber
6011 are at the same height, a distance between one end (g) of the gas balance pipe
8 and the bottom wall surface of the first separation chamber 5011 is L7, in which
L7 ≥ L5, and a distance between the other end (h) of the gas balance pipe 8 and the
bottom wall surface of the second separation chamber 6011 is L8, in which L8 ≥ L6.
[0072] Therefore, the compressor assembly according to embodiments of the present invention
can better utilize the gas balance pipe 8 to achieve gas balance in the first separation
chamber 5011 and the second separation chamber 6011 and utilize the liquid balance
pipe 7 to achieve liquid balance in the first separation chamber 5011 and the second
separation chamber 6011, which will be conducive to further improving the reliability
of the compressor assembly.
[0073] In some embodiments, the third oil return hole 5023 is between one end of the gas
balance pipe 8 and one end of the liquid balance pipe 7 in the up-down direction,
while the fourth oil return hole 6023 is between the other end of the gas balance
pipe 8 and the other end of the liquid balance pipe 7 in the up-down direction.
[0074] For example, when the bottom wall surface of the first separation chamber 5011 and
the bottom wall surface of the second separation chamber 6011 are at the same height,
L7>L5>L1 and L8>L6>L3.
[0075] Thus, the reliability of the compressor assembly can be further enhanced.
[0076] In some embodiments, the bottom wall surface of the first separation chamber 5011
and the bottom wall surface of the second separation chamber 6011 are at the same
height. One end of the liquid balance pipe 7 is at the same height as the other end
of the liquid balance pipe 7, that is, the liquid balance pipe 7 is arranged horizontally.
One end of the gas balance pipe 8 is at the same height as the other end of the gas
balance pipe 8, that is, the gas balance pipe 8 is arranged horizontally.
[0077] Therefore, when the compressor assembly is mounted, it is only necessary to position
the bottom wall surface of the first separation chamber 5011 and the bottom wall surface
of the second separation chamber 6011 at the same installation height, which facilitates
the installation of the compressor assembly.
[0078] In some embodiments, a part of the first gas outlet pipe 502 and a part of the second
gas outlet pipe 602 each comprise a U-shaped portion.
[0079] The U-shaped portion comprises a first segment, a second segment and an intermediate
segment. The first segment and the second segment both extend in the up-down direction.
One end of the intermediate segment is connected to a lower end of the first segment,
and the other end of the intermediate segment is connected to a lower end of the second
segment.
[0080] The first oil return hole 5022 is in the intermediate segment of the first gas outlet
pipe 502; the third oil return hole 5023 is in the first segment of the first gas
outlet pipe 502; the second oil return hole 6022 is in the intermediate segment of
the second gas outlet pipe 602; and the fourth oil return hole 6023 is in the first
segment of the second gas outlet pipe 602.
[0081] In the present invention, the first segment of the U-shaped portion of the first
gas outlet pipe 502 may be located between the intermediate segment of the U-shaped
portion of the first gas outlet pipe 502 and the first gas separator outlet 5021,
and the second segment of the U-shaped portion of the first gas outlet pipe 502 is
opposite to the first segment of the U-shaped portion of the first gas outlet pipe
502, and vice versa. Similarly, the first segment of the U-shaped portion of the second
gas outlet pipe 602 may be located between the intermediate segment of the U-shaped
portion of the second gas outlet pipe 602 and the first gas separator outlet 6021,
and the second segment of the U-shaped portion of the second gas outlet pipe 602 is
opposite to the first segment of the U-shaped portion of the second gas outlet pipe
602, and vice versa.
[0082] For ease of description, the following situation will serve as an example. The first
segment of the U-shaped portion of the first gas outlet pipe 502 is between the intermediate
segment of the U-shaped portion of the first gas outlet pipe and the first gas separator
outlet 5021, and the second segment of the U-shaped portion of the first gas outlet
pipe 502 is opposite to the first segment of the U-shaped portion of the first gas
outlet pipe 502. The first segment of the U-shaped portion of the second gas outlet
pipe 602 is between the intermediate segment of the U-shaped portion of the second
gas outlet pipe and the second gas separator outlet 6021, and the second segment of
the U-shaped portion of the second gas outlet pipe 602 is opposite to the first segment
of the U-shaped portion of the second gas outlet pipe 602.
[0083] In some embodiments, the third oil return hole 5023 is on the first segment of the
first gas outlet pipe 502, and the fourth oil return hole 6023 is on the first segment
of the second gas outlet pipe 602, as shown in FIG. 4.
[0084] In some embodiments, the third oil return hole 5023 is on the second segment of the
first gas outlet pipe 502, and the fourth oil return hole 6023 is on the second segment
of the second gas outlet pipe 602, as shown in FIG. 2.
[0085] In some embodiments, the third oil return hole 5023 is on the first segment of the
first gas outlet pipe 502, and the fourth oil return hole 6023 is on the second segment
of the second gas outlet pipe 602, as shown in FIG. 5;
[0086] In some embodiments, the third oil return hole 5023 is on the second segment of the
first gas outlet pipe 502, and the fourth oil return hole 6023 is on the first segment
of the second gas outlet pipe 602, as shown in FIG. 6.
[0087] An air conditioner outdoor unit 100 according to embodiments of the present invention
will be described below with reference to the accompanying drawings.
[0088] As shown in FIGS. 1 to 3, the air conditioner outdoor unit 100 according to embodiments
of the present invention comprises a four-way valve 9, an outdoor heat exchanger 10,
and a compressor assembly.
[0089] The four-way valve 9 comprises a first interface 901, a second interface 902, a third
interface 903, and a fourth interface 904. A first port 1001 of the outdoor heat exchanger
10 is connected to the first interface 901.
[0090] The compressor assembly is the compressor assembly described in any of the above
embodiments. The first oil separator 3 has a first oil separator outlet 303, and the
second oil separator 4 has a second oil separator outlet 403. The first oil separator
outlet 303 and the second oil separator outlet 403 are each connected to the second
interface 902. The first gas separator inlet 5031 and the second gas separator inlet
6031 are each connected to the fourth interface 904.
[0091] Therefore, the air conditioner outdoor unit 100 according to embodiments of the present
invention has advantages such as high operational reliability.
[0092] In some embodiments of the present invention, the air conditioner outdoor unit 100
comprises a seventh pipe 17, an eighth pipe 18, a ninth pipe 19, a tenth pipe 20,
and an eleventh pipe 21. The first gas inlet pipe 503 and the second gas inlet pipe
603 are each connected to the fourth interface 904 through the seventh pipe 17. One
end of the eighth pipe 18 is connected to the first oil separator outlet 303; one
end of the ninth pipe 19 is connected to the second oil separator outlet 403; and
the other end of the eighth pipe 18 and the other end of the ninth pipe 19 are each
connected to the second interface 902 through the tenth pipe 20. The first port 1001
of the outdoor heat exchanger 10 is connected to the first port 901 through the eleventh
pipe 21.
[0093] An air conditioning system according to embodiments of the present invention will
be described below with reference to the accompanying drawings.
[0094] The air conditioning system according to embodiments of the present invention comprises
an air conditioner outdoor unit and an air conditioner indoor unit. The air conditioner
outdoor unit is the air conditioner outdoor unit 100 described in any of the above
embodiments. The air conditioner indoor unit comprises an indoor heat exchanger. A
second port 1002 of the outdoor heat exchanger 10 is connected to a first port of
the indoor heat exchanger, and a second port of the indoor heat exchanger is connected
to the third interface 903.
[0095] Therefore, the air conditioning system according to embodiments of the present invention
has advantages such as high operational reliability.
[0096] In some embodiments of the present invention, the air conditioning system comprises
a twelfth pipe 22 and a thirteenth pipe 23. The second port 1002 of the outdoor heat
exchanger 10 is connected to the first port of the indoor heat exchanger through the
twelfth pipe 22, and the second port of the indoor heat exchanger is connected to
the third interface 903 through the thirteenth pipe 23.
[0097] In the description of the present invention, it is to be understood that terms such
as "central," "longitudinal," "transverse," "length," "width," "thickness," "upper,"
"lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom,"
"inner," "outer," "clockwise," "counterclockwise," "axial," "radial" and "circumferential"
should be construed to refer to the orientation as then described or as shown in the
drawings under discussion. These relative terms are for convenience and simplicity
of description and do not indicate or imply that the devices or elements referred
to have a particular orientation and be constructed or operated in a particular orientation.
Thus, these terms shall not be construed as limitation on the present invention.
[0098] In addition, terms such as "first" and "second" are used herein for purposes of description
and are not intended to indicate or imply relative importance or significance or to
imply the number of indicated technical features. Thus, the feature defined with "first"
and "second" may comprise one or more of this feature. In the description of the present
invention, the term "a plurality of" means at least two, such as two or three, unless
specified otherwise.
[0099] In the present invention, unless specified or limited otherwise, the terms "mounted,"
"connected," "coupled," "fixed" and the like are used broadly, and may be, for example,
fixed connections, detachable connections, or integral connections; may also be mechanical
or electrical connections; may also be direct connections or indirect connections
via intervening structures; may also be inner connection or interaction of two elements,
which can be understood by those skilled in the art according to specific situations.
[0100] In the present invention, unless specified or limited otherwise, a structure in which
a first feature is "on" or "below" a second feature may comprise an embodiment in
which the first feature is in direct contact with the second feature, and may also
comprise an embodiment in which the first feature and the second feature are not in
direct contact with each other, but are contacted via an additional feature formed
therebetween. Further, a first feature "on," "above," or "on top of" a second feature
may comprise an embodiment in which the first feature is right or obliquely "on,"
"above," or "on top of" the second feature, or just means that the first feature is
at a height higher than that of the second feature; while a first feature "below,"
"under," or "on bottom of" a second feature may comprise an embodiment in which the
first feature is right or obliquely "below," "under," or "on bottom of" the second
feature, or just means that the first feature is at a height lower than that of the
second feature.
[0101] Reference throughout this specification to "an embodiment," "some embodiments," "an
example," "a specific example," or "some examples," means that a particular feature,
structure, material, or characteristic described connected to the embodiment or example
is comprised in at least one embodiment or example of the present invention. Thus,
the above terms throughout this specification are not necessarily referring to the
same embodiment or example of the present invention. Further, the particular features,
structures, materials, or characteristics may be combined in any suitable manner in
one or more embodiments or examples. Moreover, those skilled in the art can integrate
and combine the different embodiments or examples and the features of the different
embodiments or examples described in this specification without contradicting each
other.
[0102] Although embodiments of the present invention have been shown and described, it can
be appreciated by those skilled in the art that the above embodiments are merely exemplary
and are not intended to limit the present invention, and various changes, modifications,
alternatives and variations may be made to the embodiments within the scope of the
present invention.
1. A compressor assembly, comprising:
a first compressor comprising a first exhaust port and a first gas return port;
a second compressor comprising a second exhaust port and a second gas return port;
a first oil separator comprising a first oil outlet and a first oil separator inlet,
the first oil separator inlet being communicated to the first exhaust port;
a second oil separator comprising a second oil outlet and a second oil separator inlet,
the second oil separator inlet being communicated to the second exhaust port;
a first gas-liquid separator comprising a first separation chamber, a first gas separator
inlet, a first oil return hole and a first gas separator outlet, wherein the first
gas separator inlet, the first oil return hole and the first gas separator outlet
are communicated to the first separation chamber, and wherein the first oil outlet
is communicated to the first gas separator inlet, and the first gas separator outlet
and the first oil return hole are each communicated to the first gas return port;
a second gas-liquid separator comprising a second separation chamber, a second gas
separator inlet, a second oil return hole and a second gas separator outlet, wherein
the second gas separator inlet, the second oil return hole and the second gas separator
outlet are communicated to the second separation chamber, and wherein the second oil
outlet is communicated to the second gas separator inlet, and the second gas separator
outlet and the second oil return hole are each communicated to the second gas return
port; and
a liquid balance pipe and a gas balance pipe located above the liquid balance pipe,
wherein an end of the liquid balance pipe and an end of the gas balance pipe are both
communicated to the first separation chamber, while an other end of the liquid balance
pipe and an other end of the gas balance pipe are both communicated to the second
separation chamber.
2. The compressor assembly according to claim 1, wherein:
the first gas-liquid separator comprises:
a first cylinder, the first separation chamber being defined in the first cylinder;
and
a first gas outlet pipe, a portion of the first gas outlet pipe extending into the
first separation chamber, the first oil return hole being in the portion of the first
gas outlet pipe, and the first gas separator outlet being in an other portion of the
first gas outlet pipe,
the second gas-liquid separator comprises:
a second cylinder, the second separation chamber being defined in the second cylinder;
and
a second gas outlet pipe, a portion of the second gas outlet pipe extending into the
second separation chamber, the second oil return hole being in the portion of the
second gas outlet pipe, and the second gas separator outlet being in an other portion
of the second gas outlet pipe.
wherein the end of the liquid balance pipe is above the first oil return hole or at
a same height as the first oil return hole; and the other end of the liquid balance
pipe is above the second oil return hole or at a same height as the second oil return
hole.
3. The compressor assembly according to claim 2, wherein the portion of the first gas
outlet pipe comprises a third oil return hole communicated to the first separation
chamber, and the portion of the second gas outlet pipe comprises a fourth oil return
hole communicated to the second separation chamber,
wherein the third oil return hole is above the first oil return hole or at the same
height as the first oil return hole; and the fourth oil return hole is above the second
oil return hole or at the same height as the second oil return hole.
4. The compressor assembly according to claim 3, wherein the end of the liquid balance
pipe is between the first oil return hole and the third oil return hole in an up-down
direction, and the other end of the liquid balance pipe is between the second oil
return hole and the fourth oil return hole in the up-down direction.
5. The compressor assembly according to claim 3 or 4, wherein the end of the gas balance
pipe is above the third oil return hole or at a same height as the third oil return
hole, and the other end of the gas balance pipe is above the fourth oil return hole
or at a same height as the fourth oil return hole.
6. The compressor assembly according to any one of claims 3 to 5, wherein the third oil
return hole is between the end of the gas balance pipe and the end of the liquid balance
pipe in the up-down direction; and the fourth oil return hole is between the other
end of the gas balance pipe and the other end of the liquid balance pipe in the up-down
direction.
7. The compressor assembly according to any one of claims 1 to 6, wherein the first oil
return hole and the second oil return hole are at a same height; and/or
a bottom wall surface of the first separation chamber and a bottom wall surface of
the second separation chamber are at a same height, the end of the liquid balance
pipe and the other end of the liquid balance pipe are at a same height, and the end
of the gas balance pipe and the other end of the gas balance pipe are at a same height.
8. The compressor assembly according to any one of claims 3 to 7, wherein the third oil
return hole and the fourth oil return hole are at a same height.
9. The compressor assembly according to any one of claims 3 to 7, wherein the portion
of the first gas outlet pipe and the portion of the second gas outlet pipe each comprise
a U-shaped portion, wherein the U-shaped portion comprises:
a first segment and a second segment, the first segment and the second segment extending
in the up-down direction; and
an intermediate segment, comprising an end connected to a lower end of the first segment,
and an other end connected to a lower end of the second segment,
wherein the first oil return hole is in the intermediate segment of the first gas
outlet pipe; the third oil return hole is in the first segment of the first gas outlet
pipe; the second oil return hole is in the intermediate segment of the second gas
outlet pipe; and the fourth oil return hole is in the first segment of the second
gas outlet pipe.
10. The compressor assembly according to claim 9, wherein the first segment of the U-shaped
portion of the first gas outlet pipe is between the intermediate segment of the U-shaped
portion of the first gas outlet pipe and the first gas separator outlet; and
the first segment of the U-shaped portion of the second gas outlet pipe is between
the intermediate segment of the U-shaped portion of the second gas outlet pipe and
the second gas separator outlet.
11. An air conditioner outdoor unit, comprising:
a four-way valve, comprising a first interface, a second interface, a third interface,
and a fourth interface;
an outdoor heat exchanger, a first port of the outdoor heat exchanger being connected
to the first interface; and
a compressor assembly according to any one of claims 1 to 10,
wherein a first oil separator comprises a first oil separator outlet, and a second
oil separator comprises a second oil separator outlet; the first oil separator outlet
and the second oil separator outlet are each connected to the second interface; and
a first gas separator inlet and a second gas separator inlet are each connected to
the fourth interface.
12. An air conditioning system, comprising:
an air conditioner outdoor unit according to claim 11; and
an air conditioner indoor unit comprising an indoor heat exchanger,
wherein a second port of an outdoor heat exchanger is connected to a first port of
the indoor heat exchanger, and a second port of the indoor heat exchanger is connected
to a third interface.