Patent Description:
As the requirements of scientific research and production for low temperature are becoming higher, the lowest evaporating temperature obtained by the double-stage compression refrigeration device employing medium-temperature refrigerant is also limited by a series of problems caused by too low evaporation pressure. For example, when the pressure difference between the evaporator pressure and the outside pressure increases, the possibility that the air infiltrates into the system increases, which will affect the normal operation of the system. The suction specific volume is large, and the gas actually sucked into the cylinder is reduced, which causes an increase of the size of the cylinder. Therefore, when a low evaporation temperature is required, a low-temperature refrigerant should be used. However, the condensation temperature of the low-temperature refrigerant is required to be lower, and the refrigerant cannot be condensed into liquid by ordinary water cooling and air cooling. A kind of artificial cold source is required to condense the low-temperature refrigerant, accordingly, a cascaded refrigeration cycle adopting two kinds of refrigerants occurs. However, multiple compressors are employed to realize the cascaded refrigeration cycle in the existing technology, which causes a problem of an increase of the cost of implementing a cascade refrigeration cycle in the existing technology.

<CIT>) discloses an air-conditioning system according to the preamble of claim <NUM>, and comprises a compressor adapted to prevent refrigerant combustion. The compressor comprises a high temperature side compressor of a binary refrigerating cycle device.

The main objective of the present invention is to provide an air-conditioning system and an air conditioner having the same, so as to solve a problem of a high cost of manufacturing the air-conditioning system in the prior art.

In order to achieve the above objective, according to one aspect of the present invention, an air-conditioning system is provided as set out in claim <NUM> below.

Further, the air-conditioning system further includes a condenser; the condenser is arranged in the first pipeline; an inlet of the condenser is in communication with the discharge port of the first cylinder; an outlet of the condenser is in communication with a first inlet of the evaporative condenser; and a first outlet of the evaporative condenser is in communication with the inlet of the first liquid separator.

Further, the air-conditioning system further includes a first throttle valve; the first throttle valve is arranged in the first pipeline and located between the evaporative condenser and the condenser.

Further, the air-conditioning system further includes an evaporator; the evaporator is arranged in the second pipeline; an inlet of the evaporator is in communication with a second outlet of the evaporative condenser; and an outlet of the evaporator is in communication with the inlet of the second liquid separator.

Further, the air-conditioning system further includes a second throttle valve; the second throttle valve is arranged in the second pipeline and is located between the evaporative condenser and the evaporator.

Further, a height ratio of the second cylinder to the first cylinder is T3, wherein <NUM>≤T3≤ <NUM>. Further, an effective volume ratio of the first liquid separator to the second liquid separator is T4, wherein <NUM>≤T4≤<NUM>.

According to another aspect of the present invention, the present invention provides an air conditioner including the air-conditioning system above.

In the technical solution of the air-conditioning system of the present disclosure, the first pipeline and the second pipeline are provided independently; the first pipeline and the second pipeline are respectively in communication with the same one compressor; and a first liquid separator and a second liquid separator are arranged in the first pipeline respectively. The air-conditioning system can realize a cascade refrigeration cycle. Since only one compressor is employed in the system, the cost of manufacturing the air-conditioning system is effectively saved.

The accompanying drawings attached to the specification form a part of the disclosure and are intended to provide a further understanding of the present disclosure. The illustrative embodiments of the present disclosure and the description thereof are used for explanations of the present disclosure, but not intended to limit the present disclosure improperly. In the accompanying drawings:.

Wherein, the drawings include following reference signs:.

It should be noted that the embodiments in the present disclosure and the features in the embodiments can be combined with each other if no conflicts occur. The disclosure will be described in detail below with reference to the accompanying drawings in combination with the embodiments.

It should be noted that terms used herein are only for the purpose of describing specific embodiments and not intended to limit the exemplary embodiments of the disclosure. The singular of a term used herein is intended to include the plural of the term unless the context otherwise specifies. In addition, it should also be appreciated that when terms "include" and/or "comprise" are used in the description, they indicate the presence of features, steps, operations, devices, components and/or their combination.

It should be noted that the terms "first", "second", and the like in the description, claims and drawings of the present disclosure are used to distinguish similar objects, and are not necessarily used to describe a specific order or sequence. It should be appreciated that such terms can be interchangeable if appropriate, so that the embodiments of the disclosure described herein can be implemented, for example, in an order other than those illustrated or described herein. In addition, the terms "comprise", "have" and any variations thereof, are intended to cover a non-exclusive inclusion, for example, a process, a method, a system, a product, or a device that includes a series of steps or units, which is not necessarily limited to those steps or units explicitly listed, but can include other steps or units that are not explicitly listed or inherent to such a process, a method, a product or a device.

For convenience of description, spatially relative terms such as "above", "over", "on a surface of", "upper", etc., may be used herein to describe the spatial position relationships between one device or feature and other devices or features as shown in the drawings. It should be appreciated that the spatially relative term is intended to include different directions during using or operating the device other than the directions described in the drawings. For example, if the device in the drawings is inverted, the device is described as the device "above other devices or structures" or "on other devices or structures" will be positioned "below other devices or structures" or "under other devices or structures". Thus, the exemplary term "above" can include both "above" and "under". The device can also be positioned in other different ways (rotating <NUM> degrees or at other orientations), and the corresponding description of the space used herein is interpreted accordingly.

Now, the exemplary embodiments of the disclosure will be further described in detail with reference to the accompanying drawings. However, these exemplary embodiments can be implemented in many different forms and should not be construed as only limited to the embodiments described herein. It should be appreciated that the embodiments are provided to make the present disclosure disclosed thoroughly and completely, and to fully convey the concepts of the exemplary embodiments to those skilled in the art. In the accompanying drawings, for the sake of clarity, the thicknesses of layers and regions may be enlarged, and a same reference sign is used to indicate a same device, thus the description thereof will be omitted.

With reference to <FIG>, according to an embodiment of the present invention, an air-conditioning system is provided.

As shown in <FIG>, the air-conditioning system includes a compressor <NUM>, a first pipeline <NUM>, a second pipeline <NUM>, an evaporative condenser <NUM>, a first liquid separator <NUM> and a second liquid separator <NUM>. The first pipeline <NUM> is in communication with the compressor <NUM>, and the second pipeline <NUM> is in communication with the same compressor <NUM>. The first pipeline <NUM> and the second pipeline <NUM> are arranged independently, and the evaporative condenser <NUM> is provided in the first pipeline <NUM> and the second pipeline <NUM>. The refrigerant in the first pipeline <NUM> and the refrigerant in the second pipeline <NUM> can perform heat exchange with the evaporative condenser <NUM> respectively. The first liquid separator <NUM> is arranged in the first pipeline <NUM>, and an outlet of the first liquid separator <NUM> is in communication with the compressor <NUM>. The second liquid separator <NUM> is arranged in the second pipeline <NUM>, and an outlet of the second liquid separator <NUM> is in communication with the compressor <NUM>. The first liquid separator <NUM> is disposed adjacent to the second liquid separator <NUM>.

In this embodiment of the air-conditioning system, the first pipeline and the second pipeline are provided independently; the first pipeline and the second pipeline are respectively in communication with the same one compressor; and the first liquid separator and the second liquid separator are arranged in the first pipeline respectively. The air-conditioning system can realize a cascade refrigeration cycle. Since only one compressor is employed in the system, the cost of manufacturing the air-conditioning system is effectively saved.

The compressor <NUM> includes multiple cylinders, and the multiple cylinders work independently. Such an arrangement enables the air-conditioning system to be adaptive for compressing different refrigerants, thereby improving practicability and reliability of the compressor.

Specifically, the multiple cylinders include a first cylinder <NUM>. An outlet of the first liquid separator <NUM> is in communication with a suction port of the first cylinder <NUM>. The first end of the first pipeline <NUM> is in communication with the discharge port of the first cylinder <NUM>, and the second end of the first pipeline <NUM> is in communication with the inlet of the first liquid separator <NUM>. Such an arrangement enables the first pipeline <NUM>, the first cylinder <NUM> and the first liquid separator <NUM> to form a complete circulation loop, thereby effectively improving the reliability and the stability of the pipeline system.

The air-conditioning system further includes a condenser <NUM> and a first throttle valve <NUM>. The condenser <NUM> is arranged in the first pipeline <NUM>. The inlet of the condenser <NUM> is in communication with the discharge port of the first cylinder <NUM>. The outlet of the condenser <NUM> is in communication with the first inlet of the evaporative condenser <NUM>, and the first outlet of the evaporative condenser <NUM> is in communication with the inlet of the first liquid separator <NUM>. The first throttle valve <NUM> is arranged in the first pipeline <NUM> and located between the evaporative condenser <NUM> and the condenser <NUM>. Such an arrangement can effectively improve the reliability of the air-conditioning system.

Further, the multiple cylinders further include a second cylinder <NUM>. The outlet of the second liquid separator <NUM> is in communication with the suction port of the second cylinder <NUM>, the first end of the second pipeline <NUM> is in communication with the discharge port of the second cylinder <NUM>; and the second end of the second pipeline <NUM> is in communication with the inlet of the second liquid separator <NUM>. Such an arrangement enables the second pipeline <NUM>, the second cylinder <NUM> and the second liquid separator <NUM> to form an enclosed circulation loop, and makes the circulation loop formed by the second pipeline <NUM> and the circulation loop formed by the first pipeline <NUM> independent of each other, thereby improving the practicality and the reliability of the air-conditioning system.

Further, the air-conditioning system further includes an evaporator <NUM> and a second throttle valve <NUM>. The evaporator <NUM> is arranged in the second pipeline <NUM>. The inlet of the evaporator <NUM> is in communication with the second outlet of the evaporative condenser <NUM>. The outlet of the evaporator <NUM> is in communication with the inlet of the second liquid separator <NUM>. The second throttle valve <NUM> is arranged in the second pipeline <NUM> and is located between the evaporative condenser <NUM> and the evaporator <NUM>. According to the invention, the volume ratio of the second cylinder <NUM> to the first cylinder <NUM> is T1, where <NUM> ≤ T1 ≤ <NUM>. The diameter ratio of the suction port of the second cylinder <NUM> and the suction port of the first cylinder <NUM> is T2, where <NUM> ≤ T2 ≤ <NUM>.

Preferably, the height ratio of the second cylinder <NUM> to the first cylinder <NUM> is T3, where <NUM> ≤ T3 ≤ <NUM>. The effective volume ratio of the first liquid separator <NUM> to the second liquid separator <NUM> is T4, where <NUM> ≤ T4 ≤ <NUM>. Such an arrangement can effectively improve the performance the air-conditioning system.

The air-conditioning system of the above embodiment can also be applied in the field of air conditioner technology, that is, an air conditioner is provided. The air conditioner includes an air-conditioning system, and the air-conditioning system is one of the air-conditioning systems disclosed in the foregoing embodiments. The air-conditioning system includes a compressor <NUM>, a first pipeline <NUM>, a second pipeline <NUM>, an evaporative condenser <NUM>, a first liquid separator <NUM> and a second liquid separator <NUM>. The first pipeline <NUM> is in communication with compressor <NUM>, and the second pipeline <NUM> is in communication with the same compressor <NUM>. The first pipeline <NUM> and the second pipeline <NUM> are arranged independently, and the evaporative condenser <NUM> is provided in the first pipeline <NUM> and in the second pipeline <NUM>. The refrigerant in the first pipeline <NUM> and the refrigerant in the second pipeline <NUM> can perform heat exchange with the evaporative condenser <NUM> respectively. The first liquid separator <NUM> is arranged in the first pipeline <NUM>, and the outlet of the first liquid separator <NUM> is in communication with the compressor <NUM>. The second liquid separator <NUM> is disposed in the second pipeline <NUM>, and the outlet of the second liquid separator <NUM> is in communication with the compressor <NUM>. The first liquid separator <NUM> is disposed adjacent to the second liquid separator <NUM>.

According to this embodiment, in the air-conditioning system, the first pipeline and the second pipeline are provided independently; the first pipeline and the second pipeline are respectively in communication with the same one compressor; and the first liquid separator and the second liquid separator are arranged in the first pipeline respectively. The air-conditioning system can realize a cascade refrigeration cycle. Since only one compressor is employed in the system, the cost of manufacturing the air-conditioning system is effectively saved.

Specifically, the cascaded refrigeration cycle generally includes two or three independent refrigeration circulations, which are referred to as a high temperature portion and a low temperature portion respectively. Each of these independent refrigeration circulations is a complete single-stage or two-stage compression refrigeration system, and the two portions are related by the same one evaporative condenser. Conventionally the independent systems of the two portions respectively use two compressors, which results in a complicated structure of the whole system. In this disclosure, a compressor with one unit and double refrigerants is provided. The upper cylinder and the lower cylinder of the compressor can participate in two refrigeration circulations respectively, and function as two compressors. In this embodiment, the second cylinder is disposed above the first cylinder.

The upper cylinder and the lower cylinder of the twin cylinder compressor independently complete the compression processes of the two refrigeration circulations respectively, and the compressor with one unit and double refrigerants simplifies the cascaded circulation system. In order to prevent the sucked gas from carrying liquid, the two cylinders need to be connected to the liquid separator component separately. The first cylinder is a high-temperature refrigerant cylinder. After flowing through the first liquid separator and entering the first cylinder, the high-temperature refrigerant is compressed, and then discharged into an intermediate cavity of the upper flange, and finally discharged out of the high-temperature refrigerant discharge pipe <NUM>. The second cylinder is a low-temperature refrigerant cylinder. After flowing through the first liquid separator and entering the second cylinder, the low-temperature refrigerant is compressed, and then discharged into the housing of the compressor directly through the lower flange, and finally discharged out of the low-temperature refrigerant discharge pipe <NUM>. The discharge temperature of the low-temperature refrigerant is lower, which takes an effect on lowering the temperature of the motor.

The volume ratio of the second cylinder to the first cylinder ranges from <NUM> to <NUM>. In order to prevent the volumetric efficiency being affected by too large suction ports, the high ratio of the second cylinder to the first cylinder ranges from <NUM> to <NUM>. It can be further determined that the diameter ratio of the suction port of the second cylinder to the suction port of the first cylinder ranges from <NUM> to <NUM>. Such an arrangement can further improve the reliability of the sealing inside the pump body.

When operating in the system with double refrigerants, the evaporative condenser acts as an evaporator of the high-temperature refrigerant; after flowing through the first liquid separator and entering the high-temperature refrigerant cylinder, the high-temperature refrigerant at a low-temperature and low-pressure state is compressed and discharged into the inner cavity of the lower flange, then is discharged from the high-temperature discharge pipe into the condenser and then the throttle valve, and finally flows back to the evaporative condenser, thereby completing a circulation cycle of the high-temperature refrigerant. After the high-temperature refrigerant circulates for a period of time, the low-temperature refrigerant begins to circulate. After the low-temperature refrigerant from the evaporator flows through the second liquid separator and enters the low-temperature refrigerant cylinder, the refrigerant is compressed and discharged from the discharge port of the upper flange into the inner cavity of the compressor. The effective volume ratio of the first liquid separator to the second liquid separator ranges from <NUM> to <NUM>. The discharge temperature of the low-temperature refrigerant is lower, which takes an effect on lowering the temperature of the compressor motor. The low-temperature refrigerant flows through the low-temperature refrigerant discharge pipe and enters the evaporative condenser, then enter the throttle valve, and finally flows back to the evaporator, thereby completing a circulation cycle of the low-temperature refrigerant.

A second liquid separator is provided independently at the suction inlet of the low-temperature refrigerant cylinder. The inner cavity of the lower flange is used as a high-temperature refrigerant discharge cavity. A high-temperature refrigerant discharge port is independently disposed in the lower flange and is in communication with the high-temperature refrigerant discharge pipe. The sealing distances between the parts inside the pump body are ensured to be sufficient, and the first cylinder and the second cylinder can be independently compressed. <FIG> is a top view of the compressor with one unit and double refrigerants. As far as the appearance is concerned, the compressor is provided with two liquid separators with different specifications corresponding to the high-temperature refrigerant discharge pipe and the low-temperature refrigerant discharge pipe. The low-temperature refrigerant is discharged into the housing of the compressor first, which takes an effect on lowering the temperature of the compressor motor.

<FIG> is a principle diagram of the system using the compressor with one unit and double refrigerants. Compared with the traditional cascaded refrigeration system, two independent refrigeration circulations are related through the evaporative condenser, and also through the compressor with double refrigerants; the evaporative condenser acts as an evaporator of the high-temperature refrigerant; after flowing through the first liquid separator and entering the high-temperature refrigerant cylinder, the high-temperature refrigerant at the low-temperature and low-pressure state is compressed and discharged into the inner cavity of the lower flange, then is discharged from the high-temperature discharge pipe into the condenser and the throttle valve, and finally flows back to the evaporative condenser, thereby completing a circulation cycle of the high-temperature refrigerant. After the high-temperature refrigerant circulates for a period of time, the low-temperature refrigerant begins to circulate. After the low-temperature refrigerant from the evaporator flows through the second liquid separator and enters the low-temperature refrigerant cylinder, the refrigerant is compressed, and discharged from the discharge port of the upper flange into the inner cavity of the compressor. The discharge temperature of the low-temperature refrigerant is lower, which takes an effect on lowering the temperature of the compressor motor. The low-temperature refrigerant flows through the low-temperature refrigerant discharge pipe, and enters the evaporative condenser and the throttle valve, and finally flows back to the evaporator, thereby completing a circulation cycle of the low-temperature refrigerant.

In addition to the above description, it also should be noted that "one embodiment", "another embodiment", "an embodiment" and the like in the description refer to that a specific feature, a structure or a characteristic described in combination with the embodiment is included in at least one embodiment generally described in the present disclosure. The same expression in various locations in the specification does not necessarily refer to the same embodiment. Furthermore, when a specific feature, a structure, or a characteristic is described in combination with any embodiments, what is claimed is that other embodiments which are combined to implement such a feature, a structure, or a characteristic are also included in the scope of the present disclosure.

Claim 1:
An air-conditioning system, wherein the air-conditioning system comprises:
a compressor (<NUM>), a first pipeline (<NUM>), a second pipeline (<NUM>), an evaporative condenser (<NUM>), a first liquid separator (<NUM>), and a second liquid separator (<NUM>); wherein,
the first pipeline (<NUM>) is in communication with the compressor (<NUM>);
the second pipeline (<NUM>) is in communication with a same compressor (<NUM>), and the first pipeline (<NUM>) and the second pipeline (<NUM>) are arranged independently;
the evaporative condenser (<NUM>) is provided in the first pipeline (<NUM>) and the second pipeline (<NUM>), and refrigerant in the first pipeline (<NUM>) and refrigerant in the second pipeline (<NUM>) perform heat exchange with the evaporative condenser (<NUM>) respectively;
the first liquid separator (<NUM>) is arranged in the first pipeline (<NUM>), and an outlet of the first liquid separator (<NUM>) is in communication with the compressor (<NUM>);
the second liquid separator (<NUM>) is arranged in the second pipeline (<NUM>), and an outlet of the second liquid separator (<NUM>) is in communication with the compressor (<NUM>); the first liquid separator (<NUM>) is disposed adjacent to the second liquid separator (<NUM>);
the compressor (<NUM>) comprises multiple cylinders, and the multiple cylinders are configured to work independently;
the multiple cylinders comprise a first cylinder (<NUM>); the outlet of the first liquid separator (<NUM>) is in communication with a suction port of the first cylinder (<NUM>); a first end of the first pipeline (<NUM>) is in communication with a discharge port of the first cylinder (<NUM>); and a second end of the first pipeline (<NUM>) is in communication with an inlet of the first liquid separator (<NUM>);
the multiple cylinders further comprise a second cylinder (<NUM>); the outlet of the second liquid separator (<NUM>) is in communication with a suction port of the second cylinder (<NUM>); a first end of the second pipeline (<NUM>) is in communication with a discharge port of the second cylinder (<NUM>); a second end of the second pipeline (<NUM>) is in communication with an inlet of the second liquid separator (<NUM>);
characterized in that: a volume ratio of the second cylinder (<NUM>) to the first cylinder (<NUM>) is T1, wherein <NUM>≤T1≤<NUM>; and
a diameter ratio of the suction port of the second cylinder (<NUM>) and the suction port of the first cylinder (<NUM>) is T2, wherein <NUM>≤T2≤<NUM>.