CN113803914B - Air supply device for static pressure air suspension compressor and air conditioner - Google Patents

Abstract

The application relates to the technical field of intelligent household appliances, and discloses an air supply device for a static pressure air suspension compressor, which comprises: the air supply tank comprises a liquid inlet and an air outlet, the liquid inlet is communicated with the refrigerant liquid supply assembly through a refrigerant branch, and the air outlet is connected with an air supply port of an air suspension bearing of the static air suspension compressor and is configured to convey gaseous refrigerant to the air suspension bearing; and the electromagnetic heating module is arranged in the air supply tank and is configured to generate heat in a controlled manner so as to heat the refrigerant in the air supply tank. Through setting up the air feed tank at the input of compressor gas suspension bearing to utilize electromagnetic heating module to heat the refrigerant in the air feed tank, make air feed pressure promote, and form stable air feed pressure difference, provide good condition for static pressure gas suspension compressor gas suspension bearing's steady operation, effectively improved heating efficiency, guaranteed that the whole operation of device is reliable and stable. The application also discloses an air conditioner.

Description

Air supply device for static pressure air suspension compressor and air conditioner

Technical Field

The application relates to the technical field of compressors, in particular to an air supply device for a static pressure air suspension compressor and an air conditioner.

Background

The air suspension compressor is realized by the working principle of air bearing suspension and by utilizing an air film formed by air extrusion to achieve the supporting and lubricating functions and the improvement of the air pressure of the centrifugal compressor through the high-speed rotation of an impeller and the diffusion of a diffuser. The gas suspension bearing has simple structure and high rotation precision, and is an ideal component under the working condition of high speed operation and high temperature. The start pressure difference is needed before the air suspension compressor is started, and the air supply pressure difference is needed to be provided all the time to keep running in the running process, so that the stable control of the air supply pressure is the key of the system running.

In the process of implementing the embodiments of the present disclosure, it is found that at least the following problems exist in the related art:

in the related art, the air supply pressure difference is generated by heating the suction pipe of the compressor. Since the distance from the gas flow to the air suction port of the compressor is short, there is a problem that the heating is insufficient, and a stable air supply pressure difference cannot be provided.

Disclosure of Invention

The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview, and is intended to neither identify key/critical elements nor delineate the scope of such embodiments, but is intended as a prelude to the more detailed description that follows.

The embodiment of the disclosure provides an air supply device for a static pressure air suspension compressor and an air conditioner, so as to solve the problems of insufficient heating and unstable air supply pressure difference when an air suction pipeline of the compressor is heated.

In some embodiments, the air supply device for a static pressure air suspension compressor includes: the air supply tank comprises a liquid inlet and an air outlet, the liquid inlet is communicated with the refrigerant liquid supply assembly through a refrigerant branch, and the air outlet is connected with an air supply port of an air suspension bearing of the static pressure air suspension compressor and is configured to convey gaseous refrigerant to the air suspension bearing; and the electromagnetic heating module is arranged in the air supply tank and is configured to generate heat in a controlled manner so as to heat the refrigerant in the air supply tank. In some embodiments, the air conditioner includes: the air supply device for the static pressure air suspension compressor comprises the static pressure air suspension compressor and the air supply device for the static pressure air suspension compressor.

The air supply device and the air conditioner for the static pressure air suspension compressor provided by the embodiment of the disclosure can realize the following technical effects:

the air supply tank is arranged at the input end of the air suspension bearing of the compressor, and the electromagnetic heating module is used for heating the refrigerant in the air supply tank, so that the air supply pressure is improved, a stable air supply pressure difference is formed, and good conditions are provided for the stable operation of the air suspension bearing of the static pressure air suspension compressor. Through electromagnetic heating module for liquid refrigerant in the air feed jar obtains fully heating, has effectively improved heating efficiency, guarantees that the whole operation of device is reliable and stable.

The foregoing general description and the following description are exemplary and explanatory only and are not restrictive of the application.

Drawings

One or more embodiments are illustrated by way of example and not limitation in the figures of the accompanying drawings, in which like references indicate similar elements, and in which like reference numerals refer to similar elements, and in which:

FIG. 1 is a schematic diagram of an air supply arrangement for a static air suspension compressor according to an embodiment of the present disclosure;

FIG. 2 is a schematic view of an apparatus structure of a gas supply tank in an embodiment of the present disclosure;

FIG. 3 is a schematic cross-sectional view of FIG. 2;

FIG. 4 is a schematic view of another apparatus configuration of a gas supply tank in an embodiment of the present disclosure;

FIG. 5 is a schematic diagram of the connection of a gas supply for a static pressure gas suspension compressor provided by an embodiment of the present disclosure;

fig. 6 is a schematic diagram illustrating connection of a refrigerant circulation line of an air conditioner according to an embodiment of the present disclosure;

fig. 7 is a schematic diagram of a connection relationship of an air conditioner according to an embodiment of the present disclosure.

Reference numerals:

10: a gas supply tank; 11: an exhaust port; 12: a liquid inlet; 13: a liquid level sensor; 20: an air suspension bearing; 30: a refrigerant liquid supply assembly; 31: a refrigerant branch; 40: an electromagnetic heating module; 41: an induction coil; 42: a magnetizer; 43: a buckle; 44: a clamping seat; 51: a first pressure measurement module; 52: a second pressure measurement module; 60: a controller; 70: a liquid level sensor; 81: an exhaust port of the static pressure gas suspension compressor; 82: a condenser; 83: an electronic expansion valve; 84: an evaporator; 85: static pressure gas suspension compressor air suction port; 86: a first electromagnetic valve; 87: a second electromagnetic valve; 88: a refrigerant pump; 89: a filter; 90: a one-way valve; 91: a first branch; 92: a second branch.

Detailed Description

So that the manner in which the features and techniques of the disclosed embodiments can be understood in more detail, a more particular description of the embodiments of the disclosure, briefly summarized below, may be had by reference to the appended drawings, which are not intended to be limiting of the embodiments of the disclosure. In the following description of the technology, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the disclosed embodiments. However, one or more embodiments may still be practiced without these details. In other instances, well-known structures and devices may be shown simplified in order to simplify the drawing.

The terms first, second and the like in the description and in the claims of the embodiments of the disclosure and in the above-described figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate in order to describe embodiments of the present disclosure. Furthermore, the terms "comprise" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion.

In the embodiments of the present disclosure, the terms "upper", "lower", "inner", "middle", "outer", "front", "rear", and the like indicate an azimuth or a positional relationship based on that shown in the drawings. These terms are used primarily to better describe embodiments of the present disclosure and embodiments thereof and are not intended to limit the indicated device, element, or component to a particular orientation or to be constructed and operated in a particular orientation. Also, some of the terms described above may be used to indicate other meanings in addition to orientation or positional relationships, for example, the term "upper" may also be used to indicate some sort of attachment or connection in some cases. The specific meaning of these terms in the embodiments of the present disclosure will be understood by those of ordinary skill in the art in view of the specific circumstances.

In addition, the terms "disposed," "connected," "secured" and "affixed" are to be construed broadly. For example, "connected" may be in a fixed connection, a removable connection, or a unitary construction; may be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements, or components. The specific meaning of the above terms in the embodiments of the present disclosure may be understood by those of ordinary skill in the art according to specific circumstances.

The term "plurality" means two or more, unless otherwise indicated.

In the embodiment of the present disclosure, the character "/" indicates that the front and rear objects are an or relationship. For example, A/B represents: a or B.

The term "and/or" is an associative relationship that describes an object, meaning that there may be three relationships. For example, a and/or B, represent: a or B, or, A and B.

It should be noted that, without conflict, the embodiments of the present disclosure and features of the embodiments may be combined with each other.

As shown in connection with fig. 1-4, embodiments of the present disclosure provide a gas supply apparatus for a static-pressure gas suspension compressor, including a gas supply tank 10 and an electromagnetic heating module 40. The gas supply tank 10 includes a liquid inlet 12 and a gas outlet 11, the liquid inlet 12 is communicated with the refrigerant liquid supply assembly 30 through a refrigerant branch 31, the gas outlet 11 is connected with a gas supply port of a gas suspension bearing 20 of the static gas suspension compressor, and is configured to convey gaseous refrigerant to the gas suspension bearing 20; the electromagnetic heating module 40 is provided to the air supply tank 10 and configured to be controlled to generate heat to heat the refrigerant in the air supply tank 10.

Here, the electromagnetic heating module 40 converts electric energy into magnetic energy by using an electromagnetic induction principle, so that magnetically conductive materials such as a metal pipe or a metal container actively generate heat under electromagnetic induction, thereby heating the object to be heated. Compared with the traditional resistance heating, the electromagnetic reaction heating has higher heat conversion rate and is more efficient and energy-saving. In this scheme, the air supply tank 10 is used for providing high-pressure air for the air suspension bearing 20 of the air suspension compressor, and after the liquid refrigerant in the refrigerant liquid supply assembly 30 enters the air supply tank 10, the liquid refrigerant is heated by the electromagnetic heating module 40 to form high-pressure air, so as to increase the air supply pressure and provide a starting pressure difference for the compressor.

According to the embodiment of the disclosure, the air supply tank 10 is arranged at the air supply port of the air suspension bearing 20 of the compressor, and the electromagnetic heating module 40 is used for heating the refrigerant in the air supply tank 10, so that the air supply pressure is increased, a stable air supply pressure difference is formed, and good conditions are provided for the stable operation of the static pressure air suspension compressor. Through electromagnetic heating module 40 for the liquid refrigerant in the air feed tank 10 obtains abundant heating, has effectively improved heating efficiency, guarantees that the whole operation of device is reliable and stable.

Optionally, the electromagnetic heating module 40 comprises an induction coil 41 and a magnetizer 42; the induction coil 41 is connected to a power source and configured to generate an alternating magnetic field in an energized state; the magnetizer 42 is arranged inside the air supply tank 10 and is positioned in the alternating magnetic field; and is configured to generate eddy currents under the influence of the alternating magnetic field.

Between the induction coil 41 and the magnetizer 42, the electric energy is converted into thermomagnetic energy by utilizing the magnetic induction principle, so that the magnetizer 42 actively heats under electromagnetic induction, thereby realizing the heating of the surrounding refrigerant. Compared with the traditional electric heating mode, the electromagnetic reaction heating has higher heat conversion rate and is more efficient and energy-saving.

The induction coil 41 may be provided in contact with the gas supply tank 10 or may be provided in a non-contact manner, and the generation of eddy currents by the magnetizer 42 in the energized state of the induction coil 41 may be achieved by providing the magnetizer 42 in the alternating magnetic field of the induction coil 41.

By adopting the air supply tank 10 provided by the embodiment of the disclosure, the induction coil 41 is arranged to generate an alternating magnetic field, the magnetizer 42 positioned in the alternating magnetic field is arranged in the air supply tank 10, the alternating current generated by a power supply generates the alternating magnetic field through the induction coil 41 by utilizing the electromagnetic induction heating principle, the alternating magnetic force line of the magnetic field cuts the magnetizer 42 with a resistor to generate vortex, resistance heat is further generated, and the liquid refrigerant at the bottom of the air supply tank 10 is heated by utilizing the heat of the resistance heat, so that high-pressure gaseous refrigerant is generated, the air supply pressure of the air supply tank 10 is improved, and the air supply pressure difference exists when the gaseous refrigerant is input to the air supply port of the air suspension bearing, so that the quick start of the static pressure air suspension compressor can be realized.

Alternatively, as shown in fig. 2 and 3, the induction coil 41 is sleeved on the outer wall of the air supply tank 10. Here, the induction coil 41 is disposed in contact with the gas supply tank 10. By disposing the induction coil 41 on the outer wall of the air supply tank 10, the magnetizer 42 in the air supply tank 10 is disposed in the alternating magnetic field generated by the induction coil 41, so that the magnetizer 42 generates heat to heat the refrigerant in the air supply tank 10 in the energized state of the induction coil 41, and the air supply pressure is rapidly increased.

Alternatively, as shown in fig. 4, an induction coil 41 is provided below the gas supply tank 10 by a connection means. Here, the induction coil 41 may be disposed in contact with the air supply tank 10 or may be disposed in a non-contact manner. In this case, the induction coil 41 may be in the form of a coil disk, and the disk may be provided below or under the gas supply tank 10. The induction coil 41 is detachably arranged below the air supply tank 10 through a connecting device, and can be detached according to seasons and temperature changes. The connection means may be a snap-on or screw-on means. In an embodiment of the present disclosure, the connection device is a clamping device, including: a buckle 43 provided on the top of the induction coil 41; the fastening seat 44 is disposed at the bottom of the air supply tank 10 and has a fastening slot matched with the fastening button 43. The detachable connection of the induction coil 41 with the air supply tank 10 is achieved by means of a connection device.

Alternatively, the magnetizer 42 is provided at the bottom inside the air supply tank 10. By disposing the magnetizer 42 at the bottom of the air supply tank 10, the liquid refrigerant at the bottom of the air supply tank 10 can be directly heated by the resistance heat generated under the electromagnetic induction principle in the alternating magnetic field. Compared with the electromagnetic induction heating device or the electric heating device arranged on the refrigerant flowing pipeline in the related art, the magnetizer 42 is arranged in the air supply tank 10 in the embodiment, so that the direct heating of the refrigerant in the air supply tank 10 is realized; further, in this embodiment, the magnetizer 42 is disposed at the bottom of the air supply tank 10, so that the heat generated by the magnetizer can firstly heat the liquid refrigerant at the bottom of the air supply tank 10, thereby generating high-pressure gaseous refrigerant, and increasing the air supply pressure of the air supply tank 10, so that the air supply pressure difference exists when the gaseous refrigerant is input to the air supply port of the air suspension bearing, and the quick start of the static pressure air suspension compressor can be realized.

Optionally, a gap exists between the outer wall of the magnetizer 42 and the inner wall of the air supply tank 10. So that the contact area between the magnetizer 42 and the refrigerant increases, and heat can be directly diffused into the refrigerant. Alternatively, the magnetic conductor 42 is a rectangular parallelepiped or hollow cylinder. When the magnetizer 42 is a rectangular parallelepiped, it has a plurality of outer surfaces contacting with the refrigerant, and has a regular and stable structure, and is not easy to displace, so that it is convenient to be disposed inside the air supply tank 10. When the magnetizer 42 is a hollow cylinder, its outer shape is adapted to the structure of the air supply tank 10, and the hollow structure can increase the contact area with the refrigerant, thereby further improving the heating effect. Alternatively, the magnetic conductor 42 is a martensitic steel pipe.

Optionally, the air supply tank 10 further includes a liquid level sensor 13 disposed on the magnetizer 42 or on the inner wall of the air supply tank 10 and connected to a power source; and is configured to control the power supply to be de-energized when the liquid level is below the first liquid level threshold. Specifically, the liquid level sensor 13 may be disposed on top of the magnetizer 42, and the liquid level sensing piece thereof is closely disposed with a side surface of the magnetizer 42. Alternatively, the liquid level sensing piece of the liquid level sensor 13 is provided in the middle of the side surface of the magnetizer 42. In this way, when the refrigerant level in the gas supply tank 10 drops to the top of the exposed magnetizer 42, the liquid level sensor 13 starts to detect the liquid level height, and when the liquid level is lower than the first liquid level threshold, that is, the liquid level is lower than the set position of the liquid level sensing piece, the power supply is controlled to be powered off. At this time, the liquid level in the air supply tank 10 is low, and when the control power is turned on, the heat generated by the magnetizer 42 is large, and the heat that can be absorbed by the refrigerant with a small volume is also small, which is easy to cause a fault.

By adopting the air supply device for the static pressure air suspension compressor provided by the embodiment of the disclosure, the induction coil 41 is arranged to generate an alternating magnetic field, the magnetizer 42 positioned in the alternating magnetic field is arranged in the air supply tank 10, the alternating current generated by the power supply generates the alternating magnetic field through the induction coil 41 by utilizing the electromagnetic induction heating principle, the alternating magnetic force line of the magnetic field cuts the magnetizer 42 with a resistor to generate vortex, resistance heat is further generated, the liquid refrigerant at the bottom of the air supply tank 10 is heated by utilizing the heat of the resistance heat, and the liquid refrigerant is evaporated into gaseous refrigerant to enter the compressor. The heating efficiency can be effectively improved, the air supply pressure of the air supply tank 10 is improved, so that the air supply pressure difference exists when the air refrigerant is input to the air supply port of the air suspension bearing, and the quick start of the static pressure air suspension compressor can be realized.

As shown in fig. 5, the embodiment of the present disclosure also provides a gas supply apparatus for a static pressure gas suspension compressor, including a gas supply tank 10 and an electromagnetic heating module 40. The air supply tank 10 comprises a liquid inlet 12 and an air outlet 11, the air outlet 11 is connected with an air supply port of an air suspension bearing of the static air suspension compressor, and the liquid inlet 12 is communicated with the refrigerant liquid supply assembly 30 through a refrigerant branch 31; the electromagnetic heating module 40 is provided to the air supply tank 10 and configured to be controlled to generate heat to heat the refrigerant in the air supply tank 10.

Optionally, a first pressure measurement module 51, a second pressure measurement module 52, and a controller 60 are also included. Wherein, the first pressure measuring module 51 is arranged at the exhaust port 11 of the gas supply tank 10 or at the input end of the gas suspension bearing 20, and is used for measuring the gas supply pressure of the gaseous refrigerant; the second pressure measurement module 52 is arranged at the air return port of the air suspension bearing of the compressor and is used for measuring the air return pressure of the air suspension bearing; the controller 60 is connected to the first pressure measuring module 51, the second pressure measuring module 52 and the electromagnetic heating module 40, respectively, and is configured to control the heating power of the electromagnetic heating device according to the difference between the measured results of the first pressure measuring module 51 and the second pressure measuring module 52.

Here, the first pressure measurement module 51 may be a pressure gauge valve that measures the supply pressure of the output gaseous refrigerant of the gas supply tank 10 through the gas outlet 11 provided in the gas supply tank 10, or that measures the supply pressure of the output gas of the gas supply tank 10 to the gas suspension bearing 20 through the gas supply port provided in the gas suspension bearing 20. The second pressure measurement module 52 may also be a pressure gauge valve, which measures the return air pressure of the air suspension bearing through a return air port provided in the air suspension bearing. The controller 60 controls the current and/or voltage of the electromagnetic heating device according to the difference between the measurement results of the first pressure measurement module 51 and the second pressure measurement module 52, i.e. according to the difference between the air supply pressure and the air return pressure, so as to change the heating power of the electromagnetic heating device.

Alternatively, the controller 60 is configured to reduce the heating power of the electromagnetic heating module 40 when the difference between the measurement results of the first pressure measurement module 51 and the second pressure measurement module 52 is greater than or equal to the first threshold value, that is, the difference between the supply air pressure and the return air pressure is greater than or equal to the first threshold value; when the difference between the measurement results of the first pressure measurement module 51 and the second pressure measurement module 52 is smaller than the first threshold, that is, the difference between the supply air pressure and the return air pressure is smaller than the first threshold, the heating power of the electromagnetic heating module 40 is increased.

Here, when the first pressure measurement module 51 is provided at the exhaust port 11 of the air supply tank 10, the difference in measurement results is the difference between the exhaust pressure of the air supply to the air suspension bearing 20 at the air supply tank 10 and the return pressure of the compressor air suspension bearing; when the difference is greater than or equal to the first threshold, indicating that the supply pressure is too high, the controller 60 reduces the heating power of the electromagnetic heating module 40 to slow down the output of the gaseous refrigerant; when the difference is smaller than the first threshold, the air supply pressure is smaller, and the controller 60 increases the heating power of the electromagnetic heating module 40 to accelerate the output of the gaseous refrigerant.

When the first pressure measuring module 51 is disposed at the air supply port of the air suspension bearing 20, the difference between the measured result is the difference between the air supply pressure at the input end of the air suspension bearing 20 and the air return pressure of the air suspension bearing of the compressor. When the difference is greater than or equal to the first threshold, indicating that the supply pressure is too high, the controller 60 reduces the heating power of the electromagnetic heating module 40 to slow down the output of the gaseous refrigerant; when the difference is smaller than the first threshold, the air supply pressure is smaller, and the controller 60 increases the heating power of the electromagnetic heating module 40 to accelerate the output of the gaseous refrigerant.

Optionally, the value of the first threshold is in the range of 0.45Mpa-0.65Mpa, specifically 0.45Mpa, 0.50Mpa, 0.55Mpa, 0.60Mpa or 0.65Mpa.

By adopting the air supply device for the static pressure air suspension compressor, which is provided by the embodiment of the disclosure, the air supply tank 10 is arranged at the input end of the air suspension bearing 20 of the compressor, and the electromagnetic heating module 40 is utilized to heat the refrigerant in the air supply tank 10, so that the air supply pressure is increased, stable air supply pressure difference is formed, and good conditions are provided for the stable operation of the static pressure air suspension compressor. Through electromagnetic heating module 40 for the liquid refrigerant in the air feed tank 10 obtains abundant heating, has effectively improved heating efficiency, guarantees that the whole operation of device is reliable and stable. Meanwhile, by detecting the air supply pressure of the gaseous refrigerant and adjusting the power of the electromagnetic heating module 40 according to the difference of the air supply pressure differences, the starting pressure difference for quick starting and the stable air supply pressure difference are provided for the air suspension compressor, and the reliability of the whole operation of the device is ensured.

The embodiment of the disclosure also provides an air conditioner, as shown in fig. 6 and 7, comprising a static pressure air suspension compressor and the air supply device for the static pressure air suspension compressor. The air conditioner includes a refrigerant circulation circuit formed by connecting a static pressure air suspension compressor, a four-way valve, a condenser 82 and an evaporator 84 through pipes. The exhaust port 11 of the air supply tank 10 is connected with an air supply port of an air suspension bearing of the static-pressure air suspension compressor through a pipeline.

By providing the air supply device for the static pressure air suspension compressor, the air outlet 11 of the air supply tank 10 is connected with the air suspension bearing 20 of the static pressure air suspension compressor, high-pressure air is provided for the air suspension bearing 20 of the air suspension compressor, and after the liquid refrigerant in the refrigerant liquid supply assembly 30 enters the air supply tank 10, the high-pressure air is formed through heating of the electromagnetic heating module 40, so that the air supply pressure is improved, and a starting pressure difference is provided for the compressor.

Optionally, the refrigerant liquid supply assembly 30 of the gas supply includes a condenser 82 of the air conditioner, and/or an evaporator 84. By providing the refrigerant branch circuit 31 at the refrigerant outlets of the condenser 82 and the evaporator 84, part of the refrigerant in the refrigerant circulation loop enters the gas supply tank 10 through the refrigerant branch circuit 31 and participates in the process of providing the starting pressure difference and the gas supply pressure difference for the static pressure gas suspension compressor.

Optionally, the refrigerant branch 31 further includes: a first electromagnetic valve 86 provided between the liquid inlet 12 of the gas supply tank 10 and the condenser 82; the second electromagnetic valve 87 is provided between the liquid inlet 12 of the gas supply tank 10 and the evaporator 84. The source of the refrigerant entering the gas supply tank 10 can be controlled by switching on and off the first solenoid valve 86 and the second solenoid valve 87.

Optionally, a refrigerant pump 88 is further included and is disposed between the liquid inlet 12 of the gas supply tank 10 and the first branch 91 and the second branch 92. In this way, after the refrigerant enters the refrigerant pump 88 from the refrigerant branch 31, the refrigerant is sent to the gas supply tank 10 by the refrigerant pump 88, and the refrigerant can be pressurized during the sending process.

Optionally, the output end of the refrigerant pump 88 is provided with a one-way valve 90, and the input end of the refrigerant pump 88 is provided with a filter 89 for filtering the refrigerant flowing in the pipeline, preventing the input section of the refrigerant pump 88 from being dirty and blocked, causing system faults and playing a role in filtering protection. Optionally, the refrigerant pump 88 is connected to the liquid level sensor 13 and configured to shut off the refrigerant pump 88 and stop delivering refrigerant to the gas supply tank 10 when the liquid level is higher than or equal to the second liquid level threshold; when the liquid level is lower than the second liquid level threshold, the refrigerant pump 88 is turned on, and the refrigerant is continuously supplied to the supply tank 10. In this way, the start and stop of the refrigerant pump 88 is controlled according to the liquid level, and insufficient heating due to excessive refrigerant in the gas supply tank 10 can be prevented, and the gas supply pressure cannot be provided.

Optionally, a check valve 90 is provided between the output of the refrigerant pump 88 and the gas supply tank 10, so that refrigerant can only flow from the refrigerant pump 88 to the gas supply tank 10. In this way, the refrigerant can be prevented from flowing back to the refrigerant pump 88 when the air pressure in the air supply tank 10 is large.

Alternatively, the first solenoid valve 86 and the second solenoid valve 87 are respectively connected to the controller 60, and are controlled to be turned on and off by the controller 60. When the first electromagnetic valve 86 is opened and the second electromagnetic valve 87 is closed, the refrigerant entering the gas supply tank 10 comes from the condenser 82, so that the loss of the refrigerant can be reduced, the refrigerant at the outlet of the condenser 82 has a little supercooling degree, and the good operation condition of the refrigerant pump 88 can be ensured; when the first electromagnetic valve 86 is closed and the second electromagnetic valve 87 is opened, the refrigerant entering the gas supply tank 10 comes from the evaporator 84, so that the refrigerant pump 88 can be ensured to have a larger gravity pressure head when the gas supply tank is started, and the operation condition of the refrigerant pump 88 is good.

The embodiments described above are described with reference to specific embodiments, and the air conditioner provided in the embodiments of the present disclosure is a central air conditioner. Specifically, the air conditioner includes a static pressure air suspension compressor, and the refrigerant enters the condenser 82 from the exhaust port 11 of the static pressure air suspension compressor, enters the main electronic expansion valve 83 through the output end of the condenser 82, enters the evaporator 84 after being output from the main electronic expansion valve 83, and enters the air suction port 85 of the static pressure air suspension compressor through the output end of the evaporator 84 to form circulation of the refrigerant.

The air conditioner further comprises an air supply device for the static pressure air suspension compressor. The air outlet 11 of the air supply tank 10 is connected to the input end of the air suspension bearing 20 of the static pressure air suspension compressor, and supplies gaseous refrigerant to the air suspension bearing 20, and heats the liquid refrigerant in the air supply pipe through the electromagnetic heating module 40 arranged on the air supply tank 10, so as to improve the air supply pressure of the air supply tank 10 for inputting the gaseous refrigerant to the air suspension bearing 20.

Before the hydrostatic gas suspension compressor operates, a steady start pressure differential is required, which is expressed as the difference between the gas supply pressure of the gas suspension bearing 20 and the return gas pressure of the return gas port of the compressor gas suspension bearing 20. The liquid refrigerant in the gas supply tank 10 is heated by the electromagnetic heating module 40, so that the gas supply pressure is raised, and a stable gas supply pressure difference is formed, thereby providing good conditions for the stable operation of the static pressure gas suspension compressor.

Here, the refrigerant in the air supply tank 10 comes from two branches, the first branch 91 connects the liquid inlet 12 of the air supply tank 10 and the refrigerant outlet of the condenser 82, and part of the supercooled liquid refrigerant in the condenser 82 is introduced into the refrigerant branch 31 to enter the air supply tank 10; the second branch 92 connects the gas supply tank 10 with the refrigerant outlet of the evaporator 84, and introduces a part of the liquid refrigerant in the lower portion of the cylinder of the evaporator 84 into the refrigerant branch 31 to enter the gas supply tank 10. Here, the first branch 91 and the second branch 92 are provided with a first solenoid valve 86 and a second solenoid valve 87, respectively, for controlling the source of the refrigerant entering the gas supply tank 10. Specifically, the on-off of the first solenoid valve 86 and the second solenoid valve 87 is controlled as follows:

when the static pressure of the air supply tank 10 starts, the first electromagnetic valve 86 is controlled to be closed, the second electromagnetic valve 87 is opened, the refrigerant in the evaporator 84 is conveyed to the air supply tank 10, and the start and stop of the refrigerant pump 88 are controlled according to the liquid level in the air supply tank 10; acquiring a difference value between the air supply pressure and the air return pressure, and controlling the heating power of the electromagnetic heating module 40 according to the difference value;

after the air supply tank 10 is started and operated for a set time, the first electromagnetic valve 86 is controlled to be opened, the second electromagnetic valve 87 is closed, the refrigerant in the condenser 82 is conveyed to the air supply tank 10, and the start and stop of the refrigerant pump 88 are controlled according to the liquid level in the air supply tank 10; the difference between the supply air pressure and the return air pressure is obtained, and the heating power of the electromagnetic heating module 40 is controlled according to the difference.

For the central air conditioner, the evaporator 84 is located above the condenser 82, and refrigerant is input to the air supply tank 10 through the evaporator 84 during the startup process, so that the refrigerant pump 88 can be ensured to have a larger gravity head during the startup process, and good operation conditions can be maintained.

By adopting the air conditioner provided by the embodiment of the disclosure, the air supply tank 10 is arranged at the input end of the air suspension bearing 20 of the compressor, and the electromagnetic heating module 40 is utilized to heat the refrigerant in the air supply tank 10, so that the air supply pressure is improved, a stable air supply pressure difference is formed, and a good condition is provided for the stable operation of the static pressure air suspension compressor. Through electromagnetic heating module 40 for the liquid refrigerant in the air feed tank 10 obtains abundant heating, has effectively improved heating efficiency, guarantees that the whole operation of device is reliable and stable.

The above description and the drawings illustrate embodiments of the disclosure sufficiently to enable those skilled in the art to practice them. Other embodiments may include structural and other modifications. The embodiments represent only possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in, or substituted for, those of others. The embodiments of the present disclosure are not limited to the structures that have been described above and shown in the drawings, and various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (5)

1. An air conditioner, comprising:

a static pressure gas suspension compressor; and, a step of, in the first embodiment,

the air supply device is used for the static pressure air suspension compressor;

the air supply device for the static pressure air suspension compressor comprises:

the air supply tank comprises a liquid inlet and an air outlet, the liquid inlet is communicated with the refrigerant liquid supply assembly through a refrigerant branch, and the air outlet is connected with an air supply port of an air suspension bearing of the static pressure air suspension compressor and is configured to convey gaseous refrigerant to the air suspension bearing;

the electromagnetic heating module is arranged in the air supply tank and is configured to generate heat in a controlled manner so as to heat the refrigerant in the air supply tank;

the air supply tank includes: the liquid level sensor is arranged on the inner wall of the air supply tank and is connected with a power supply of the electromagnetic heating module; and configured to control the power supply to be powered off when the liquid level is below a first liquid level threshold;

the refrigerant liquid supply assembly includes:

a condenser and an evaporator of the air conditioner; the liquid inlet of the gas supply tank is connected with the refrigerant outlet of the condenser through a first branch and connected with the refrigerant outlet of the evaporator through a second branch;

the first electromagnetic valve is arranged between the liquid inlet of the gas supply tank and the condenser;

the second electromagnetic valve is arranged between the liquid inlet of the gas supply tank and the evaporator;

the refrigerant pump is arranged between the liquid inlet of the gas supply tank and the first branch and the second branch; the refrigerant pump is connected with the liquid level sensor and is configured to close the refrigerant pump and stop delivering the refrigerant to the air supply tank when the liquid level is higher than or equal to a second liquid level threshold value; when the liquid level is lower than a second liquid level threshold value, starting a refrigerant pump, and continuously conveying the refrigerant to the air supply tank; when the first electromagnetic valve is opened and the second electromagnetic valve is closed, the refrigerant entering the gas supply tank through the refrigerant pump comes from the condenser; when the first electromagnetic valve is closed and the second electromagnetic valve is opened, the refrigerant entering the air supply tank through the refrigerant pump comes from the evaporator.

2. The air conditioner of claim 1, wherein the air supply device for the static pressure air suspension compressor further comprises:

the first pressure measurement module is arranged at the exhaust port of the air supply tank or the air supply port of the air suspension bearing;

and the second pressure measurement module is arranged at the air return port of the air suspension bearing.

3. The air conditioner of claim 2, wherein the air supply device for the static pressure air suspension compressor further comprises:

and the controller is respectively connected with the first pressure measurement module, the second pressure measurement module and the electromagnetic heating module and is configured to control the heating power of the electromagnetic heating device according to the difference value of the measurement results of the first pressure measurement module and the second pressure measurement module.

4. The air conditioner of claim 3, wherein the controller is configured to:

when the difference value of the measurement results of the first pressure measurement module and the second pressure measurement module is larger than or equal to a first threshold value, reducing the heating power of the electromagnetic heating module;

and when the difference value of the measurement results of the first pressure measurement module and the second pressure measurement module is smaller than the first threshold value, the heating power of the electromagnetic heating module is increased.

5. The air conditioner according to any one of claims 1 to 4, wherein the electromagnetic heating module includes:

an induction coil connected to a power source and configured to generate an alternating magnetic field in an energized state;

the magnetizer is arranged in the air supply tank and is positioned in the alternating magnetic field; and is configured to generate eddy currents under the influence of the alternating magnetic field.