BR112013031245B1 - SEALED COMPRESSOR AND COOLING CYCLE DEVICE - Google Patents

Abstract

sealed compressor and refrigeration cycle device A sealed compressor single-section cycle device configured for refrigeration mechanism to be used in one of an embodiment includes a rotary compression device, accommodated in a sealed enclosure, and an accumulator, provided outside the sealed enclosure. the sealed compressor is configured to draw a working fluid into the rotary compression mechanism section through at least one suction tube, which extends into and is connected to the accumulator. the rotary compression mechanism section minus one cylinder, each of this cylindrical farmando. the sealed compressor has ratios of aac/acy (less than equal) 4, vac/vcy (greater than equal) and as/acy (greater than equal) 0, 12, when an area of the cross-sectional area of the internal diameter of the accumulator is denoted by aac ( mm2), one including at a chamber cross-sectional area of the inner diameter of a cylindrical chamber is denoted by acy (mm2), a liquid holding capacity for an upper end of the suction tube, within the accumulator, is denoted by vac (cm3) , a total displacement volume of the rotary compression mechanism section is denoted by vcy (cm3), and a cross-sectional area of the total inner diameter of an extended part within the suction tube accumulator is denoted per as (mm2) .

Description

TECHNICAL FIELD

[0001] The embodiments of the invention refer to sealed compressors and refrigeration cycle devices.

BACKGROUND OF THE INVENTION

[0002] In a refrigeration cycle device, such as an air conditioner, a technique is known in which the refrigerant, compressed by a sealed compressor, passes through an external heat exchanger, an expansion device and a heat exchanger internal, connected to the sealed compressor through a four-way valve, like a cycle. The sealed compressor, used in the refrigeration cycle device, includes a rotary compression mechanism section therein, and an accumulator on its suction side. The accumulator prevents backflow of liquid. Furthermore, the sealed compressor is configured to vary its rotational speed by an inverter. LIST OF QUOTES Patent Literature Patent Literature 1: Japanese Patent Application Publication No. 2003-227486.

SUMMARY OF THE INVENTION TECHNICAL PROBLEM

[0003] In the related art, the sealed compressor is designed to improve its characteristics, while operating at a nominal rotation speed, for example, at a rotation speed of 60 rps (revolutions per second). Then, since the suction loss does not cause any problem during operation, at rated rotational speed, the suction loss was not considered sufficiently. However, it has been proven that there is a case in which suction loss increases and performance is greatly degraded when the sealed compressor is operated at a rotation speed different from the nominal rotation speed, for example, at a high rotation speed . Therefore, it is an object of the invention to provide a sealed compressor and a refrigeration cycle device, capable of reducing suction loss in a state of high rotational speed.

SOLUTION TO THE PROBLEM

[0004] According to one embodiment, a sealed compressor comprises a rotary compression mechanism section, accommodated in a sealed casing, and an accumulator provided outside the sealed casing, the compressor configured to suction a working fluid in the section of rotary compression mechanism, by at least one suction tube extending into and connected to the accumulator, wherein the rotary compression mechanism section comprises at least one cylinder, each cylinder forming a cylindrical chamber, and where an area of the cross-section of the inside diameter of the accumulator is denoted Aac (mm2), a cross-sectional area of the inside diameter of a cylindrical chamber is denoted by Acy (mm2), a liquid holding capacity for an upper end of the suction tube, inside of the accumulator, is denoted by Vac (cm3), a total displacement volume of the rotary compression mechanism section is denoted by Vcy (cm3), and an area of the transv section. ersal of the total inner diameter of an extended part within the suction tube accumulator is denoted by As (mm2), the ratios of Aac/Acy <4, Vac/Vcy >20 and As/Acy >0.12 are satisfied.

BRIEF DESCRIPTION OF THE DRAWINGS

[0005] Figure 1 is an explanatory diagram schematically illustrating a configuration of a refrigeration cycle device of an embodiment.

[0006] Figure 2 is a cross-sectional view illustrating a configuration of a sealed compressor used in the refrigeration cycle device.

[0007] Figure 3 is an explanatory diagram illustrating a relationship between a suction loss and an area ratio of a total inner diameter cross sectional area and an inner diameter cross sectional area of the sealed compressor cylinder.

[0008] Figure 4 is an explanatory diagram illustrating a relationship between a flow velocity in the tube and the ratio of areas of a cross-sectional area of total inner diameter and a cross-sectional area of inner diameter of the sealed compressor cylinder.

[0009] Figure 5 is an explanatory diagram illustrating a relationship between suction loss and the ratio of areas of a total bore cross-sectional area and an inner diameter cross-sectional area of the sealed compressor cylinder.

DESCRIPTION OF ACHIEVEMENTS

[0010] A refrigeration cycle device 100, which uses a sealed compressor 1, according to one embodiment, will be described with reference to Figures 1 to 5.

[0011] Figure 1 is an explanatory diagram schematically illustrating a configuration of the refrigeration cycle device 100, according to the embodiment, Figure 2 is a cross-sectional view illustrating a configuration of the sealed compressor 1 and an accumulator 2, used in the refrigeration cycle device 100, Figure 3 is an explanatory diagram illustrating a relationship between an area ratio As/Acy of a total inner diameter cross-sectional area As of an extended portion within the accumulator of a tube. suction, and a cross-sectional area of inside diameter Acy of a cylindrical chamber in sealed compressor 1, and a suction loss ratio Ws/Wth of suction loss Ws of the extending part, inside the suction tube accumulator, to Wth theoretical work of the compressor, Figure 4 is an explanatory diagram illustrating a relationship between the area ratio As/Acy of the cross-sectional area of the total inside diameter As of the extended part, inside of the suction tube accumulator, and the inner diameter cross-sectional area Acy of a cylindrical chamber and the flow velocity in the tube Vs of the suction tube extension part in sealed compressor 1, and Figure 5 is an explanatory diagram illustrating a relationship between the As/Acy area ratio and the Ws/Wth suction loss ratio of sealed compressor 1 during nominal operation and high speed operation.

[0012] The refrigeration cycle device 100 is used in an air conditioner. In the following, the refrigeration cycle device 100 will be described as an air conditioner 100.

[0013] As illustrated in Figure 1, the air conditioner 100 comprises: a sealed compressor 1, comprising an accumulator 2 on a suction side thereof; a four-way valve 101; an external heat exchanger 102 as a heat exchanger on the heat source side; an expansion device 103; and an internal heat exchanger 104 as a use-side heat exchanger. The air conditioner 100 has a configuration in which the sealed compressor 1, the four-way valve 101, the external heat exchanger 102, the expansion device 103 and the internal heat exchanger 104 communicate with each other as a cycle.

[0014] In the air conditioner 100, the four-way valve 101 is connected to a suction side of the accumulator 2 of the sealed compressor 1. Furthermore, in the air conditioner 100, the four-way valve 101 is connected to one side seal compressor discharge valve 1. In the air conditioner 100, the external heat exchanger 102, the expansion device 103 and the heat exchanger 104 are sequentially connected to the four-way valve 101, and the flow direction of the refrigerant, discharged of sealed compressor 1 is changed when the passage of four-way valve 101 is changed.

[0015] The sealed compressor 1 includes a sealed container 10, a rotary compression mechanism section 11 provided at the bottom within the sealed container 10, a motor unit 12 provided at the top of the sealed container 10, a suction tube of refrigerant 13 provided in sealed container 10, and a refrigerant discharge tube 14 provided in sealed container 10. Further, sealed compressor 1 includes accumulator 1, connected to suction tube 13.

[0016] The upper part of the sealed container 10 is provided with an upper cover 10a, which seals the inner part of the sealed container 10, and the upper cover 10a is fixed by soldering, or the like, in order to seal the inner part of the container. sealed 10, after the rotary compression mechanism section 11 and the motor unit 12 are accommodated in the sealed container 10.

[0017] The rotary compression mechanism section 11 includes a first cylinder 21, a second cylinder 22, a rotary shaft 23, a pair of cylinders 24, a bearing 25, a divider plate 26 and vanes.

[0018] The first cylinder 21 forms a first cylindrical chamber 21a having a columnar shape. Still further, the first cylinder 21 includes a vane accommodating groove in communication with the first cylindrical chamber 21a and a suction port connected to the suction tube 13 so as to communicate with the first cylindrical chamber 21a. The vane is accommodated in the vane accommodation groove so as to project and retract with respect to the first cylindrical chamber 21a.

[0019] The outer dimension of the first cylinder 21 is slightly smaller than the inner diameter of the sealed container 10. The first cylinder 21 is inserted into the sealed container 10 and is positioned and secured to the inner peripheral surface of the sealed container 10 by welding, outside the sealed container 10. Furthermore, the first cylinder 21 includes a communication port 21 to communicate with an upper space of the first cylinder 21 when the first cylinder is secured to the sealed container 10.

The second cylinder 22 forms a second cylindrical chamber 22a having a columnar shape. Still further, the second cylinder 22 includes a vane accommodating groove in communication with the second cylindrical chamber 22a and a suction port connected to the suction tube 13 so as to communicate with the second cylindrical chamber 22a. The vane is accommodated in the vane accommodation groove so as to project and retract with respect to the second cylindrical chamber 22a.

[0021] The first cylinder 21 and the second cylinder 22 have different shapes and external dimensions. Furthermore, the first cylindrical chamber 21a and the second cylindrical chamber 22a are adjusted so that they have the same internal diameter and the same height.

[0022] The rotary shaft 23 is inserted by the first cylindrical chamber 21a and the second cylindrical chamber 22a, and is pivoted by the bearing 25. The rotary shaft 23 includes eccentric crank parts 28, which are positioned within the first cylindrical chamber 21a and second chamber cylindrical 22a, so as to have, for example, a phase difference of about 180°.

[0023] The two eccentric crank parts 28 have the same degree of eccentricity, and their heights are slightly smaller than those of the first cylindrical chamber 21a and second cylindrical chamber 22a.

[0024] The bearings 25 couple, respectively, with the eccentric parts of crank 28, so as to be sliding inside the first cylindrical chamber 21a and second cylindrical chamber 22a and to be sliding at the end of the vane. The heights of the bearings 24 are substantially equal to the heights of the first cylindrical chamber 21a and second cylindrical chamber 22a.

[0025] Since the pair of bearings 24 is provided on eccentric crank parts 28, arranged with a phase difference between them, the bearings have a phase difference of about 180°. Bearings 24 rotate eccentrically within first cylindrical chamber 21a and second cylindrical chamber 22a. Since the first and second cylindrical chambers 21 and 22 have the same internal diameter and the same height, and the two eccentric crank parts 28 and 28 have the same degree of eccentricity, the first and second cylinders 21 and 22 have the same displacement volume.

[0026] The bearing 25 includes a primary bearing 31, provided on an upper surface part of the first cylinder 21, covering the upper side of the first cylindrical chamber 21, and a secondary bearing 32, provided on a lower surface part of the second cylinder 22, covering the underside of the second cylindrical chamber 22a. Bearing 25 is formed so that rotary shaft 23 is pivoted by primary bearing 31 and secondary bearing 32.

[0027] The primary bearing 31 forms the upper surface of the first cylindrical chamber 21a, and the bearing 24 slides on the upper surface. The primary bearing 31 is equipped with a first valve cover 33, which covers the upper side of the primary bearing 31. In addition, the primary bearing 31 includes a first discharge port 34, which guides refrigerant from the first cylindrical chamber 21a to the first valve cover 33, and a first open/close valve 35, which opens and closes the first discharge port 34.

[0028] The secondary bearing 32 forms the lower surface of the second cylindrical chamber 22a, and the bearing 24 slides on the lower surface. The secondary bearing 32 is equipped with a second valve cover 36, which covers the underside of the secondary bearing 32. In addition, the secondary bearing 32 includes a second discharge port 37, which guides refrigerant from the second cylindrical chamber 22a to the second valve cover 36, and a second open/close valve 38, which opens and closes the second discharge port 37.

[0029] Furthermore, the first cylinder 21, the second cylinder 22, the divider plate 26, the primary bearing 31, the secondary bearing 32, the first valve cover 33 and the second valve cover 36 are integrally coupled with each other by a screw B and the like, and the coupled components are fixed to the sealed container 10 by means of the first cylinder 21.

[0030] The divider plate 26 has an outer diameter greater than the inner diameters of the first cylindrical chamber 21a and second cylindrical chamber 22a and smaller than the outer dimensions of the first cylinder 21 and second cylinder 22. The divider plate 26 is arranged so as to cover the first cylindrical chamber 21a and the second cylindrical chamber 22a.

[0031] The vane is formed so that its height is substantially equal to each of the heights of the first and second cylindrical chambers 21a and 22a. The reed is formed so that its front end has, for example, a semi-cylindrical shape. For example, when back pressure is applied to the back surface of the vane, the vane is compressed towards the bearing 24 by the back pressure, and the front end of the vane is in linear contact with the outer peripheral surface of the bearing 24, regardless of the angle of rotation of bearing 24.

[0032] The vane accommodation grooves are formed, respectively, in the first and second cylinders 21 and 22, so that the vanes divide between the suction holes and the first and second discharge holes 34 and 37. When the vanes come into contact with the bearings 24, the first and second cylindrical chambers 21a and 22a are defined as the suction chambers and the compression chambers.

[0033] The motor unit 12 includes a stator 51, fixed to the inner surface of the sealed container 10, and a rotor 52, disposed within the stator 51, with a predetermined clearance between them. The rotor 52 is fixed to the rotating shaft 23. The motor unit 12 is connected to, for example, an inverter, which varies the operating frequency. Furthermore, the inverter is electrically connected to a control unit, which controls the inverter and varies the rotation speed of the rotary shaft 23 to an arbitrary rotation speed, if necessary.

[0034] The suction tubes 13 are respectively connected to the suction holes of the first cylinder 21 and second cylinder 22. Furthermore, each suction tube 13 is curved upwards about 90° at the intermediate part, protruding from the container. sealed 10 so as to extend into accumulator 2, and its end is arranged at a predetermined height of accumulator 2. Furthermore, the height of the end of suction tube 13, extending into accumulator 2, is properly adjusted, if necessary, as the capacity for liquid refrigerant and lubricating oil, storable within accumulator 2, varies with height.

[0035] Furthermore, the suction tube 13 includes an oil return hole 13a, provided in a predetermined position in the height direction, from the bottom surface of the accumulator 2, in the part extending into the accumulator 2. Furthermore, the oil return port 13a can be formed so as to supply the lubricating oil, accumulated on the underside of the accumulator 2, to the first cylindrical chamber 21a and second cylindrical chamber 22a, together with the gaseous refrigerant, and the height of oil return hole 13a is adjusted accordingly depending on the size of the capacity of the accumulator 2.

[0036] The discharge tube 14 is connected to the top end of the sealed container 10, i.e. the top cover 10a. The discharge port 14 is connected to the four-way valve 101.

[0037] The accumulator 2 includes a cylindrical container 61, the ends of which are locked and a gas/liquid separation unit 62 provided within the container 61. In the accumulator 2, the suction tube 13 is inserted into the container 61 from the lower end of the container 61, the suction tube 13 extends to the position just below the gas/liquid separation unit 62, and the upper end of the container 61 is connected to a return tube 63, through which the refrigerant returns. Furthermore, the return tube 63 is connected to the four-way valve 101.

[0038] The gas / liquid separation unit 62 is a refrigerant guide unit, which prevents the refrigerant, returned from the return pipe 63, from entering directly into the suction pipes 13 and rectangle just below the gas / liquid separation unit 62. That is, the gas/liquid separation unit 62 is formed so that the refrigerant, as the gas/liquid mixture, returned from the return tube 63, can collide with the gas/liquid separation unit 62, and the refrigerant after collision, like the gas/liquid mixture, it can be oriented towards the inner peripheral surface of the container 61.

[0039] The accumulator 2 is a so-called gas / liquid separator, capable of storing the liquid refrigerant and the lubricating oil on the underside of the container 61 in the gas / liquid separation unit 62 and supplying the gaseous refrigerant from the suction tube 13.

[0040] Further, in sealed compressor 1, as illustrated in Figure 2, when the cross-sectional area of the inner diameter of the container 61 of the accumulator 2 is denoted by Aac (mm2), the cross-sectional area of the inner diameter of each one of the first and second cylindrical chambers 21a and 22a (the cross-sectional area of the inner diameter of a cylindrical chamber) is denoted by Acy (mm2), the cross-sectional area of the inner diameter of extending parts within the accumulator of the tubes. suction 13 and 13 (the sum of the cross-sectional areas of the inner diameters of the two suction tubes) is denoted by As (mm2), the total displacement volume of the rotary compression mechanism section 11 of the sealed compressor 1 (the sum of the displacement volumes of the first and second cylinders 21 and 22) is denoted by Vcy (cm3), the liquid holding capacity from the bottom surface of the container 61 to the upper end of the suction tube 13 of the accumulator 2 is denoted by Vac (cm3), the inner diameter of each of the first and second cylindrical chambers 21a and 22a (the inner diameter of a cylindrical chamber) is denoted by ΦDcy (mm), the axial distance between the upper surface of the first cylinder 21 and the lower surface of the second cylinder 22 is denoted by l (mm), the distance between the axial center of the first cylinder 21 and the axial center of the second cylinder 22 is denoted by Lc (mm), and the distance between the axial centers of the parts of connection of two suction tubes 13 and 13, with respect to the first cylinder 21 and the second cylinder 22, is denoted by Lp (mm), the respective dimensions of the sealed compressor 1 are adjusted so as to satisfy the ratio of:

[0041] Furthermore, the cross-sectional area of the inside diameter Aac of the accumulator 2 indicates the opening area of the container body 61 of the accumulator 2. The cross-sectional area of the total inside diameter As of the extended parts within the accumulator of suction tubes 13 and 13, indicates the sum of the opening areas of the two suction tubes extending into accumulator 2. Furthermore, the total displacement volume Vcy of the first and second cylinders 21 and 22 indicates the sum of the displacement volume of the first cylinder 21, as the volume between the inner peripheral surface of the first cylindrical chamber 21a and the outer peripheral surface of the bearing 24, and the displacement volume of the second cylinder 22, as the volume between the inner peripheral surface of the second chamber cylindrical 22a and the outer peripheral surface of the bearing 24.

[0042] The liquid holding capacity Vac of accumulator 2 indicates the capacity at which liquid refrigerant and lubricating oil can be stored within accumulator 2, when the accumulator performs gas / liquid separation, and specifically the volume that reaches the water level at which liquid refrigerant and lubricating oil do not enter suction tubes 13 and 13, inside accumulator 2, becomes the liquid holding capacity.

[0043] In the air conditioner 100, which uses the sealed compressor 1 with this configuration, when power is first supplied to the motor unit 12 of the sealed compressor average diameter of a drive device, such as an inverter, the rotor 52 rotates, and, therefore, the rotary shaft 23 fixed to the rotor 52 rotates. Due to the rotation of the rotary shaft 23, the crank eccentric parts 28 and 28 and the bearings 24 and 24 rotate eccentrically. By means of the rotating sliding actions of bearings 24 and 24, the coolant, sucked into the first cylindrical chamber 21a and second cylindrical chamber 22a, is compressed.

[0044] When bearings 24 and 24 move to a predetermined position, the first and second open/close valves 35 and 38 are opened, and compressed refrigerant is discharged from the first discharge port 34 and second discharge port 37 to the sealed container 10 by the first valve cover 33 and the second valve cover 36. The refrigerant, which flows into the sealed container 10, moves to the four-way valve 101 by the discharge pipe 14.

[0045] In this case, the four-way valve 101 connects the secondary side of the sealed compressor 1 to the external heat exchanger 102, during the cooling operation of the air conditioner 100. As indicated by the solid arrow C of Figure 1, the refrigerant compressed by sealed compressor 1 passes through external heat exchanger 102, and exchanges heat with external air so as to become condensed. Subsequently, the condensed refrigerant passes through the indoor heat exchanger 104, through the expansion device 103, exchanges heat with the indoor air, evaporates, and cools the indoor air.

[0046] The refrigerant, which passes through the internal heat exchanger 104, passes through the four-way valve 101 and moves to the accumulator 2. In the refrigerant, which moves to the accumulator 2, the liquid refrigerant and the lubricating oil are stored in accumulator 2 by the gas/liquid separation unit 62, and the gaseous refrigerant is sucked from the suction pipes 13 to the sealed compressor 1. Furthermore, at this time, the stored lubricating oil is sucked from the oil return port 13a and is sucked into the first cylindrical chamber 21a and second cylindrical chamber 22a, together with the gaseous refrigerant. By repeating these operations, the air conditioner 100 performs a heat exchange operation, such as a cooling operation.

[0047] Furthermore, in the heating operation of the air conditioner 100, the four-way valve 101 connects the secondary side of the sealed compressor 1 to the internal heat exchanger 104. As indicated by the dashed arrow H of Figure 1, the refrigerant , compressed by sealed compressor 1, passes through internal heat exchanger 104 and exchanges heat with internal air to be condensed. The condensed refrigerant passes through external heat exchanger 102, expansion device 103, and exchanges heat with external air in external heat exchanger 102 to evaporate. Evaporating refrigerant is separated into gas and liquid by the four-way valve 101 and the accumulator 2, and is sucked in by the sealed compressor 1. By repeating these operations, the air conditioner 100 performs a heat exchange operation, like a heat exchange operation. heating.

[0048] In the following, the basis of the adjustment of the respective dimensions of the sealed compressor 1, according to the embodiment, will be described in detail with reference to Figures 3 to 5.

[0049] In sealed compressor 1 using bearings 24, when the ratio Aac/Acy, between the cross-sectional area of the inside diameter Aac (mm2) of the container 61 of the accumulator 2 and the cross-sectional area of the inside diameter Acy (mm2 ) of each of the first and second cylindrical chambers 21a and 22a (the cross-sectional area of the inner diameter of a cylindrical chamber) becomes greater than 4, the inner diameter of accumulator 2 increases, the entire sealed compressor 1 increases in size, the weight balance is bad, and the installation property is degraded. In contrast, in the sealed compressor 1 of the embodiment, once the Aac/Acy ratio is set to a value equal to or less than 4, the accumulator and the entire sealed compressor 1 decrease in size, and the weight balance and property of installation can be improved.

[0050] Furthermore, when the Aac/Acy ratio is simply set to 4 or less, the internal diameter of accumulator 2 decreases, and therefore there is a concern that the gas/liquid separation function may be degraded. For this reason, as a result of various experiments, when the Aac/Acy ratio, between the liquid holding capacity Vas, from the lower surface of the container 61 to the upper end of the suction tube 13 of the accumulator 2, and the displacement volume total Vcy of the rotary compression mechanism section 11 (the sum of the displacement volumes of the first and second cylinders 21 and 22), is set to 20 or more, a sufficient liquid holding capacity can be ensured, and liquid return can be prevented.

[0051] Furthermore, Figure 3 illustrates the relationship between the Aac/Acy ratio, between the cross-sectional area of the inner diameter As of the extension parts, within the accumulator of the suction tubes 13 and 13 (the sum of the areas of the cross sections of the inner diameters of the two suction tubes), and the cross-sectional area of the inner diameter Acy (mm2) of each of the first cylindrical chamber 21a and second cylindrical chamber 22a (the cross-sectional area of the inner diameter of one chamber cylindrical), and the ratio Ws/Wth, between the suction loss Ws of the extended parts inside the accumulator of the suction tubes 13 and 13 and the theoretical work Wth of the compressor. That is, in Figure 3, the horizontal axis indicates the As/Acy ratio, and the vertical axis indicates the Ws/Wth ratio. From Figure 3, it should be understood that the Ws/Wth ratio increases as the As/Acy ratio decreases, and the Ws/Tth ratio, that is, the ratio of suction loss with respect to theoretical work, increases significantly , particularly when the As/Acy ratio becomes less than 0.12.

[0052] As described above, when the As/Acy ratio is adjusted to a value equal to or greater than 0.12, the suction loss Ws of suction tubes 13 and 13, within accumulator 2, with respect to the theoretical work of the compressor, can be set to a value equal to or less than substantially 2%, as illustrated in Figure 3. In this case, the theoretical work Wth of the compressor indicates the theoretical work, which is generated by the design calculation of the sealed compressor 1.

[0053] Furthermore, Figure 3 illustrates the measurement characteristics of four types of sealed compressors, by preparation of the sealed compressor, in which the heights of the first cylinder 21 and the second cylinder 22 are adjusted, respectively, in 18 mm, using the configuration of the two cylinders of the first cylinder 21 and second cylinder 22 of the embodiment, the sealed compressor, in which the heights of the first cylinder 21 and second cylinder 22 are respectively adjusted to 22 mm, using the configuration described above, the sealed compressor of the single cylinder type with one cylinder, in which the cylinder height is adjusted by 20 mm, and the sealed compressor of the single cylinder type with one cylinder, in which the cylinder height is adjusted by 25 mm. As illustrated in Figure 3, the characteristics of the four types of sealed compressors substantially overlap each other along the same curve. In the four types of sealed compressors, the internal diameters of the respective cylindrical chambers are set at 43 mm, and the characteristics are measured by adjusting the operating rotation speed, so that the cooling capacity is kW rectangle, using R410A refrigerant .

[0054] As evident from Figure 3, once the As/Acy ratio >0.12 is adjusted, the suction loss ratio Ws/Wth (%) can be reduced, regardless of the number of its cylinders or its volume, and a significant increase in suction loss can be prevented.

[0055] Figure 4 is an explanatory diagram, illustrating a relationship between the ratio of areas As/Acy, of the cross-sectional area of the total inner diameter As of the extension part, inside the accumulator of the suction tube of the sealed compressor 1, and the cross-sectional area of the inner diameter Acy of a cylindrical chamber, and the tube flow velocity Vs (m/s) of the extending part within the suction tube accumulator, where the horizontal axis indicates the ratio of As/Acy areas and the vertical axis indicate the flow velocity in the tube Vs (m/s).

[0056] In a case where the As/Acy ratio is set to 0.12 or more, as illustrated in Figure 4, there is a tendency that the flow velocity in the tube Vs (m/s) of the suction tube 13 , inside accumulator 2, decreases as the As/Acy ratio increases, even when one cylinder or two cylinders are used.

[0057] The suction tube 13 inside the accumulator 2 is provided with the oil return hole 13a, which returns the lubricating oil, accumulated in the accumulator 2, and the lubricating oil is returned from the oil return hole 13a to the first cylindrical chamber 21a and second cylindrical chamber 22a. In this case, when the flow velocity in tube Vs decreases, there is a concern that oil cannot be sufficiently returned from return port 13a.

[0058] However, as illustrated in Figure 4, when the As/Acy ratio <0.25 is satisfied, the flow velocity in the tube Vs can be maintained at a value equal to or greater than 1 (m/s), and oil can be safely returned through oil return hole 13a.

[0059] Figure 5 is an explanatory diagram illustrating a relationship between the area ratio As/Acy and the ratio Ws/Wth of the suction loss Ws and the theoretical work Wth of the compressor in sealed compressor 1, at the nominal rotation speed ( 60 rps) and at high rotation speed (125 rps).

[0060] As evident from Figure 5, the ratios of <0.12 <As/Acy <0.25 and Vac/Vcy <20 are satisfied, the suction loss ratio Ws/Wth (%) can be reduced not only at rated rotational speed (60 rps), but also at high rotational speed (125 rps), and an increase in suction loss can be prevented.

[0061] Even more, when the L/Dcy ratio of the axial distance L (mm), between the upper surface of the first cylinder 21 and the lower surface of the second cylinder 22, and the inner diameter ΦDcy (mm) of each of the first and second cylinders 21 and 22 (the inner diameter of a cylindrical chamber) is adjusted to be less than 0.9, the heights (thicknesses) of the first and second cylinders 21 and 22 decrease, and the suction holes, which connect the suction tubes 13 and 13 also decrease in size so that the suction loss increases. Meanwhile, when the L/Dcy ratio becomes greater than 1.1, the distance between the bearings increases, and the rotary shaft is bent by the compression load, so that performance is degraded.

[0062] On the contrary, when the ratio of 0.9 <L/Dcy <1.1 is satisfied, the large suction holes of the first cylinder 21 and second cylinder 22 can be secured, and an increase in the distance between the bearings can be eliminated, so that degradation in performance can be prevented.

[0063] Even more, when the ratio of the distance Lc (mm), between the axial center of the first cylinder 21 and the axial center of the second cylinder 22, and the distance Lp (mm), between the axial centers of the connecting parts of the two suction tubes 13 and 13, with respect to first cylinder 21 and second cylinder 22, is set as Lp > Lc, the distance Lp between the axial centers of suction tubes 13 and 13 can be increased. That is, when the suction tubes 13 and 13 are connected to the sealed container 10, the element, which connects the suction tubes 13 and 13, is connected to the sealed container 10 by soldering. For this reason, when the distance Lp between the axial centers of the suction tubes 13 and 13 is set to the highest possible value, the degradation in mechanical strength caused by the soldering can be prevented.

[0064] As described above, according to the air conditioner 100, which uses the sealed compressor 1 of the embodiment, since the configuration described above is employed, even when the sealed compressor 1 is operated in a high-speed state of rotation, an abrupt increase in suction loss can be prevented, and the degradation in suction loss can be reduced. Furthermore, according to the air conditioner 100, which uses sealed compressor 1, the oil is safely returned, and therefore reliability can be improved.

[0065] Furthermore, the invention is not limited to the refrigeration cycle device 100, which uses the sealed compressor 1 of the embodiment. In the sealed compressor 1 of the embodiment described above, a configuration has been described in which two cylinders, i.e. first cylinder 21 and second cylinder 22, are used as the cylinders, but the invention is not limited thereto. In the ratios of Aac/Acy <4, 0.12 <As/Acy <0.25 and Vac/Vcy <20, the number of cylinders can be equal to one or three, or more.

[0066] With this configuration, as illustrated in Figures 3 and 4, even in a cylinder, the suction loss can be reduced and the flow velocity in the tube Vs of the suction tube 13, to return the oil, can be obtained as in sealed compressor 1 of the embodiment, using two cylinders. What's more, the same effect can be achieved even on three cylinders.

[0067] Further, in the example described above, the refrigeration cycle device 100 has been described as the air conditioner 100, with a configuration having the four-way valve 101, but the invention is not limited thereto. For example, the refrigeration cycle device 100 can also be a refrigeration cycle device that performs only a heating operation or a cooling operation, without the four-way valve 101 or a refrigeration cycle device other than the water conditioner. air.

[0068] Furthermore, in the example described above, the sealed compressor 1 has been described using a configuration in which the bearing 24 and the vane are provided separately, but the invention is not limited thereto. For example, even in a sealed oscillating type compressor, in which a bearing and a vane are integrally proportioned, the same effect can be achieved.

Claims (5)

1. Sealed compressor, characterized in that it comprises a rotary compression mechanism section, accommodated in a sealed casing, and an accumulator provided outside the sealed casing, the compressor configured to suction a working fluid in the mechanism section. rotary compression, by at least one suction tube extending into and connected to the accumulator, wherein the rotary compression mechanism section comprises at least one cylinder, each cylinder forming a cylindrical chamber, and where a cross-sectional area of the inside diameter of the accumulator is denoted Aac (mm ), a cross-sectional area of the inside diameter of a cylindrical chamber is denoted by Acy (mm2), a liquid holding capacity for an upper end of the suction tube, inside the accumulator , is denoted by Vac (cm ), a total displacement volume of the rotary compression mechanism section is denoted by Vcy (cm3), and a cross sectional area of the total inner diameter of an extended part, inside the suction tube accumulator, is denoted by As (mm2), the ratios of:

2. Sealed compressor according to claim 1, characterized in that the cross-sectional area of the inner diameter Acy (mm2) of a cylindrical chamber and the cross-sectional area of the inner diameter As (mm2) of the extended part, inside the suction tube accumulator, have a relationship of:

3. Sealed compressor according to claim 1, characterized in that the rotary compression mechanism section comprises two cylinders, provided with a dividing plate interposed between them, and, when an inner diameter of a cylindrical chamber is denoted by Dcy (mm) and the distance between the end surfaces of said two cylinders, opposite the dividing plate, is denoted by L (mm), a ratio of 0.9 <L/Dcy <1.1 is satisfied. 4. Sealed compressor according to claim 1, characterized in that the rotary compression mechanism section comprises two cylinders, provided with a dividing plate interposed between them, and two suction tubes, connecting the respective cylinders to the accumulator, and , when a distance between the axial centers of the respective cylinders is denoted by Lc (mm), and a distance between the axial centers of connecting parts of the two suction tubes, with the respective cylinders, is denoted by Lp (mm), a relation of Lp > Lc is satisfied. 5. Refrigeration cycle device, characterized in that it comprises: the sealed compressor as defined in any one of claims 1 to 4; a condenser connected to the sealed compressor; an expansion device connected to the condenser; and an evaporator connected to the expansion device.

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