KR101509378B1 - Hermetically sealed compressor and refrigeration cycle device - Google Patents

Abstract

In the hermetic compressor used in the refrigeration cycle apparatus of the embodiment, the rotary compression mechanism is housed in the closed casing, and the accumulator is provided outside the closed casing. The hermetic compressing device extends into the accumulator and sucks the working fluid through the at least one suction pipe connected to the rotary compression mechanism. The rotary compression mechanism includes one or more cylinders forming a cylinder chamber. The sealed compressor has an inner diameter cross sectional area Aac (mm 2), an inner diameter cross sectional area Acy (mm 2) of one cylinder chamber, Vac (cc) to the upper end of the suction pipe in the accumulator, a total displacement volume Vcy Ace / Acy ≤ 4, Vac / Vcy ≥ 20 and As / Acy ≥ 0.12 when the total inner diameter cross-sectional area of the extension portion in the accumulator of the suction pipe is defined as As (mm2).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hermetic compressor and a refrigerating cycle apparatus,

An embodiment of the present invention relates to a hermetic compressor and a refrigeration cycle apparatus.

BACKGROUND ART [0002] A refrigerating cycle apparatus such as an air conditioner is known in which a refrigerant compressed by a hermetic compressor is cyclically passed through an outdoor heat exchanger, an expansion device, and an indoor heat exchanger connected to a hermetic compressor through a four-way valve. The hermetic compressor used in such a refrigeration cycle apparatus has a rotary compression mechanism in its interior and an accumulator for preventing liquid back is used on the suction side. In addition, the hermetically sealed compressor is configured such that the number of revolutions thereof can be varied by an inverter.

Japanese Patent Application Laid-Open No. 2003-227486

In such a hermetic compressor, conventionally, the design is performed so that the characteristics at the time of operation at a rated rotation speed, for example, a rotation speed of 60 rps, are improved. Since the suction loss does not become a problem in the operation at the rated rotational speed, sufficient consideration is not given to the suction loss. However, it has been found that when the engine is operated at a rotational speed other than the rated rotational speed, for example, at a high rotational speed, the suction loss is increased, and the performance is considerably lowered.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a hermetic compressor and a refrigeration cycle apparatus capable of reducing the suction loss during high-speed rotation.

In the hermetic compressor of the embodiment, the rotary compression mechanism is housed in the closed casing, the accumulator is provided outside the closed casing, and the working fluid is supplied to the rotary compression mechanism through the at least one suction pipe extended and connected to the accumulator Wherein the rotary compression mechanism includes at least one cylinder defining a cylinder chamber, wherein an inner diameter cross-sectional area of the accumulator is Aac (mm 2), an inner diameter cross-sectional area of one cylinder chamber is Acy (mm 2) And the total internal diameter cross-sectional area of the extension portion of the suction pipe in the accumulator is As (mm 2), the total discharge (rejection) volume of the rotary compression mechanism portion is Vcy (cc) , Aac / Acy? 4, Vac / Vcy? 20, and As / Acy? 0.12.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an explanatory diagram schematically showing a configuration of a refrigeration cycle apparatus according to an embodiment,
Fig. 2 is a sectional view showing the construction of a hermetic compressor used in the refrigeration cycle apparatus,
Fig. 3 is an explanatory view showing the relationship between the total internal diameter cross-sectional area and the area ratio of the cylinder internal diameter cross-sectional area to the suction loss in the hermetic compressor,
Fig. 4 is an explanatory view showing the relationship between the total inner diameter cross-sectional area and the area ratio of the inner diameter cross-sectional area of the cylinder to the in-
5 is an explanatory view showing the relationship between the total internal diameter cross-sectional area and the area ratio of the cylinder internal diameter cross-sectional area to the suction loss in the hermetic compressor.

A refrigeration cycle apparatus 100 using the hermetic compressor 1 according to the present embodiment will be described with reference to Figs. 1 to 5. Fig.

Fig. 1 is an explanatory view schematically showing the configuration of the refrigeration cycle apparatus 100 according to the present embodiment. Fig. 2 is a schematic view showing the constitution of the hermetic compressor 1 and the accumulator 2 used in the refrigeration cycle apparatus 100 Fig. 3 is a cross-sectional view of the hermetically sealed compressor 1, showing the total inner diameter cross-sectional area As of the extension portion of the suction pipe of the hermetic compressor 1 and the area ratio As / Acy of the inner diameter cross-sectional area Acy of one cylinder chamber and the suction loss Ws 4 shows the relationship between the total inner diameter cross-sectional area As of the extension of the suction pipe of the hermetic compressor 1 and the inner diameter cross-sectional area Acy of one cylinder chamber Fig. 5 is an explanatory diagram showing the relationship between As / Acy and the in-pipe flow velocity Vs of the extension pipe in the accumulator of the suction pipe, Fig. 5 is a cross- And the suction loss rate Ws / Wth, as shown in Fig.

The refrigeration cycle apparatus 100 is used in an air conditioner. Hereinafter, the refrigeration cycle apparatus 100 will be described as the air conditioner 100. Fig.

1, the air conditioner 100 includes a hermetic compressor 1 having an accumulator 2 on the suction side, a four-way valve 101, an outdoor heat exchanger 102 as a heat source side heat exchanger, An expansion device 103, and an indoor heat exchanger 104 as a utilization side heat exchanger. In the air conditioner 100, the hermetic compressor 1, the four-way valve 101, the outdoor heat exchanger 102, the expansion device 103, and the indoor heat exchanger 104 communicate in a cyclic manner.

The four-way valve 101 is connected to the suction side of the accumulator 2 of the hermetic compressor 1 in the air conditioner 100. Further, the four-way valve 101 is connected to the discharge side of the hermetic compressor 1 in the air conditioner 100. The air conditioner 100 sequentially connects the outdoor heat exchanger 102, the expansion device 103 and the indoor heat exchanger 104 to the four-way valve 101 and switches the flow path of the four- So that the flow direction of the refrigerant discharged from the hermetic compressor (1) can be switched.

The hermetic compressor 1 includes a hermetically sealed container 10, a rotary compression mechanism 11 provided below the hermetically sealed container 10, a motor base 12 provided at an upper portion of the hermetically sealed container 10, A suction pipe 13 for the refrigerant provided in the indoor unit 10 and a discharge pipe 14 for the refrigerant provided in the sealed container 10 are provided. The hermetic compressor (1) has an accumulator (2) connected to the suction pipe (13).

The hermetically sealed container 10 is provided with an upper lid 10a for sealing the inside of the hermetically sealed container 10 and houses the rotary compression mechanism 11 and the motor base 12 therein and thereafter the upper lid 10a It is sealed by welding or the like.

The rotary compression mechanism 11 includes a first cylinder 21 and a second cylinder 22, a rotary shaft 23, a pair of rollers 24, a bearing 25, a partition plate 26, And a blade.

The first cylinder 21 forms a cylinder-shaped first cylinder chamber 21a. The first cylinder 21 has a blade storage groove communicating with the first cylinder chamber 21a and a suction port connected to the suction pipe 13 and communicating with the first cylinder chamber 21a. In the blade receiving groove, the blade is accommodated so as to protrude into the first cylinder chamber 21a.

The outer diameter of the first cylinder 21 is slightly smaller than the inner diameter of the hermetically sealed container 10. The first cylinder 21 is inserted into the hermetically sealed container 10 and is positioned and fixed to the inner peripheral surface of the hermetically sealed container 10 by welding processing from the outside of the hermetically sealed container 10. The first cylinder 21 has a communication hole 21b for communicating a space below the first cylinder 21 with a space above the first cylinder 21 when the first cylinder 21 is fixed to the hermetically sealed container 10, .

The second cylinder 22 forms a cylindrical second cylinder chamber 22a. The second cylinder 22 has a blade storage groove communicating with the second cylinder chamber 22a and a suction port connected to the suction pipe 13 and communicating with the second cylinder chamber 22a. In the blade receiving groove, the blade is rotatably received with respect to the second cylinder chamber 22a.

The first cylinder 21 and the second cylinder 22 are set so that the outer shape and the dimension are different from each other and the inner diameter dimension and the height dimension of the first cylinder chamber 21a and the second cylinder chamber 22a are the same .

The rotary shaft 23 is inserted into the first cylinder chamber 21a and into the second cylinder chamber 22a and is pivoted by the bearing 25. The rotary shaft 23 is provided with a crank eccentric portion 28 having a phase difference of, for example, about 180 degrees in the first cylinder chamber 21a and the second cylinder chamber 22a have.

The eccentric amounts of the two crank eccentric portions 28 are the same and the height dimension thereof is formed to be slightly smaller than the height dimension of the first cylinder chamber 21a and the second cylinder chamber 22a.

The rollers 24 are respectively engaged with the crank eccentric portions 28 and are slidable in the first cylinder chamber 21a and the second cylinder chamber 22a and are formed so as to be slidable with the ends of the blades have. The roller 24 is formed so that its height dimension is approximately equal to the height dimension of the first cylinder chamber 21a and the second cylinder chamber 22a.

Since the pair of rollers 24 are respectively provided in the crank eccentric portion 28 having a phase difference, there is a phase difference of about 180 degrees with each other. The roller 24 eccentrically rotates in the first and second cylinder chambers 21a and 22a. Since the inner diameter dimension and the height dimension of the first and second cylinder chambers 21a and 22a are the same and the eccentric amounts of the two crank eccentric portions 28 and 28 are the same, 22) are the same.

The bearing 25 includes a main bearing 31 provided on the upper surface portion of the first cylinder 21 covering the upper portion of the first cylinder chamber 21a and a second cylinder 21b covering the lower portion of the second cylinder chamber 22a And a sub bearing (32) provided on the lower surface of the base (22). The bearing 25 is pivotally rotatable about the rotary shaft 23 by a main bearing 31 and a sub bearing 32.

The main bearing 31 forms the upper surface of the first cylinder chamber 21a, and the roller 24 slides. The main bearing 31 is provided with a first valve cover 33 so as to cover the upper portion thereof. The main bearing 31 has a first discharge hole 34 for guiding the refrigerant from the first cylinder chamber 21a to the first valve cover 33 and a second discharge hole 34 for discharging the first discharge hole 34 And an opening / closing valve (35).

The sub bearing (32) forms the lower surface of the second cylinder chamber (22a), and the roller (24) slides. The sub-bearing 32 is provided with a second valve cover 36 so as to cover the lower portion thereof. The sub bearing 32 includes a second discharge hole 37 for guiding the refrigerant from the second cylinder chamber 22a to the second valve cover 36 and a second discharge hole 37 for opening and closing the second discharge hole 37 And an opening / closing valve (38).

In addition, the first cylinder 21, the second cylinder 22, the partition plate 26, the main bearing 31, the sub bearing 32, the first valve cover 33 and the second valve cover 36 Bolts B and the like, and fixed to the hermetically sealed container 10 via the first cylinder 21. [

The outer diameter of the partition plate 26 is larger than the inner diameter dimension of the first cylinder chamber 21a and the second cylinder chamber 22a and is larger than the outer dimension of the first cylinder 21 and the second cylinder 22 And is formed in a small diameter. The partition plate 26 is disposed so as to cover the first cylinder chamber 21a and the second cylinder chamber 22a.

The blade is formed so that its height dimension is approximately equal to the height dimension of the first and second cylinder chambers (21a, 22a). The tip of the blade is formed, for example, in a semicylindrical shape. The blade is pressed toward the roller 24 by the back pressure by applying a back pressure to the back surface of the roller 24 so that the leading end of the blade 24 is pressed against the roller 24 regardless of the rotation angle of the roller 24. [ And is formed in line contact with the outer circumferential surface.

The blade receiving grooves are provided in the first and second cylinders 21 and 22 such that the blades partition the inlet and the first and second discharge ports 34 and 37, respectively. The blade separates the first and second cylinder chambers (21a, 22a) into a suction chamber and a compression chamber by contacting the roller (24).

The motor base 12 includes a stator 51 fixed to the inner surface of the hermetically sealed container 10 and a rotor disposed in the stator 51 at a predetermined interval and fixed to the rotating shaft 23 52). The electric motor unit 12 is connected to, for example, an inverter that varies the operation frequency. The inverter is electrically connected to a control unit for controlling the inverter, and rotates the rotation speed of the rotation shaft 23 at an arbitrary number of rotations as required.

The two suction pipes 13 are connected to the suction ports of the first cylinder 21 and the second cylinder 22, respectively. The suction pipe 13 is bent upward at an angle of about 90 degrees in the middle portion projecting from the hermetically sealed container 10 and extends into the accumulator 2 and the end thereof is disposed at a predetermined height of the accumulator 2 . The height of the end portion of the suction pipe 13 extending into the accumulator 2 is appropriately set as necessary since the capacity of the liquid refrigerant and the lubricating oil that can be stored in the accumulator 2 vary depending on the height thereof.

The suction pipe 13 extends into the accumulator 2 and has an oil return hole 13a at a predetermined position in the height direction from the bottom surface of the accumulator 2. It is sufficient that the oil return hole 13a is capable of supplying the lubricating oil collected under the accumulator 2 to the first cylinder chamber 21a and the second cylinder chamber 22a simultaneously with the gaseous refrigerant, 2, the height thereof is set appropriately.

The discharge pipe 14 is connected to the upper end portion of the hermetically sealed container 10, specifically, the upper lid 10a. The discharge pipe (14) is connected to the four-way valve (101).

The accumulator 2 is provided with a cylindrical container 61 in which both ends thereof are closed and a gas-liquid separating section 62 provided in the container 61. The accumulator 2 has a structure in which the suction pipe 13 is inserted into the interior of the container 61 from the lower end thereof and the suction pipe 13 extends to just below the gas-liquid separation portion 62, A return pipe 63 for returning the refrigerant is connected. Further, the return pipe 63 is connected to the four-way valve 101.

The gas-liquid separator 62 is guiding means for the refrigerant to prevent the refrigerant returned from the return pipe 63 from directly entering the suction pipes 13 and 13 immediately below. That is, the gas-liquid separator 62 is formed so that the refrigerant of the gas-liquid mixture returned from the return pipe 63 can collide with and the refrigerant of the gas-liquid mixture that has collided can be guided in the direction of the inner peripheral surface of the container 61 .

The accumulator 2 is a so-called gas-liquid separator capable of storing liquid refrigerant and lubricating oil under the container 61 by the gas-liquid separator 62 and supplying the refrigerant of the gas from the suction pipe 13.

2, the inner diameter cross-sectional area of the container 61 of the accumulator 2 is defined as Aac (mm 2), the inner diameter of the first and second cylinder chambers 21a and 22a As (mm 2) represents the total internal cross-sectional area (the sum of the inner diameter cross-sectional areas of the two suction pipes) of the extensions of the accumulators in the accumulators of the suction pipes 13 and 13, Ac (mm 2) Vcy (cc) is the total displacement volume of the rotary compression mechanism 11 of the accumulator 2 (the sum of the displacement volumes of the first and second cylinders 21 and 22) (Inner diameter of one cylinder chamber) of the first and second cylinder chambers 21a and 22a to the upper end of the first cylinder 21 is denoted by Vac (cc) A distance Lc (mm) between the axial center of the first cylinder 21 and the axial center of the second cylinder 22, and Lc (mm) The two suction pipes (13, 13) (Mm) between the axial centers of the connecting portions of the first cylinder 21 and the second cylinder 22,

Aac / Acy≤4

0.12? As / Acy? 0.25

Vac / Vcy≥20

0.9? L / Dcy? 1.1

Lp> Lc

The respective dimensions of the hermetic compressor 1 are set.

The inner diameter cross-sectional area Aac of the accumulator 2 is the opening area of the trunk portion of the container 61 of the accumulator 2. The total inner diameter cross-sectional area As of the extension parts of the intake pipes 13, 13 in the accumulator is the sum of the opening areas of the two suction pipes 13 extending into the accumulator 2. The total displacement volume Vcy of the first and second cylinders 21 and 22 is the sum of the displacement volume of the first cylinder 21 between the inner peripheral surface of the first cylinder chamber 21a and the outer peripheral surface of the roller 24, , The sum of the displacement volume of the second cylinder 22 which is active between the inner peripheral surface of the second cylinder chamber 22a and the outer peripheral surface of the roller 24.

The low capacity capacity Vac of the accumulator 2 is a capacity capable of storing the liquid refrigerant and the lubricating oil in the accumulator 2 when the accumulator 2 performs the gas-liquid separation. Concretely, the capacity of the suction pipes 13 and 13 in the accumulator 2, The volume up to the water level at which the refrigerant of the liquid phase and the lubricating oil do not intrude becomes a low liquid capacity.

In the air conditioner 100 using the hermetically sealed compressor 1 configured as described above, power is first supplied to the electric motor unit 12 of the hermetic compressor 1 by a drive device such as an inverter, whereby the rotor 52 And the rotary shaft 23 fixed to the rotor 52 rotates. The crank eccentric portions 28 and 28 and the rollers 24 and 24 are eccentrically rotated by the rotation of the rotary shaft 23. The refrigerant sucked into the first cylinder chamber 21a and the second cylinder chamber 22a is compressed by the rotational sliding movement of the rollers 24 and 24.

When the rollers 24 and 24 are moved to the predetermined positions, the first and second open / close valves 35 and 38 are opened, and the first and second discharge holes 34 and 37 The refrigerant is discharged into the sealed container 10 through the first valve cover 33 and the second valve cover 36. [ The refrigerant discharged into the closed container 10 moves to the four-way valve 101 via the discharge pipe 14. [

Here, in the cooling operation of the air conditioner 100, the four-way valve 101 connects the secondary side of the hermetic compressor 1 and the outdoor heat exchanger 102. 1, the refrigerant compressed in the hermetic compressor 1 passes through the outdoor heat exchanger 102 and is heat-exchanged with the outside air to be condensed. Next, the condensed refrigerant passes through the indoor heat exchanger (104) through the expansion device (103), performs heat exchange with the room air, evaporates, and cools the room air.

The refrigerant having passed through the indoor heat exchanger (104) passes through the four-way valve (101) and moves to the accumulator (2). Liquid refrigerant and lubricating oil are stored in the accumulator 2 by the gas-liquid separator 62 and the gaseous refrigerant is sucked into the hermetic compressor 1 from the suction pipe 13. At this time, the stored lubricating oil is sucked from the oil return hole 13a and sucked into the first cylinder chamber 21a and the second cylinder chamber 22a together with the gaseous refrigerant. By this repetition, the air conditioner 100 performs heat exchange as a cooling operation.

Further, in the heating operation of the air conditioner 100, the four-way valve 101 connects the secondary side of the hermetic compressor 1 and the indoor heat exchanger 104. 1, the refrigerant compressed in the hermetic compressor 1 passes through the indoor heat exchanger 104, performs heat exchange with the indoor air, and is condensed. The condensed refrigerant passes through the expansion device 103, passes through the outdoor heat exchanger 102, and performs heat exchange with the outdoor air in the outdoor heat exchanger 102 to evaporate. The evaporated refrigerant is gas-liquid separated through the four-way valve 101 and the accumulator 2 and sucked into the hermetic compressor 1. [ By this repetition, the air conditioner 100 performs heat exchange as a heating operation.

Next, the basis of the setting of the respective dimensions of the hermetic compressor 1 according to the present embodiment will be described in detail with reference to Figs. 3 to 5. Fig.

Sectional area Aac (mm 2) of the container 61 of the accumulator 2 and the inner diameter cross-sectional area of the first and second cylinder chambers 21a and 22a (one cylinder If the ratio Aac / Acy of Acy (mm 2) is larger than 4, the inner diameter of the accumulator 2 becomes larger, the size of the hermetic compressor 1 becomes larger, the weight balance becomes worse, and the installation property also decreases. On the other hand, in the hermetic compressor 1 of the present embodiment, the accumulator and the hermetic compressor 1 as a whole can be reduced in size by setting the ratio Aac / Acy to 4 or less, and the weight balance and the installation property can be improved.

In addition, when the ratio Aac / Acy is simply set to 4 or less, the inner diameter of the accumulator 2 becomes small, and the gas-liquid separating function may be deteriorated. Therefore, as a result of various experiments repeatedly, it has been found that the low liquid capacity Vac from the bottom surface of the container 61 of the accumulator 2 to the upper end of the suction pipe 13 and the total displacement volume of the rotary compression mechanism section 11 The sum of the displacement amounts of the first and second cylinders 21 and 22] Vcy is 20 or more, sufficient liquid storage capacity can be ensured and liquid crystal can be prevented.

The total inner diameter cross-sectional area (the sum of the inner diameter cross-sectional areas of the two suction pipes) As and the inner diameter cross-sectional area of the first and second cylinder chambers 21a and 22a (the inner diameter of one cylinder chamber The ratio As / Acy of the intake air amount As (Ac) (area of cross section) Acy (mm 2) and the ratio Ws / Wth of the intake air loss Ws at the extension portion in the accumulator of the intake pipes 13, 13 to the compressor theoretical Wth are as shown in Fig. That is, in Fig. 3, the horizontal axis represents the ratio As / Acy and the vertical axis represents the ratio Ws / Wth. 3, it can be seen that when Ws / Wth becomes larger as As / Acy becomes smaller, and particularly when As / Acy becomes smaller than 0.12, the ratio of Ws / Wth, that is, have.

As described above, by setting As / Acy to 0.12 or more, the suction loss Ws of the suction pipes 13, 13 in the accumulator 2 with respect to the compressor theoretical work Wth is set to approximately 2% or less Lt; / RTI > Here, the compressor theoretical work Wth is the theoretical work derived by the design calculation of the hermetic compressor 1. [

3 is a graph showing the relationship between the height of the first cylinder 21 and the height of the second cylinder 22 in the structure using the two cylinders of the first cylinder 21 and the second cylinder 22 in this embodiment In the one-cylinder type closed-type compressor having the first cylinder 21 and the second cylinder 22 each having a height of 22 mm and only one cylinder, the height of the cylinder is 20 Mm, and a one-cylinder-type hermetic compressor with a cylinder height of 25 mm, and their measurement characteristics are shown. As shown in Fig. 3, all the characteristics of the four kinds of hermetic compressors are superimposed on roughly the same curves. In each of the four types of hermetic compressors, the inner diameter of each cylinder chamber is 43 mm, and the characteristics are measured by adjusting the operation revolution speed so that the refrigerant is R410A and the refrigeration capacity is 15 kw.

3, it is possible to reduce the suction loss rate Ws / Wth (%) irrespective of the number of cylinders and the volume, and to prevent a sudden increase in suction loss by setting As / Acy≥0.12 It becomes.

4 shows the relationship between the total inner diameter cross-sectional area As of the extension of the suction pipe of the hermetic compressor 1 in the accumulator and the area ratio As / Acy of the inner diameter cross-sectional area Acy of one cylinder chamber as the abscissa, and the in- m / s) is taken as the vertical axis.

In the case where As / Acy is set to 0.12 or more, as shown in Fig. 4, in the case of using one cylinder and two cylinders as the As / Acy becomes larger, the flow velocity Vs of the suction pipe 13 in the accumulator 2 (m / s) is in a decreasing tendency.

A lubricating oil is supplied from the oil return hole 13a to the first cylinder chamber 21a and the second cylinder chamber 21b from the oil return hole 13a for returning the lubricating oil stored in the accumulator 2 to the suction pipe 13 in the accumulator 2, And returns to the second cylinder chamber 22a. Here, if the in-pipe flow velocity Vs decreases, there is a fear that oil return from the oil return hole 13a is not sufficiently performed.

However, as shown in Fig. 4, by satisfying As / Acy ≤ 0.25, the in-pipe flow velocity Vs can be maintained at 1 (m / s) or more and oil return by the oil return hole 13a can be reliably It becomes possible to execute it.

5 shows the relationship between the area ratio As / Acy in the hermetic compressor 1 at the rated rotational speed (60 rps) and the high rotational speed (125 rps), and the ratio Ws / Wth of the suction loss Ws to the compressor theoretical work Wth Fig.

5, the suction loss rate Ws / Wth (%) can be obtained not only at the rated rotation speed (60 rps) but also at the high rotation speed (125 rps) by setting 0.12? As / Acy? 0.25 and Vac / Vcy? It is possible to reduce the suction loss, and it is possible to prevent the suction loss from increasing.

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 of the first and second cylinders 21 and 22 (inner diameter of one cylinder chamber) (Thickness) of the first and second cylinders 21 and 22 is made small and the suction port connecting the suction tubes 13 and 13 is also small, so that the suction loss (L / Dcy) Lt; / RTI > On the other hand, if L / Dcy is larger than 1.1, the distance between the bearings becomes longer, and the rotary shaft is bent by the compressive load, and the performance is lowered.

On the other hand, by making 0.9? L / Dcy? 1.1, it is possible to secure a large intake port for the first cylinder 21 and the second cylinder 22, and to suppress the increase in the distance between the bearings, .

Further, 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 Lc (mm) between the second cylinder 22 and the first cylinder 21 It is possible to increase the distance Lp between the centers of the suction pipes 13, 13 by setting the relationship Lp (mm) between the axes of the connecting portions with the cylinder 22 to be Lp> Lc. That is, when the suction pipes 13 and 13 are connected to the hermetically sealed container 10, the members for connecting the suction pipes 13 and 13 by welding are connected to the hermetically sealed container 10. Therefore, by making the distance Lp between the centers of the suction pipes 13, 13 as large as possible, it is possible to prevent the strength from being lowered by welding.

As described above, according to the air conditioner 100 using the hermetic compressor 1 according to the present embodiment, even when the hermetic compressor 1 is operated at a high speed, the sudden increase in suction loss can be prevented So that the suction loss can be reduced. Further, according to the air conditioner 100 using the hermetic compressor 1, it is possible to reliably perform the oil return and improve the reliability.

The present invention is not limited to the refrigeration cycle apparatus 100 using the hermetic compressor 1 of the present embodiment. In the hermetic compressor 1 of the above-described embodiment, a structure in which two cylinders of the first cylinder 21 and the second cylinder 22 are used as the cylinder has been described, but the present invention is not limited thereto. In the relation of Aac / Acy? 4, 0.12? As / Acy? 0.25, and Vac / Vcy? 20 described above, one cylinder or three or more cylinders may be used.

3 and 4, as in the case of the hermetically sealed compressor 1 of the present embodiment using two cylinders, even in the case of one cylinder, it is possible to reduce the suction loss, It is possible to set the flow velocity Vs of the suction pipe 13 to be in the pipe. It is also possible to obtain the same effect with three cylinders.

In the above-described example, the refrigeration cycle apparatus 100 has been described as having the four-way valve 101 as the air conditioner 100, but the present invention is not limited thereto. For example, Alternatively, it may be a refrigeration cycle apparatus 100 that performs only heating operation or cooling operation, or may be a refrigeration cycle apparatus other than the air conditioner.

Furthermore, in the above-described example, the hermetic compressor 1 has been described using the configuration in which the roller 24 and the blade are separate members, but the invention is not limited thereto. For example, an equivalent effect can be obtained in a swing type hermetic compressor in which a roller and a blade are integrated.

While several embodiments of the invention have been described, these embodiments are provided by way of example and are not intended to limit the scope of the invention. These new embodiments can be implemented in various other forms, and various omissions, substitutions, and alterations can be made without departing from the gist of the invention. These embodiments and their modifications fall within the scope and spirit of the invention, and are included in the scope of the invention as defined in the claims and their equivalents.

The present invention relates to a compressor of a hermetic type and an accumulator of an internal combustion engine in which an internal combustion engine is provided with an internal combustion engine and an internal combustion engine. A first cylinder 21a a first cylinder chamber 21b a communicating hole 22 a second cylinder 22a a second cylinder chamber 23 a rotating shaft 24 roller 25 bearing 26 partition plate 31 35: first opening / closing valve, 36: second valve cover, 37: second discharge hole, 38: second opening / closing valve, The present invention relates to a refrigeration cycle apparatus and a refrigeration cycle apparatus which are provided with a refrigeration cycle apparatus and a refrigeration cycle apparatus in which a refrigeration cycle apparatus and a refrigeration cycle apparatus are provided. Device, 104: indoor heat exchanger

Claims (5)

A hermetic compressor which houses a rotary compression mechanism in a hermetically sealed case, an accumulator provided outside the hermetic casing, and a working fluid is sucked into the rotary compression mechanism through at least one suction pipe extending into the accumulator,
Wherein the rotary compression mechanism includes one or more cylinders forming a cylinder chamber,
(AIC), the inner diameter cross-sectional area of one of the cylinder chambers is Acy (mm < 2 >), the low liquid capacity to the upper end of the suction pipe in the accumulator is Vac (cc), the total displacement volume of the rotary compression mechanism Vcy (cc) and the total internal cross-sectional area of the extension of the suction pipe in the accumulator is As (mm < 2 >),
Aac / Acy≤4
Vac / Vcy≥20
As / Acy≥0.12
, And the relationship
Hermetic compressor. The method according to claim 1,
Sectional area As (mm 2) of the one cylinder chamber and the total inner diameter cross-sectional area As (mm 2) of the extension portion of the intake pipe in the accumulator,
As / Acy? 0.25
, And the relationship
Hermetic compressor. The method according to claim 1,
Wherein the rotary compression mechanism includes two cylinders with a partition plate interposed therebetween,
When the inner diameter of one of the cylinder chambers is Dcy (mm) and the distance between the end faces of the two cylinders opposite to the partition plate side is L (mm)
0.9? L / Dcy? 1.1
, And the relationship
Hermetic compressor. The method according to claim 1,
Wherein the rotary compression mechanism includes two cylinders with a partition plate interposed therebetween and two suction pipes connecting the cylinders and the accumulator,
(Mm) is a distance between the axial centers of the respective cylinders and Lp (mm) is a distance between the axes of the connecting portions of the two suction pipes with the cylinder,
Lp> Lc
, And the relationship
Hermetic compressor. A hermetically sealed compressor according to any one of claims 1 to 4,
A condenser connected to the hermetic compressor,
An expansion device connected to the condenser,
And an evaporator connected to the expansion device
Refrigeration cycle equipment.

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