A refrigeration cycle device includes a compressor which compresses a gaseous refrigerant. The compressor includes a compressor main body and an accumulator. The accumulator performs gas-liquid separation of a refrigerant and supplies a gaseous refrigerant to the compressor main body.
Compressors are required to be made compact.
In embodiments, a compressor includes a compressor main body, an accumulator, and three suction pipes. The compressor main body houses a plurality of compression mechanism units and an electric motor unit driving the plurality of compression mechanism units in a case. The accumulator is supported by the compressor main body and includes a refrigerant introduction part at an upper portion thereof. Three suction pipes penetrate a bottom portion of the accumulator, have one end sides which open inside the accumulator, and have the other end sides connected to three suction ports provided in the case. The three suction pipes are a first suction pipe, a second suction pipe, and a third suction pipe. The three suction pipes are disposed so that a first center of a first flow path cross section of the first suction pipe, a second center of a second flow path cross section of the second suction pipe, and a third center of a third flow path cross section of the third suction pipe are positioned at vertices of a triangle in a portion penetrating the bottom portion of the accumulator when viewed from above the accumulator. The first suction pipe is disposed so that a first distance between the first center and a center of the compressor main body is smaller than a second distance between the second center and the center of the compressor main body and a third distance between the third center and the center of the compressor main body. The first suction pipe is disposed so that the first flow path cross section overlaps a center connection line passing through the center of the compressor main body and a center of the accumulator when viewed from above the accumulator. The second suction pipe and the third suction pipe are disposed so that the second flow path cross section and the third flow path cross section are positioned on opposite sides of the center connection line sandwiched therebetween when viewed from above the accumulator. The other end side of the first suction pipe is connected to a suction port which is at an uppermost position among the three suction ports.
Hereinafter, a compressor 2 and a refrigeration cycle device 1 of the embodiment will be described with reference to the drawings.
In the present application, an X direction, a Y direction, and a Z direction are defined as follows. The X direction is a direction in which a compressor main body 10 and an accumulator 50 are aligned, and a +X direction is a direction from the compressor main body 10 toward the accumulator 50. The Z direction is a direction parallel to a central axis of the compressor main body 10, and a +Z direction is a direction from a compression mechanism unit 20 toward an electric motor unit 15. The Y direction is a direction perpendicular to the X direction and the Z direction. The X direction and the Y direction may be, for example, horizontal directions. The Z direction may be, for example, a vertical direction, and the +Z direction may be, for example, vertically upward.
The refrigeration cycle device 1 will be briefly described.
As illustrated in
The compressor 2 is a so-called rotary type compressor. The compressor 2, for example, compresses a low-pressure gaseous refrigerant (fluid) taken into the inside into a high-temperature and high-pressure gaseous refrigerant. A specific configuration of the compressor 2 will be described below.
The condenser 3 radiates heat from the high-temperature and high-pressure gaseous refrigerant discharged from the compressor 2 to convert the high-temperature and high-pressure gaseous refrigerant into a high-pressure liquid refrigerant.
The expansion device 4 reduces a pressure of the high-pressure liquid refrigerant sent from the condenser 3 to convert the high-pressure liquid refrigerant into a low-temperature and low-pressure liquid refrigerant.
The evaporator 5 evaporates the low-temperature and low-pressure liquid refrigerant sent from the expansion device 4 to convert the low-temperature and low-pressure liquid refrigerant into a low-pressure gaseous refrigerant. In the evaporator 5, evaporation of the low-pressure liquid refrigerant takes evaporation heat from the surroundings, and thus the surroundings are cooled. Further, the low-pressure gaseous refrigerant that has passed through the evaporator 5 is taken into the compressor 2 described above.
As described above, in the refrigeration cycle device 1 of the present embodiment, a refrigerant serving as a working fluid circulates while changing its phase between a gaseous refrigerant and a liquid refrigerant, in which heat is radiated in the process of changing phase from the gaseous refrigerant to the liquid refrigerant, and heat is absorbed in the process of changing phase from the liquid refrigerant to the gaseous refrigerant. Thus, heating, cooling, or the like is performed by utilizing such heat radiation and heat absorption.
The compressor 2 of a first embodiment will be described.
The compressor 2 includes the compressor main body 10 and the accumulator 50.
The compressor main body 10 includes a shaft 13, the electric motor unit 15 which rotates the shaft 13, a plurality of compression mechanism units 20 which compress a gaseous refrigerant by rotation of the shaft 13, and a cylindrical case 11 which houses the shaft 13, the electric motor unit 15 and the compression mechanism unit 20.
The shaft 13 is disposed along the central axis of the compressor main body 10.
The electric motor unit 15 is disposed in the +Z direction of the shaft 13. The electric motor unit 15 includes a stator 15a and a rotor 15b. The stator 15a is fixed to an inner circumferential surface of the case 11. The rotor 15b is fixed to an outer circumferential surface of the shaft 13. The electric motor unit 15 rotates the shaft 13 inside the case 11.
The case 11 is formed in a cylindrical shape with both end portions closed. The case 11 includes a discharge part 19 at an upper end portion. The discharge part 19 is formed by a pipe and is disposed along a central axis of the case 11. The discharge part 19 has a discharge port at an upper end portion. The discharge part 19 discharges the gaseous refrigerant inside the case 11 from the discharge port.
The plurality of compression mechanism units 20 are disposed in the −Z direction of the shaft 13. The plurality of compression mechanism units 20 may include three compression mechanism units 20 including, for example, a first compression mechanism unit 21, a second compression mechanism unit 22, and a third compression mechanism unit 23. The first compression mechanism unit 21, the second compression mechanism unit 22, and the third compression mechanism unit 23 are disposed to be aligned in that order from the +Z direction to the −Z direction. The first compression mechanism unit 21 is at an uppermost position in the +Z direction among the plurality of compression mechanism units 20. Hereinafter, a configuration of the first compression mechanism unit 21 will be described as a representative. The configurations of the second compression mechanism unit 22 and the third compression mechanism unit 23 are the same as that of the first compression mechanism unit 21 except for a direction of eccentricity of an eccentric part 32.
The first compression mechanism unit 21 includes the eccentric part 32, a roller 33, a cylinder 35, a bearing 17, and a partition plate 25.
The eccentric part 32 is formed integrally with the shaft 13 in a columnar shape. When viewed from the +Z direction, a center of the eccentric part 32 is eccentric from a central axis of the shaft 13.
The roller 33 is formed in a cylindrical shape and is disposed along an outer circumference of the eccentric part 32.
The cylinder 35 is fixed to a frame 20a, and an outer circumferential surface of the frame 20a is fixed to an inner circumferential surface of the case 11. The cylinder 35 includes a cylinder chamber 36, a vane (not illustrated), and a suction hole 38. The cylinder chamber 36 houses the eccentric part 32 and the roller 33 inside. The vane is housed in a vane groove formed in the cylinder 35 and can advance into and retreat from an inside of the cylinder chamber 36. The vane is biased such that a distal end portion thereof is brought into contact with an outer circumferential surface of the roller 33. The vane, together with the eccentric part 32 and the roller 33, partitions the inside of the cylinder chamber 36 into a suction chamber and a compression chamber. The suction hole 38 is formed from an outer circumferential surface of the cylinder 35 in contact with the inner circumferential surface of the case 11 to the cylinder chamber 36. The suction hole 38 introduces a gaseous refrigerant into the suction chamber of the cylinder chamber 36. A first suction port 26 facing the suction hole 38 is provided in the case 11.
Similarly to the first suction port 26, a second suction port 27 is provided to face the suction hole 38 of the second compression mechanism unit 22, and a third suction port 28 is provided to face the suction hole 38 of the third compression mechanism unit 23.
The bearing 17 and the partition plate 25 are disposed on both sides of the cylinder 35 in the Z direction. The bearing 17 and the partition plate 25 close both end portions of the cylinder chamber 36 in the Z direction. The bearing 17 and the partition plate 25 have a discharge hole. The discharge hole discharges a gaseous refrigerant compressed in the compression chamber of the cylinder chamber 36 to the inside of the case 11.
An operation of the first compression mechanism unit 21 will be described.
When the electric motor unit 15 rotates the shaft 13, the eccentric part 32 and the roller 33 eccentrically rotate inside the cylinder chamber 36. When the roller 33 rotates eccentrically, a gaseous refrigerant is suctioned into the suction chamber of the cylinder chamber 36, and the gaseous refrigerant in the compression chamber is compressed. The compressed gaseous refrigerant is discharged from the discharge hole of the bearing 17 and the partition plate 25 to the inside of the case 11. The gaseous refrigerant inside the case 11 is discharged from the discharge part 19 to the outside of the case 11.
The accumulator 50 will be described.
The accumulator 50 includes a case 51, a plurality of suction pipes 40, and a strainer plate 60. The accumulator 50 separates an introduced refrigerant into a gaseous refrigerant and a liquid refrigerant. The liquid refrigerant is stored in a bottom portion of the case 51. The gaseous refrigerant is supplied to the compressor main body 10 through the suction pipes 40.
The case 51 is formed in a cylindrical shape with both end portions closed. The case 51 is formed by connecting a first case 51a in the +Z direction and a second case 51b in the −Z direction. Through holes 58 through which the plurality of suction pipes 40 pass are formed in the bottom portion of the case 51. The case 51 is supported by the compressor main body 10 via a bracket 55 and a belt 56 (see
The case 51 includes an introduction part 59 and a retainer 52.
The introduction part 59 is provided at an upper end portion of the case 51. The introduction part 59 is formed by a pipe and is disposed along a central axis of the case 51. The introduction part 59 has an introduction port of a refrigerant at the upper end portion. The introduction part 59 introduces a refrigerant into the case 51 from the introduction port.
The retainer 52 is provided inside the case 51. The retainer 52 is formed in a ring shape, and an outer circumferential surface thereof is fixed to an inner circumferential surface of the case 51. The retainer 52 increases rigidity of the case 51.
The plurality of suction pipes 40 will be described in detail.
The plurality of suction pipes 40 are three suction pipes including a first suction pipe 41, a second suction pipe 42, and a third suction pipe 43. The three suction pipes 41, 42, and 43 are provided through a through hole 58 formed in the bottom portion of the case 51. The three suction pipes 41, 42, and 43 are formed by connecting external suction pipes 41a, 42a, and 43a disposed outside the case 51 and internal suction pipes 41b, 42b, and 43b disposed inside the case 51 in the vicinity of the bottom portion of the case 51. Since the external suction pipes 41a, 42a, and 43a are in contact with air, the external suction pipes 41a, 42a, and 43a are formed of a copper material or the like having corrosion resistance. Since the internal suction pipes 41b, 42b, and 43b are not in contact with air, the internal suction pipes 41b, 42b, and 43b are formed of a low-cost steel material or the like. Further, the external suction pipes 41a, 42a, and 43a and the internal suction pipes 41b, 42b, and 43b may be integrally formed of the same material.
The internal suction pipes 41b, 42b, and 43b each have a straight central axis. The central axes of the internal suction pipes 41b, 42b, and 43b are disposed parallel to the central axis of the case 51 of the accumulator 50. End portions of the internal suction pipes 41b, 42b, and 43b in the +Z direction open inside the case 51. Outflow holes 49 of a liquid refrigerant are formed in lower portions of the internal suction pipes 41b, 42b, and 43b. The liquid refrigerant accumulated in the lower portion of the case 51 flows out of the outflow holes 49 little by little to the internal suction pipes 41b, 42b, and 43b in addition to being evaporated inside the case 51.
End portions of the external suction pipes 41a, 42a, and 43a in the −Z direction are curved toward the compressor main body 10. The end portions of the external suction pipes 41a, 42a, and 43a in the −Z direction are respectively connected to the three suction ports 26, 27, and 28 of the compressor main body 10 to communicate with the suction holes 38 of the cylinder 35. That is, the first suction pipe 41 is connected to the suction hole 38 of the cylinder 35 of the first compression mechanism unit 21 through the first suction port 26 and is brazed to the first suction port 26 outside the case 11. The second suction pipe 42 is connected to the suction hole 38 of the cylinder 35 of the second compression mechanism unit 22 through the second suction port 27 and is brazed to the second suction port 27 outside the case 11. The third suction pipe 43 is connected to the suction hole 38 of the cylinder 35 of the third compression mechanism unit 23 through the third suction port 28 and is brazed to the third suction port 28 outside the case 11.
When the accumulator 50 is made compact, components for an accumulator having two suction pipes can be used for components of the accumulator 50.
The compressor main body 10 vibrates in accordance with eccentric rotation of the eccentric part 32 and the roller 33. When the accumulator 50 is made compact, a distance between a center 10c of the compressor main body 10 and a center 50c of the accumulator 50 decreases as illustrated in
A first distance S1 between the first center 41c and the center 10c of the compressor main body 10, a second distance S2 between the second center 42c and the center 10c of the compressor main body 10, and a third distance S3 between the third center 43c and the center 10c of the compressor main body 10 are defined as illustrated in
As illustrated in
The first suction pipe 41 is disposed to satisfy the following. As illustrated in
The second suction pipe 42 and the third suction pipe 43 are disposed to satisfy the following. As illustrated in
As illustrated in
As illustrated in
As described above, the first suction pipe 41 has the following configuration. The first suction pipe 41 is disposed closer to the compressor main body 10 than the second suction pipe 42 and the third suction pipe 43 are. When viewed from the +Z direction, the first flow path cross section 41s of the first suction pipe 41 overlaps the center connection line CL. The first suction pipe 41 is connected to the first suction port 26 which is at the uppermost position among the three suction ports 26, 27, and 28. When viewed from the +Z direction, the first suction port 26 overlaps the center connection line CL.
Thereby, a length of the first suction pipe 41 decreases. Therefore, heat loss of a gaseous refrigerant flowing through the first suction pipe 41 decreases, improving efficiency of the compressor 2. Also, as illustrated in
The second suction pipe 42 and the third suction pipe 43 have the following configuration. The second suction pipe 42 and the third suction pipe 43 are disposed farther from the compressor main body 10 than the first suction pipe 41 is. When viewed from the +Z direction, the second flow path cross section 42s of the second suction pipe 42 and the third flow path cross section 43s of the third suction pipe 43 are positioned on opposite sides of the center connection line CL sandwiched therebetween. The third suction pipe 43 is connected to the third suction port 28 of the third compression mechanism unit 23 which is at the lowermost position. The second suction pipe 42 is connected to the second suction port 27 of the second compression mechanism unit 22 positioned in the middle in the Z direction. When viewed from the +Z direction, the second suction port 27 and the third suction port 28 overlap the center connection line CL.
Thereby, as illustrated in
As illustrated in
The strainer plate 60 includes a plate main body 61 and the net member 68. The net member 68 is disposed in the +Z direction of the plate main body 61. The net member 68 captures foreign substances contained in the refrigerant introduced from the introduction part 59.
The plate main body 61 is formed in a disc shape using a steel plate material or the like. The plate main body 61 includes a rectifying part 62. The rectifying part 62 is formed at an intermediate portion in a radial direction of the plate main body 61. The rectifying part 62 is formed to be recessed in the −Z direction from the plate main body 61. A surface of the rectifying part 62 in the +7 direction is an inclined surface 63 which is inclined in the −Z direction outward in the radial direction of the plate main body 61. An opening 64 is formed at an end portion of the rectifying part 62 on a radially outward side of the plate main body 61. The opening 64 opens outward in the radial direction of the plate main body 61. The rectifying part 62 rectifies the refrigerant introduced from the introduction part 59 outward in the radial direction of the plate main body 61.
As illustrated in
In the opening 64 of the rectifying part 62, a point positioned on an innermost side in the radial direction of the plate main body 61 is defined as an innermost point 64p. A center of an innermost circle 64r including the innermost points 64p of the plurality of rectifying parts 62 coincides with the center 50c of the accumulator 50. On the other hand, a center of a circumscribed circle 40r circumscribing the three suction pipes 41, 42, and 43 inside the case 51 also coincides with the center 50c of the accumulator 50. A diameter DS of the innermost circle 64r of the opening 64 of the rectifying part 62 is larger than a diameter D1 of the circumscribed circle 40r of the three suction pipes 41, 42, and 43. Thus, even when a liquid refrigerant that has passed through the opening 64 falls in the −Z direction, the liquid refrigerant does not flow into the three suction pipes 41, 42, and 43. Therefore, gas-liquid separation performance of the accumulator 50 is improved.
As described in detail above, the compressor 2 of the present embodiment has the following configuration. The compressor 2 includes the three suction pipes 41, 42, and 43. The first center 41c of the first suction pipe 41, the second center 42c of the second suction pipe 42, and the third center 43c of the third suction pipe 43 are positioned at vertices of the triangle TR. The first distance S1 between the first center 41c and the center 10c of the compressor main body 10 is smaller than the second distance S2 between the second center 42c and the center 10c of the compressor main body 10 and the third distance S3 between the third center 43c and the center 10c of the compressor main body 10. The first flow path cross section 41s of the first suction pipe 41 overlaps the center connection line CL passing through the center 10c of the compressor main body 10 and the center 50c of the accumulator 50. The second flow path cross section 42s of the second suction pipe 42 and the third flow path cross section 43s of the third suction pipe 43 are positioned on opposite sides of the center connection line CL sandwiched therebetween. The first suction pipe 41 is connected to the first suction port 26 which is at the uppermost position among the three suction ports 26, 27, and 28.
Since the first center 41c, the second center 42c, and the third center 43c are positioned at vertices of the triangle TR, the three suction pipes 41, 42, and 43 are disposed close to each other. Therefore, the accumulator 50 is made compact. Also, a length of the first suction pipe 41 decreases, and the shape is simplified. Therefore, material costs and processing costs of the first suction pipe 41 are suppressed. Also, lengths of the second suction pipe 42 and the third suction pipe 43 are not unnecessarily large, and curved shapes thereof are gently and smoothly realized. Therefore, material costs and processing costs of the second suction pipe 42 and the third suction pipe 43 are suppressed.
The three suction pipes 41, 42, and 43 are disposed such that all the interior angles of the triangle TR are less than 90 degrees. Thereby, the accumulator 50 is made compact.
The three suction ports 26, 27, and 28 are disposed to overlap the center connection line CL when viewed from above the accumulator 50. Thus, the three suction pipes 41, 42, and 43 are connected to the three suction ports 26, 27, and 28 from the same direction. Therefore, connection work of the three suction pipes 41, 42, and 43 is simplified.
A compressor 202 according to a second embodiment will be described.
The compressor 202 includes an accumulator 250. The accumulator 250 includes a case 251, a plurality of suction pipes 240, and a columnar member 245. The plurality of suction pipes 240 are three suction pipes including a first suction pipe 241, a second suction pipe 242, and a third suction pipe 243. The three suction pipes 241, 242, and 243 include external suction pipes 241a, 242a, and 243a and internal suction pipes 241b, 242b, and 243b.
As illustrated in
In the first embodiment illustrated in
In contrast, in the second embodiment illustrated in
A compressor 302 of a first modified example of the second embodiment will be described.
The compressor 302 includes the accumulator 350. The accumulator 350 includes a plurality of suction pipes 340 and a columnar member 345. The plurality of suction pipes 340 are three suction pipes including a first suction pipe 341, a second suction pipe 342, and a third suction pipe 343. The columnar member 345 includes three columnar member suction passages 341m, 342m, and 343m.
The columnar member 345 penetrates a bottom portion of the case 251 and extends to an upper portion of the case 251. The three columnar member suction passages 341m, 342m, and 343m open at an upper end portion of the columnar member 345. The three suction pipes 341, 342, and 343 are formed by the external suction pipes 241a, 242a, and 243a and the columnar member suction passages 341m, 342m, and 343m. The columnar member suction passages 341m, 342m, and 343m also serve as the internal suction pipes 241b, 242b, and 243b illustrated in
A compressor 402 of a second modified example of the second embodiment will be described.
The compressor 402 includes the accumulator 450. The accumulator 450 includes a plurality of suction pipes 440. The plurality of suction pipes 440 are three suction pipes including a first suction pipe 441, a second suction pipe 442, and a third suction pipe 443.
The accumulator 450 of the present modified example includes the same columnar member 245 as in the second embodiment. A cylindrical common suction pipe 440b is connected to an end portion of the columnar member 245 in the +Z direction. An outer diameter of the common suction pipe 440b is formed, for example, to be equal to an outer diameter of the columnar member 245. Upper end portions of the columnar member suction passages 241m, 242m, and 243m open inside the common suction pipe 440b. A central axis of the common suction pipe 440b of the columnar member 245 is parallel to the Z direction. The common suction pipe 440b extends to an upper portion of the case 251. An upper end portion of the common suction pipe 440b opens inside the case 251. The three suction pipes 441, 442, and 443 are formed by the external suction pipes 241a, 242a, and 243a, the columnar member suction passages 241m, 242m, and 243m, and the common suction pipe 440b. The common suction pipe 440b also serves as the internal suction pipes 241b, 242b, and 243b illustrated in
The compressor of the embodiment includes three compression mechanism units for three suction pipes. The compressor may include four or more compression mechanism units for three suction pipes. In this case, a suction hole communicating with a pair of compression mechanism units is formed in a partition plate that partitions the pair of compression mechanism units, and a suction pipe is connected to the suction hole.
According to at least any one embodiment described above, as illustrated in
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other fat its; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2018-006768 | Jan 2018 | JP | national |
This is a Continuation Application of International Application No. PCT/JP2018/037074, filed on Oct. 3, 2018, which is based upon and claims the benefit of priority from Japanese Patent Application No. 2018-006768, filed on Jan. 18, 2018; the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/JP2018/037074 | Oct 2018 | US |
Child | 16916319 | US |