This disclosure belongs to the field of compressor manufacturing, in particular, relating to a small-sized sealed refrigeration compressor housing.
Currently in the field of sealed refrigeration compressors for refrigerators, a compressor housing generally is made by snap fitting together an upper cover and a lower shell. The upper cover and the lower shell each have a cylindrical shape with an elliptical cross-section. The major axial centerlines of the elliptical cross-section of the upper cover and the lower shell are aligned with each other. A terminal pin bore of the lower shell has a centerline of symmetry in a horizontal direction (also known as a terminal pin bore centerline). The centerline of the terminal pin bore is designed to align with the major axial centerlines of the upper cover and the lower shell. Meanwhile, in order to simplify the process of welding compressor feet onto the bottom of the lower shell, planes for welding the compressor feet are symmetrically positioned on opposite sides of the major axial centerline of the upper cover and the lower shell. When this symmetrical design is utilized, the production and its related processing technology are relatively simple, and the compressor takes on a symmetrical and aesthetically pleasing appearance. However, the space utilization of the compressor housing is not optimal, and the external dimensions and weight of the housing are also consequentially increased. In order to meet the requirements toward miniaturization and energy consumption reduction for compressors, there is a need for a rational layout design to reduce the sizes of the housing, to reduce the weight of the compressor, to reduce the cost of the compressor (parts and transportation), and to enhance the market competitiveness of the compressor.
The technical problem to be solved by this disclosure is to make improvements on the structure of currently available compressor housing. The embodiments described herein provide a compressor housing that is hermetic and spatially compact with relatively smaller dimensions and light weight. The compressor housing described herein is easy to produce and is particularly suitable for use as a small-sized, sealed refrigeration compressor housing.
In one embodiment, a sealed compressor housing includes an upper cover and a lower shell each have a cylindrical shape with an elliptical horizontal cross-section. The upper cover and the lower shell can be snap-fitted together with a major elliptical axial centerline and a minor elliptical axial centerline of the upper cover being aligned with a respective major elliptical axial centerline and a respective minor elliptical axial centerline of the lower shell. The elliptical major axial centerlines are aligned with a centerline of a cylinder bore of a compressor cylinder block. A terminal pin is located on the lower shell and is symmetrically formed with respect to a centerline of a terminal pin bore. A top surface of the upper cover is an asymmetric spherical contraction. The top surface on the side of the terminal pin and a front side of the top surface are higher than a rear side of the top surface. A bottom surface of the lower shell is a smooth ellipsoidal contraction. The centerline of the terminal pin bore forms an angle with the elliptical major axial centerlines of the upper cover and the lower shell.
According to the above embodiment, an angle A between the centerline of the terminal pin bore and the elliptical major axial centerlines is formed by a clockwise rotation of the centerline of the terminal pin bore with respect to the elliptical major axial centerline. The angle A is in the range of 10° to 45°.
According to the above embodiment, an internal side of a bottom portion of the lower shell is provided with four welding planes for internal support pins that support pump components inside the housing. Two of the planes are symmetrically positioned on opposite sides of the elliptical major axial centerline. The remaining two of the planes are spaced apart and positioned on the elliptical major axial centerline. The welding planes are positioned with an offset toward the side of a rear portion of the compressor cylinder block.
According to the above embodiment, the lower shell has a bottom portion having a smooth ellipsoidal outer surface. On the side of the terminal pin and the opposite side of the bottom portion, welding surfaces are respectively provided for welding compressor feet onto the bottom portion of the lower shell. The welding surfaces are curved and have a curvature consistent with that of the outer surface. Two of the welding surfaces on either side are distributed on opposite sides of the centerline of the terminal pin bore. The welding surfaces are distributed along a periphery of the bottom portion of the lower shell, and are configured to weld a corresponding welding end of a compressor foot. The welding end of each compressor foot are two forked and interconnected, upwardly arching, curved welding surfaces that are consistent with the curvature of the welding surface. An opposite end of each compressor foot is a supporting plane having a distance of 3 to 8 mm from the lowest point on the lower shell bottom. A centerline connecting the compressor foot supporting planes on the two opposite sides is in alignment with the terminal pin bore centerline.
According to the above embodiment, the lower shell sidewall is provided with two lower shell retaining grooves that are symmetrically positioned with respect to the elliptical major axial centerline. The upper cover is provided with three upper cover retaining grooves where two of the grooves are symmetrically positioned on opposite sides of the elliptical major axial centerline and at a location above the head portion of the compressor cylinder block, and the third groove is positioned on the elliptical major axial centerline and at a location above the rear portion of the compressor cylinder block. The grooves are sunk below the outer surface of the housing into the inside of the housing and form smooth projections on the interior wall of the housing.
The shape of the grooves is one of circular, oval, or smooth polygonal.
According to the above embodiment, at a location above the terminal pin bore, the upper cover and the lower shell are each provided with a positioning plane that have equal width and match each other. Each of the positioning planes makes a smooth transition to the housing body.
According to the above embodiment, the upper cover is provided with an enhancing groove at a location above the positioning plane thereof. The enhancing groove is sunk below the outer surface of the upper cover into the inside of the upper cover and forms a smooth projection on the interior wall of the housing. The enhancing groove is a vertically straight strip.
According to the above embodiment, the housing is suitable for use as a small-sized sealed refrigeration compressor housing.
The embodiments described therein have the following advantages compared to existing technologies:
1. A terminal pin bore centerline of a lower shell is aligned to not coincide with major axial centerlines of elliptical cross-sections of the lower shell or an upper cover, nor coincide with a cylinder bore centerline for a compressor cylinder block. Instead, the terminal pin bore centerline of the lower shell is rotated an angle A (10° to 45°) with respect to the major axial centerlines. This allows a terminal pin of the housing to keep away from other components inside the housing such as, for example, a muffler chamber, a compressor cylinder cover, etc. This can prevent collision among the compressor cylinder cover, the muffler chamber, and the terminal pin. The need to extend the length of the elliptical major axial centerline of the housing is eliminated, the dimensions of the housing are minimized, the amount of space needed is reduced, and the cost is lowered.
2. Four welding planes are provided on a bottom of the lower shell for welding four respective internal support pins, which are compactly positioned. In order to allocate maximum space to accommodate components inside the housing such as, for example, the compressor cylinder cover, the muffler chamber, etc., the location of the welding planes as a whole is offset toward the rear portion of the compressor cylinder block. The four planes are used to support pump components inside the compressor housing.
3. The lowest part of the lower shell bottom is no longer an entirely flat surface upon which the compressor feet are welded. Instead, the compressor foot welding surface is a curved welding surface formed on a bottom surface of the lower shell. The bottom surface is a smooth ellipsoidal outer surface of the lower shell bottom that has a curvature consistent with that of the lower shell. This allows the supporting planes of the compressor feet to be at 3 mm to 8 mm above the lowest part of the lower shell bottom, therefore allowing the outer surface of the lower shell bottom to be of a smooth ellipsoidal shape instead of a cylindrical shape. Thus the amount of oil injected can be minimized and the overall height of the compressor is reduced.
4. In order to prevent collision among critical compressor components during transportation, the lower shell is designed with two retaining features that are symmetrically positioned on opposite sides of the elliptical major axial centerline, and these features prevent a lower portion of a pump from moving left and right beyond an acceptable movement range.
The upper cover has three retaining features. Two of the retaining features are positioned on opposite sides of the elliptical major axial centerline of the housing so as to limit the left and right movement range of the compressor cylinder cover. The third retaining feature is positioned above the rear portion of the compressor cylinder block, so as to limit the front and back movement range of the rear portion of the compressor cylinder block.
5. In order to prevent the upper cover and the lower shell from rotating into dislocation during the assembly process, two matching positioning planes are incorporated into the design of the mating surfaces of the upper cover and the lower shell to facilitate the mating and positioning of the upper cover and the lower shell.
6. An enhancing groove is positioned above the upper cover positioning plane to enhance the integrity of the upper cover.
Features in the drawings include the following: 1—upper cover, 2—lower shell, 3—terminal pin, 4—internal support pin (4), 5—compressor foot (2), 6—compressor cylinder block, 7—compressor cylinder cover, 8—intake muffler chamber, 9—welding plane for internal support pin (4 locations), 10—curved compressor foot welding surface (4 locations), 11—first retaining groove on the lower shell, 12—second retaining groove on the lower shell, 13—first retaining groove on the upper cover, 14—second retaining groove on the upper cover, 15—third retaining groove on the upper cover, 16—lower shell positioning plane, 17—upper cover positioning plane, 18—upper cover groove, 19—rear portion of compressor cylinder block, 20—head portion of compressor cylinder block, 21—elliptical major axial centerline (compressor cylinder block cylinder bore centerline), 22—elliptical minor axial centerline, 23—terminal pin bore centerline.
The following, in conjunction with the examples in
In reference to
A terminal pin 3 is provided on the lower shell 2 and is symmetrically disposed with respect to a terminal pin bore centerline 23. The upper cover 1 has a top surface that is an asymmetric spherical contraction. A portion of the top surface on the side of the terminal pin 3 and a front side portion of the top surface are higher than a rear side portion of the top surface. The lower shell 2 has a bottom surface that is a smooth ellipsoidal contraction.
A compressor cylinder block 6 is positioned along the major axial centerline 21 and attached to the compressor housing via respective cylinder bores at ends thereof. The cylinder bores are disposed around a cylinder bore centerline that is aligned to coincide with the major axial centerline 21. The compressor cylinder block 6 includes a larger end that is a head portion 20, and a smaller end that is a rear portion 19 of the compressor cylinder block 6. A compressor cylinder cover 7 and a muffler chamber 8 are located at the head portion 20 of the compressor cylinder block 6.
The terminal pin bore centerline 23 forms an angle A (10° to 45°) with the major axial centerline 21. This can prevent collision between the compressor cylinder cover 7 and the terminal pins and between the muffler chamber 8 and the terminal pin 3. This structure can eliminate the need to extend the length of the elliptical major axial centerline of the lower shell, thereby reduce the amount of space and cost.
Four welding planes 9 are provided at an internal side of a bottom portion of the lower shell 2. The welding planes 9 are configured to weld internal support pins 4 to the lower shell 2. Two of the welding planes 9 are symmetrically located on opposite sides of the major axial centerline 21. The other two of the welding planes 9 are spaced apart and located along the major axial centerline 21. The welding planes 9 as a whole are positioned with an offset toward the side of the rear portion 19 of the compressor cylinder block 6 to provide a compact configuration. The offset toward the side of the rear portion 19 can allocate a maximum space to accommodate components of the compressor such as, for example, the compressor cylinder cover 7, the muffler chamber 8, etc. The welding planes 9 can support, for example, pump components inside the compressor housing.
Welding surfaces 10 are formed on a bottom portion of the lower shell 2 for welding respective compressor feet 5 to the lower shell 2. The welding surfaces 10 are respectively disposed on the side of the terminal pin 3 and the opposite side. The welding surfaces 10 are curved and have a curvature that is consistent with that of an outer surface of the bottom portion of the lower shell 2. The welding surfaces 10 are positioned on opposite sides of the terminal pin bore centerline 23, with two of the welding surfaces 10 positioned on one side and two of the welding surfaces 10 posited on the opposite side. The welding surfaces 10 are distributed along a periphery of the bottom portion of the lower shell 2 that has a smooth ellipsoidal shape. The welding surfaces 10 can correspondingly weld welding ends of the compressor feet 5 thereon.
The welding ends of the compressor feet 5 each include a curved welding surface with two forked interconnections. The curved welding surfaces each upwardly arch and have a curvature consistent with that of the respective welding surfaces 10 of the lower shell 2. A supporting plane is provided at the opposite end of the respective compressor feet 5, which is about 3 to 8 mm (preferably 5 mm) away from the lowest point on the bottom portion of the lower shell 2. A centerline connecting the supporting planes of the compressor feet 5 on opposite sides of the bottom shell 2 is aligned to coincide with the terminal pin bore centerline 23. In this embodiment, the compressor feet 5 are directly welded onto the welding surfaces 10 that have a curvature consistent with that of the lower shell 2, instead of welding a compressor foot onto an entirely flat surface on the lowest part of a lower shell. This allows the outer surface of the bottom portion of the lower shell 2 to have a smooth ellipsoidal shape instead of a cylindrical shape. Thus the amount of oil injected into the compressor housing can be minimized and the overall height of the compressor can be reduced.
A first retaining groove 11 and a second retaining groove 12 are provided on a side wall of the lower shell 2. The first and second retaining grooves 11 and 12 of the lower shell 2 are symmetrically positioned with respect to the major axial centerline 21, and are configured to prevent excessive left and right movements of a lower portion of a pump.
Three retaining grooves are provided on the upper cover 1, including first, second and third retaining grooves 13, 14 and 15. The second retaining groove 14 and the third retaining groove 15 of the upper cover 1 are symmetrically positioned on opposite sides of the major axial centerline 21 and are positioned above the head portion 20 of the compressor cylinder block 6, so as to limit the left and right movements of the compressor cylinder cover 7. The first retaining groove 13 of the upper cover 1 is positioned on the major axial centerline 21 and at a location above the rear portion 19 of the compressor cylinder block 6, so as to limit the range of front and back movement of the rear portion 19 of the compressor cylinder block 6.
The grooves 11-15 are sunk below the outer surface of the compressor housing into an inside of the housing and form smooth projections on an interior wall of the housing. The grooves 11-15 may be circular, oval, or smooth polygonal.
The housing is used as a sealed housing for a compressor. The major and minor elliptical axial centerlines of the upper cover 1 are respectively aligned to coincide with the respective major and minor elliptical axial centerlines of the lower shell 2. To prevent the upper cover 1 and the lower shell 2 from misplacement when rotated with respect to each other during assembly, positioning planes 16 and 17 are provided as mating surfaces configured to engage the upper cover 1 and the lower shell 2 and to facilitate the mating and positioning of the upper cover 1 and the lower shell 2. The positioning plane 17 with a particular width is provided above a terminal pin bore on the upper cover 1. The positioning plane 16 is provided on the lower shell 2 and has a width matching the width of the positioning plane 17. The positioning planes 16 and 17 each have a smooth transition into their respective cover/shell.
An enhancing groove 18 is provided above the positioning plane 17 of the upper cover 1 to improve the strength of the upper cover 1. The enhancing groove 18 is sunk below the outer surface of the upper cover 1 into the inside of the upper cover 1, and forms a smooth projection on the interior wall of the upper cover 1. The enhancing groove 18 includes a vertically straight strip.
The above disclosure is only intended to illustrate the preferred embodiments of the present invention and is not intended to limit the scope of the present invention. Therefore any equivalent changes made based on the disclosure of the present invention, such as improvements on the process parameters or the apparatus, are still within the protective scope of the present invention.
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Number | Date | Country | |
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Parent | PCT/CN2012/072585 | Mar 2012 | US |
Child | 14143892 | US |