Swash plate type compressor piston wherein inner surface of base section of neck portion has as-cast surface area

Information

  • Patent Grant
  • 6453554
  • Patent Number
    6,453,554
  • Date Filed
    Thursday, August 24, 2000
    24 years ago
  • Date Issued
    Tuesday, September 24, 2002
    22 years ago
Abstract
A die-cast piston for a swash plate type compressor including a cylinder block having a cylinder bore, including a generally cylindrical head portion slidably movably received in a cylinder bore formed in a cylinder block of the compressor, and a generally U-shaped neck portion having a base section and a pair of substantially parallel arm sections which extend from the base section, wherein the base section has an inner surface including at least one as-cast surface area formed in a die-casting process.
Description




This application is based on Japanese Patent Application No. 11-239364 filed Aug. 26, 1999, the contents of which are incorporated hereinto by reference.




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates in general to a piston for a swash plate type compressor, and more particularly to a die-cast piston for such a compressor, and a method of producing such a piston by die-casting.




2. Discussion of Related Art




A piston for a swash plate type compressor is conventionally produced by forging or die-casting. Described more specifically, a blank for the piston is formed by forging or die-casting, and the blank is subjected to appropriate machining operations, to produce the desired piston. The swash plate type compressor piston may be a single-headed piston or a double-headed piston. The single-headed piston includes a head portion and a neck portion which are slidably movable in a cylinder bore formed in a cylinder block of the compressor. The neck portion is a generally U-shaped portion having a base section and a pair of substantially parallel arm sections which extend from the base section. The double-headed piston includes two head portions on the opposite sides of the neck portion. Since the single- or double-headed piston is reciprocated within the cylinder bore, it is generally required to reduce the weight of the piston. For this reason, there has been proposed a piston formed of an aluminum alloy and designed to have a wall thickness as small as possible. On the other hand, the base section of the neck portion of the piston is subject to repeated application of a bending moment during a reciprocating movement of the piston. To assure the intended durability of the piston, therefore, the reduction of the wall thickness is limited. While the piston produced from a forged blank has a comparatively high degree of strength, the piston by produced by die-casing inevitably has a lower strength.




SUMMARY OF THE INVENTION




It is therefore a first object of the present invention to provide a die-cast piston for a swash plate type compressor, which piston has a sufficiently high degree of durability while having a reduced weight. A second object if the invention is to provide a method of producing such a lightweight, highly durable die-cast piston.




The first or second object may be achieved according to any one of the following modes of the present invention, each of which is numbered like the appended claims and depends from the other mode or modes, where appropriate, to indicate and clarify possible combinations of elements or technical features. It is to be understood that the present invention is not limited to the technical features or any combinations thereof which will be described for illustrative purpose only. It is to be further understood that a plurality of elements or features included in any one of the following modes of the invention are not necessarily provided all together, and that the invention may be embodied without some of the elements or features described with respect to the same mode.




(1) A die-cast piston for a swash plate type compressor including a cylinder block having a cylinder bore formed therein, the piston comprising a generally cylindrical head portion slidably movably received in the cylinder bore, and generally U-shaped neck portion having a base section and a pair of substantially parallel arm sections which extend from the base section, the die-cast piston being characterized in that the base section has an inner surface including at least one as-cast surface area formed in a die-casting process.




In the die-cast piston constructed according to the above mode (1) of this invention wherein the inner surface of the base section of the neck portion includes an as-cast surface area or areas, the base section has an increased degree of durability or strength. Generally, a die-cast article or product has a chilled layer adjacent to its surface, and the chilled layer left unmachined after the die casting process is effective to improve the strength of the die-cast article. The chilled layer is formed by rapid cooling and solidification of a molten mass of iron in a casting mold, at a portion of the molten mass in contact with the inner surface of the mold which defines a mold cavity. The chilled layer is characterized by a discontinuous change in the crystallization ratio of the primary crystal or α-phase (proeutectic) and the eutectic silicon with respect to each other. Since the chilled layer has high values of hardness and strength, the presence of the chilled layer adjacent to the inner surface of the base section of the neck portion is effective to increase the bending strength of the base section, particularly, the durability of the base section. The inner surface of the base section, which is located close to the outer circumferential surface of the swash plate of the compressor, is conventionally subjected to a machining operation, which results in the removal of the chilled layer. In the piston according to the present invention, however, the chilled layer adjacent to at least a portion of the inner surface of the base section is left unmachined, so as to provide at least one as-cast surface area, so that, like a forged piston, the present die-cast piston has sufficiently high degrees of durability and strength owing to the chilled layer while having a significantly reduced weight. Although the inner surface of the base section is preferably left as-cast over a surface area as large as possible, the inner surface may be required to be more or less machined at some area, for the purpose of removing a rib or casting fins. A die-cast blank that is subjected to machining and other working operations to produce the piston is usually provided with a reinforcing rib or ribs to assure accurate and efficient machining of the blank. The casing fins are inevitably formed on the blank, at a parting plane of the mold at which the mold halves are butted together to define the mold cavity. Where the inner surface of the base section is partially machined, the surface area to be machined is desirably minimized to maximize the total as-cast surface area for maximizing the durability and strength of the base section of the neck portion.




(2) A die-cast piston according to the above mode (1), wherein the inner surface includes a central machined surface area and a pair of as-cast surface areas, the central machined surface area being located at an intermediate portion of the inner surface as viewed in a direction perpendicular to a centerline of the piston which passes a center of the generally cylindrical head portion, the central machined surface area being formed as a result of a machining operation in the intermediate portion of the inner surface, and wherein the pair of as-cast surface areas are located on opposite sides of the central machined surface area as viewed in the direction.




The die-cast blank which is processed to produce the die-cast piston is generally provided with reinforcing rib or ribs for the purpose of preventing thermal strains of the blank during heat treatment thereof and reducing elastic deformation during machining operations on the blank. For instance, a rib is formed so as to extend between a pair of arm sections which extend from a base section of a neck portion of the blank in a direction perpendicular to the centerline of the blank which passes the center of the head portion, so that the rib connects the base section and the two arm sections. The rib is formed so as to extend from a central portion of the inner surface of the base section, which central portion is located an intermediate portion of the inner surface as viewed in the direction perpendicular to the centerline. The rib is eventually removed by a machining operation, so that the die-cast piston does not have the rib. Accordingly, the central portion of the inner surface of the base section of the blank must be subjected to a machining operation to remove the rib, so that the inner surface of the base section inevitably has a central machined surface area. In other words, the inner surface of the base section of the piston can have a pair of as-caset surface areas on the opposite sides of the central machine surface area as viewed in the direction in which the arm sections extend. The as-cast surface areas left on the inner surface of the base section are effective to increase the neck portion of the piston.




(3) A die-cast piston according to the above mode (1), wherein a substantially entire portion of the inner surface is an as-cast surface area.




The piston according to the above mode (3) is most preferred from the standpoint of the durability of the neck portion.




(4) A die-cast piston according to any one of the above modes (1)-(3), wherein the pair of arm sections have opposed inner surfaces having as-cast surface areas adjacent to the at least one as-cast surface area of the base section, the as-cast areas of the arm sections being also formed in the die-casting process.




The opposed inner surfaces if the pair of arm sections are usually machined to be flat surfaces in which part-spherical recesses are formed by machining so that part-spherical shoes are partially received in the respective recesses, for sliding contact with the opposite surfaces of the swash plate of the compressor. For increasing the durability of the neck portion, the opposed inner surfaces of the arm sections preferably remain as-cast, particularly, at the end portions of the opposed inner surfaces adjacent to the end portions of the inner surface of the base section. Generally, there are provided fillets of a small radius of curvature at the boundaries of the inner surface of the base section and the opposed inner surfaces of the arm sections, in order to reduce the stress concentration at those boundaries. For increasing the durability of the neck portion, the fillets are preferably left as-cast, namely, preferably have as-cast surfaces.




(5) A die-cast piston according to any one of the above modes (1)-(4), wherein the head portion includes a body section having a circular shape in transverse cross section and cooperating with the cylinder bore of the compressor to partially define a pressurizing chamber, the piston further comprising a connecting portion which connects the head portion and the neck portion.




The configuration of the die-cast piston according to the above mode (5) is desirable for facilitating the removal of the blank from the casting mold. Usually, the casting mold consists of two mold halves which are butted together so as to define a parting plane which includes the centerline of the head portion having the circular body section and which is parallel to the direction of extension of the arm sections from the base section. Where the rib indicated above is not formed so as to extend from the intermediate or central portion of the inner surface of the base section, the casting fins are likely to be formed on this central portion due to the abutting contact of the two mold halves at the parting line indicated above. In this case wherein the rib is not formed, the central portion is preferably subjected to a machining operation to remove the fins. As in the case wherein the inner surface of the base section is machined to remove the rib, the machined surface area is desirably minimized to maximize the as-cast surface area, in the case where the inner surface of the base section is defined.




(6) A die-cast piston according to the above mode (5), wherein the head portion further includes a sliding section extending from the body section and connecting the body section and the connecting portion.




The sliding section provided between the circular body section of the head portion and the connecting portion is effective to assure smooth sliding movement of the piston within the cylinder bore, without an inclination of the centerline with respect to the centerline of the cylinder bore. However, the sliding section desirably has a relatively small weight to reduce the overall weight of the piston. To reduce the weight of the sliding section, the sliding section preferably consists of a radially outer sliding section and a radially inner sliding section which correspond to radially outer and inner portions of the cylinder block.




(7) A method of producing a die-cast piston for a swash plate type compressor including a cylinder block having a cylinder bore formed therein, the die-cast piston comprising a generally cylindrical head portion slidably movably received in the cylinder bore, and a generally U-shaped neck portion having a base section and a pair of substantially parallel arm sections which extend from the base section, the method comprising the steps of:




forming a blank by die casting such that the blank includes: a head portion which gives the head portion of the piston; a neck portion which gives the neck portion of the piston and which includes a base section and a pair of arm sections; and a reinforcing portion which extends so as to connect the pair of arm sections of the neck portion of the blank, in a direction parallel to a centerline of the blank which passes a center of the head portion of the blank; and




subjecting the blank to a machining operation to remove the reinforcing portion such that the base section of the neck portion of the blank has an inner surface including at least one as-cast surface area which is left unmachined.




Conventionally, the inner surface of the base section of the neck portion of the blank which give the inner surface of the base section of the neck portion of the piston is machined upon removal of the reinforcing portion. In the method according to the above mode (7) of the present invention, the area of the inner surface of the blank to be machined is minimized to maximize the as-cast surface area, for the purpose of maximizing the durability and strength of the neck portion of the piston produced by processing the blank.




(8) A method according to the above mode (7), wherein the reinforcing portion is a rib extending from a central portion of the inner surface of the base section of the blank in a direction of extension of the pair of arm sections of the blank, the central portion being located at an intermediate portion of the inner surface of the base section of the blank as viewed in a direction perpendicular to the centerline, the rib connecting the base section and pair of arm sections of the blank, and wherein the step of subjecting the blank to a machining operation comprises removing the rib such that the inner surface of the base section of the blank includes a central machined surface area and a pair of as-cast surface areas located on the opposite sides of the central machined surface area as viewed in the direction perpendicular to the centerline.




In the method according to the above mode (8), the central portion of the inner surface of the base section of the neck portion of the blank is removed when the rib is removed by the machining operation. However, there are left as-cast surface areas in the portions of the inner surface located on the opposite sides of the central machine surface area formed by the removal of the rib. These as-cast surface areas are effective to increase the durability of the neck portion of the piston produced from the blank.




(9) A method according to the above mode (7), wherein the reinforcing portion is a bridge portion extending to connect the pair of arm sections of the blank in the direction parallel to the centerline, the bridge portion being spaced apart from the inner surface of the base section of the blank, and wherein the subjecting central portion being located at an intermediate portion of the inner surface of the base section of the blank as viewed in a direction perpendicular to the centerline, and wherein the step of subjecting the blank to a machining operation comprises removing the bridge portion and machining a central portion of the inner surface of the base section of the blank to remove fins formed in the step of forming a blank, such that the inner surface of the base section of aid blank includes a central machined surface area and a pair of as-cast surface areas located on the opposite sides of the central machined surface area as viewed in the direction perpendicular to the centerline.




In the method according to the above mode (9), the fins formed along the parting plane of the mold halves are removed by machining the central portion of the inner surface of the base section of the neck section of the blank, such that the portions on the opposite sides of the central machined surface area are left as as-cast surface areas, which improve the durability of the neck portion of the piston produced by processing the blank.




(10) A method according to any one of the above modes (7)-(9), wherein the step of subjecting the blank to a machining operation comprises:




positioning a rotary cutting tool having a peripheral cutting edge such that the rotary cutting tool is rotatable about an axis which is parallel to the centerline and which is aligned with a center of the reinforcing portion as viewed in the direction perpendicular to the centerline;




feeding the rotary cutting tool in a radial direction thereof toward the inner surface of the base section of the neck portion of the blank while the rotary cutting tool is rotated, so that the reinforcing portion extending between the pair of arm sections of the blank is removed.




In the method according to the above mode (10) wherein the rotary cutting tool is used to remove the reinforcing portion, the portions of the inner surface of the base section of the neck portion of the blank located on the opposite sides of the central machined area can be easily left as the as-cast surface areas.




(11) A method according to any one of the above modes (7)-(10), wherein the pair of arm sections of the neck portion of the blank have respective opposed inner surfaces which are opposed to each other in the direction parallel to the centerline, and the rotary cutting edge further has side cutting edges formed on opposite sides of the peripheral cutting edge, and wherein the machining operation comprises machining at least a portion of each of the opposed inner surfaces such that an end portion of the each of the opposed inner surfaces which is adjacent to the inner surface of the base section of the blank is left as an as-cast surface area.




In the method according to the above mode (11) wherein the machining operation is performed by the rotary cutting tool having both the peripheral cutting edge and the side cutting edges, not only the central portion of the inner surface of the base section of the blank but also portions of the opposed inner surfaces of the pair of arm sections are removed by the same rotary cutting tool. To produce the piston, two recesses are formed in the above-indicated machined portions of the opposed inner surfaces of the arm sections, so that shoes are partially received in the recesses, for sliding contact with the opposite surfaces of the swash plate of the compressor. The machining operation on the opposed inner surfaces is performed such that the end portions of the opposed inner surfaces adjacent to the inner surface of the base section are left as cast, in order to reduce the stress concentration at the boundaries between the inner surface of the base section and the opposed inner surfaces of the arm sections, which stress concentration would easily take place in the absence of the as-cast surfaces at those boundaries. Thus, the durability of the piston produced from the blank is further increased according to the above mode (11) of this invention.











BRIEF DESCRIPTION OF THE INVENTION




The above and other objects, features, advantages and technical and industrial significance of the present invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings, in which:





FIG. 1

is a front elevational view in cross section of a swash plate type compressor incorporating a die-cast piston produced by a method according to one embodiment of this invention;





FIG. 2

is a front elevational view of the die-cast piston of the compressor of

FIG. 1

;





FIG. 3

is a plan view showing a part of the die-cast piston;





FIG. 4

is a front elevational view of a blank used for producing the die-cast piston of

FIG. 1

;





FIG. 5

is a front elevational view showing a part of the blank of

FIG. 4

while it is subjected to a machining operation with a cutting tool;





FIG. 6

is a cross sectional view taken along line


6


-


6


of

FIG. 4

;





FIG. 7

is a front elevational view partly in cross section of a blank used for producing a piston according to a second embodiment of this invention.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




Referring first to

FIG. 1

, there is shown a compressor of swash plate type incorporating a plurality of single-headed pistons each constructed and produced according to one embodiment of this invention.




In

FIG. 1

, reference numeral


10


denotes a cylinder block having a centerline M and a plurality of cylinder bores


12


formed so as to extend in its axial direction such that the cylinder bores


12


are arranged along a circle whose center lies on the centerline M. A single-headed piston generally indicated at


14


(hereinafter referred to as “piston


14


”) is reciprocably received in each of the cylinder bores


12


. To one of the axially opposite end faces (the left end face as seen in

FIG. 1

, witch will be referred to as “front end face”) of the cylinder block


10


, there is attached a front housing


16


. To the other end face (the right end face as seen in

FIG. 1

, which will be referred to as “rear end face”), there is attached a rear housing


18


through a valve plate structure


20


. The front housing


16


, rear housing


18


and cylinder block


10


cooperate to constitute a major portion of the housing assembly of the swash plate type compressor.




The rear housing


18


and the valve plate structure


20


cooperate to define a suction chamber


22


and a discharge chamber


24


, which are connected to a refrigerating circuit (not shown) through an inlet


26


and an outlet


28


, respectively. The valve plate structure


20


has suction ports


40


, suction valves


42


, discharge ports


44


and discharge valves


48


.




A rotary drive shaft


50


is disposed in the cylinder block


10


and the front housing


16


such that the axis of rotation of the drive shaft


50


is aligned with the centerline M of the cylinder block


10


. The drive shaft


50


is supported at its opposite end portions by the front housing


16


and the cylinder block


10


via respective bearings. The cylinder block


10


has a central bearing hole


56


in a central portion thereof, and the bearing is disposed in this central bearing hole


56


, for supporting the drive shaft


50


at its rear end portion.




The front end portion of the rotary drive shaft


50


extends through a central portion of the front housing


16


, such that the front end of the drive shaft


50


is located outside the front housing


16


, so that the drive shaft


50


is connected at its front end to a drive power source (not shown). The drive shaft


50


carries a swash plate


60


mounted thereon such that the swash plate


60


is axially movable and tiltable relative to the drive shaft


50


. The swash plate


60


has a center hole


61


through which the driveshaft


50


extends. The diameter of the center hole


61


gradually increases in the opposite axial directions from its axially intermediate portion towards the axially opposite ends. To the drive shaft


50


, there is fixed a lug plate


62


which is held in engagement with the swash plate


60


through a hinge mechanism


64


. The lug plate


62


is rotatable with the drive shaft


50


relative to the front housing


16


through a thrust bearing


66


. The hinge mechanism


64


causes the swash plate


60


to be rotated with the drive shaft


50


during rotation of the drive shaft


50


, and permits axial and tilting motions of the swash plate


60


. In this respect, it is noted that the diameter of the center hole


61


at its opposite axial ends is larger than the outside diameter of the drive shaft


50


.




The hinge mechanism


64


includes a pair of support arms


70


fixed to the lug plate


62


, and guide pins


74


formed on the swash plate


60


. The guide pins


74


slidably engage guide holes


72


formed in the support arms


70


.




The piston


14


indicated above includes a neck portion


80


engaging the swash plate


60


, a generally cylindrical head portion


82


fitted in the corresponding cylinder bore


12


, and a connecting portion


83


connecting the neck portion


80


and the head portion


82


. The neck portion


80


has a groove


84


formed therein, and the swash plate


60


is held in engagement with the groove


84


through a pair of hemispherical shoes


86


. The hemi-spherical shoes


86


are held in the groove


84


such that the shoes


86


slidably engage the neck portion


80


at their hemi-spherical surfaces, and slidably engage the opposite surfaces of the swash plate


60


at their flat surfaces. It will be understood that the head portion


82


cooperates with the cylinder block


10


and the valve plate structure


20


to define a pressurizing chamber


87


. The configuration of the piston


14


will be described in detail.




A rotary motion of the swash plate


60


is converted into a reciprocating linear motion of the piston


14


through the shoes


86


. A refrigerant gas in the suction chamber


22


is sucked or admitted into the pressurizing chamber


87


through the suction port


40


and the suction valve


42


, when the piston


14


is moved from its upper dead point to its lower dead point, that is, when the piston


14


is in the suction stroke. The refrigerant in the pressurizing chamber


87


is pressurized by the piston


14


when the piston


14


is moved from its lower dead point to its upper dead point, that is, when the piston


14


is in the compression stroke. The thus pressurized refrigerant gas is delivered into the discharge chamber


24


through the discharge port


46


and the discharge valve


48


. A reaction force acts on the piston


14


in the axial direction as a result of compression of the refrigerant gas in the pressurizing chamber


87


. This compression reaction force is received by the front housing


16


through the piston


14


, swash plate


60


, lug plate


62


and thrust bearing


66


.




As shown in

FIG. 2

, the neck portion


80


of the piston


14


has an integrally formed rotation preventive part


88


, which is arranged to contact the inner circumferential surface of the front housing


16


, for thereby preventing a rotary motion of the piston


14


about its centerline N (FIG.


1


).




The cylinder block


10


has a supply passage


94


formed therethrough for communication between the discharge chamber


24


and a crank chamber


96


which is defined between the front housing


16


and the cylinder block


10


. The supply passage


94


is connected to a solenoid-operated control valve


100


provided to control the pressure in the crank chamber


96


. The solenoid-operated control valve


100


includes a solenoid coil


102


, and a shut-off valve


104


which is selectively closed and opened by energization and de-energization of the solenoid coil


120


. Namely, the shut-off valve


104


is placed in its closed state when the solenoid coil


102


is energized, and is placed in its open state when the coil


102


is de-energized.




The rotary drive shaft


50


has a bleeding passage


110


formed therethrough. The bleeding passage


110


is open at one of its opposite ends to the central bearing hole


56


indicated above, and is open to the crank chamber


96


through a communication passage


112


. The central bearing hole


56


communicates at its bottom with the suction chamber


22


through a communication port


114


.




When the solenoid coil


102


of the solenoid-operated control valve


100


is energized, the supply passage


94


is closed, so that the pressurized refrigerant gas in the discharge chamber


24


is not delivered into the crank chamber


96


. In this condition, the refrigerant gas in the crank chamber


96


flows into the suction chamber


22


through the bleeding passage


110


and the communication port


114


, so that the pressure in the crank chamber


96


is lowered. As a result, the angle of inclination of the swash plate


60


with respect to a plane perpendicular to the axis of rotation M of the drive shaft


50


is increased, and the discharge capacity of the compressor is accordingly increased.




When the solenoid coil


102


is de-energized, the supply passage


94


is opened, permitting the pressurized refrigerant gas to be delivered from the discharge chamber


24


into the crank chamber


96


, resulting in an increase in the pressure in the crank chamber


96


, and the angle of inclination of the swash plate


60


is reduced, so that the discharge capacity of the compressor is accordingly reduced.




The maximum angle of inclination of the swash plate


60


is limited by abutting contact of a stop


120


formed on the swash plate


60


, with the lug plate


62


, and the minimum angle of inclination of the swash plate


60


is limited by abutting contact of the swash plate


60


with a stop


122


in the form of a ring fixedly fitted on the drive shaft


50


.




As described above, the pressure in the crank chamber


96


is controlled by controlling the solenoid-operated control valve


100


to selectively connect and disconnect the crank chamber


96


to and from the discharge chamber


24


. The angle of inclination of the swash plate


60


is changed with a change in the pressure in the crank chamber


96


, so that the stroke of the piston


14


is controlled to control the discharge capacity of the compressor. Thus, the swash plate type compressor having the piston


14


in each cylinder bore


12


is of a variable capacity type. The solenoid coil


102


of the solenoid-operated control valve


100


is controlled by a control device (not shown) depending upon a load acting on the air conditioning system including the present compressor. The control device is principally constituted by a computer.




The cylinder block


10


and each piston


14


are formed of an aluminum alloy. The piston


14


is coated at its outer circumferential surface with a fluoro resin film, which prevents a direct contact of the aluminum alloy of the piston


14


with the aluminum alloy of the cylinder block


10


, and makes it possible to minimize the amount of clearance between the piston


14


and the cylinder bore


12


. The cylinder block


10


and the piston


14


may also be formed of a hyper-eutectic aluminum silicon alloy. Other materials may be used for the cylinder block


10


and the piston


14


.




There will next be described the configuration of the piston


14


.




As shown in

FIG. 2

, the head portion


82


of the piston


14


includes a body section


126


, and an outer sliding section


128


and an inner sliding section


130


which correspond to respective radially outer and inner portions of the cylinder block


10


. The radially outer portion of the cylinder block


10


is more distant from the centerline M than the radially inner portion of the cylinder block


10


. The body section


126


has a circular shape in cross section. The outer and inner sliding sections


128


,


130


extend towards the neck portion


80


from respective circumferential parts of the circular body section


126


, which parts correspond to the radially outer and inner portions of the cylinder block


10


. The outer and inner sliding sections


128


,


130


are adapted to slid on the respective circumferential portions of the inner circumferential surface of the cylinder bore


12


, which portions correspond to the radially outer and inner portions of the cylinder block


12


.




The connecting portion


83


of the piston


14


consists of a radially outer section


132


connecting the radially outer sliding portion


128


and the neck portion


80


, and a radially inner section


134


connecting the radially inner sliding portion


130


and the neck portion


80


. The piston


14


consists of the head portion


82


, neck portion


80


and connecting portion


83


, which are formed integrally with each other.




The neck portion


80


of the piston


14


is a generally U-shaped portion as seen in

FIG. 2

, which includes a base section


140


having an surface


142


, and a pair of side walls in the form of two parallel arm sections


144


,


146


which extend from the base section


140


in a direction perpendicular to the centerline N of the piston


14


which passes the center of the cylindrical head portion


82


. The arm section


144


is located at the end of the neck portion


80


remote from the head portion


82


. The arm sections


144


,


146


have respective inner surfaces


148


,


150


which are opposed to each other in the direction of the centerline N and which cooperate with the inner surface


142


of the base section


140


to define the groove


84


indicated above. The neck portion


80


has a fillet formed at the boundary between each of the opposed inner surfaces


148


,


150


of the arm sections


144


,


146


and the inner surface


142


of the base section


140


. The fillet has a comparatively small radius of curvature, so that the inner surface


142


is smoothly connected at its opposite ends to the opposed inner surfaces


148


,


150


. The inner surfaces


148


,


150


have respective part-spherical recesses


152


. The two part-spherical shoes


86


whose flat surfaces slidably engage the opposite surfaces of the swash plate


60


are held in contact at their part-spherical surfaces with the part-spherical surfaces of the respective part-spherical recesses


152


.




As shown in

FIG. 3

, the inner surface


142


of the base section


140


includes a central machined surface area


154


at an intermediate portion thereof as viewed in a direction perpendicular to the centerline N (as viewed in the direction perpendicular to the plane of view of FIG.


2


). The machined surface area


154


is a generally elongate area (intermediate hatched area shown in

FIG. 3

) extending in the direction of the centerline N. The machined surface area


154


is formed by a machining operation, which will be described. On the opposite sides of the central machined surface area


154


as seen in

FIG. 3

, there are provided two as-cast surface areas


156


(two hatched areas shown in

FIG. 3

on the opposite sides of the intermediate hatched area). The as-cast surface areas


156


are areas formed by die-casting to form a blank


160


, which will be described. The curved surfaces of the fillets between the inner surface


142


of the base section


140


and the opposed surfaces


148


,


150


of the arm sections


144


,


146


are also as-cast surface areas.




Two pieces of the single-headed piston


14


constructed as described above are produced from a single blank


160


. As schematically shown in

FIG. 4

, the blank


160


consists of a single twin neck portion


166


, two connecting portions


168


and two head portions


170


, which are formed such that each of the two connecting portions


168


connects the centrally located twin neck portion


166


and the corresponding one of the two head portions


170


located at the opposite ends of the blank


160


. The twin neck portion


166


consists of two neck portions


164


which are formed in series and integrally with each other and which provide respective two neck portions


80


of the two single-headed pistons


14


. The two connecting portions


168


provide respective two connecting portions


83


of the two single-headed pistons


14


, while the two head portions


170


provide respective two head portions


82


of the two single-headed pistons


14


. Each of the two neck portions


164


of the twin neck portion


166


includes a base section


172


having an inner surface


174


, a pair of opposed parallel arm sections


178


,


180


extending from the opposite ends of the base section


172


, and a reinforcing rib


176


which extends between the two arm sections


178


,


180


in the longitudinal direction of the blank


160


. The rib


176


extends also in the direction of extension of the base sections


172


, from a central part of the inner surface


174


of the base section


172


, which central part is central as seen in the direction perpendicular to the plane of view of FIG.


4


. Thus, the rib


176


connects the inner surface


174


of the base section


172


and inner surfaces


182


,


184


of the arm sections


178


,


180


, in order to reinforce the neck portion


164


for thereby increasing the rigidity and strength of the blank


160


.




In the present embodiment, the blank


160


is formed of a metallic material, more precisely, an aluminum alloy, by diecasting using a suitable casting mold which consists of two halves. The two halves of the mold define a parting plane which includes a centerline of the blank


160


passing the centers of the generally cylindrical head portions


170


and which is parallel to the direction of extension of the arm sections


178


,


180


from the base sections


172


. This process of forming the blank


160


by die-casting is a die-casting step in a method of producing the piston


14


. Following this die-casting step, a machining step is performed on the die-cast blank


160


. The machining step includes cutting operations on a plurality of portions of the blank


160


, which include the outer circumferential surfaces of the two head portions


170


. To machine this outer circumferential surfaces, the head portions


170


have respective holding portions


186


extending from their end faces, as shown in FIG.


4


. The holding portions


186


have respective center holes


188


, so that the blank


160


is held at the holding portions


186


by respective chucks while the blank


160


is centered with a pair of centers which engage the respective center holes


188


. To machine the outer circumferential surfaces of the head portions


170


on a suitable turning machine, the blank


160


is rotated by a suitable rotary drive device through the chucks. The integrally formed blank


160


the rigidity of which is increased by the ribs


176


can be efficiently and accurately machined.




Then, the machined outer circumferential surfaces of the head portions


170


and other selected surfaces of the blank


160


are coated with a suitable material, such as a film of polytetrafluoroethylene. Subsequently, the end faces of the head portions


170


are cut to remove the holding portions


186


, and the coated outer circumferential surfaces of the head portions


170


are subjected to a centerless grinding operation.




Subsequently, the twin neck portion


166


is subjected to a machining operation, to remove the ribs


176


of the two neck portions


164


, using a cutting tool


190


indicated by two-dot chain lines in

FIGS. 5 and 6

. The cutting tool


190


includes a body


194


and a shank


196


. The body


194


has a peripheral cutting edge formed on its outer circumferential surface, and side cutting edges formed along the peripheries of the opposite side surfaces. The cutting tool


190


is rotated by a spindle of a suitable machine tool (e.g., a milling machine), with the shank


196


removably fitted in the bore of the spindle. The cutting tool


190


, which may be a milling cutter, is capable of performing both a peripheral cutting operation with the peripheral cutting edge and a side cutting operation with the side cutting edges, with the rotating body


194


being moved in the radial direction relative to the rib


176


. It will be understood that a difference between the radii of the body


194


and the shank


196


is made slightly larger than the distance of overhang or extension of the arm sections


178


,


180


from the inner surface


174


of the base section


172


, in order to prevent an interference between the shank


196


and the distal end portions of the arm sections


178


,


180


, during the cutting operation with the body


194


. To form the fillets between the inner surface


142


of the base section


140


and the inner surfaces


148


,


150


of the arm sections


144


,


146


of the neck portion


80


of the piston


14


, there are formed fillets between the opposite ends of the machined inner surface


174


of the base section


172


and the adjacent ends of the machined inner surfaces


182


,


184


of the arm sections


178


,


180


. To this end, the body


194


is rounded with a suitable radius of curvature at the opposite ends of the peripheral cutting edge so that the peripheral cutting edge is smoothly connected to the side cutting edges through curved cutting edges, as indicated in FIG.


5


. The fillets are effective to reduce the stress concentration at the boundaries between the inner surface


142


and the inner surfaces


148


,


150


. The stress concentration can be more or less reduced by chamfering the body


194


at the boundaries between the peripheral and side cutting edges.




Before the machining operation to remove the rib


176


with the cutting tool


190


, the cutting tool


190


is positioned such that the axis of the tool


190


(shank


196


) is parallel to the centerline of the head portions


170


and is aligned with the center of the rib


176


as viewed in the direction perpendicular to the plane of view of

FIG. 5

, namely, in the horizontal direction as seen in FIG.


6


. Further, the cutting tool


190


is positioned in its axial direction such that one of the side cutting edges of the body


194


which is remote from the shank


196


is substantially aligned with the inner surface


184


of the arm section


180


, as indicated in FIG.


5


. The cutting tool


190


thus positioned is rotated about its axis and is fed in the radial direction toward the inner surface


174


(i.e., in the direction from the distal ends toward the proximal ends of the arm sections


178


,


180


). As a result, the end portion of the rib


176


adjacent to the arm section


180


is removed with the peripheral cutting edge of the body


194


, while at the same time the inner surface


184


is machined with the above-indicated one of the side cutting edges. The part-spherical recess


152


indicated above is subsequently cut in the machined inner surface


184


. In the presence of the rounded or chamfered edge between the peripheral and side cutting edges, there is left an uncut area or fillet


198


between the adjacent ends of the inner surface


174


of the base section


172


and the inner surface


184


of the arm section


180


, as indicated in FIG.


6


.




Then, the cutting tool


190


is retracted in its radial direction away from the inner surface


174


of the base section


172


to the initial position, and is fed in the axial direction until the other side cutting edge of the body


194


which is nearer to the inner surface


182


of the arm section


178


is substantially aligned with the inner surface


182


. The cutting tool


190


is then fed in the radial direction toward the inner surface


174


, to remove the remaining portion of the rib


176


and cut the inner surface


182


, in the same manner as described above. In this case, too, a fillet


198


is left between the adjacent ends of the inner surface


174


and the inner surface


182


.




The cutting operation with the cutting tool


190


is performed such that only the rib


176


is removed, without cutting any part of the inner surface


174


on which the rib


176


is not formed on the blank


160


before the cutting operation. As a result of removal of the rib


176


, the inner surface


142


of the base section of the piston


14


produced from the blank


160


has the central machined surface area


154


extending in the direction of the centerline N, and the two as-cast surface areas


156


on the opposite sides of the machined surface area


154


, as indicated in FIG.


3


and as described above. The as-cast surface areas


154


are provided by chilled layers having comparatively high degrees of hardness and strength, which are obtained by die-casting and which contribute to significant increase in the bending strength and durability of the base section


140


of the piston


14


. It is also noted that the fillets


198


between the adjacent ends of the inner surfaces


174


,


182


,


184


of the base and arm sections


172


,


178


,


180


are left uncut so as to provide as-cast surface areas, which contribute to a significant increase in the durability of the neck portion


80


of the piston


14


. The fillets


198


are located at the portions of the neck portion


80


at which the stress concentration is likely to occur.




The step of removing the ribs


176


from the blank


160


is followed by a step of forming the part-spherical recesses


152


in the machined inner surfaces


180


and


182


of the arm sections


178


,


180


, and a step of cutting the blank


160


into two pieces, at a midpoint intermediate between the adjacent arm sections


178


of the two neck portions


164


, to thereby provide the two pistons


14


.




The present embodiment of the invention assures improved durability of the piston


14


produced by die-casting, more particularly, a sufficiently high degree of durability of the neck portion


80


, although the piston


14


is configured and designed so as to reduce its weight.




While the body


194


of the cutting tool


190


used in the present embodiment has an axial dimension smaller than the dimension of the groove


84


of the piston as measured in the direction parallel to the centerline N, the body


194


may have a dimension equal to the dimension of the groove


84


. In this case, the rib


176


may be removed without moving the cutting tool


190


in the axial direction. It is also noted that the body


194


need not have the side cutting edges.




Referring next to

FIG. 7

, there will be described a second embodiment of this invention wherein a blank


200


is used to produce two pieces of a single-headed pistons for a swash plate type compressor, which piston has a single hollow cylindrical head portion.




The blank


200


consists of a body member


202


and a pair of closure members


204


. The body member


202


consists of a single twin neck portion


206


, and two hollow cylindrical head sections


208


formed integrally with the twin neck portion


206


such that the two hollow cylindrical head sections


208


extend from the opposite ends of the twin neck portion


206


. The twin neck portion


206


consists of mutually integrally formed two neck portions


205


which provide neck portions of the two pistons. Like the neck portions


164


of the blank


160


, each of the neck portions


205


includes a base section


210


and a pair of parallel arm sections


214


,


216


extending from an inner surface


212


of the base section


210


. The arm sections


214


,


216


have respective inner surfaces


218


,


220


which cooperate with the inner surface of the base section


210


to define a generally U-shaped structure. The neck portion


205


further includes a reinforcing rib in the form of a bridge section


222


connecting the opposed inner surfaces


218


,


220


of the arm sections


214


,


216


such that the bridge section


222


is spaced from the inner surface


212


. The body member


202


and the closure members


204


are formed by die-casting. In the blank


200


as shown in

FIG. 7

, the closure members


204


are fixedly fitted in the open end portions of the respective head sections


208


, by suitable fixing means such as beam welding. In the present second embodiment, the same reference numerals as used in

FIGS. 1-6

are used to identify the structurally similar or functionally corresponding elements.




The bridge section


222


of each neck portion


205


of the twin neck portion


206


of the blank


200


is removed by the cutting tool


190


, in the same manner as described above with respect to the first embodiment. Then, casting fins formed on the central portion of the inner surface


212


of the base section


210


are removed by the cutting tool


190


. In this second embodiment, too, two mold halves used to die-cast the blank


200


define a parting plane which includes the centerline of the hollow cylindrical head sections


208


and which is parallel to the direction of extension of the arm sections


214


,


216


. When the die-cast blank


200


is removed from the mold halves, small fins are formed in the generally elongate central portion of the inner surface


212


which extends in the direction of the centerline. In this embodiment, too, only the elongate central portion of the inner surface


212


of the base section


210


is machined to remove the fins, and the two portions of the inner surface


212


on the opposite sides of the central portion as well as the fillets between the inner surface


212


and the inner surfaces


218


,


220


of the arm sections


214


,


216


are left as-cast, so that the pistons obtained from the blank


200


has a high degree of durability at the base section


210


of their neck portions.




While the central part of the inner surface


142


,


212


of the base section


140


,


210


and the fillets


198


are left as-cast in the illustrated embodiments, only the central part of the inner surface


142


,


212


may be left as-cast, or any desired portions other than the inner surface


142


,


212


and fillets


198


may be left as-cast, in order to increase the strength or wear resistance of those other portions. Those other portions may include the outer surface of the base section


140


,


210


, and the surface of the rotation preventing part


88


.




Further, the piston according to the present invention may be configured otherwise. For instance, the present invention is equally applicable to a double-headed piston having two head portions on the opposite sides of the neck portion.




It is to be understood that the present invention may be embodied with various other changes, modifications and improvements such as those described above in the SUMMARY OF THE INVENTION, which may occur to those skilled in the art, without departing from the spirit and scope of the invention defined in the following claims.



Claims
  • 1. A die-cast piston for use in a swash plate compressor including a cylinder block having a cylinder bore formed therein, said piston comprising a generally cylindrical head portion capable of being slidably received in said cylinder bore, and a generally U-shaped neck portion having a base section and a pair of substantially parallel arm sections which extend from said base section,wherein said base section has an inner surface including at least one as-cast surface area formed in a die-casting process.
  • 2. A die-cast piston according to claim 1, wherein said inner surface includes a central machined surface area and a pair of as-cast surface areas, said central machined surface area being located at an intermediate portion of said inner surface as viewed in a direction perpendicular to a centerline of the piston which passes a center of said generally cylindrical head portion, said central machined surface area being formed as a result of a machining operation in said intermediate portion of said inner surface, and wherein said pair of as-cast surface areas are located on opposite sides of said central machined surface area as viewed in said direction.
  • 3. A die-cast piston according to claim 1, wherein a substantially entire portion of said inner surface is an as-cast surface area.
  • 4. A die-cast piston according to claim 1, wherein said pair of arm sections have opposed inner surfaces having as-cast surface areas adjacent to said at least one as-cast surface area, said as-cast areas of said arm sections being also formed in said die-casting process.
  • 5. A die-cast piston according to claim 1, wherein said head portion includes a body section having a circular shape in transverse cross section and cooperating with said cylinder bore to partially define a pressurizing chamber, said piston further comprising a connecting portion which connects said head portion and said neck portion.
  • 6. A die-cast piston according to claim 5, wherein said head portion further includes a sliding section extending from said body section and connecting said body section and said connecting portion.
  • 7. A die-case piston according to claim 1, wherein as-cast surface areas are formed at the boundary between the opposed inner surfaces of the arm sections and the inner surface of the base section.
  • 8. A method of producing a die-cast piston for use in a swash plate compressor including a cylinder block having a cylinder bore formed therein, said die-cast piston comprising a generally cylindrical head portion capable of being slidably received in said cylinder bore, and a generally U-shaped neck portion having a base section and a pair of substantially parallel arm sections which extend from said base section, said method comprising the steps of:forming a blank by die casting such that said blank includes: a head portion which gives said head portion of said piston; a neck portion which gives said neck portion of said piston and which includes a base section and a pair of arm sections; and a reinforcing portion which extends so as to connect said pair of arm sections of said neck portion of said blank, in a direction parallel to a centerline of said blank which passes a center of said head portion of the blank; and subjecting said blank to a machining operation to remove said reinforcing portion such that said base section of said neck portion of said blank has an inner surface including at least one as-cast surface area which is left unmachined.
  • 9. A method according to claim 8, wherein said reinforcing portion is a rib extending from a central portion of said inner surface of said base section of said blank in a direction of extension of said pair of arm sections of said blank, said central portion being located at an intermediate portion of the inner surface of the base section of said blank as viewed in a direction perpendicular to said centerline, said rib connecting said base section and pair of arm sections of said blank, and wherein said step of subjecting said blank to a machining operation comprises removing said rib such that said inner surface of said base section of said blank includes a central machined surface area and a pair of as-cast surface areas located on the opposite sides of said central machined surface area as viewed in the direction perpendicular to said centerline.
  • 10. A method according to claim 8, wherein said reinforcing portion is a bridge portion extending to connect said pair of arm sections of said blank in the direction parallel to said centerline, said bridge portion being spaced apart from said inner surface of said base section of said blank, and wherein said central portion is located at an intermediate portion of the inner surface of the base section of said blank as viewed in a direction perpendicular to said centerline, and wherein said step of subjecting said blank to a machining operation comprises removing said bridge portion and machining a central portion of said inner surface of said base section of said blank to remove fins formed in said step of forming a blank, such that said inner surface of said base section of aid blank includes a central machined surface area and a pair of as-cast surface areas located on the opposite sides of said central machined surface area as viewed in the direction perpendicular to said centerline.
  • 11. A method according to claim 9, wherein said step of subjecting said blank to a machining operation comprises:positioning a rotary cutting tool having a peripheral cutting edge such that said rotary cutting tool is rotatable about an axis which is parallel to said centerline and which is aligned with a center of said rib as viewed in the direction perpendicular to said centerline; feeding said rotary cutting tool in a radial direction thereof toward said inner surface of said base section of said neck portion of said blank while said rotary cutting tool is rotated, so that said rib connecting said base section and said pair of arm sections of said blank is removed.
  • 12. A method according to claim 8, wherein said pair of arm sections of said neck portion of said blank have respective opposed inner surfaces which are opposed to each other in the direction parallel to said centerline, and said rotary cutting edge further has side cutting edges formed on opposite sides of said peripheral cutting edge, and wherein said machining operation comprises machining at least a portion of each of said opposed inner surfaces such that an end portion of said each of said opposed inner surfaces which is adjacent to said inner surface of said base section of said blank is left as an as-cast surface area.
  • 13. A method according to claim 10, wherein said step of subjecting said blank to a machining operation comprises:positioning a rotary cutting tool having a peripheral cutting edge such that said rotary cutting tool is rotatable about an axis which is parallel to said centerline and which is aligned with a center of said bridge portion as viewed in the direction perpendicular to said centerline; feeding said rotary cutting tool in a radial direction thereof toward said inner surface of said base section of said neck portion of said blank while said rotary cutting tool is rotated, so that said bridge portion connecting said pair of arm sections of said blank in the direction parallel to said centerline and said fins formed in said step of forming a blank are removed.
  • 14. A die-cast piston for use in a swash plate compressor including a cylinder block having a cylinder bore formed therein, said piston comprising a generally cylindrical head portion capable of being slidably received in said cylinder bore, and a generally U-shaped neck portion having a base section and a pair of substantially parallel arm sections which extend from said base section,wherein said base section has an inner surface including a machined surface area and at least one as-cast surface area formed in a die-casting process.
  • 15. A method of producing a die-cast piston for use in a swash plate compressor including a cylinder block having a cylinder bore formed therein, said die-cast piston comprising a generally cylindrical head portion capable of being slidably received in said cylinder bore, and a generally U-shaped neck portion having a base section and a pair of substantially parallel arm sections which extend from said base section, said method comprising the steps of:forming a blank by die casting such that said blank includes: a head portion which gives said head portion of said piston; a neck portion which gives said neck portion of said piston and which includes a base section and a pair of arm sections; and a reinforcing portion which extends so as to connect said pair of arm sections of said neck portion of said blank, in a direction parallel to a centerline of said blank which passes a center of said head portion of the blank; and subjecting said blank to a machining operation to remove said reinforcing portion such that said base section of said neck portion of said blank has an inner surface including a machined surface area and at least one as-cast surface area which is left unmachined.
Priority Claims (1)
Number Date Country Kind
11-239364 Aug 1999 JP
US Referenced Citations (5)
Number Name Date Kind
4519119 Nakayama et al. May 1985 A
5318091 Pavoni et al. Jun 1994 A
5960542 Umemura et al. Oct 1999 A
6146110 Higashihara et al. Nov 2000 A
6189434 Kawaguchi et al. Feb 2001 B1
Foreign Referenced Citations (2)
Number Date Country
9-203378 Aug 1997 JP
9-256952 Sep 1997 JP