Information
-
Patent Grant
-
6402481
-
Patent Number
6,402,481
-
Date Filed
Tuesday, August 22, 200024 years ago
-
Date Issued
Tuesday, June 11, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
-
CPC
-
US Classifications
Field of Search
US
- 092 122
- 092 71
- 417 2221
- 417 2222
- 417 269
-
International Classifications
-
Abstract
The present invention relates to a variable capacity swash plate type compressor. The present invention is provided a variable capacity swash plate type compressor comprising: a housing means having a cylinder block with a plurality of cylinder bores formed therein and enclosing therein a crank chamber, a suction chamber, and a discharge chamber; a drive shaft rotatably supported by the housing means; a plurality of pistons reciprocatively disposed in each of the cylinder bores; a rotor mounted on the drive shaft so as to rotate together with said drive shaft in the crank chamber; a swash plate operatively connected to the rotor via a hinge means and slidably mounted on the drive shaft to thereby change an inclination angle thereof in response to changes of pressure in the crank chamber; a motion conversion means disposed between the swash plate and the pistons for converting rotation of the swash plate into reciprocation of the pistons in the respective cylinder bores; and a control valve means for changing a pressure level in the crank chamber; the hinge means including a support arm protruding from the rotor toward the swash plate, an arm having one end extending from the swash plate, and a pin means supported by the other end of the arm; and, the support arm having a recess with a depth being able to receive a displacement due to change of the inclination angle of the swash plate from one end surface of the support arm, and the arm is movably coupled with the support arm by the pin means so that the pin means is slidable in the recess in compliance with the change of the inclination angle of the swash plate.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a variable capacity swash plate type compressor adapted for use in an air conditioner for a vehicle, and more particularly to such compressor of an improved type which has a hinge mechanism for pivotally supporting a swash plate.
2. Description of the Related Art
In automotive air conditioners, a variable capacity swash plate type compressor is widely used, which generally comprises a drive shaft, a rotor or lug plate mounted on and rotating with the drive shaft, and a swash plate. The swash plate is rotatably disposed on a spherical outer surface of a spherical sleeve member slidably mounted on the drive shaft.
Between the rotor and the swash plate is arranged a hinge mechanism which normally includes a first arm member projecting from the rotor in the rear direction of the compressor, a second arm member projecting from the swash plate in the front direction of the compressor, and a pin member connecting the first and second arm members through a pair of holes each formed in the respective arm members. One of the holes, for example the hole formed in the rotor is elongated to guide the pin therein according to the change of inclination angle of the swash plate. The sliding motion of the pin within the elongated hole changes the inclination angle of the swash plate. The sliding motion of the pin within the elongated hole changes the inclination angle of the swash plate. The compressor also includes a plurality of pistons each engaged with the swash plate via semi-spherical shoes.
The hinge mechanism allows the swash plate to slide along and change its inclination angle with respect to the drive shaft. The hinge mechanism also allows the swash plate to rotate together with the drive shaft and the rotor. Rotation of the drive shaft causes the rotor and swash plate to rotate therewith, and accordingly, each pistion engaged with the swash plate reciprocates within respective cylinder bores so that suction and compression of the refrigerant gas are completed. The capacity of the compressor is controlled by changing the inclination angle of the swash plate according to the pressure difference between the pressure in the crank chamber and the suction pressure.
In the above described variable capacity swash plate type compressor, the swash plate rotates with the drive shaft and nutates back and forth with respect to the rotor, and the rotation of the swash plate is converted into the reciprocation of the pistons within the respective cylinder bores. A suction force acts on the swash plate from the pistons during the suction stroke while a compression reaction force also acts on the swash plate from the pistons during the compression stroke. Therefore, the swash plate is subject to a twisting motion or bending moment due to the suction and compression reaction forces acting from each piston on the swash plate. Moreover, since a torque exerted by the drive shaft is transmitted to the swash plate through the hinge mechanism, the swash plate is twisted with respect to the rotor in a direction different from the back and forth nutating motion.
As a solution for the above mentioned problems, U.S. Pat. No. 5,540,559 discloses a variable capacity compressor having an improved hinge unit. The hinge units comprise a pair of brackets protruding from the back surface of the rotary swash plate, a pair of guide pins each having one end fixed to each bracket and the other end fixed to a spherical element, and a pair of support arms protruding from the upper front surface of the rotor. Each support arm is provided with a circular guide hole into which the spherical element of the guide pin is rotatably and slidably inserted. U.S. Pat. No. 5,336,056 discloses a hinge means including two support arms extended axially rewardly from the rotary support. Each of the support arms has a through-bore in which a race member is fixedly seated to tunably receive a ball element. Each ball element, too, has formed therein a through-hole operative as a guide hole permitting an axial slide of a guide pin therin. The guide pins are fixedly press-fitted in two through-bores formed in the rotary drive element of the swash plate assembly, respectiverly.
However, the hinge mechanisms disclosed in the above U.S. Patents are complex, and in particular, they require precise and time-consuming machining to form the circular guide holes and spherical elements of the guide pins in U.S. Pat. No. 5,540,559 and to form through-bores in U.S. Pat. No. 5,336,056. Moreover, to make symmetrical the hinge mechanism including two support arms protruding from the rotor or the rotary drive element must be accurate and therefore is relatively burdensome. These raise the cost in manufacturing the compressor. Therefore, it is advantageous to provide a compressor with a hinge mechanism which is simple in its construction and machining thereof and prevents the twisting and bending of the swash plate.
SUMMARY OF THE INVENTION
An object of the present invention is, therefore, to provide a variable capacity swash plate type compressor which is free of the above-mentioned problems.
Another object of the present invention is to provide a variable capacity swash plate type compressor provided with a novel hinge mechanism which can be easily and inexpensively manufactured.
According to the present invention, there is provided a variable capacity swash plate type compressor comprising:
a housing means having a cylinder block with a plurality of cylinder bores formed therein and enclosing therein a crank chamber, a suction chamber, and a discharge chamber;
a drive shaft rotatably supported by said housing means
a plurality of pistons reciprocatively disposed in each of said cylinder bores;
a rotor mounted on said drive shaft so as to rotate together with said drive shaft in said crank chamber;
a swash plate operatively connected to said rotor via a hinge means and slidably mounted on said drive shaft to thereby change an inclination angle thereof in response to changes of pressure in said crank chamber;
a motion conversion means disposed between said swash plate and said pistons for converting rotation of said swash plate into reciprocation of said pistons in the respective cylinder bores; and
a control valve means for changing a pressure level in said crank chamber;
said hinge means including a support arm protruding from said rotor toward said swash plate, an arm having one end extending from said swash plate, and a pin means supported by the other end of said arm; and
said support arm having a recess with a depth being able to receive a displacement due to change of the inclination angle of said swash plate from one end surface of said support arm, and said arm is movably coupled with said support arm by said pin means so that said pin means is slidable in said recess in compliance with the change of the inclination angle of said swash plate.
Other objects, features, and advantages of the present invention will be understood from the detailed description of the preferred embodiments of the present invention with reference to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a longitudinal cross-sectional view of a variable capacity swash plate type compressor with a hinge means according to one embodiment of the present invention.
FIG. 2
is a perspective view showing the elements around a rotor in the compressor of FIG.
1
.
FIG. 3
is a partial cross-sectional view showing an assembled relation of a hinge means according to the present invention.
FIG. 4
is a partial cross-sectional view showing an assembled relation of a hinge means according to another embodiment of the present invention.
FIG. 5
shows a position on which the sum of the suction and compression reaction forces acts when suction and compression of a refrigerant gas occur.
FIG. 6
is a diagrammatical view illustrating a relationship between the time and the position of a piston and the pressure in a cylinder.
FIG. 7
shows a relationship between the operating point of sum of suction and compression reaction forces and the positions of support arms of the rotor.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to
FIGS. 1 through 3
, a variable capacity swash plate type compressor
10
has a cylinder block
12
provided with a plurality of cylinder bores
14
, a front housing
16
and a rear housing
18
. Both front and rear ends of the cylinder block
12
are sealingly closed by the front and rear housings
16
and
18
, and a valve plate
20
is intervened between the cylinder block
12
and the rear housing
18
. The cylinder block
12
and the front housing
16
define an air-tight sealed crank chamber
22
. A drive shaft
24
is centrally arranged to extend through the front housing
16
to the cylinder block
12
, and rotatably supported by radial bearings
26
and
27
. The cylinder block
12
and the front and rear housings
16
and
18
are tightly combined by a long screw
29
.
A rotor
30
is fixedly mounted on the drive shaft
24
within the crank chamber
22
to be rotatable with the drive shaft
24
, and supported by a thrust bearing
32
seated on an inner end of the front housing
16
. A swash plate
34
is rotatably supported on the drive shaft
24
. A spherical sleeve can be intervened between the drive shaft
24
and the swash plate
34
, and in this case, the swash plate
34
is rotatably supported on an outer support surface of the spherical sleeve. In
FIG. 1
, the swash plate
34
is in its largest inclination angle position, and at this time, a spring
38
is most compressed and a stop surface
36
a
of a projection
36
comes into contact with the rotor
30
so that a further increase of inclination angle of the swash plate
34
is restricted by the rotor
30
. On the other hand, a further decrease of inclination angle of the swash plate
34
is restricted by a stopper
37
provided with the drive shaft
24
.
As shown well in
FIGS. 2 and 3
, a hinge means or hinge mechanism designated by “K” includes a pair of support arms
40
protruding from an upper front surface of the rotor
30
in the rear direction of the drive shaft
24
, an arm
44
protruding from an upper back surface of the swash plate
34
toward the support arms
40
, and a pin
48
extending across the arm
44
. A rectangular or arc shaped recess
42
to guide the movement of the pin
48
is linearly formed around a free end of each support arm
40
in such a manner that the two recesses
42
formed in each support arm are opposed to each other in a parallel relation. Each recess
42
extends from the corresponding bottom surface of the support arms
40
toward the upper direction, and both opposed ends of each recess are open ended. The recesses
42
are also arranged in such a manner that the recesses
42
are formed along the loci connecting a pair of predetermined positions, at which both ends of the pin
48
in the arm
44
come into contact with the support arms
40
when a piston
50
is positioned at its top dead center and the swash plate
34
is in its largest inclination angle position, and another pair of predetermined positions, at which both ends of the pin
48
come into contact with the support arms
40
when a piston
50
is positioned at its top dead center and the swash plate
34
is in its smallest inclination angle position. The recesses
42
are symmetrically opposed with each other, and the depth of each recess
42
is defined to sufficiently receive the displacement of the swash plate from the smallest inclination angle position to the largest inclination angle position. In this manner, the support arms
40
and arm
44
are slidably connected to each other by the pin
48
. In this construction, the drive shaft
24
is arranged so as to be remotely interposed between the two support arms
40
when viewing over the compressor
10
.
In the above-described construction, the support arms
40
and arm
44
are formed in the rotor
30
and swash plate
34
, respectively, but to the contrary, the support arms
40
may be formed in the swash plate
34
and the arm
44
in the rotor
30
.
The pin
48
is able to be manufactured to have various shapes as long as it is able to guide the displacement of the swash plate
34
according to the changes in the inclination angle. Preferably, the pin
48
has a cylindrical shape to allow the friction due to the contact between the inside surfaces of the recesses
42
and the pin
48
to be minimized. As shown well in
FIG. 3
, the pin
48
includes at least one stepped portion
47
which is formed in one end portion of the pin
48
and has a smaller diameter than the central portion of the pin
48
. When the stepped portion
47
is formed in one end portion thereof, it is provided toward the direction to which the rotation of the swash plate
34
is applied. The stepped portion
47
of the pin
48
allows the rotation of the drive shaft
24
to be transmitted finally to the swash plate
34
by means of the contact between the stepped surface of the stepped portion
47
and the inside surface around the recess
42
in the support arm
40
.
Unlike the embodiment in
FIGS. 2 and 3
in which the stepped portion
47
is formed in the pin
48
as a means to transmit the rotational force of the drive shaft
24
to the swash plate
34
via the rotor
30
, the rotational force of the drive shaft
24
is able to be transmitted with the uniform diameter of the pin
48
without forming the stepped portion
47
. As shown in
FIG. 4
, at least one side surface of the arm
44
comes into surface contact with the inside surface of one of the support arms
40
in a direction of the rotation of the swash plate
34
so as to transmit the rotation of the drive shaft
24
to the swash plate
34
. Both ends of the arm
44
come into close contact with the inside surfaces of the support arms
40
.
The pin
48
is coupled with the arm
44
of the swash plate
34
by inserting the pin
48
into a through-bore
45
formed in the arm
44
. Alternatively, the arm
44
and the pin
48
are formed together. In addition, a single support arm
40
protruding from the rotor
30
may be formed, and in this case, the support arm
40
and the arm
44
are coupled with each other by the pin
48
which is, in turn, fixed by a means such as bolts and nuts.
By the hinge means “K”, the rotor
30
and the swash plate
34
are hinged to each other, and therefore, when the rotor
30
is rotated by rotation of the drive shaft
24
, the swash plate
34
is also rotated. Upward and downward movement of the pin
48
along the recesses
42
of the support arms
40
therewithin allows the swash plate
34
to slide along and incline with respect to the drive shaft
24
. Namely, the inclination angle of the swash plate
34
is adjusted with respect to an imaginary plane perpendicular to the axis of the drive shaft
24
.
As shown in
FIG. 1
, inner flat surfaces of semi-spherical shoes
52
come into contact with the outer peripheral portion of the swash plate
34
, and outer semi-spherical surfaces of the shoes
52
are slidably engaged with shoe pockets
51
formed in the respective pistons
50
. With this arrangement, a plurality of pistons
50
are engaged with the swash plate
34
via the shoes
52
, and the pistons
50
reciprocate within the respective cylinder bores
14
in response to the rotation of the swash plate
34
. That is, the shoes
52
serve as a motion conversion means for converting rotation of the swash plate
34
into reciprocation of each piston
50
.
The rear housing
18
is provided with inlet and outlet ports
54
and
56
, and divided into suction and discharge chambers
58
and
60
. The valve plate
20
has suction and discharge ports
66
and
68
. Each cylinder bore
14
is communicated with the suction chamber
58
and the discharge chamber
60
via the suction ports
66
and the discharge ports
68
. Each suction port
66
is opened and closed by a suction valve
62
, and each discharge port
68
is opened and closed by a discharge valve
64
, in response to the reciprocal movement of the respective pistons
50
. The opening motion of the discharge valve
64
is restricted by a retainer
70
.
A control valve means
72
is provided with the compressor
10
for adjusting a pressure level within the crank chamber
22
as shown in FIG.
1
.
Turning to
FIGS. 5 and 6
, the operating point of the resultant force of suction and compression reaction forces acting on the swash plate
34
is shifted from a position “P”, at which the swash plate
34
is engaged with one of the pistons
50
moved in the cylinder bore
14
to the top dead center “TDC” thereof, to a position “S” in a right direction with respect to the rotational direction of the swash plate
34
. When seven pistons, for example, reciprocate in the respective cylinder bores
14
in response to the rotation of the swash plate
34
, with respect to the rotational direction of the swash plate
34
compression reaction forces Pd and Pint act on the swash plate
34
in the right half portion therof while suction forces Ps act on the swash plate
34
in the left half portion thereof. At this time, the relation between the forces in their strength is Pd>Pint>Ps. When each of the pistons
50
approaches to the top dead center “TDC” thereof during the reciprocation thereof, the discharge of the compressed refrigerant gas from the corresponding cylinder bore
14
into the discharge chamber
60
is completed. And when the movement of the piston just having completed the discharge is reversed from the top dead center “TDC” to the bottom dead center “BDC
1
”, the suction of the refrigerant gas before compression is subsequently carried out for a time between the top dead center “TDC” and the bottom dead center “BDC
2
”. When each of the pistons
50
moves between the bottom dead center “BDC
1
” and the top dead center “TDC”, the compression reaction force of the refrigerant gas acts on the swash plate
34
, while when the piston
50
moves between the top dead center “TDC” and the bottom dead center “BDC2”, the suction force acts on the swsh plate
34
. Therefore, the resultant force of the compression reaction and suction forces applied to the swash plate
34
via the pistons
50
moves from the predetermined position “P” which lies on the center line of the swash plate
34
, i.e., at which the swash plate
34
is engaged with the pistion
50
moved in the cylinder bore
14
thereof to the top dead center “TDC” thereof, to the right position “S” with respect to the rotational direction of the swash plate
34
. The broken lines designate the pressure level within each cylinder bore
14
.
In the compressor having the above-described construction, when the drive shaft
24
is rotated, the swash plate
34
having a certain inclination angle is also rotated via the hinge means K, and thus the rotation of the swash plate
34
is converted into the reciprocation of the pistons
50
within the respective cylinder bores
14
via the shoes
52
. This reciprocating motion causes the refrigerant gas to be introduced from the suction chamber
58
of the rear housing
18
into the respective cylinder bores
14
in which the refrigerant gas is compressed by the reciprocating motion of the pistons
50
. The compresed refrigerant gas is discharged from the respective cylinder bores
14
into the discharge chamber
60
.
At this time, the capacity of the compressed refrigerant gas discharged from the cylinder bores
14
into the discharge chamber
60
is controlled by the control valve means
72
which adjustably changes the pressure level within the crank chamber
22
. Namely, when the pressure level Psc in the suction chamber
58
is raised with increase of the thermal load of an evaporator, the control valve means
72
cuts off the refrigerant gas travelling from the discharge chamber
60
into the crank chamber
22
so that the pressure level Pcc in the crank chamber
22
is lowerd. When the pressure level in the crank chamber
22
is lowered, a back pressure (crank chamber pressure Pcc) acting on the respective pistons
50
is decreased, and therefore, the angle of inclination of the swash plate
34
is increased. Namely, the pin
48
of the hinge means K in contact at both ends thereof with the recesses
42
slides along the recesses
42
of the support arms
40
toward the inner direction of the recesses
42
(the upper direction in FIG.
1
). Accordingly, the swash plate
34
is moved in a forward direction against the force of the spring
38
. Therefore, the angle of inclination of the swash plate
34
is increased, and as a result, the stroke of the respective pistons
50
is increased and the discharge capacity is increased.
On the contrary, when the pressure level Psc in the suction chamber
58
is lowered with decrease of the thermal load of the evaporator, the control valve means
72
passes the compressed refrigerant gas of the discharge chamber
60
into the crank chamber
22
. When the pressure level in the crank chamber
22
is raised, a back pressure (crank chamber pressure Pcc) acting on the respective piston
50
is increased, and therefore, the angle of inclination of the swash plate
34
is decreased. Namely, the pin
48
of the hinge means K in contact at both ends thereof with the recesses
42
slides along the recesses
42
of the support arms
40
toward the opened outer direction of the recesses
42
(the lower direction in FIG.
1
). Accordingly, the swash plate
34
is moved in a reward direction yielding to the force of the spring
38
. Therefore, the inclination angle of the swash plate
34
is decreased, and as a result, the stroke of the respective pistons
50
is shortened and the discharge capacity is decreased.
Referring to
FIGS. 5 and 6
again, in the compressor with the above-described construction, when operation of the compressor the suction force acts on about the left half portion of the swash plate
34
via the pistons
50
. On the other hand, the compression reaction force acts on about the right half portion of the swash plate
34
via the pistons
50
. One of the two support arms
40
in the rotor
30
is disposed on a position in the rotor
30
opposed to the position “S=P2” and the other of the support arms
40
is disposed on a position in the rotor
30
opposed to the position “P
1
”, while the arm
44
in the swash plate
34
is placed on the center line of the swash plate
34
. With this construction, the hinge means K prevents the bending moment applied to the swash plate
34
and, therefore, reduces a force exerted on the drive shaft
24
from the swash plate
34
. Since one of the support arms
40
of the hinge means K is disposed on the left position P
1
with respect to the top dead center TDC and the other is disposed on the right position P
2
with respect to the top dead center TDC, the suction and compression reaction forces are supported and absorbed by the hinge means of the support arms
40
, arm
44
and pin
48
. Therefore, the swash plate
34
can be prevented from being twisted around an axis perpendicular to the drive shaft
24
and from being subject to a bending moment around the above axis.
Now referring to
FIG. 7
, the support arms
40
may have their central axes locating in outsides of the positions P
1
and P
2
, respectively, as the next best way, although the support arms
40
are most preferable to being symmetrically formed in the respective positions P
1
and P
2
as described above. That is to say, the support arms
40
is able to be placed to meet
Lh≧Ls
where Lh is the horizontal distance between a plane M passing through the top dead cender TDC and the central axis of one of the support arms
40
, and Ls is the horizontal distance between the plane M and one of the positions P
1
and P
2
, for example, the position P
2
which is the operating point of the resultant force. If Lh<Ls, the support of the swash plate
34
becomes unstable so as to cause damage to the swash plate
34
because of a strong bending moment acting on a half portion of the swash plate
34
(the right half portion in FIG.
5
).
Biased abrasion of the surfaces of the recesses
42
caused by the exertion of the suction and compression reaction forces is able to be prevented because both end surfaces of the pin
48
come into surface contact with the respective surfaces of the recesses
42
of the support arms
40
.
Although the present invention has been described in connection with the preferred embodiments, the invention is not limited thereto. It will be easily understood by those skilled in the art that variations and modifications can be easily made within the scope of the present invention as defined by the appended claims.
Claims
- 1. A variable capacity swash plate type compressor comprising:a housing having a cylinder block with a plurality of cylinder bores formed therein and enclosing therein a crank chamber, a suction chamber, and a discharge chamber; a drive shaft rotatably supported by said housing; a plurality of pistons reciprocatively disposed in each of said cylinder bores; a rotor mounted on said drive shaft so as to rotate together with said drive shaft in said crank chamber; a swash plate operatively connected to said rotor via a hinge and slidably mounted on said drive shaft to thereby change an inclination angle thereof in response to changes of pressure in said crank chamber; a motion conversion means disposed between said swash plate and said pistons for converting rotation of said swash plate into a reciprocation of said pistons in the respective cylinder bores; and a control valve for changing a pressure level in said crank chamber; said hinge including a support arm protruding from said rotor toward said swash plate, a swash plate arm having one end extending from said swash plate, and a pin supported by the other end of said swash plate arm; and said support arm having a slot-shaped recess for receiving a displacement due to change of the inclination angle of said swash plate from one end surface of said support arm, and said swash plate arm is movably coupled with said support arm by said pin, so that said swash plate is slidable in said recess in compliance with the change of the inclination angle of said swash plate, wherein said pin includes a cylindrical pin provided with at least one stepped portion formed at one end portion of said pin, and the surface of said stepped portion comes into slidable contact with a surface around the recess of said support arm, so as to transmit the rotation of said drive shaft to said swash plate.
- 2. The compressor of claim 1, wherein said support arm includes a pair of a first support arm and a second support arm, each having a recess with a depth being able to receive the displacement due to change of the inclination angle of said swash plate from one end surface of the support arm, and said swash plate arm is movably coupled between said pair of said first and second support arms by said pin so that said pin is slidable in the recesses in compliance with the change of the inclination angle of said swash plate.
- 3. The compressor of claim 2, wherein said pin includes a second stepped portion formed at the other end portion of said pin, and said second stepped surface of said second stepped portion comes into slidable contact with a surface of said recess so as to transmit the rotation of said drive shaft to said swash plate.
- 4. The compressor of claim 2, wherein said swash plate arm of said swash plate comes into surface contact with one of said pair of said first and second support arms of said rotor to transmit the rotation of said drive shaft to said swash plate.
- 5. The compressor of claim 4, wherein said swash plate arm of said swash plate at both sides comes into contact with said pair of said first and second support arms therebetween.
- 6. The compressor of claim 3, wherein said pin is formed integrally with said swash plate arm of said swash plate.
- 7. The compressor of claim 2, wherein said recesses are arranged in the respective support arms in such a manner that said recesses are formed along loci connecting a pair of predetermined positions, at which both ends of said pin come into contact with said support arms when one of said pistons is positioned at its top dead center and the swash plate is in its largest inclination angle position, and another pair of predetermined positions at which said both ends of said pin come into contact with said support arms when said one of said pistons is positioned at its top dead center and said swash plate is in its smallest inclination angle position.
- 8. The compressor of claim 2, wherein one of said support arms is disposed on a corresponding position in said rotor opposed to an operating position on which a resultant force of suction and compression reaction forces applied to said swash plate acts, and the other is disposed on a corresponding position in said rotor opposed to a position, which, in turn, opposed to said operating position, and wherein said swash plate arm of said swash plate is disposed between said support arms.
- 9. The compressor of claim 2, wherein one of said support arms is disposed on a corresponding position in said rotor opposed to a first position in said swash plate satisfying a condition of Lh>Ls, in which Lh is a horizontal distance between a plane passing through a top dead center of one of said pistons and a central axis of one of said support arms, and Ls is a horizontal distance between said plane and an operating point on which a resultant force of suction and compression reaction forces applied to said swash plate acts, and the other of said support arms is disposed on a corresponding position in said rotor opposed to said first position, and wherein said swash plate arm of said swash plate is disposed between said support arms.
- 10. The compressor of claim 1, wherein said support arm includes a pair of arms, and said support arm is movably coupled between said pair of arms by said pin, so that said pin is slidable in said recess in compliance with the change of the inclination angle of said swash plate.
- 11. A variable capacity swash plate type compressor comprising:a housing having a cylinder block with a plurality of cylinder bores formed therein and enclosing therein a crank chamber, a suction chamber, and a discharge chamber; a drive shaft rotatably supported by said housing; a plurality of pistons reciprocatively disposed in each of said cylinder bores; a rotor mounted on said drive shaft so as to rotate together with said drive shaft in said crank chamber; a swash plate operatively connected to said rotor via a hinge and slidably mounted on said drive shaft to thereby change an inclination angle thereof in response to changes of pressure in said crank chamber; a motion conversion means disposed between said swash plate and said pistons for converting rotation of said swash plate into reciprocation of said pistons in the respective cylinder bores; a control valve for changing a pressure level in said crank chamber; said hinge including a pair of arms protruding from said swash plate toward said rotor, a support arm having one end extending from said rotor, and a pin supported by the other end of said support arm; said support arms having a recess for receiving a displacement due to change of the inclination angle of said swash plate from one end surface of the arm, and said support arm is coupled with said pair of arms by said pin, so that said pin is slidable in the recesses in compliance with the change of the inclination angle of said swash plate, wherein said pin includes a cylindrical pin provided with at least one stepped portion formed at one end portion of said pin, and the surface of said stepped portion comes into slidable contact with a surface of the recess of said support arm, so as to transmit the rotation of said drive shaft to said swash plate.
- 12. The compressor of claim 11, wherein said support arm comes into surface contact with one of said pair of arms of said swash plate to transmit the rotation of said drive shaft to said swash plate.
- 13. The compressor of claim 11, wherein one of said arms is disposed on a first position in said swash plate satisfying a condition of Lh≧Ls, in which Lh is a horizontal distance between a plane passing through a top dead center of one of said pistons and a central axis of one of said arms, and Ls is a horizontal distance between said plane and an operating point on which a resultant force of suction and compression reaction forces applied to said swash plate acts, and the other of said arms is disposed on a position in said swash plate opposed to said first position, and wherein said support arm of said rotor is disposed between said arms.
Priority Claims (1)
Number |
Date |
Country |
Kind |
99-58104 |
Dec 1999 |
KR |
|
US Referenced Citations (6)
Foreign Referenced Citations (2)
Number |
Date |
Country |
0775824 |
May 1997 |
EP |
0869281 |
Oct 1998 |
EP |