Information
-
Patent Grant
-
6481977
-
Patent Number
6,481,977
-
Date Filed
Thursday, February 8, 200123 years ago
-
Date Issued
Tuesday, November 19, 200222 years ago
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Inventors
-
Original Assignees
-
Examiners
- Tyler; Cheryl J.
- Gray; Michael K.
Agents
-
CPC
-
US Classifications
Field of Search
US
- 417 2222
- 417 270
- 417 295
- 417 298
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International Classifications
-
Abstract
A swashplate type variable-displacement compressor includes a compressor housing defining therein a crank chamber, a refrigerant suction chamber, a refrigerant discharge chamber, and a low-pressure refrigerant passage connected to an evaporator outlet, and a pressure regulator. The pressure regulator controls the amount of low-pressure refrigerant gas flowing into the refrigerant suction chamber by regulating a differential pressure between the pressure in the refrigerant suction chamber and the pressure in the crank chamber. The pressure regulator is comprised of a flow control valve including a first spring-loaded, normally-closed spool valve and a pressure chamber accumulating the working pressure used to force the spool valve toward its fully-opened position, and a flow control valve actuating mechanism including a communication passage through which the refrigerant discharge chamber is communicated with the pressure chamber, a second spring-loaded, normally-closed pilot valve provided in the communication passage, and an electromagnetic solenoid controlling the opening of the pilot valve so that the opening increases with an increase in exciting current supplied to the solenoid. The pilot valve serves to introduce high-pressure refrigerant gas in the refrigerant discharge chamber into the pressure chamber as the working pressure with the opening controlled by the solenoid.
Description
TECHNICAL FIELD
The present invention relates to a swashplate type variable-displacement compressor, and particularly to a swashplate type variable-displacement compressor serving as a compression part of a refrigerator circuit such as an automotive air-conditioning system, so as to compress refrigerant vapor to a relatively high pressure.
BACKGROUND ART
In recent years, there have been proposed and developed various swashplate type variable-displacement compressors in which a valve opening of a pilot valve is controlled depending on a current value of exciting current for an electromagnetic solenoid, in order to act high-pressure refrigerant gas introduced from a refrigerant discharge chamber via the pilot valve having the controlled opening on the back of a piston-shaped spool valve portion for adjustment of axial position of the piston-shaped spool valve portion, and consequently to control the amount of low-pressure refrigerant gas flowing into a refrigerant suction chamber. One such swashplate type variable-displacement compressor has been disclosed in Japanese Patent Second Publication No. 6-89741. The swashplate type variable-displacement compressor disclosed in the Japanese Patent Second Publication No. 6-89741, is basically constructed as a typical swashplate type variable-displacement compressor equipped with a compressor clutch which is a solenoid-type electromagnetic clutch located in a compressor pulley. The clutch equipped swashplate type variable-displacement compressor is complicated in structure. Generally, the clutch equipped swashplate type variable-displacement compressor is comparatively heavy in weight, and also requires many component parts. In addition to the above, when the amount of low-pressure refrigerant gas flowing from the evaporator outlet into the refrigerant suction chamber of the compressor must be adjusted to “0” to prevent icing of the evaporator core during operation of the swashplate type compressor with the compressor clutch engaged, the magnitude of exciting current of the electromagnetic solenoid which is used to actuate the pilot valve is generally controlled to the maximum so as to move the piston-shaped spool valve portion to a fully-closed position corresponding to the maximum length of the piston-shaped spool valve stroke, thus resulting in increased electric power consumption.
SUMMARY OF THE INVENTION
Accordingly, it is an object of the invention to provide a swashplate type variable-displacement compressor, which avoids the aforementioned disadvantages.
It is another object of the invention to provide a lightweight, clutchless swashplate type variable-displacement compressor, which is capable of being switched between operative (ON) and inoperative (OFF) states without using a compressor clutch, and of controlling evaporator icing by demagnetizing an electromagnetic solenoid used to operate a pilot valve (capable of controlling the flow of refrigerant from the evaporator outlet to a refrigerant suction chamber of the compressor) for the purpose of adjustment of the amount of low-pressure refrigerant gas flowing into the refrigerant suction chamber to “0”.
In order to accomplish the aforementioned and other objects of the present invention, a swashplate type variable-displacement compressor comprises a compressor housing which defines therein a crank chamber, a refrigerant suction chamber, a refrigerant discharge chamber, and a low-pressure refrigerant passage connected to an evaporator outlet, a pressure regulator which controls an amount of refrigerant gas flowing into the refrigerant suction chamber by regulating a differential pressure between a pressure in the refrigerant suction chamber and a pressure in the crank chamber, the pressure regulator comprising a flow control valve including a first spring-loaded, normally-closed valve, a return spring permanently biasing the first valve to a fully-closed position, a spring chamber operably accommodating therein the return spring, and a pressure chamber accumulating a working pressure used to force the first valve toward a fully-opened position, the flow control valve provided in the low-pressure refrigerant passage upstream of the refrigerant suction chamber, and a flow control valve actuating mechanism including a communication passage through which the refrigerant discharge chamber communicates with the pressure chamber, a second spring-loaded, normally-closed valve provided in the communication passage, a return spring permanently biasing the second valve to a fully-closed position, and an electromagnetic solenoid controlling an opening of the second valve so that the opening increases with an increase in exciting current supplied to the solenoid, the second valve serving to introduce high-pressure refrigerant gas in the refrigerant discharge chamber into the pressure chamber as the working pressure with the opening controlled by the solenoid.
According to another aspect of the invention, a swashplate type variable-displacement compressor comprising a compressor housing which defines therein a crank chamber, a refrigerant suction chamber, a refrigerant discharge chamber, and a low-pressure refrigerant passage connected to an evaporator outlet, a pressure regulator which controls an amount of refrigerant gas flowing into the refrigerant suction chamber by regulating a differential pressure between a pressure in the refrigerant suction chamber and a pressure in the crank chamber, the pressure regulator comprising a flow control valve including a spring-loaded, normally-closed spool valve, a return spring permanently biasing the spool valve to a fully-closed position, a spring chamber operably accommodating therein the return spring, and a pressure chamber accumulating a working pressure used to force the first valve toward a fully-opened position, the flow control valve provided in the low-pressure refrigerant passage upstream of the refrigerant suction chamber, and a flow control valve actuating mechanism including a communication passage through which the refrigerant discharge chamber communicates with the pressure chamber, a second spring-loaded, normally-closed pilot valve provided in the communication passage, a return spring permanently biasing the pilot valve to a fully-closed position, and an electromagnetic solenoid controlling an opening of the pilot valve so that the opening increases with an increase in exciting current supplied to the solenoid, the pilot valve serving to introduce high-pressure refrigerant gas in the refrigerant discharge chamber into the pressure chamber as the working pressure with the opening controlled by the solenoid, and the flow control valve including a pressure regulating passage which escapes or channels the working pressure in the pressure chamber into the refrigerant suction chamber, and a flow-constriction means which serves to generally fully close the pressure regulating passage when the spool valve is held at the fully-opened position. It is preferable that the pressure regulating passage may comprise a communication passage through which the spring chamber of the flow control valve communicates with the refrigerant suction chamber, and a flow-constriction passage formed in the spool valve to intercommunicate the pressure chamber and the spring chamber. More preferably, the variable-displacement compressor may further comprise a stopper provided in the spring chamber to limit the fully-opened position of the spool valve and to close an opening end of the flow-constriction passage facing the spring chamber by abutment between the spool valve and an end face of the stopper when the spool valve is held at the fully-opened position. Also, the flow-constriction means may comprise a flow-constriction orifice groove formed on at least one of the end face of the stopper and the opening end of the flow-constriction passage facing the spring chamber to provide a flow-constriction orifice having a predetermined orifice size smaller than a flow-constriction passage area of the flow-constriction passage under a condition in which the fully-opened position of the spool valve is limited by abutment between the spool valve and the end face of the stopper. Preferably, the spool valve has a spool groove, and a pressure-receiving surface area of one side wall of the spool groove is dimensioned to be equal to a pressure-receiving surface area of the other side wall of the spool groove. It is preferable that the flow control valve actuating mechanism may further comprise a feedback means which detects a change in pressure in the evaporator outlet side of the low-pressure refrigerant passage upstream of the flow control valve to shift the pilot valve to either of a valve opening direction and a valve closing direction depending on the pressure change detected when the pressure change in the evaporator outlet side of the low-pressure refrigerant passage exceeds a predetermined allowable pressure change under a condition that the pilot valve is held at a given opening, so that an opening of the flow control valve is controlled and thus the pressure in the evaporator outlet side is kept constant. The flow control valve actuating mechanism may further comprise a pressure regulating passage through which the crank chamber communicates with the evaporator outlet side of the low-pressure refrigerant passage upstream of the flow control valve.
According to a still further aspect of the invention, a swashplate type variable-displacement compressor comprises a compressor housing which defines therein a crank chamber, a refrigerant suction chamber, a refrigerant discharge chamber, and a low-pressure refrigerant passage connected to an evaporator outlet, a pressure regulator which controls an amount of refrigerant gas flowing into the refrigerant suction chamber by regulating a differential pressure between a pressure in the refrigerant suction chamber and a pressure in the crank chamber, the pressure regulator comprising a flow control valve including a spring-loaded, normally-closed spool valve, a return spring permanently biasing the spool valve to a fully-closed position, a spring chamber operably accommodating therein the return spring, and a pressure chamber accumulating a working pressure used to force the first valve toward a fully-opened position, the flow control valve provided in the low-pressure refrigerant passage upstream of the refrigerant suction chamber, and a flow control valve actuating mechanism including a communication passage through which the refrigerant discharge chamber communicates with the pressure chamber, a second spring-loaded, normally-closed pilot valve provided in the communication passage, a return spring permanently biasing the pilot valve to a fully-closed position, and an electromagnetic solenoid controlling an opening of the pilot valve so that the opening increases with an increase in exciting current supplied to the solenoid, the pilot valve serving to introduce high-pressure refrigerant gas in the refrigerant discharge chamber into the pressure chamber as the working pressure with the opening controlled by the solenoid, and the flow control valve including a pressure regulating passage which channels the working pressure in the pressure chamber into the refrigerant suction chamber, and a fluid-flow passage shutoff means which serves to fully close the pressure regulating passage when the spool valve is held at the fully-closed position. Additionally, the fluid-flow passage shutoff means serves to fully close the pressure regulating passage even when the spool valve is held at the fully-opened position. It is preferable that the pressure regulating passage may comprise a communication passage formed in the housing accommodating therein the spool valve to communicate the pressure chamber with the refrigerant suction chamber there via, a recessed portion formed on an outer periphery of the spool valve which is communicatable with an opening end of the communication passage facing the pressure chamber depending on an axial position of the spool valve, and an orifice passage formed in the spool valve to communicate the recessed portion with the pressure chamber there via, and the recessed portion is formed on the outer periphery of the spool valve so that the recessed portion is brought into fluid-communication with the opening end of the communication passage facing the pressure chamber only when the spool valve is held within a predetermined valve opening range of the spool valve except for both the fully-closed position and the fully-opened position, so as to form the fluid-flow passage shutoff means by the spool valve itself. More preferably, the pressure regulating passage may comprise a communication passage through which the spring chamber of the flow control valve communicates with the refrigerant suction chamber, and a flow-constriction passage formed in the spool valve to intercommunicate the pressure chamber and the spring chamber. Preferably, the fluid-flow passage shutoff means may comprise a differential pressure valve provided in the flow-constriction passage to fully close the flow-constriction passage in response to a differential pressure between the pressure chamber and the spring chamber when the spool valve is held at the fully-closed position, and a stopper provided in the spring chamber to limit the fully-opened position of the spool valve and to close an opening end of the flow-constriction passage facing the spring chamber by abutment between the spool valve and an end face of the stopper when the spool valve is held at the fully-opened position. Alternatively, the flow-constriction passage may comprise a communication passage provided in the spool valve to intercommunicate the pressure chamber and the spring chamber, and a bushing fitted to one opening end of the communication passage and having an orifice passage.
The other objects and features of this invention will become understood from the following description with reference to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a longitudinal cross-sectional view showing one embodiment of a swash plate type variable-displacement compressor of the invention.
FIG. 2
is a cross-sectional view systematically showing a first embodiment of a pressure regulator means incorporated in the variable-displacement compressor shown in
FIG. 1
, with a flow-control spool valve kept in its fully-opened state.
FIG. 3
is an enlarged cross-sectional view showing the detailed structure of a flow control valve of the pressure regulator means of the first embodiment shown in
FIG. 2
, with the flow-control spool valve partially opened.
FIG. 4
is a cross-sectional view systematically showing a second embodiment of a pressure regulator means incorporated in the variable-displacement compressor shown in
FIG. 1
, with a flow-control spool valve kept in its fully-opened state.
FIG. 5
is an enlarged cross sectional view showing the detailed structure of a flow control valve of the pressure regulator means sown in
FIG. 4
, with a flow-control spool valve kept in its fully-closed state.
FIG. 6
is an enlarged cross sectional view showing the detailed structure of the flow control valve of the pressure regulator means shown in
FIG. 4
, with the flow-control spool valve kept in its fully-opened state.
FIG. 7A
is an enlarged cross sectional view showing the detailed structure of a modified flow control valve of the pressure regulator means shown in
FIG. 4
, with a flow-control spool valve kept in its fully-closed state.
FIG. 7B
is a partly-enlarged cross sectional view showing the detailed structure of a fluid-flow passage shutoff means of the modified flow control valve of the pressure regulator means shown in FIG.
4
.
FIG. 8
is an enlarged cross sectional view showing the detailed structure of the modified flow control valve of the pressure regulator means shown in
FIG. 4
, with the flow-control spool valve kept in its fully-opened state.
FIG. 9
is an enlarged cross sectional view showing the detailed structure of a spool,valve of a further modified flow control valve of the pressure regulator means shown in FIG.
4
.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring now to the drawings, particularly to
FIG. 1
, there is shown a swashplate type variable-displacement compressor suitable for an automotive air conditioning system. In
FIG. 1
, a compressor housing or a compressor crankcase
1
of the variable-displacement compressor of the embodiment is comprised of a cylinder block
2
formed with a plurality of cylinder bores
3
, a front housing
4
located in front of the cylinder block
2
to define a crank chamber
5
in conjunction with the cylinder block
2
, and a rear housing
6
located in rear of the cylinder block
2
via a valve plate
9
to define both a refrigerant suction chamber
7
and a refrigerant discharge chamber
8
. Three parts, namely a drive plate
11
, a journal
14
, and a swash plate or a wobble plate
15
are provided in the crank chamber
5
. The drive plate
11
is fixedly connected to a drive shaft or a compressor shaft
10
. By means of a pin
13
, the journal
14
is rockably connected to a sleeve
12
which is rockably fitted onto the drive shaft
10
. The swash plate
15
is threadably connected onto the outer periphery of the journal
14
. The journal
14
is mechanically linked to the drive plate
11
by way of a substantially circular-arc shaped slotted cam
16
and pin connection of a pin
17
which is loosely fitted into the cam slot
16
, in such a manner as to allow the movement of the journal
14
with limits based on the cam slot
16
. A plurality of pistons
18
are reciprocatingly accommodated in the respective cylinder bores
3
. Each of the pistons
18
fits around the swash plate
15
through a pair of shoes (
19
,
19
) each of which is substantially hemispherical in shape. A compressor pulley
20
is rotatably supported on one end (the left-hand end as viewed from
FIG. 1
) of the drive shaft
10
through a radial ball bearing
21
. A first driving-torque transmission plate
22
is threadably connected onto the inner periphery of the pulley
21
, while a second driving-torque transmission plate
23
is fixedly connected to the leftmost shaft end of the drive shaft
10
. To provide a torque limiter, the first and second driving-torque transmission plates
22
and
23
are connected to each other in a manner so as to permit the second driving-torque transmission plate
23
to slip or slide with respect to the first driving-torque transmission plate
22
, in case of application of excessive driving torque exceeding a predetermined driving-torque limiting value. As is generally known, the swashplate type compressor can vary the piston displacement or the length of piston stroke according to the amount of low-pressure refrigerant needed. The length of the piston stroke can be adjusted by varying the inclination angle of the swash plate
15
. Hereinbelow described in detail, the inclination angle of the swash plate
15
can be changed while the compressor is running. The greater the angle of the swash plate
15
, the farther the pistons
18
move. in their cylinder bores
3
. As can be appreciated from the cross section shown in
FIG. 1
, the increased angle of the swash plate
15
increases the length of the piston stroke, so that the piston pumps more refrigerant gas. Conversely, as the inclination angle of the swash plate
15
is reduced, the length of the piston stroke also reduces, and thus each piston stroke pumps less refrigerant gas. In this manner, the compressor can be continuously run while only pumping the required amount of refrigerant gas. The swash-plate inclination angle can be controlled by means of a pressure regulator (or a pressure regulating means)
30
. The pressure regulating means
30
is provided in the rear housing
6
. Actually, the swash-plate inclination angle is controlled by the moment of a force about the pin
17
of the swash plate
15
, which moment occurs owing to the differential pressure between the refrigerant-suction-chamber pressure and the crankcase pressure (the pressure in crank chamber
5
). The differential pressure between the refrigerant-suction-chamber pressure and the crankcase pressure is controlled or regulated by the pressure regulating means
30
. As shown in
FIGS. 1 and 2
, in the variable-displacement compressor of the embodiment, pressure regulating means
30
is comprised of a flow control valve
31
, and a flow control valve actuating mechanism
32
which drives the flow control valve
31
. Flow control valve
31
is provided in a low-pressure refrigerant passage
25
close to a refrigerant inlet
24
located upstream of the refrigerant suction chamber
7
and connected to an evaporator outlet (not shown), so as to directly control the flow of low-pressure refrigerant gas sucked into the refrigerant suction chamber
7
.
For the sake of illustrative simplicity and for convenience, in
FIG. 1
the flow control valve
31
is arranged perpendicularly to the axis of the flow control valve actuating mechanism
32
, although the flow control valve
31
is actually arranged. parallel to the flow control valve actuating mechanism
32
so the compressor can be compactly designed. As shown in
FIG. 1
, the flow control valve
31
is comprised of a spool valve
33
whose axis is perpendicular to the low pressure refrigerant passage
25
, a spring chamber
37
in which a return spring (or a spool valve spring)
34
is operably accommodated to permanently bias the spool valve
33
to a fully-closed position, and a pressure chamber
35
which accumulates a working pressure used to force the spool valve
33
toward a fully-opened position. As can be seen from the cross section of
FIGS. 2 and 3
, the spool valve
33
is constructed as a spring-loaded, normally-closed spool valve, and the pressure-receiving surface area of one side wall
36
a
of the spool groove
36
of the spool valve
33
is dimensioned to be equal to that of the other side wall
36
b.
The spring chamber
37
, accommodating therein the spring
34
, is communicated through a communication passage
38
with the refrigerant suction chamber
7
downstream of the flow control valve
31
provided in the low-pressure refrigerant passage
25
. The flow control valve actuating mechanism
32
is provided in a communication passage
40
through which the refrigerant discharge chamber
8
and the pressure chamber
35
are communicated. The flow control valve actuating mechanism
32
is comprised of a ball valve
41
and an electromagnetic solenoid
42
. The ball valve
41
serves as a pilot valve which controls the flow of refrigerant gas in the high-pressure side of refrigerant discharge chamber
8
introduced into the pressure chamber
35
. As can be seen in
FIG. 2
, the pilot valve
41
is constructed as a spring-loaded, normally-closed ball valve. The pressure of refrigerant gas in the high-pressure side acts as a working pressure for the spool valve. The solenoid
42
functions to control the opening of the ball valve
41
, responsively to the current value of exciting current used to energize the solenoid. The ball valve
41
is a spring-loaded, normally-closed valve which is kept on its valve seat by means of a return spring
43
. When the solenoid
42
is energized, it forces an armature
44
upwards (viewing
FIG. 2
) to push a plunger
45
and consequently to control or adjust the opening of ball valve
41
. Actually, the valve opening of the pilot valve
41
increases with an increase in exciting current supplied to the solenoid
42
. For instance, when the current value of exciting current supplied to the solenoid becomes zero and thus the solenoid is de-energized, the valve opening becomes zero. Flow control valve actuating mechanism
32
is equipped with a feedback means
46
. The feedback means
46
is designed to detect or sense the pressure (or the pressure change) in the evaporator outlet side of the low-pressure refrigerant passage
25
upstream of the flow control valve
31
, so that the pressure in the evaporator outlet side is kept constant under a condition that the pilot valve
41
is held at a given opening substantially corresponding to the magnitude of exciting current supplied to the solenoid
42
. As best seen in
FIG. 2
, the feedback means
46
is comprised of a diaphragm
47
, a feedback passage
50
, and a plunger
51
. The diaphragm
47
separates an atmospheric chamber
48
from a refrigerant pressure chamber
49
. The feedback passage
50
is provided to introduce the pressure at the evaporator side of the low-pressure refrigerant passage
25
into the refrigerant pressure chamber
49
. The plunger
51
is supported by the central portion of the diaphragm
47
. The plunger
51
is arranged coaxially with respect to the axis of the plunger
45
of the solenoid
42
, so that the plungers
45
and
51
are opposed to each other. Actually, the feedback means
46
operates as follows. When an actual pressure change in the evaporator outlet side of low-pressure refrigerant passage
25
exceeds a predetermined allowable pressure change under a particular condition where the pilot valve
41
is controlled or held to a given opening substantially corresponding to the magnitude of exciting current supplied to the solenoid
42
, the actual pressure change is sensed or detected by means of the diaphragm
47
, and thus the pilot valve
41
is shifted to either of a valve opening direction and a valve closing direction by means of the plunger
51
depending on the pressure change detected, that is, a deviation from the predetermined allowable pressure change, so that the pressure in the evaporator outlet side of low-pressure refrigerant passage
25
can be kept constant and be brought into a desired pressure level by adjusting the opening of flow control valve
31
. The aforementioned refrigerant pressure chamber
49
is communicated with the crank chamber
5
through a pressure regulating passage
52
, so that the crank chamber
5
is communicated with the evaporator outlet side of the low-pressure refrigerant passage
25
upstream of the flow control valve
31
. On the other hand, the flow control valve
31
includes a pressure regulating passage
53
and a flow-constriction means or a flow-constriction orifice means
60
. Pressure regulating passage
53
relieves the pressure in the pressure chamber
35
and escapes the working pressure toward within the refrigerant suction chamber side of low-pressure refrigerant passage.
25
. Flow-constriction means
60
serves to generally fully close the pressure regulating passage
53
when the spool valve
33
is fully opened. In the variable-displacement compressor of the embodiment, as shown in
FIG. 3
the pressure regulating passage
53
is constructed by a flow-constriction passage
61
and a communication passage
38
. The flow-constriction passage
61
is formed in the spool valve
33
and has a predetermined orifice, size or a predetermined flow-constriction passage cross-sectional area through which the pressure chamber
35
is communicated with the spring chamber
37
. The communication passage
38
is provided to communicate the flow-constriction passage
61
and spring chamber
37
with;the refrigerant suction chamber side therethrough, so that the flow-constriction passage
61
and spring chamber
37
both open into the refrigerant suction chamber
7
. A stopper
62
is provided in the spring chamber
37
so that the stopper limits a fully-opened position of the spool valve
33
by way of abutment between the lower end of the spool valve
33
and the upper end face of the stopper
62
at a position that the upper end face closes the opening end
61
a
of flow-constriction passage
61
, facing the spring chamber.
Flow-constriction means
60
is constructed by forming a flow-constriction orifice groove
63
on the upper end face of the stopper
62
. The groove
63
is dimensioned to provide a predetermined flow-constriction orifice size or a predetermined flow-constriction passage area smaller than that of the flow-constriction passage
61
under a particular condition in. which the fully-opened position of spool valve
33
is limited by abutment between the upper end face of stopper
62
and the lower end of spool valve
33
. In the shown embodiment, although the groove
63
is provided at the upper end face of stopper
62
, in lieu thereof the flow-constriction orifice groove
63
may be provided at a side of the opening end
61
a
of flow-constriction passage
61
, or the groove
63
may be provided at both the side of the opening end
61
a
of flow-constriction passage
61
and the upper end face of stopper
62
.
With the previously-described arrangement, the opening of the ball valve
41
is controlled depending on the current value of exciting current flowing through the solenoid
42
, and thus the high-pressure refrigerant gas in refrigerant discharge chamber
8
is supplied through the ball valve
41
of the controlled opening into the communication passage
40
, and then introduced into the pressure chamber
35
as a working pressure for spool valve
33
. In response to the pressure in the pressure chamber
35
, the spool valve
33
moves toward its fully-opened position against the bias of spring
34
. The movement of spool valve
33
toward the fully-opened position tends to enlarge the fluid-flow passage area of low-pressure refrigerant passage
25
to properly control the flow of refrigerant gas flowing into the refrigerant suction chamber
7
. Depending on the controlled flow of refrigerant gas the pressure difference between the pressure in refrigerant suction chamber
7
and the crank-chamber pressure can be adjusted, and thus the swash-plate inclination angle can be controlled. As a result of this, the length of the piston stroke can be varied so as to control the flow of refrigerant gas discharged. In this manner, the temperature control of the evaporator (not shown) can be achieved. Hereupon, as discussed above, the flow control valve
31
includes the pressure regulating passage
53
through which the pressure in the pressure chamber
35
can be relieved and channeled into the refrigerant suction chamber side of low-pressure refrigerant passage
25
. Therefore, when the pilot valve (ball valve)
41
is closed by way of demagnetization of the electromagnetic solenoid
42
under a condition that the spool valve
33
is held at a given valve opening, the pressure regulating passage
53
serves to rapidly channel the working pressure in the pressure chamber
35
therethrough into the refrigerant suction chamber
7
, thus ensuring a smooth valve closing operation for the spool valve
33
by virtue of the bias of spring
34
. This enhances a response of the compressor serving as a power unit of the air conditioning system. As a whole, the refrigeration system response can be enhanced significantly. Additionally, according to the variable-displacement compressor of the embodiment, when the spool valve
33
is kept at the fully-opened position, the downstream opening end
61
a
of flow-constriction passage
61
(pressure regulating passage
53
) is maintained at the generally fully-closed state by means of the flow-constriction means
60
. Therefore, during high load of the variable-displacement compressor during which the spool valve
33
is held fully opened, there is no risk of leaking refrigerant gas under high temperature and high pressure, which gas can be introduced into the pressure chamber
35
, via the pressure regulating passage
53
into the refrigerant suction chamber
7
. This prevents a cooling performance of the refrigeration system from lowering during high compressor load with the spool valve
33
fully opened. Also, according to the variable-displacement compressor of the embodiment, the flow-constriction means
60
(flow-constriction orifice groove
63
) allows a controlled channeling of refrigerant-gas pressure from the pressure chamber
35
even when the spool valve
33
is kept at its fully-opened state, thus insuring smooth sliding movement of the spool valve
33
from the fully-opened position to the valve closed position, occurring owing to demagnetization of the solenoid
42
.
As set forth above, in the shown embodiment, the pressure regulating passage
53
is constructed by the flow-constriction passage
61
which is provided in the spool valve
33
itself, and the communication passage
38
through which the spring chamber
37
is opened into the refrigerant suction chamber
7
land which is used for balanced operation of the spool valve
33
. In this case, the pressure regulating passage
53
can be provided by boring only the communication passage
38
in the rear housing
6
. Thus, the number of machining processes for boring fluid passages in the housing can be reduced. This ensures a more simplified passage structure in the rear housing
6
, and also increases the design flexibility of the rear housing
6
. Furthermore, in the shown embodiment, the flow-constriction means
60
can be easily constructed by forming or machining the flow-constriction orifice groove
63
on the upper end face of the spool-valve fully-opened-position limiting stopper
62
, thereby ensuring reduced machining processes for the rear housing
6
, and thus reducing the production costs of the variable-displacement compressor or the total production costs of the automotive air conditioning system. Moreover, according to the variable-displacement compressor of the embodiment, in order to prevent an undesirable pressure drop in the evaporator side of low-pressure refrigerant passage
25
upstream of the flow control valve
31
by way of fluid-flow control of refrigerant flowing into the refrigerant suction chamber
7
for the purpose of preventing evaporator core icing when the refrigeration system is operating, the current value of exciting current flowing through the solenoid
42
is controlled to “0”, and thus the solenoid is merely demagnetized. Owing to demagnetization of the solenoid, the ball valve (pilot valve)
41
is fully closed so as to stop the working-pressure supply to the pressure chamber
35
of flow control valve
31
, and therefore the spool valve
33
moves toward its closed position by way of the bias of spring
34
to shut off the low-pressure refrigerant passage
25
. As a result, the amount of refrigerant gas introduced into the refrigerant suction chamber
7
can be controlled to “0” to cause a decreased angle of the swash plate
15
. The decreased swash-plate angle reduces the length of the piston stroke, thereby preventing the refrigerant gas pressure in the evaporator side of low-pressure refrigerant passage
25
from dropping, and thus preventing icing of the evaporator core. As discussed above, in the variable-displacement compressor of the embodiment, during the evaporator-deicing operating mode, only the supply of exciting current to the solenoid
42
is stopped. This effectively reduces electric power consumption. Additionally, the load of the compressor can be reduced to below almost zero by way of sliding movement of the spool valve
33
toward the fully-closed position by virtue of the spring bias. Thus it is possible to enhance the output of the driving source. Moreover, according to the variable-displacement compressor of the embodiment, when the spool valve
33
of flow control valve
31
is shifted to the fully-closed position by stopping the supply of exciting current to the solenoid
42
, the pressure in refrigerant suction chamber
7
tends to drop and thus the differential pressure between the in-cylinder pressure (the refrigerant-suction-chamber pressure) and the crankcase pressure (the crank-chamber pressure) becomes maximum, and thus the swash-plate angle reduces by the moment of a force about the pin
17
. As a result, the piston stroke becomes less and thus the work of compression of the compressor becomes almost zero. In this manner, the work of the compressor can be intermittently operated by energizing (magnetizing) or de-energizing (demagnetizing) the solenoid
42
. Therefore, in the variable-displacement compressor of the embodiment, there is no necessity of a compressor clutch which engages or disengages to permit transmission of driving torque to the compressor shaft (drive shaft) or prevent transmission of driving torque to the compressor shaft. That is to say, there is no necessity for heavy magnets and electromagnetic coils required for an electromagnetic compressor clutch, for example. In other words, according to the fundamental concept of the invention, a clutchless swashplate type variable-displacement compressor can be realized by controlling energization (magnetization) and de-energization (demagnetization) of the solenoid
42
of flow control valve actuating mechanism
32
. As a matter of course, the variable-displacement compressor of the embodiment is simple in structure. Also, there is no necessity of wiring harnesses for the electromagnetic clutch. This realizes a lightweight, clutchless swashplate type variable-displacement compressor. This means reduced production costs in manufacturing variable-displacement compressors. When rapidly accelerating or decelerating the vehicle under a condition that the ball valve (pilot valve)
41
is kept at a given opening by flowing exciting current of a predetermined current value across the solenoid
42
of flow control valve actuating mechanism
32
, the drive shaft
10
tends to positively or negatively fluctuate owing to torque fluctuations arising from the vehicle acceleration or deceleration. Due to the fluctuations in rotation of the compressor drive shaft, the refrigerant gas pressure at the evaporator side of low-pressure refrigerant passage
25
upstream of the flow control valve
31
also tends to change. The pressure change in the pressure at the evaporator side can be sensed by the diaphragm of the feedback means
46
at once, and as a result the ball valve
41
is properly shifted to the valve opening direction or to the valve closing direction by means of the plunger
51
depending on the pressure change, and whereby the pressure at the evaporator side can be maintained at a predetermined pressure level substantially corresponding to the current value of exciting current flowing through the solenoid
42
. Thus, it is possible to avoid a controlled temperature of the evaporator from undesiredly fluctuating owing to rapid vehicle acceleration or rapid vehicle deceleration. When the variable-displacement compressor with the feedback means is used for an automotive air conditioning system, there are less temperature fluctuations in conditioned air discharged from discharge outlets, and thus it is possible to provide stable air-conditioning operation. Additionally, in the variable-displacement compressor of the embodiment, the pressure-receiving surface area of the first side wall
36
a
of spool groove
36
of spool valve
33
is dimensioned to be equal to that of the second side wall
36
b
of spool groove
36
. Therefore, it is unnecessary to sense the pressure difference between the pressure applied to the first side wall
36
a
and the pressure applied to the second side wall
36
b.
That is, it is possible to easily enhance the control accuracy of upstroke (upward sliding movement) or downstroke (downward sliding movement) of spool valve
33
by managing or controlling both the bias of spring
34
and the working pressure applied to the pressure chamber
35
. This enables a high-accuracy flow control. Moreover, in variable-displacement compressor of the embodiment, the crank chamber
5
is communicated through the pressure regulating passage
52
with the evaporator side of low-pressure refrigerant passage
25
upstream of the flow control valve
31
, so the pressure in crank chamber
5
is adjusted to and held at the same low-side pressure at the evaporator side. Thus, it is possible to enhance the variable-displacement control accuracy of the compressor, while reducing a gas pressure change occurring due to blow-by gases introduced into the crank chamber
5
to the minimum.
Referring now to
FIGS. 4 through 6
, there are shown the longitudinal cross sections of the pressure regulating means
30
incorporated in the variable-displacement compressor of the second embodiment. The cross section of the pressure regulating means of
FIGS. 4-6
is similar to that of
FIGS. 2 and 3
, except that the structure of the flow control valve
31
of the pressure regulating means
30
of the second embodiment is different than the first embodiment. Thus, the same reference signs used to designate elements of the pressure regulating means shown in
FIGS. 2 and 3
will be applied to the corresponding elements of the second embodiment shown in
FIGS. 4-6
, for the purpose of comparison of the first and second embodiments. Elements
70
,
71
,
72
,
73
and
76
will be hereinafter described in detail with reference to the accompanying drawings, while detailed description of the other elements will be omitted because the above description thereon seems to be self-explanatory. As shown in
FIGS. 5 and 6
, the flow control valve
31
of the pressure regulating means
30
of the compressor of the second embodiment includes a fluid-flow passage shutoff means
70
as well as the pressure regulating passage
53
. As discussed above, the pressure regulating passage
53
serves to relieve the pressure in the pressure chamber
35
and to channel the pressure into the refrigerant suction chamber side of low-pressure refrigerant passage
25
. The fluid-flow passage shutoff means
70
functions to fully close the pressure regulating passage
53
when the spool valve
33
is fully closed. In the flow control valve structure of the second embodiment, as can be appreciated from the cross sections shown in
FIGS. 5 and 6
, fluid-flow passage shutoff means
70
also functions to fully close the pressure regulating passage
53
when the spool valve
33
is fully opened (see
FIG. 6
) and when the spool valve
33
is fully closed (see FIG.
5
). In more detail, as shown in
FIGS. 4 through 6
, a communication passage
71
is provided in the rear housing
6
which accommodates therein the spool valve
33
, so that the communication passage
71
communicates the refrigerant suction chamber side of low-pressure refrigerant passage
25
. The communication passage
71
is communicatable with the pressure chamber
35
depending on the axial position of the spool valve
33
. A substantially annular recessed portion
72
is formed on the outer peripheral surface of the spool valve
33
in such a manner as to be communicatable with the opening end of the communication passage
71
facing the pressure chamber
35
depending on the axial position of the spool valve
33
. To provide a desired orifice-constriction effect, an orifice passage
73
having a predetermined orifice size or a predetermined flow-constriction passage area is formed in the spool valve
33
. The substantially annular recessed portion
72
communicates with the pressure chamber
35
via the orifice passage
73
. In the second embodiment shown in
FIGS. 4 through 6
, the previously-noted pressure regulating passage
53
is comprised of the communication passage
71
, the recessed portion
72
, and the orifice passage
73
. Recessed portion
72
is designed or formed on the outer periphery of the spool valve
33
so that the recessed portion is brought into fluid-communication with the opening end of communication passage
71
only when the spool valve
33
is held within a predetermined stroke range of axial spool-valve stroke, that is, within a predetermined valve opening range of the spool valve
33
except for both the fully-closed position and the fully-opened position. Thus, the spool valve
33
itself serves as the previously-noted fluid-flow passage shutoff means
70
. A component part denoted by reference sign
76
corresponds to the spool-valve fully-opened-position limiting stopper
62
of flow control valve
31
of the first embodiment that limits the maximum downstroke (bottom dead center) of spool valve
33
by way of abutment between the lower end of the spool valve and the upper end face of the stopper. With the aforementioned arrangement of the second embodiment, when the solenoid
42
is energized, the opening of the ball valve
41
is controlled depending on the current value of exciting current flowing through the solenoid
42
. As a result, high-pressure and high-temperature refrigerant gas in the refrigerant discharge chamber
8
flows through the ball valve
41
into the communication passage
40
. The high-pressure, high-temperature refrigerant gas is thus introduced into the pressure chamber
35
as a working pressure for spool valve
33
. In response to the pressure in the pressure chamber
35
, the spool valve
33
moves toward its fully-opened position against the spring bias. The axial sliding movement of the spool valve
33
toward the fully-opened position tends to enlarge the fluid flow passage area of the low-pressure refrigerant passage
25
to control the flow of refrigerant flowing into the refrigerant suction chamber
7
. By the controlled flow of low-pressure refrigerant gas, the differential pressure between the refrigerant-suction-chamber pressure and the crank-chamber pressure can be adjusted and thus the swash-plate inclination angle can be controlled. As a result of this, the length of the piston stroke can be varied to control the flow of refrigerant gas discharged for the purpose of temperature control of the evaporator (not shown). In the same manner as the first embodiment, in the pressure regulating means incorporated in the variable displacement compressor of the second embodiment, the flow control valve
31
includes the pressure regulating passage
53
through which the pressure in the pressure chamber
35
can be relieved and channeled into the refrigerant suction chamber side of low-pressure refrigerant passage
25
. Thus, when the pilot valve (ball valve)
41
is closed by way of demagnetization of the solenoid
42
under a condition that the spool valve
33
is held at a given valve opening, the pressure regulating passage
53
serves to rapidly channel the working pressure in the pressure chamber
35
therethrough into the refrigerant suction chamber
7
, thus ensuring a smooth valve closing operation for the spool valve
33
by virtue of the spring bias. This enhances a response of the compressor (a power unit of the air conditioning system), thus ensuring enhanced entire system response. In addition to the above, according to the variable-displacement compressor of the second embodiment, when the spool valve
33
is kept at the fully-closed position (see FIG.
5
), the opening end of pressure regulating passage
53
facing the pressure chamber
35
is kept generally fully closed by means of the fluid-flow passage shutoff means
70
. This enables a rapid rise in the pressure in the pressure chamber
35
when the pilot valve (ball valve)
41
is opened. Therefore, even during low load of the compressor, that is, even in an operating range in which the discharge pressure of refrigerant gas introduced into the pressure chamber
35
as a working pressure is relatively low, it is possible to rapidly rise the pressure in the pressure chamber
35
, thereby ensuring initial sliding motion of the spool valve
33
, and thus enhancing the spool-valve start-up performance (that is, the spool-valve opening performance). Furthermore, in the variable-displacement compressor of the second embodiment, even when the spool valve
33
is kept at the fully-opened position (see FIG.
6
), the opening end of pressure regulating passage
53
facing the pressure chamber
35
is kept generally fully closed by means of the fluid-flow passage shutoff means
70
. Therefore, even during high load of the compressor with the spool valve
33
fully opened, it is possible to prevent the high-pressure and high-temperature refrigerant gas introduced into the pressure chamber
35
from flowing via the pressure regulating passage
53
into the refrigerant suction chamber
7
. This prevents a cooling performance of the refrigeration system from lowering during the high compressor load with the spool valve
33
fully opened. In particular, in the variable-displacement compressor of the second embodiment shown in
FIGS. 4-6
, depending upon the mutual setting between the position of the opening end of communication passage
71
facing the pressure chamber
35
and formed in the rear housing, and the axial machining range of the recessed portion
72
formed on the outer periphery of the spool valve
33
, the spool valve
33
itself constructs the fluid-flow passage shutoff means
70
. This effectively reduces the number of component parts, thus ensuring reduced production costs. Additionally, in the same manner as the first embodiment, in the variable-displacement compressor of the second embodiment, for the purpose of preventing icing of the evaporator core when the refrigeration system is operating, the current value of exciting current flowing through the solenoid
42
is simply controlled to “0”, and thus the solenoid is merely demagnetized. Owing to demagnetization of solenoid
42
, the ball valve (pilot valve)
41
is fully closed so as to stop the working-pressure supply to the pressure chamber
35
, and therefore the spool valve
33
moves toward its closed position by way of the spring bias to shut off the low-pressure refrigerant passage
25
. As a result, the amount of refrigerant gas introduced into the refrigerant suction chamber
7
can be controlled to “0” to cause a decreased angle of the swash plate
15
. The decreased swash-plate angle reduces the length of the piston stroke, thereby preventing the pressure in the evaporator side of low-pressure refrigerant passage
25
from falling too low, and thus preventing icing of the evaporator. As discussed above, according to the variable-displacement compressor of the second embodiment, during the evaporator-deicing mode, only the supply of exciting current to the solenoid
42
is stopped. This effectively reduces electric power consumption. As appreciated from the above, the variable-displacement compressor of the second embodiment provides the same effects as the first embodiment.
Referring now to
FIGS. 7A
,
7
B and
8
, there are shown the longitudinal cross sections of the modified flow control valve of the pressure regulating means
30
. The flow control valve
31
of
FIGS. 7A
,
7
B and
8
is slightly different from that of
FIGS. 4 through 6
, in that in the modified flow control valve of
FIGS. 7A
,
7
B and
8
, the pressure regulating passage
53
is constructed by a flow-constriction passage
74
and the communication passage
38
. Flow-constriction passage
74
is provided in the spool valve
33
in such a manner as to intercommunicate the pressure chamber
35
and the spring chamber
37
with orifice constriction. To-provide a desired orifice-constriction effect, flow-constriction passage
74
has a predetermined orifice size or a predetermined flow-constriction passage area. Spring chamber
37
is communicated through the communication passage
38
with the refrigerant suction chamber
7
. Flow-constriction passage
74
is also communicated through a differential pressure valve
75
(which will be fully described later) via the communication passage
38
with the refrigerant suction chamber
7
. As best seen in
FIGS. 7A and 8
, the flow-constriction passage
74
is provided in the spool valve
33
as an axial orifice passage formed along the axis of the spool valve
33
. As shown in
FIG. 8
, when the spool valve
33
is held at its fully-opened position, the opening end (the lower end) of flow-constriction passage
74
facing the spring chamber
37
is closed by way of the upper end face of spool-valve fully-opened-position limiting stopper
76
disposed in the spring chamber
37
. Conversely when the spool valve
33
is held at its fully-closed position (see FIG.
7
A), the differential pressure valve
75
, disposed in the flow-constriction passage
74
, serves to fully close the flow-constriction passage
74
in response to the differential pressure between the pressure in the pressure chamber
35
and the pressure in the spring chamber
37
. In the modified flow control valve shown in
FIGS. 7A
,
7
B and
8
, the fluid-flow passage shutoff means
70
is comprised of both the differential pressure valve
75
and the spool-valve fully-opened-position limiting stopper
76
. In the embodiment shown in
FIGS. 7A
,
7
B and
8
, a large-diameter bore portion is formed in the lower opening end portion of flow-constriction passage
74
facing the spring chamber
37
, and differential pressure valve
75
is provided in the large-diameter bore portion. As clearly shown in
FIG. 7B
, the differential pressure valve
75
is comprised of a ball valve
77
, a return spring
79
, and a spring seat
81
. Ball valve
77
is normally seated on a tapered valve seat
78
formed at the lower end of flow-constriction passage
74
by way of the bias of the spring
79
. The spring
79
forces the ball valve
77
toward the tapered valve seat
78
. Spring seat
81
is fixedly connected and fitted into the previously-noted large-diameter bore portion so as to define a valve chamber
80
and to support the lower end of spring
79
. Spring seat
81
has a plurality of axial through holes
82
through which the valve chamber
80
is communicated with the spring chamber
37
. As can be seen from the cross section of
FIG. 8
, when the spool valve
33
is held at the fully-opened position, all of the through holes
82
are closed by way of the upper end face of spool-valve fully-opened-position limiting stopper
76
. The spring bias of spring
79
is preset to quickly open the ball valve
77
when the working pressure is introduced into the pressure chamber
35
with the pilot valve
41
opened and thus the differential pressure between the pressure in the pressure chamber
35
and the pressure in the spring chamber
37
exceeds a predetermined differential-pressure threshold. With the previously-described arrangement of the embodiment shown in
FIGS. 7A
,
7
B and
8
, the variable-displacement compressor having the valve structure shown in
FIGS. 7A
,
7
B and
8
can provide the same effects as that shown in
FIGS. 4 through 6
. In addition, the pressure regulating passage
53
is constructed by both the flow-constriction passage
74
which is provided in the spool valve
33
itself, and the communication passage
38
through which the spring chamber
37
is opened into the refrigerant suction chamber
7
and which is used for balanced operation of the spool valve
33
. Thus, the number of machining processes for boring fluid passages in the rear housing
6
can be reduced. This ensures a more simplified passage structure in the rear housing, and also increases the design flexibility of the rear housing. Furthermore, the shutting-off operation of the pressure regulating passage
53
executed when the spool valve
33
is fully closed or fully opened can be achieved by both the differential pressure valve
75
and the spool-valve fully-opened-position limiting stopper
76
. Thus, the fluid-flow passage shutoff means
70
is very simple in structure.
Referring now to
FIG. 9
, there is shown the longitudinal cross section of another modified flow control valve structure of the pressure regulating means
30
. The flow control valve structure of
FIG. 9
is slightly different from that of
FIGS. 7A
,
7
B and
8
, as described hereunder.
In the flow control valve:structure of
FIGS. 7A
,
7
B and
8
, the flow-constriction passage
74
having the predetermined flow-constriction orifice passage area is formed in the spool valve
33
. On the other hand, in the flow control valve structure of
FIG. 9
, a communication passage
83
is provided in the spool valve
33
as an axial passage formed along the axis of the spool valve
33
and intercommunicating the pressure chamber
35
and the spring chamber
37
. A large-diameter bore portion is formed in the upper opening end portion of communication passage
83
facing the pressure chamber
35
. A bushing
84
has an orifice passage
85
. Bushing
84
is fitted into the large-diameter bore portion formed in the upper opening end portion of communication passage
83
. That is to say, the flow-constriction passage
74
is constructed by the axial communication passage
83
and the bushing
84
having the orifice passage
85
of the predetermined orifice size. In the flow control valve structure shown in
FIGS. 7A
,
7
B and
8
, to provide a predetermined orifice-constriction effect, the flow-constriction passage
74
of a relatively small orifice size has to be finely formed or bored directly in the spool valve
33
. In comparison with the flow-constriction orifice passage
74
of the flow control valve structure shown in
FIGS. 7A
,
7
B and
8
, the bore size of the communication passage
83
of the flow control valve structure of
FIG. 9
is comparatively large, thus facilitating machining of the axial bore formed in the spool valve
33
. Additionally, the predetermined orifice-constriction effect can be easily obtained only by fitting the bushing
84
having the fixed orifice
85
of the predetermined orifice size into the large-diameter bore portion of the spool valve, thus enhancing the productivity of the variable-displacement compressor.
In both the flow control valve structure shown in
FIGS. 7A
,
7
B and
8
and the flow control valve structure shown in
FIG. 9
, the differential pressure valve
75
is provided at one opening end of flow-constriction passage
74
facing the spring chamber
37
. In lieu thereof, the differential pressure valve may be provided at the other opening end of flow-constriction passage
74
facing the pressure chamber
35
. In this case, the bushing
84
of the flow control valve structure shown in
FIG. 9
has to be provided at the opening end of flow-constriction passage
74
facing the spring chamber
37
.
The entire contents of Japanese Patent Application No. P2000-040907 (filed Feb. 18, 2000) and P2000-040918 (filed Feb. 18, 2000) are incorporated herein by reference.
While the foregoing is a description of the preferred embodiments carried out the invention, it will be understood that the invention is not limited to the particular embodiments shown and described herein, but that various changes and modifications may be made without departing from the scope or spirit of this invention as defined by the following claims.
Claims
- 1. A swashplate type variable-displacement compressor comprising;a compressor housing which defines therein a crank chamber, a refrigerant suction chamber, a refrigerant discharge chamber, and a low-pressure refrigerant passage connected to an evaporator outlet; a pressure regulator which controls an amount of refrigerant gas flowing into the refrigerant suction chamber by regulating a differential pressure between a pressure in the refrigerant suction chamber and a pressure in the crank chamber, the pressure regulator comprising: (a) a flow control valve including a spring-loaded, normally-closed spool valve, a return spring permanently biasing the spool valve to a fully-closed position, a spring chamber operably accommodating therein the return spring, and a pressure chamber accumulating a working pressure used to force the spool valve toward a fully-opened position, the flow control valve provided in the low-pressure refrigerant passage upstream of the refrigerant suction chamber; and (b) a flow control valve actuating mechanism including a communication passage through which the refrigerant discharge chamber communicates with the pressure chamber, a second spring-loaded, normally-closed pilot valve provided in the communication passage, a return spring permanently biasing the pilot valve to a fully-closed position, and an electromagnetic solenoid controlling an opening of the pilot valve so that the opening increases with an increase in exciting current supplied to the solenoid, the pilot valve serving to introduce high-pressure refrigerant gas in the refrigerant discharge chamber into the pressure chamber as the working pressure with the opening controlled by the solenoid; and the flow control valve including a pressure regulating passage which channels the working pressure in the pressure chamber into the refrigerant suction chamber, and a flow-constriction means which serves to generally fully close the pressure regulating passage when the spool valve is held at the fully-opened position.
- 2. The swashplate type variable-displacement compressor as claimed in claim 1, wherein the pressure regulating passage comprises a communication passage through which the spring chamber of the flow control valve communicates with the refrigerant suction chamber, and a flow-constriction passage formed in the spool valve to intercommunicate the pressure chamber and the spring chamber, and which further comprises a stopper provided in the spring chamber to limit the fully-opened position of the spool valve and to close an opening end of the flow-constriction passage facing the spring chamber by abutment between the spool valve and an end face of the stopper when the spool valve is held at the fully-opened position, and wherein the flow-constriction means comprises a flow-constriction orifice groove formed on at least one of the end face of the stopper and the opening end of the flow-constriction passage facing the spring chamber to provide a flow-constriction orifice having a predetermined orifice size smaller than a flow-constriction passage area of the flow-constriction passage under a condition in which the fully-opened position of the spool valve is limited by abutment between the spool valve and the end face of the stopper.
- 3. The swashplate type variable-displacement compressor as claimed in claim 1, wherein the spool valve comprises a spool groove, and a pressure-receiving surface area of one side wall of the spool groove is dimensioned to be equal to a pressure-receiving surface area of the other side wall of the spool groove.
- 4. The swashplate type variable-displacement compressor as claimed in claim 1, wherein the flow control valve actuating mechanism further comprises a feedback means which detects a change in pressure in the evaporator outlet side of the low-pressure refrigerant passage upstream of the flow control valve to shift the pilot valve to either of a valve opening direction and a valve closing direction depending on the pressure change detected when the pressure change in the evaporator outlet side of the low-pressure refrigerant passage exceeds a predetermined allowable pressure change under a condition that the pilot valve is held at a given opening, so that an opening of the flow control valve is controlled and thus the pressure in the evaporator outlet side is kept constant.
- 5. The swashplate type variable-displacement compressor as claimed in claim 1, wherein the flow control valve actuating mechanism further comprises a pressure regulating passage through which the crank chamber communicates with the evaporator outlet side of the low-pressure refrigerant passage upstream of the flow control valve.
- 6. A swashplate type variable-displacement compressor comprising:a compressor housing which defines therein a crank chamber, a refrigerant suction chamber, a refrigerant discharge chamber, and a low-pressure refrigerant passage connected to an evaporator outlet; a pressure regulator which controls an amount of refrigerant gas flowing into the refrigerant suction chamber by regulating a differential pressure between a pressure in the refrigerant suction chamber and a pressure in the crank chamber, the pressure regulator comprising: (a) a flow control valve including a spring-loaded, normally-closed spool valve, a return spring permanently biasing the spool valve to a fully-closed position, a spring chamber operably accommodating therein the return spring, and a pressure chamber accumulating a working pressure used to force the first valve toward a fully-opened position, the flow control valve provided in the low-pressure refrigerant passage upstream of the refrigerant suction chamber; and (b) a flow. control valve actuating mechanism including a communication passage through which the refrigerant discharge chamber communicates with the pressure chamber, a second spring-loaded, normally-closed pilot valve provided in the communication passage, a return spring permanently biasing the pilot valve to a fully-closed position, and an electromagnetic solenoid controlling an opening of the pilot valve so that the opening increases with an increase in exciting current supplied to the solenoid, the pilot valve serving to introduce high-pressure refrigerant gas in the refrigerant discharge chamber into the pressure chamber as the working pressure with the opening controlled by the solenoid; and the flow control valve including a pressure regulating passage which channels the working pressure in the pressure chamber into the refrigerant suction chamber, and a fluid-flow passage shutoff means which serves to fully close the pressure regulating passage when the spool valve is held at the fully-closed position.
- 7. The swashplate type variable-displacement compressor as claimed in claim 6, wherein the fluid-flow passage shutoff means serves to fully close the pressure regulating passage when the spool valve is held at the fully-opened position.
- 8. The swashplate type variable-displacement compressor as claimed in claim 6, wherein the pressure regulating passage comprises a communication passage formed in the housing accommodating therein the spool valve to communicate the pressure chamber with the refrigerant suction chamber there via, a recessed portion formed on an outer periphery of the spool valve which is communicatable with an opening end of the communication passage facing the pressure chamber depending on an axial position of the spool valve, and an orifice passage formed in the spool valve to communicate the recessed portion with the pressure chamber there via, and the recessed portion is formed on the outer periphery of the spool valve so that the recessed portion is brought into fluid-communication with the opening end of the communication passage facing the pressure chamber only when the spool valve is held within a predetermined valve opening range of the spool valve except for both the fully-closed position and the fully-opened position, so as to form the fluid-flow passage shutoff means by the spool valve itself.
- 9. The swashplate type variable-displacement compressor as claimed in claim 6, wherein the pressure regulating passage comprises a communication passage through which the spring chamber of the flow control valve communicates with the refrigerant suction chamber, and a flow-constriction passage formed in the spool valve to intercommunicate the pressure chamber and the spring chamber.
- 10. The swashplate type variable-displacement compressor as claimed in claim 9, wherein the fluid-flow passage shutoff means serves to fully close the pressure regulating passage when the spool valve is held at the fully-opened position.
- 11. The swashplate type variable-displacement compressor as claimed in claim 10, wherein the fluid-flow passage shutoff means comprises a differential pressure valve provided in the flow-constriction passage to fully close the flow-constriction passage in response to a differential pressure between the pressure chamber and the spring chamber when the spool valve is held at the fully-closed position, and a stopper provided in the spring chamber to limit the fully-opened position of the spool valve and to close an opening end of the flow-constriction passage facing the spring chamber by abutment between the spool valve and the end face of the stopper when the spool valve is held at the fully-opened position.
- 12. The swashplate type variable-displacement compressor as claimed in claim 11, wherein the flow-constriction passage comprises a communication passage provided in the spool valve to intercommunicate the pressure chamber and the spring chamber, and a bushing fitted to one opening end of the communication passage and having an orifice passage.
- 13. The swashplate type variable-displacement compressor as claimed in claim 6, wherein the spool valve comprises a spool grove, and a pressure-receiving surface area of one side wall of the spool groove is dimensioned to be equal to a pressure-receiving surface area of the other side wall of the spool groove.
- 14. The swashplate type variable-displacement compressor as claimed in claim 6, wherein the flow control valve actuating mechanism further comprises a feedback means which detects a change in pressure in the evaporator outlet side of the low-pressure refrigerant passage upstream of the flow control valve to shift the pilot valve to either of a valve opening direction and a valve closing direction depending on the pressure change detected when the pressure change in the evaporator outlet side of the low-pressure refrigerant passage exceeds a predetermined allowable pressure change under a condition that the pilot valve is held at a given opening, so that an opening of the flow control valve is controlled and thus the pressure in the evaporator outlet side is kept constant.
- 15. The swashplate type variable-displacement compressor as claimed in claim 6, wherein the flow control valve actuating mechanism further comprises a pressure regulating passage through which the crank chamber communicates with the evaporator outlet side of the low-pressure refrigerant passage upstream of the flow control valve.
Priority Claims (2)
Number |
Date |
Country |
Kind |
2000-040907 |
Feb 2000 |
JP |
|
2000-040918 |
Feb 2000 |
JP |
|
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A |
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Nov 2000 |
A |
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Number |
Date |
Country |
6-89741 |
Nov 1994 |
JP |
2001-90657 |
Apr 2001 |
JP |