BACKGROUND OF THE INVENTION
(1) Field of the Invention
[0001] The present invention relates to a scroll type compressor suitable for an automobile
air conditioner, more particularly, to an improvement thereof of the lubrication for
a sealing means, bearings, and an anti-spin mechanism.
(2) Description of the Related Arts
[0002] A small size scroll type compressor suitably used for an automobile air conditioner
is disclosed in Japanese Unexamined Patent Publication No. 57-62988. According to
this scroll type compressor (hereinafter referred to as "compressor"), as shown in
Fig. 5, a stationary scroll member 52 comprising a stationary side plate 521 and a
stationary spiral body 522 is fixed to a housing half 51, and movable scroll member
54 comprising a movable side plate 541 and a movable spiral body 542 is arranged in
the housing half 51 and other housing half 53. The movable scroll member 54 is engaged
with the fixed scroll member 52, and thus a plurality of compression chambers 56 are
formed therebetween.
[0003] Within the interior of a housing consisting of both housing halves 51 and 53, is
rotatably secured a driving shaft 59 via a sealing means 57 and a main bearing 58,
and a pin 60 is eccentrically mounted to the inner end of the driving shaft 59. To
a base end region of the pin 60 closer to the main bearing 58 is fixed a counterweight
61, and to the other end region is fixed a drive bush 64 which supports the movable
scroll member 54 by a bearing 63 so that, in association with an anti-spin mechanism,
the movable scroll member is subjected only to an orbital motion and cannot spin on
its own axis. Structures and functions of the counterweight and the anti-spin mechanism
are described in detail such as in Japanese Unexamined Patent Publication Nos. 57-148,087
or 57-148,092.
[0004] As the spiral bodies 522 and 542 are defined by involute curves engageable with each
other, volume variations occur in each compression chamber 56 formed between the scroll
members 52 and 54 in accordance with the orbital motion of the movable scroll member
54, and this causes a coolant gas to flow into the compression chamber 56 through
an intake port 55, which gas is successively compressed in the chamber 56 and flows
out of an exit port 65 arranged centrally in the scroll members 52, 54, into a flow-out
chamber 66, and finally, is fed to a refrigeration circuit (not shown) through a fluid
discharge port 67.
[0005] In the compressor of the abovesaid type, the lubrication for front side mechanisms,
such as the sealing means 57, the bearings 58, 63 or the anti-spin mechanism 62, is
carried out by oil particles contained in the coolant gas.
[0006] According to the conventional compressor, however, the intake port 55 is provided
in the housing wall closer to a rear side, i.e., to the compression chamber 56, rather
than to the lubrication indispensable mechanisms in the front side area, so that the
coolant gas can be directly taken into the compression chamber 56 while keeping the
intake resistance at a lowest level. Accordingly, the coolant gas cannot be smoothly
introduced to the lubrication indispensable mechanism, whereby it also becomes difficult
to be sufficiently feed the lubricant in the coolant gas to such mechanisms, and in
the worst case, a seizure or over-wear of these mechanisms may occur.
[0007] To avoid such problems, it has been proposed to provide an additional path in the
housing for communicating the intake port and the sealing means (see Japanese Unexamined
Utility Model publication No. 59-24992). According to this means, however, it is necessary
to form, at an entrance of the additional path, a stepped portion having a complicated
shape, to correctly guide a lubricant in the coolant gas into the additional path,
which lowers the productivity thereof.
[0008] Thus, an object of the present invention is to provide a means for readily feeding
a sufficient amount of lubricant to the mechanisms arranged in the front side region
of the scroll type compressor, while avoiding an increase of the intake resistance
of the coolant gas.
SUMMARY OF THE INVENTION
[0009] The above object is achieved by a scroll type compressor, according to the present
invention, comprising a housing, a stationary scroll member fixed to the housing,
a movable scroll member engaged with the stationary scroll member and forming compression
chambers between the two scroll members, a drive shaft rotatably secured in the housing
by a main bearing, a pin eccentrically mounted on the inner end region of the pin,
a drive bush secured on the pin and supporting the movable scroll member so that the
movable scroll member is subjected to an orbital motion via a bearing while inhibited,
by an association with an anti-spin mechanism, from a rotation about its own axis,
and a counterweight mounted on the drive shaft for absorbing a dynamic unbalance of
the movable scroll member, whereby a coolant gas it taken into the compression chamber
through an intake port and pressurized in the compression chamber before being discharged
therefrom, in accordance with the orbital motion of the movable scroll member, and
is characterized in that the intake port is formed in a region of the housing wall
where the extention of the rotational plane of the counterweight intersects with the
housing wall, and communicates with an intake path directly connected to the compression
chamber.
[0010] Preferably, the counterweight is shaped to positively guide the coolant gas toward
the front side area. For example, the surface of the counterweight closer to the front
side area may be tapered so that the counterweight has a thinner width from the center
of rotation toward the periphery thereof.
[0011] According to the compressor of the present invention, the coolant gas is sucked into
the interior of the housing through the intake port formed in the defined region of
the housing wall, due to a negative pressure caused by the rotation of the counterweight.
When the counterweight occupies a rotational angular position at which the periphery
of the counterweight is away from the intake port, the coolant gas flows into the
housing without the interference of the counterweight and penetrates the lubrication
indispensable mechanisms in the front side area, such as the sealing means, the main
bearing or the anti-spin mechanism, whereby the sufficient lubrication can be performed.
Thereafter, the coolant gas is introduced into the compression chamber. On the other
hand, when the counterweight occupies a rotational angular position at which the periphery
of the counterweight confronts closer to the intake port, the main part of the coolant
gas is guided to the intake path directly communicating with the compression chamber.
Accordingly, the lubrication for the lubrication indispensable mechanisms is assuredly
carried out once a rotation of the counterweight.
[0012] The use of the counterweight having a shape which enhances the guiding of coolant
gas to the front side of the housing, enables the coolant gas to be better introduced
to the lubrication indispensable mechanisms in accordance with the rotation of the
counterweight.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] The present invention will be described in more detail with reference to the following
drawings illustrating preferred embodiments thereof:
Fig. 1 is a side sectional view of a scroll type compressor according to a first embodiment
of the present invention,
Fig. 2 is a section taken along line A-A in Fig. 1,
Fig. 3 is a section taken along line B-B in Fig. 1,
Fig. 4 is a side sectional view of a scroll type compressor according to a second
embodiment of the present invention, and
Fig. 5 is a side sectional view of a scroll type compressor according to the prior
art.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0014] As shown in Fig. 1, a scroll type compressor of a first embodiment of the present
invention has a stationary scroll member 2 consisting of a stationary side plate 21,
an outer shell 22 formed integrally with the stationary side plate 21, and a stationary
spiral body 23 formed in the inner side of the stationary side plate 21 and defined
by an involute curve. The stationary scroll member 2 is associated with a movable
scroll member 4 consisting of a movable side plate 41 and a movable spiral body 42
formed in the inner side of the stationary side plate 41, and is defined by another
involute curve so that a plurality of compression chambers 39 are formed by the engagement
of the spiral bodies 23, 42 with each other. Within the interior of a front housing
30 rigidly connected to the outer shell 22 of the stationary scroll member 2 through
a fastening means, a drive shaft 33 is rotatably supported by a sealing means 31 and
a main bearing 32. At the inner end of a larger diameter portion of the drive shaft
33 is eccentrically implanted a pin 34 to which a drive bush 36 is mounted. The bush
36 rotatably supports the movable scroll member 4 through a bearing 38 so that the
movable scroll member can be subjected to an orbital motion while preventing a rotation
thereof about its own axis, in association with an anti-spin mechanism 37. Further,
a counterweight 35 is secured to the pin 34 or the drive bush 36 for absorbing a dynamic
unbalance of the movable scroll member 4.
[0015] The anti-spin mechanism 37 consists of a stationary race 371 fixedly secured to the
front housing 30, a stationary ring 372 fixedly mounted to the race 371 and having
a plurality of positioning apertures 372a circularly arranged at a distance therebetween,
a plurality of balls 373, each accommodated in the respective aperture 372a, and a
movable ring 374 arranged opposite to the stationary ring 372 and having a plurality
of positioning apertures 374a coinciding with the respective balls 373. The movable
side plate 41 of the movable scroll member 4 is fixedly secured to the movable ring
374 of the anti-spin mechanism 37, and an exit port 11 is provided through the central
portion of the stationary side plate 21 of the stationary scroll member 2 and communicated
with the compression chamber 39 in the discharging phase. A rear housing 10 is fixedly
secured to the stationary scroll member 2 to form a flow-out chamber 13 inside of
the rear housing 10, and the flow-out chamber 13 is communicated with the compression
chamber 39 through the exit port 11 via a check valve 12, and with a refrigeration
circuit through a fluid discharging port (not shown).
[0016] A characteristic feature of the present invention is the structure of an intake port
8 communicating with the refrigeration circuit. The intake port 8 is formed in the
wall of the front housing 30 so that it is positioned in a region with which an extension
of a rotational plane of the counterweight 35 intersects. That is, during the rotation
of the counterweight, the periphery 35a of the counterweight can alternately occupy
two positions, away from the intake port 8 and closer thereto. An intake path 9 is
formed through the wall of the front housing 30, the stationary race 371 and the stationary
ring 372 so that the intake port 8 is directly communicated with the interior of the
compression chamber 39, whereby a coolant gas can flow into the compression chamber
39 without interference by the counterweight 35.
[0017] The operation of the above compressor will be explained below:
The compressor is driven by power from an engine (not shown) transmitted to a drive
shaft 33 (Fig. 1) via an electromagnetic clutch (not shown). The movable scroll member
4 is subjected to an orbital motion by the action of the driving bush 36 in association
with the anti-spin mechanism 37. Figure 3 illustrates the volume variation of the
compression chambers 39, a shape of the counterweight 35, and a position of the intake
path 9. Due to the rotation of the counterweight 35 having substantially a sector
shape, a negative pressure is generated in the area behind the counterweight, when
seen in the rotational direction. A coolant gas is readily introduced into the interior
of the housing through the intake port 8 due to this negative pressure, and fed to
the neighboring main bearing 32 and sealing means 31. After passing through the anti-spin
mechanism 37 and bearing 38, the coolant gas flows into the compression chamber 39,
the interior of which has a negative pressure due to the volume variation. In an angular
phase of rotation of the counterweight 35 shown in Fig. 1, at which the periphery
35a confronts the intake port 8, the coolant gas is directly introduced into the compression
chamber 39 through the intake path 9 communicating with the intake port 8. Therefore,
the coolant gas can be smoothly sucked in the compression chamber 39 without interference.
Thereafter, the coolant gas in the compression chamber 39 is successively pressurized
due to the orbital motion of the movable scroll member and delivered from the compression
chamber 39 into the flow-out chamber 13 through the exit port 11 against the check
valve 12, before being fed to the refrigeration circuit.
[0018] While, when the counterweight 35 further makes half a rotation from the position
shown in Fig. 1, the periphery 35a confronts the intake port 8. Thereby main part
of the coolant gas sucked from the intake port 8 is directed to the intake path 9
and directly reaches the compression chamber 39 without resistance.
[0019] As stated above, according to the present invention, the coolant gas is sufficiently
fed to the lubricant indispensable mechanisms once a rotation of the counterweight.
The structure of the inventive compressor is relatively simple and can be easily and
effectively manufactured. Also, as the intake resistance of the coolant gas is not
increased compared to the conventional compressor, the engine is not subjected to
an excessive burden.
[0020] A second embodiment of the present invention will be explained below with reference
to Fig. 4. The basic structure thereof is substantially the same as that of the first
embodiment, and accordingly, the same reference numerals are used in Fig. 4 as used
in Figs. 1 through 3 to designate similar parts and clarify the relationship therebetween.
[0021] In the second embodiment, the shape of a counterweight 351 is different from that
shown in Fig. 1, i.e., a thickness of the counterweight 351 becomes thinner as a function
of a distance from the rotational center to the periphery of the counterweight, as
defined by a slanted front side surface 35b. According to this structure, the guiding
of the coolant gas toward the front side is further enhanced by the slanted surface
35b when the counterweight 351 is rotating, whereby a better lubrication of the front
side mechanisms is achieved.
[0022] According to the embodiments stated above, the intake port is provided through the
wall of the front housing, but this is not essential to the present invention, as
the intake port may be formed in another position if the structure of the compressor
permits, provided that it confronts the periphery of the counterweight. Also, the
intake path need not be bored through the stationary race, if the structure of the
compressor permits.
[0023] A scroll type compressor comprising a stationary scroll member (2) and a movable
scroll member (4) accommodated in a housing (10, 39), the scroll members (2, 4) being
engaged with each other so that the movable scroll member (4) is subjected to an orbital
motion around the stationary scroll member (2) and forms compression chambers (39)
therebetween, in which chambers (39) a coolant gas is compressed by a volume reduction
of the chamber (39) in accordance with the orbital motion, and is discharged therefrom
to a refrigeration circuit. An intake port (8) for introducing the coolant gas into
the housing (10, 30) is provided at a position closer to lubrication indispensable
mechanisms such as a main bearing (32) or a sealing means (31) while confronting the
periphery of a counterweight (35). The coolant gas is sucked into the interior of
the housing (10, 39) and fed to the lubrication indispensable mechanisms (31, 32).
When the counterweight (35) is positioned on the side closer to the intake port (8),
the coolant gas is introduced directly therefrom to the compression chamber (39).
1. A scroll type compressor comprising a housing (10, 30), a stationary scroll member
(2) fixed to the housing (10), a movable scroll member (4) engaged with the stationary
scroll member (2) and forming compression chambers (39) between side two scroll members
(2, 4), a drive shaft (33) rotatably secured in the housing by a main bearing (32),
a pin (34) eccentrically mounted on the inner end region of the pin (34), a drive
bush (36) secured on the pin (34) and supporting the movable scroll member (4) so
that the movable scroll member (4) is subjected to an orbital motion via a bearing
(38) while being inhibited, by an association with an anti-spin mechanism (37), from
a rotation about its own axis, and a counterweight (35) mounted on the drive shaft
(33) for absorbing a dynamic unbalance of the movable scroll member (4), whereby a
coolant gas is taken into the compression chamber (39) through an intake port (8)
and pressurized in the compression chamber (39) before being discharged therefrom
in accordance with the orbital motion of the movable scroll member (4), characterized
in that
the intake port (8) is formed in a region of the housing wall where the extension
of the rotational plane of the counterweight (35) intersects with the housing wall,
and communicates with an intake path (9) directly connected to the compression chamber
(39).
2. A scroll type compressor as defined by claim 1, characterized in that
the counterweight (35) is shaped to positively guide the coolant gas toward lubricant
indispensable mechanisms (31, 33, 37, 38) accommodated in the front side area of the
interior of the compressor housing (10, 30).
3. A scroll type compressor as defined by claim 2, characterized in that
the thickness of the counterweight (35) becomes thinner toward the periphery (35a)
thereof, as a function of a distance from the rotational center of the counterweight
(35).
4. A scroll type compressor as defined by claim 1, characterized in that the intake
path (9) is proved in the vicinity of the intake port (8) in such a manner that it
is always open irrespective of the angular phase of rotation of the counterweight
(35).