JP3671201B2 - Rotary compressor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an improvement of a rotary compressor including a piston in which a blade is integrally projected on a roller capable of rotating eccentrically, and more particularly to measures for lubrication and cooling around the blade.
[0002]
[Prior art]
In general, for example, the piston in the rotary compressor as disclosed in JP-A 7-27074 Patent Publication, which is arranged as shown in FIGS. 4-6, the cylinder chamber of the cylinder (a) (b) (c ) Is an integrated body of the roller (d) and the blade (e), and the blade (e) protruding integrally from the roller (d) is inserted into the blade sliding groove (f) formed in the cylinder (a). The two holding members (h) and (h) constituting the rotary holding body (g) disposed in the blade sliding groove (f) are slidable and swingable.
[0003]
The cylinder chamber (b) is partitioned by the blade (e) into a suction chamber (i) and a compression chamber (j), and the eccentric rotational movement of the roller (d) and the sliding of the blade (e) The gas is sucked into the suction chamber (i) by the oscillating motion and is compressed in the compression chamber (j). In FIG. 9, the roller (d) is at the top dead center, and the entire cylinder (b) is the suction chamber (i).
[0004]
[Problems to be solved by the invention]
By the way, since the blade (e) slides while being sandwiched between the two sandwiching members (h) and (h), it is naturally required that the blade (e) slide smoothly.
[0005]
However, since the blade (e) and each clamping member (h) are always in surface contact with each other, even though the sliding resistance is reduced, there is a limit in itself and it is not always satisfactory.
[0006]
In addition, the fact that the sliding resistance reduction effect cannot be expected so much means that frictional heat is likely to be generated in the blade (e) that slides under high speed and high load, and seizure occurs when the frictional heat accumulates. This will reduce the reliability.
[0007]
In particular, the sliding contact position of the blade (e) with respect to each clamping member (h) changes with the eccentric rotational movement of the roller (d), and the blade (e) is alternately sandwiched between the distal end side and the proximal end side. Although the part which is not covered with a member (h) arises, the place always covered with each clamping member (h) also arises. And when the front end side and the base end side of the blade (e) are not covered with the holding members (h), they are exposed to the compressed gas and the mist-like lubricating oil mixed therewith to be cooled and have lubricity. Although it is replenished, the part always covered with each clamping member (h) is not exposed to the compressed gas and mist-like lubricating oil, and it cannot be denied that frictional heat accumulates and seizure occurs.
[0008]
The location means that when the roller (d), which is the maximum stalk of the blade (e), is at the top dead center (see FIG. 5 ) and at the bottom dead center (see FIG. 6 ), each clamping member (h) This is the S1 region covered with. That is, in the former case, the S2 region on the tip side of the blade (e) is exposed to the blade sliding groove (f) from each clamping member (h), but conversely in the latter case, the blade (e) base side S3 region of the blade (e) is exposed to the blade sliding groove (f), and therefore the S1 region excluding the S2 region on the distal end side and the S3 region on the proximal end side of the blade (e) is always each clamping member. It becomes a part covered with (h).
[0009]
The present invention has been made in view of the above points, and the object of the present invention is to expose the entire blade to a compressed gas and a mist-like lubricating oil mixed therewith, thereby reducing the sliding resistance of the blade and causing friction. It is to prevent seizure due to heat.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, the present invention is characterized in that a non-sliding contact portion is provided between a blade and a rotary holding body that holds the blade in a slidable and swingable manner.
[0011]
Specifically, as shown in FIGS. 2 and 3 , the present invention is a piston in which a rectangular plate-like blade (21) is integrally protruded radially outward on a roller (20) capable of eccentric rotation. 19), the roller (20) is disposed in the cylinder chamber (11) of the cylinder (12), and the blade (21) is inserted into a blade sliding groove (12d) formed in the cylinder (12). Then, the roller (20) is slidably and oscillated between the blade sliding grooves (12d) by the rotating clamping body (22) so that the roller (20) is eccentrically rotated in the cylinder chamber (11). At the same time, by sliding the blade (21) while sliding, the cylinder chamber (11) is divided into a suction chamber (11a) and a compression chamber (11b) by the blade (21), and gas is sucked into the suction chamber. (11a) while inhaling, compression A rotary compressor for compressing in (11b) assuming, took solving means as follows.
[0012]
In other words, solving means of the present invention, as shown in FIG. 1, the upper Symbol blade (21), so as to communicate between both sides facing the blade of the times Dokyo bearing member (22) (21) notch The portion (30) is opened to the tip end side of the blade (21), and a notch is formed in the middle of the blade (21) where the blade (21) and the rotary holding body (22) are always in contact with each other. In the section (30), the blade (21) and the rotating clamping body (22) are exposed to the compressed gas on the back side of the blade sliding groove (12d) and the mist-like lubricating oil (O) mixed therewith. It is characterized by having constituted so.
[0013]
By the above configuration, the resolving means of the present invention, the roller (20) rotates eccentrically in the cylinder (11), pivoting clamping blades with the eccentric rotary motion (21) in the blade sliding groove (12d) It swings while being slid between the body (22). Thus, the cylinder chamber (11) is partitioned into a suction chamber (11a) and a compression chamber (11b) by the blade (21), and the gas sucked into the suction chamber (11a) is compressed in the compression chamber (11b). The
[0014]
At this time, switching to the cutout portion (30), mist lubrication mixed in the compressed gas and it in the blade sliding groove (12d) between the blade (21) rotating clamping member (22) Oil (O) flows in from the tip side of the blade (21), and the blade (21) and the rotating clamp (22) are always exposed to compressed gas and mist-like lubricating oil (O) to be cooled and lubricated. Secured. Thus, the blade (21) is a high speed, even under conditions of sliding under a high load, the sliding resistance is frictional heat to the blade (21) hardly occurs less of the blade (21), the frictional heat is muffled The seizure caused by this is prevented and the reliability is improved.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
2 and 3 show the overall configuration of the rotary compressor according to the embodiment of the present invention. 2 and 3 , (1) is a casing, and the casing (1) has an upper end opening of a cylindrical intermediate cylinder (2) as an upper lid (3) and a lower end opening as a lower lid (3). 4) each of which is configured to have a sealed structure in which the inside is sealed, and a suction pipe (5) for introducing gas into the casing (1) is connected to the lower end of the intermediate cylinder (2). The upper lid (3) is connected to a discharge pipe (6) for discharging high-pressure compressed gas compressed in the casing (1) to the outside.
[0016]
Near the lower end of the casing (1), a compression mechanism (7) for sucking and compressing gas is disposed corresponding to the suction pipe (5), and above the compression mechanism (7) is operated. The driving mechanism (8) to be moved is arranged so as to occupy almost the entire inner space. And the space (lower lid (4) part) of the lower end part of the said casing (1) is used as the oil reservoir part (9) which stores lubricating oil (O), and the other space is the storage space (10 which stores compressed gas). ).
[0017]
The compression mechanism (7) includes a cylinder (12) having a cylinder chamber (11) having a circular cross section, and boss-like bearing portions (13a) are provided in the center on both upper and lower surfaces of the cylinder (12). The front head (13) having the same and a rear head (14) having a boss-like bearing (14a) at the center are fastened by a plurality of bolts (15), (15),. Is sealed. The cylinder (12) is fixed to the inner wall of the intermediate cylinder (2) of the casing (1) and is stably supported horizontally in the casing (1). A muffler member (16) is attached around the bearing portion (13a) of the front head (13) with an annular gap.
[0018]
A suction port (12a) is opened in the cylinder (12), and the suction pipe (5) communicates with the cylinder chamber (11) through the suction port (12a). Further, a discharge port (12b) is opened on the side of the suction port (12a) of the cylinder (12), and the discharge port (12b) communicates with a recess (12c) formed on the back side thereof. The recess (12c) communicates with the storage space (10) through a through-hole (not shown) formed in the front head (13), whereby the cylinder chamber (11) is connected to the storage space ( 10).
[0019]
In the recess (12c), a leaf spring-like discharge valve (17) is arranged to be supported by a pin (18) so that the discharge port (12b) can be opened and closed, and discharged into the storage space (10). The compressed gas is prevented from flowing back into the cylinder chamber (11).
[0020]
A piston (19) is disposed in the cylinder chamber (11) of the cylinder (12). The piston (19) includes an annular roller (20) having a circular insertion hole (20a) and the roller ( 20) and a rectangular plate-like blade (21) integrally projecting radially outward on the side wall, and the roller (20) is moved into the cylinder chamber (11) by a crankshaft (26) described later. It is arranged eccentrically.
[0021]
A blade sliding groove (12d) extending outward in the cylinder radial direction is formed between the suction port (12a) and the discharge port (12b) of the cylinder (12), and the blade sliding groove (12d) A perfectly circular bulging recess (12e) is formed on the front side, and two semicircular block-shaped clamping members (23) constituting the rotating clamping body (22) are formed in the bulging recess (12e). , (23) are arranged to be rotatable around a rotation center (Q). The blade (21) of the piston (19) is inserted into the blade sliding groove (12d) and is sandwiched by the clamping members (23) and (23) so as to be slidable from both sides in the cylinder radial direction. At the same time, the rotation of the rotation clamping body (22) is caused to swing around the rotation center (Q).
[0022]
On the other hand, the drive mechanism (8) is made includes an electric motor configured out with stator (24) and a low data (25), an intermediate cylindrical body of the stator (24) is a casing (1) (2) the inner wall a fixed support, the row data (25) are arranged concentrically with a gap in the circumferential direction inside the stator (24). Further, the upper half portion of the crankshaft (26) is rotatably integrated around the axis (P) inside the rotor (25), and the lower half portion of the crankshaft (26) is attached to the front head (13). ) And the rear head (14) are rotatably fitted and supported by both bearing portions (13a) and (14a). An oil passage (26a) extending in the axial direction is formed in the crankshaft (26), and a centrifugal oil pump (27) is attached to the lower end of the crankshaft (26). The oil pump (27) is constantly immersed in the lubricating oil (O) of the oil reservoir (9), and sucks the lubricating oil (O) into the oil passage (26a) according to the rotation of the crankshaft (26). It supplies to each sliding location of the said compression mechanism (7) and drive mechanism (8).
[0023]
An eccentric shaft portion (26b) is formed near the lower end of the crankshaft (26). The eccentric shaft portion (26b) is located in the cylinder chamber (11) and is inserted into the roller (20) of the piston (19). The roller (20a) is inserted into the hole (20a) so as to rotate integrally, and the roller (20) is eccentrically rotated in the cylinder chamber (11) by the rotation of the crankshaft (26) around the axis (P), so Thus, the cylinder chamber (11) is divided into a suction chamber (11a) and a compression chamber (11b). The volumes of the suction chamber (11a) and the compression chamber (11b) gradually change relative to each other due to the eccentric rotational movement of the roller (20), and the roller (20) moves through the suction port (12a) and the discharge port (12b). When the top dead center is closed at the same time, the entire cylinder chamber (11) becomes the suction chamber (11a), while when the roller (20) is 180 ° opposite to the bottom dead center, suction is performed. The volume of the chamber (11a) and the compression chamber (11b) is made uniform with the blade (21) as a boundary.
[0024]
As shown in FIG. 1, as a feature of the present invention, the blade (21 ) of the piston (19) is communicated with both side surfaces facing the blade (21) of the rotating clamping body (22). with notch (30) is opened to the blade (21) distal end side notch horizontally long rectangle across the middle of the blade (21) which blade (21) and Kaidokyo bearing member (22) is always in contact is formed, the notch (30) in a blade (21) and the compressed gas and mixed-with that of the rear side of the clamping member (23) and blade slide groove (12d) of the rotary holding member (22) It is always exposed to mist-like lubricating oil (O) .
[0025]
The thus configured rotary compressor is used, for example, to compress refrigerant gas in a refrigerant circuit of an air conditioner. In this case, the refrigerant gas is sucked from the evaporator through the suction pipe (5) into the suction chamber (11a) of the cylinder chamber (11), and the sucked refrigerant gas is compressed with the eccentric rotational motion of the roller (20). 11b), and is discharged to the storage space (10) from the discharge port (12b) through the gap between the bearing portion (13a) of the front head (13) and the muffler member (16), in a high pressure state. It is discharged to the condenser via the discharge pipe (6). During this time, in the compression chamber (11b), the refrigerant gas is compressed in a mixed gas state in which the lubricating oil (O) is mixed, so the lubricating oil (O) is scattered in a mist state in the storage space (10). This mist state lubricating oil (O) is separated from the refrigerant gas and collected in the oil sump (9).
[0026]
At this time, the blade (21) slides between the holding members (23) and (23) of the rotating holding body (22) in accordance with the eccentric rotational movement of the roller (20), and moves the rotating holding body (22). It swings around the center of rotation (Q).
[0027]
Then, to enter the flow in the sliding groove notch compressed gas in (12d) and a mist-like lubricating oil is mixed thereto (O) blade (21) distal side or Love blade (21) (30) The
[0028]
Thus, always the blade (21) and Kaidokyo bearing member sliding portion between the clamping member (23) in (22), notch on (30) the compressed gas has flowed into and mist of the lubricating oil (O) The blade (21) can be efficiently cooled and sufficient lubricity can be ensured, so that the blade (21) can slide under high speed and high load. Further, the sliding resistance of the blade (21) can be kept low, the generation of frictional heat on the blade (21) can be reduced, and seizure due to the accumulation of frictional heat can be prevented to improve the reliability .
[0029]
【The invention's effect】
As described above, according to the present invention, the cutout portion blade (21) (30) a blade (21) so as to open the front end side, and the blade (21) and Kaidokyo bearing member (22) A notch was formed in the middle of the blade (21) that always contacts with the blade. Therefore, the blade (21) and the rotating sandwiching body (22) by the compressed gas and the mist-like lubricating oil (O) flowing into the notch (30) from the blade (21) tip side in the blade sliding groove (12d). The sliding portion can always be cooled and the lubricity of the sliding portion can be ensured, and seizure of the sliding portion can be prevented by low sliding resistance and low frictional heat.
[Brief description of the drawings]
FIG. 1 is a perspective view of a blade of a piston constituting a compression mechanism in a rotary compressor according to an embodiment of the present invention .
FIG. 2 is a cross-sectional view showing a general configuration of a rotary compressor.
It is a sectional view taken along the line III - [3] of III FIG.
FIG. 4 is a perspective view of a conventional blade.
FIG. 5 is a plan view showing a state in which a blade is attached to a rotary holding body when a piston reaches top dead center in a conventional example.
FIG. 6 is a plan view showing a mounting state of the blade with respect to the rotating clamp when the piston reaches bottom dead center in the conventional example.
[Explanation of symbols]
(11) the cylinder chamber (11a) suction chamber (11b) compression chamber (12) cylinder (12d) blade sliding groove (19) piston (20) rollers (21) blades (22) Kaidokyoji body (30) notch

Claims (1)

A roller (20) capable of rotating eccentrically includes a piston (19) in which a rectangular plate-like blade (21) integrally projects radially outward,
The roller (20) is disposed in the cylinder chamber (11) of the cylinder (12), and the blade (21) is inserted into a blade sliding groove (12d) formed in the cylinder (12) so as to slide the blade. It is slidably and slidably held by a rotating holding body (22) disposed on the front side of the moving groove (12d),
The roller (20) is eccentrically rotated in the cylinder chamber (11), and the blade (21) is swung while being slid, whereby the cylinder chamber (11) is moved by the blade (21) to the suction chamber (11a). A rotary compressor that divides the gas into a suction chamber (11b) and compresses the gas into the suction chamber (11a) while compressing in the compression chamber (11b),
The blade (21) has a notch (30) that opens to the front end side of the blade (21) so as to allow communication between both side surfaces facing the blade (21) of the rotary clamping body (22). A notch is formed in the middle of the blade (21) in which the (21) and the rotation holding body (22) are always in contact, and the blade (21) and the rotation holding body (22 in the notch (30). ) Is exposed to the compressed gas on the back side of the blade sliding groove (12d) and the mist-like lubricating oil (O) mixed therewith.

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