TH3497A - Rotary compressor lubrication arrangement - Google Patents

Abstract

In a sealed rotary compressor Improved lubrication arrangements were made for the sliding impeller (84), the oil pump (116) in the lower (62) of the crankshaft (26) that protruded into the compressor oil reservoir (120). The oil pump consists of an axial opening (116) in the crankshaft (26) which is radially diagonal outward in the upward direction. Oil is pumped through this opening (116) into the ring chamber (126). ) Located around the crankshaft (26), passages (128) in the outer support (56) radially remove oil from the annular chamber (126) and up, against the gravity of the earth along the passageway. Vertical oil (134) that opens to both sides of the sliding impeller (84) and is close to it. The large pressure generated by the oil pump will ensure that the oil funnel (134) is always full of oil. The excess oil goes out to the upper end of the impeller (84) through the vent in the main support (46) and flows down around the compressor (66) by gravity and into the reservoir. Oil (120)

Claims (9)

1.Rotary compressor, including a vertical crankshaft, which rotates in a support body. The compressor cylinder, which includes an impeller groove in one wall of the cylinder, and a sliding propeller in the groove. For compressed gases where the propeller has at least two sliding surfaces. The lubrication part for lubricating the impeller consists of Oil storage Which is at the bottom of the case Oil pump part Which consists of an axial channel in the said crankshaft The channel is connected to the said oil reservoir. For gas stations up from the said oil storage Lubrication oil channel Which extends upward in the said cylinder The funnel opens up to the impeller, the pipe, which connects the lubricant channel directly to the axial channel for delivering oil upwards under greater pressure against the force of gravity. From the said axial channel to the lubricant pass channel for at least two sliding surfaces of the impeller 2. Lubrication section as in claim 1, where the aforementioned oil section consists of a radial channel section in the aforementioned support for bringing oil from the pump section to the lubrication channel. 3. Lubrication part as in claim 1, where the upper end of the channel through the said lubricant Open onto the top surface of the cylinder Where excess oil will flow from the channel through the lubricant to the top surface of the cylinder. And return to the oil reservoir by gravity of the Earth 4. Lubrication part as in claim 1, where the said oil pump part consists of an axial channel in the said crankshaft. The compartment connects to the said oil reservoir. The opening is directed radially from the crankshaft axis in the above direction. Where the upper end of the channel is positioned radially outer from the lower end of the channel. 5. Compressors, as in claim 1, where the aforementioned lubricant port consists of a pair of long grooves located in the wall of the cylinder on opposite sides of the impeller groove. The groove opens into the impeller groove along one of the corresponding long sides to form a longitudinal depression in the lateral wall of the impeller. 6. Lubrication section as in claim 5, where each aforementioned long groove consists of a semicircular section. Each of these holes opens up, mostly along its entire length, into the impeller grooves. 7. Compressor, as in claim 5, where the cylinder includes the bore and vane that is connected to it. The long groove is positioned centrally between the cavity and the periphery of the cylinder wall. And closer to the opening than the outer surface of the wall 8.In a hermetically sealed rotary compressor for refrigerant compression, including the housing An electric motor to drive the compressor. Crankshaft driven by such a motor Such a crankshaft moves in a support. Cylinder, which is adjacent to the support And have a common axis Impeller grooves in the wall of the cylinder And the propeller, which has been sliding in the said groove The lubricant for lubricating the said impeller. Oil storage in the said housing The oil pump in the crankshaft for the oil pump up from the said oil storage. The pump section consists of an axial channel in the said crankshaft. The cavity is further axially and radially outward from the said crankshaft axis. The upper part of the axial channel is connected to the radial channel in the said crankshaft for the said oil to the annular chamber surrounding the crankshaft. A funnel in the supporter to carry the oil from the ring chamber up to the impeller under greater pressure. One or more longitudinal oil channels that pass through the barrel. The cavity is axially parallel to the said crankshaft axis. And this channel opens into the said groove along its entire length, and one end opens into a channel in the support. And the other end opens up to the top surface of the cylinder for supplying lubricating oil to the impeller. Under the greater pressure of the said gas station 9. Lubrication section, as in claim 8, where the said oil is carried through the support radially and upward axially into the said oil channel 1. 0. Lubrication part as in claim 8, where the lubricant in the impeller groove is a hydraulic seal to prevent refrigerant leakage through the said impeller groove.