LT4264B - A hermetic rotary cooled compressor - Google Patents

Abstract

This invention belongs to the branch of compressor technology, related to refrigerating equipment. This hermetic rotary refrigerating compressor consists of a rotor, crankshaft, cylinder, vane tramping inside the notch of the cylinder, spring pressing the vane to the rotor, sliding element mounted into the notch at the end of the vane, which turns around its axis, top and bottom covers with slide bearings and electrical motor. The compressor rotor and the crankshaft make up a single part, or the rotor is eccentrically mounted on the crankshaft and the radius of the cylindrical working surface of the sliding element R1 is always greater than the radius of rotor R2. If R2=0.02-0.05 m, then R1=R2+"δR", where δR=3.333 x R2<3>+4.7057 x R2<2>+0.2782 x R2-481.43 x IR2<2>+6162.5 x I<2>R2-86.06 x IR2-17833.33 x I<3>+286.875 x I<2>-1.251 x I+0.001202; I=0.2R2+0.002, where R1 is the radius of the working surface of the sliding element in metres; R2 is the radius of the rotor in metres; I is the arc length of the working surface of the sliding element in metres.

Description

FIELD OF THE INVENTION The present invention relates to the field of compressor technology related to refrigeration equipment, such as household refrigerators.

Known rotary blade compressor [see Japanese Application No. 6480787 TPK F 04 C 18/356, 1989], which consists of a rotor, crankshaft, cylinder, blade, spring. The end of its blade has a circular arc which coincides with the outer surface of the rotor. In this case, the full surface contact is obtained at only one rotor position, with the crankshaft eccentric axis coinciding with the blade axis. As a result, leakages between the blade and the rotor are slightly reduced. In addition, friction losses increase.

Known rotary compressor with bypass rotor [see VFR Application No. 3611395 TPK F 04 C 18/356, 1987], consisting of a rotor, a crankshaft, a cylinder, a blade sliding in a cylinder recess, a spring that presses the blade against a rotor, a sliding element inserted into the recess at the end of the blade and capable of rotating about its own. axle, upper and lower caps with sliding bearings, electric motor. The sealing between the blade and the rotor is obtained over a certain surface area, but the configuration of the sliding element is quite complicated with no definite working surface geometry. Therefore, there is no guarantee that a sealing grease film will be formed. Reducing volumetric losses will increase frictional losses, resulting in a total compressor n.v.k. (refrigeration coefficient) will not change significantly.

The object of the invention is to increase the refrigeration coefficient of a sealed rotary refrigeration compressor by reducing the volume losses due to leaks between the rotor and the blade separating the suction cavity from the compression cavity.

The sealed rotary refrigeration compressor consists of a rotor, crankshaft, cylinder, blade, sliding in cylinder recess, springs which press the blade against the rotor, a sliding element inserted into the notch at the end of the blade and upper and lower caps with a sliding bearing engine. The rotor of the compressor and the crankshaft are one piece or the rotor is eccentrically fixed to the shaft and the radius of the working cylindrical surface of the sliding element is <1 always greater than the radius Rz of the rotor and at Rz = 0.02-0.05 m is equal to:

Ri = Rz + AR, where

Δ7? = 3.333-7? 2 + 4.7O57-7? 2 + 0.2782- « ₂ -481.43 - /« j + 6162.5- / ² « ₂ -86.06-IR ₂ -17833.33-Z ³ + 286.875 · / ² -1.251- / + 0.00120¾ /=0.2 «2 + 0.002, where Ri is the radius of the working surface of the sliding element, m;

«2 - radius of rotor, m;

Z - length of the working surface of the sliding element, m.

This results in hydrodynamic sealing between the rotor and the sliding element during compressor operation. Passages between these slip surfaces are significantly reduced, which also reduces volumetric losses. On the other hand, frictional losses in hydrodynamic lubrication are also reduced. Therefore, the refrigeration coefficient increases significantly, i.e. consuming the same amount of electricity will give us a higher amount of frost.

BRIEF DESCRIPTION OF THE DRAWINGS FIGS.

Fig. 1 shows the design of a sealed rotary refrigeration compressor. Housed in the hood, the compressor comprises rotor 1, shaft 2, cylinder 3, intake port 4, blade 5, slots in cylinder 6, springs 7, exhaust ports 8, slip member 9. The intake and exhaust cavities of the compressor are limited by rotor 1, cylinder 2 and blade 5 Top and bottom covers with sliding bearings (not shown).

The sealed rotary refrigeration compressor works as follows. An electric motor (not shown) rotates the shaft counterclockwise. The refrigerant vapor is sucked in through the opening 4 and discharged through the opening 8. The blade 5 separating the suction side from the pressure side slides in the recess 6 of the cylinder 3. It is pressed against the rotor by a spring 7. A partial circular recess is inserted into the rotor. capable of rotating freely about its axis.

Since the rotor does not rotate relative to the crankshaft and the radius Ri of the working surface of the member in contact with the rotor is larger than the radius Rz of the rotor (FIG. 2), hydrodynamic lubrication is obtained between the sliding surfaces. The lubricating film seals the space between the rotor and the sliding element over a certain area. In addition, the bearing capacity of the lubricating film prevents metal contact during compressor operation, which reduces friction losses. The radius Ri of the working surface of the sliding element 9 is optimal when the lubricating film formed between the rotor and the sliding element has a maximum bearing capacity. Its size is mainly influenced by the size of the rotor radius Rz and the arc / length of the working surface of the sliding element. The load-bearing capacity of the lubricating film is calculated by numerically integrating the function of the pressure distribution under the slip element, which is a solution of the Reynolds equation.

Calculating these values for Ri = 0.02-0.05 m, the statistical relationship between Ri and Rz and l is given above. Rz ranges are based on the range of performance of rotary compressors being manufactured.

Definition of the Invention

Claims (1)

Definition of the Invention Sealed rotary refrigeration compressor consisting of rotor, crankshaft, cylinder, blade sliding in cylinder recess, springs pressing blade to rotor, sliding element inserted into end of blade and pivotable with upper and lower lids, electric motor, characterized in that the rotor and the crankshaft are one piece or the rotor is eccentrically fixed on the shaft and the radius R1 of the working cylindrical surface of the sliding element is always greater than the radius of rotor R2 and at Rz = 0.02-0.05 m is equal to: Ri = R2 + AR, where AR = 3.333-Rl + 4.7057 · /? ₂ ² + 0.2782 · R2-48143-lRl + 6162.5-l ² R2 -86.06-IR ₂ -17833.33-l ³ + 286.875 · l ² -1.251 · / + 0.001202; /=0.2 ^ 2 + 0.002, where Ri is the radius of the working surface of the sliding element, m; R2 is the radius of the rotor, m; / - length of the working surface of the sliding element, m.