DE3413711A1 - Oil-cooled asynchronous motor, especially for hermetic coolant compressors - Google Patents

Abstract

The invention is used in the construction of oil-cooled asynchronous motors as are used in hermetic coolant compressors for generating cold conditions in domestic and industrial cooling apparatuses. The aim of the invention is to reduce the mean winding temperature and to avoid temperature spreading. The invention relates to oil-cooled asynchronous motors for hermetically encapsulated compressors, the motor consisting of a rotor and stator. The rotor has a squirrel cage with an upper and a lower short-circuiting ring. Located on the upper short-circuiting ring is an element which is cylindrical or opens conically upwards and has radially arranged sinusoidal cutouts. The element projects beyond the upper winding overhang by at least 1 mm, and the rise in the sinusoidal function at the point of inflection is calculated in accordance with the formula: tan = (n +/- h)/ +/- d The invention is used in the case of oil-cooled asynchronous motors in the construction of hermetically encapsulated coolant compressors. <IMAGE>

Description

Title of the invention

Oil-cooled asynchronous motor, especially for hermetic refrigerant compressors Field of application of the invention The invention relates to the construction of oil-cooled Asynchronous motors, such as those used in hermetic refrigerant compressors are used to generate cold in household and commercial refrigeration appliances.

Characteristics of the known technical solutions They are asynchronous motors known for use in her.etic refrigerant compressors. their rotor on the upper short-circuit ring obliquely upward surfaces of different heights Has. the distribution of the oil at the top Winding head and on make the capsule This solution does not meet the requirement for an even Distribution of the oil over the entire upper winding head. There will be a splash of the oil is achieved in two levels. the ultropods of the lower level are in the winding head is thrown, while the ultra-drops of the upper level are thrown by a The gap between the end winding and the motor mount was thrown against the inside wall of the capsule and cool off there.

By spraying the oil in the winding head level. Center winding head, impermissible temperature gradients occur within the end winding. Further it is more beneficial.

the oil flow from the end winding in the form of a closed oil file and not in the form of drops to the upper winding head or through the gap between the winding head and to bring the motor mount to the inner wall of the domestic enclosure.

Aim of the invention The aim of the invention is to determine the mean winding temperature and the temperature spread within the end windings of oil-cooled asynchronous motors significantly lower compared to known products.

Explain the essence of the invention - The technical problem. by the invention is achieved Based on the object of the invention, the object is to To cool the asynchronous motor, the oil measuring current required to the upper end winding statig to be supplied over the entire scope and over its entire height and above In addition, the oil mass flow required for cooling through the annular gap between feed the upper end winding and motor mount to the Kepselwand.

It is necessary to have both mass flows in the form of one closed To train films.

- Features of the invention The features of the invention are that the rotor of an oil-cooled asynchronous motor on its upper short-circuit ring an element for constant UI distribution over the entire circumference and the entire height of the upper winding head, which also has the supply of a defined Ulassenstromes guaranteed to the capsule wall. Said element has a cylindrical shape or conical shape that widens upwards; its total height exceeds the upper one Winding head by at least 1 mm.

In this cylindrical or conical base body is located one or preferably two sinusoidal recesses.

The increase in the sine function at the inflection point must have the following relationship tan oC <= 1.5 n.h ## d h = height of the recess or winding head height n = Number of recesses d = mean diameter of the cylindrical or

conical element The cutouts mentioned cause a steady Wetting of the upper winding head over its height and circumference with Ul, with it for there is a clear formation of an oil film.

The winding temperature and the temperature spread within of the winding head lowered significantly.

Exemplary embodiment The invention is illustrated below using an exemplary embodiment described. The accompanying drawing shows an oil-cooled Asynchronous motor with rotor according to the invention in a hermetic refrigerant compressor The asynchronous motor 1 consists of a hermetically sealed refrigerant compressor 2 from stator 3 and rotor 4.

Oil is sucked in from the oil sump of the capsule and through the shaft 5 both the sliding parts and its skis. as well as about those in the wave 5 existing holes 6 to the rotor 4 firmly connected conical Eleagent 7 funded. From there it passes via preferably two sinusoidal cutouts 8 to the upper end winding 10 and over the upper edge of the conical element 7 through the annular gap 9 between the upper end winding 10 and the motor mount 11 on the capsule 12. The cutouts 8 corresponding to a sine function ensure the training an oil film.

which intensively cools the entire upper winding head.

List of used. Reference number.

1 asynchronous motor 2 hermetically sealed refrigerant compressor 3 stator 4 rotor 5 shaft 6 bore 7 cylindrical or conical element 8 sinusoidal Cutout 9 Annular gap 10 Upper winding head 11 Motor support 12 Capsule

Claims (1)

Invention claim 1 oil-cooled asynchronous motor, in particular for Hermetic refrigerant compressor, consists of rotor and stator, with the rotor has a short-circuit cage with an upper and lower short-circuit ring. characterized. that on the upper short-circuit ring of the rotor with the upper short-circuit ring Permanently connected, cylindrical or conical upward opening element with radial arranged, sinusoidal cutouts for the constant distribution of an oil mass flow over the full circumference and the full height of the upper winding head and on the capsule is located. that cylindrical or conical element the upper winding head by at least Protrudes 1 mm and the increase in the sine function in the inflection point thereby the relationship tan = 1.5 ###.