SK278782B6 - Hermetically sealed rotating compressor - Google Patents

Abstract

The equipment described in this patent consists of hermetic box (2) containing the cylindrical box (5) in principle, arranged in the vertical direction, of the electric motor (3) equipped with the cylindrical stator (12) with its circuit in a cylindrical shape and this stator is fixed to the cylindrical box (5) which also is equipped with the coil (13), the bottom end (13b) of which hangs over the bottom wall of the stator (12) of rotating cooling and compressing mechanism (4) arranged under the bottom end (13b) of the coil (13) inside the hermetic box (2), while this mechanism is connected to the drive of the electric motor (3) and equipped with the cylindrical body having a reel shape and the cylindrical outer circuit, in principle, and this body is fixed to the cylindrical box (3), and this equipment also consists of connecting block (37) connected to the power supply for the electric motor and located in the cylindrical box. The connecting block (37) is located between the cylindrical body (14) and the hollow cylindrical stator (12) opposite the outer circuit closed to bottom end (13b) of the coil (13) and the cylindrical box (5) is equipped with the extended part (35), arranged opposite the outer circuit of the bottom end (13b) of the coil (13) and going out the cylindrical box (5) in a radial direction, while the connecting block (37) connected via this extended part (35) and it is fixed on the outer side.

Description

The apparatus comprises a hermetic housing (2) comprising a substantially cylindrical housing (5) arranged substantially vertically, an electric motor (3) provided with a cylindrical stator (12) having a substantially cylindrical outer circumference attached to the cylindrical housing (5) provided a coil (13) whose lower end (13b) extends beyond the lower wall of the stator (12) from a rotary cooling compression device (4) arranged below the lower end (13b) of the coil (13) inside the hermetic housing (2) and having a cylindrical disk-shaped body having a substantially cylindrical outer periphery mounted in the cylindrical housing (3), and a terminal (37) connected to the power supply to the electric motor and arranged on the cylindrical housing. The terminal block (37) is arranged between the cylindrical body (14) and the hollow cylindrical stator (12) opposite the outer periphery of the lower end (13b) of the coil (13) and the cylindrical housing (5) is provided with an enlarged portion (35) arranged opposite the outer periphery of the lower the end (13b) of the coil (13), and extending radially outwardly from the cylindrical housing (5), the terminal block (37) being connected through this expanded portion (35) and fixed on its outside.

Technical field

The invention relates to a hermetically sealed rotary compressor.

BACKGROUND OF THE INVENTION

The rotary compressor generates less shaking in general, and its crankshaft has a smaller, i. shorter, 10 eccentricity than a linear reciprocating compressor. Therefore, converting such a rotary compressor, especially to a hermetically sealed compressor, allows to reduce its size. In most conventional hermetically sealed rotary compressors, the triplex compression assembly and the electric motor driving the compression device are housed in a cylindrical hermetic housing. However, in the construction of such conventional rotary compressors, the main problem to be considered is not their size, but the reduction of their overall height. 20

To reduce the overall height of the rotary compressor, an improved hermetically sealed rotary compressor has been proposed which consists of a vertical up and down open cylindrical housing to which the upper open end is welded to the upper wall and the lower end is cooked with the lower wall of an electric motor. in a cylindrical housing and located at the top of its interior, from a rotary cooling compression device located near the bottom wall in the lower interior of the cylindrical housing driven by an electric motor. This rotary cooling compressor device comprises a cylindrical body in the form of a disc inserted in a cylinder housing.

The cylindrical body is secured on its circumference by a cut-out and a terminal block for supplying current to the electric motor 35, inserted into a socket formed in the cylindrical housing in the cutout made in the cylindrical body. If this terminal block is mounted in the top wall of a hermetically sealed rotary compressor, its total height necessarily increases. However, with an improved hermetically sealed compressor, the overall height of the rotary compressor can be reduced because the terminal box is located on a cylindrical housing. In addition, since the cutout is provided on the periphery of the cylindrical body and the terminal block is located in the cutout, it is possible to reduce the size of the rotary chamber of the pressor to a minimum.

However, in a hermetically sealed rotary compressor, the terminal box receptacle is formed on the cylindrical housing near the bottom wall of the rotary compressor and is additionally formed on the inner peripheral wall of the cylindrical housing 50 into which the cylindrical body is inserted. As a result, when the terminal box socket is drilled by the machine, the drilling force deforms the open lower part of the cylindrical housing and partly the inner circumferential wall of the cylindrical housing into which the cylindrical body is inserted. This creates a problem in that the deformation caused in the open lower part of the cylindrical housing and in the inner peripheral wall portion of the cylindrical housing into which the cylindrical body is inserted breaks the circularity of the open lower part and damages the inner part of the peripheral wall. This deformation 60 also has a detrimental effect when welding the cylindrical housing from the bottom wall, thereby reducing the efficiency of the welding operation. Moreover, this deformation makes it difficult to insert the cylindrical body into the cylindrical housing, thereby reducing the reliability of the rotary compressor. In addition, if the terminal box is located near the bottom of the cylindrical housing and the bottom wall to be welded, the welding heat will damage the terminal box, thereby reducing the efficiency of the insulating portion of the terminal box. Since the terminal block is located in close proximity to the bottom of the compressor, there is a danger that the wires connected to the outer terminals of the terminal block will come into contact with the base structure and be damaged.

It is an object of the invention to provide a hermetically sealed rotary compressor with increased reliability and increased welding efficiency while reducing its overall height and size.

SUMMARY OF THE INVENTION

The hermetically sealed rotary compressor according to the invention consists of a hermetic housing which comprises a substantially cylindrical housing arranged substantially vertically, an electric motor provided with a hollow cylindrical stator having a substantially cylindrical outer periphery attached to the cylindrical housing and further provided with a coil whose lower end is a stator, of a rotary cooling compression device arranged below the lower end of the coil inside a hermetic housing, connected to a drive from the electric motor and provided with a cylindrical outer casing mounted in a cylindrical housing, wherein the terminal block is arranged between the cylindrical body and the hollow cylindrical stator opposite the outer periphery of the lower end of the coil and the cylindrical housing is provided with an enlarged portion arranged opposite the outer periphery of the sp the spool end extending radially outwardly from the cylindrical housing, the terminal block being connected through this expanded portion and secured to the outside thereof.

The widened portion may preferably have a bowl shape and include a central flat top and a frustoconical peripheral portion arranged around a flat top provided with a terminal receptacle.

The terminal block may comprise a metal body inserted into a socket from within the cylindrical housing and provided on its outer periphery with a flange welded to the wall of the terminal box.

The widened portion is preferably circular and occupies a portion of the vertical wall of the cylindrical housing between the lower wall of the cylindrical body and the lower wall of the stator.

Preferably, the top end of the coil of the electric motor extends upwardly from the top wall of the stator, the outer diameter of the lower end of the coil being smaller than the diameter of the upper end of the coil.

A cut-out is preferably provided at the periphery of the cylindrical body under the terminal block.

The terminal block is preferably provided with a plurality of outwardly extending conductive pins to which the holder is attached, provided with a temperature sensitive surface and comprising a start relay and a safety relay, wherein a tongue is provided on the outer wall of the cylinder housing; holder attached to conductive pins.

On the outer wall of the cylindrical housing, a barrier surrounding the terminal block is preferably mounted above the terminal block, the tongue being the total part of the terminal block block.

It is also preferred that the terminal block comprises a bowl-shaped metal body fixed to the cylindrical housing, a plurality of tubular portions extending from the terminal box and forming holes therein for several conductive pins through the holes provided in the corresponding tubular portions, the holes filled with glass to achieve a hermetic seal between the tubular portions and the conductive pins, an insulating cover disposed within the terminal block body for hermetically covering a portion of the inner wall of the terminal block body, the outer walls of the tubular bodies, the inner ends of the glass filled holes and portions of the conductive pins.

It is also advantageous if the insulating cover is spaced from the inner surfaces of the apertures, forming gaps between them.

The insulating cover may then advantageously comprise a platform provided with a rotating ring hermetically slid onto the inner wall of the terminal block body and a plurality of portions extending from the platform to the interior, each of the portions extending inwardly having a larger diameter corresponding to the outer wall of the tubular portion; The pin and the connector portion of the larger diameter connector portion and the tapered diameter portion cover the inner ends of the glass filled holes.

Preferably, the insulating cover platform may be provided with a through hole.

The insulating cover can be made of synthetic resin resistant to the effects of coolant and oil. Preferably, the insulating cover may be a thin film of polyethylene telephthalate.

BRIEF DESCRIPTION OF THE DRAWINGS

An exemplary embodiment of the invention is shown in the drawings, in which: FIG. 1 is a top view of a rotary compressor; FIG. 2 is a cross-sectional side view of the rotary compressor in plane II-II of FIG. 1, FIG. 3 is an exploded perspective view of the rotary compressor of FIG. 1, FIG. 4a, b, c are a top view of the cooling compression device showing its operation in three stages; 5 is a cross-sectional view of a portion of a rotary compressor in a top view of FIG. 1, FIG. 6 is a cross-sectional view of the rotary compressor terminal block of FIG. 1 in a side view, FIG. 7 is a front view of the insulating portion of the rotary compressor housing of FIG. 1, FIG. 8 is a cross-sectional view of the terminal block of FIG. 6 is a side view showing a method for attaching the insulating portion of the housing of FIG. 7 to the terminal block body, FIG. 9 is a side view of the rotary compressor holder of FIG. 1, FIG. 10 is a view of the holder of FIG. 9 is a right side view of FIG. 9, FIG. 11 is a front view of the terminal block of FIG. 6, attached to the hermetically sealed housing of the rotary compressor of FIG. 1 and FIG. 12 is a partial cross-sectional side view of FIG. 11 showing the holder of FIG. 9, mounted on the terminal block of FIG. 6th

DETAILED DESCRIPTION OF THE INVENTION

According to FIG. 1, 2, 3 a hermetically sealed rotary compressor 1 consists of a hermetic housing 2, an electric motor 3 located in the upper interior of the hermetic housing 2 and a rotary cooling compressor 4 located in the lower interior of the hermetic housing 2. The hermetic housing 2 comprises a vertical a cylindrical housing 5 with an upper and a lower open end, an upper wall 6 welded to the periphery of the upper end portion of the cylindrical housing 5 and covering the open upper end of the cylindrical housing 5 and a lower wall 7 welded to the periphery of the lower end portion of the cylinder housing 5 wardrobes. A cylindrical housing 5, a top wall 6 and a bottom wall 7 define a hermetic space 8. A plurality of feet 9 are attached to the bottom of the outer wall of the cylindrical housing 5 by which the rotary compressor 1 is attached to the bottom or base plate of the refrigerator and the like.

The electric motor 3 comprises a vertical shaft 10 lying on the axis of the cylinder housing 5. On the vertical shaft 10 is mounted a rotor 11 which is surrounded by a hollow cylindrical stator 12 and the coil 13 is wound on the stator 12. The upper end 13a of the coil 13 stator 12 protrudes up the top wall of the stator 12 and the bottom end 13b extends downwardly from the bottom wall of the stator 12. As shown in FIG. 2, the coil 13 of the stator 12 is formed such that its lower end 13b is slightly smaller than its upper end 13a. The outer wall of the stator 12 is cylindrical and the stator 12 is hot pressed into the cylindrical housing 5. The stator 12 is positioned above the center of the overall height of the rotary compressor 1.

The rotary cooling compressor 4 comprises a horizontally disposed cylindrical body 14 in which a cylinder 15 is formed. The cylindrical body 14 has the shape of a flat disc with a relatively small thickness over its entire surface and a cutout 16 is formed on its periphery. the inner wall of the cylindrical housing 5 is welded.

As shown in FIG. 2, the cylindrical body 14 is disposed midway between the stator 12 and the bottom wall 7. A top plate 17 is attached to the flat top surface of the cylindrical body 14, to which surface the top 18 is attached. the opposing ends of the cylinder 15 are covered by two plates 17 and 19. The plates 17 and 19 accommodate a rotating shaft 10 which extends through the plates. In FIG. 2 to 4, an eccentric circular cam 20 is formed on the shaft 10 and is mounted in a cylinder 15 formed in a cylindrical body 14. A ring 21 is pivoted on the circular cam 20 and a groove 22 extending radially out of the cylinder 15 is formed on the wall of the cylinder. The inner space of the cylinder 15 is divided by a flat wing 23 into a suction chamber 25 and a compression chamber 26. The coolant suction opening 27 opens into the suction chamber 25 in the vicinity of the flat The casing 23, and the carved portion 28 formed in the upper edge of the wall of the cylinder 15 and forming the refrigerant outlet opening, also opens into the compression chamber 26 near the flat casing 23. As can be seen from FIG. 2, the coolant suction opening 27 is connected to the coolant inlet conduit 29 and the cut-out portion 28 is connected by a channel 30 formed in the top plate 17 to the inner space of the cap 18 and is positioned through the valve 31 in the cap 28. The valve 31 opens when pressure the refrigerant in the compression chamber 26 exceeds the specified pressure. When the electric motor 3 is in operation, the shaft 10 rotates counterclockwise as shown in FIG. 4, whereby the ring 21 gradually assumes the positions shown in FIG. 4 (A), 4 (B), and 4 (C). As shown in FIG. 4, at this time the volume of the suction chamber 25 gradually increases and, conversely, the volume of the compression chamber 26 gradually decreases. As a result, when the shaft 10 is rotated, the refrigerant gas in the compression chamber 26 is compressed. When the refrigerant pressure in the compression chamber 26 passes, the pressure set by the valve 31 (Figs. 2, 3), the refrigerant that is under excessive pressure in the compression chamber 26 flows into the lid 18 through the cut-out 28, channel 30 and valve 31. the pressurized refrigerant 8 into the hermetic chamber 8 in the hermetic housing 2 through the apertures formed in the lid 18, thereby filling the hermetic chamber 8 with pressurized refrigerant. This pressurized refrigerant flows out of the hermetic chamber 8 through an outlet pipe 32 or 33 attached to the cylinder housing 5. The lubricating oil is contained in the lower interior of the hermetic housing 2 and shaft 10 is provided with a lubricating oil pump vane which divides into different parts of the hermetic chamber 8. that need to be deleted.

As shown in FIG. 1 and 2, the portion 35 of the cylindrical housing 5 formed against the outer periphery of the lower end 13b of the spool 13 is widened outwards. The widened portion 35 comprises a flat top surface 35a with a circular contour and a circumferential conical portion 35b of a frusto-conical shape, also with a circular contour, as a result of which the widened portion 35 has the shape of a bowl. The outwardly extending portion 35 is formed by compression so that the flat top surface 35a extends about 5 mm from the level of the outer peripheral wall of the cylindrical housing 5. The lower end of the outwardly extending portion 35 is nearly at the same level as the lower surface of the cylindrical body 14 and The circular receptacle 36 of the terminal 37 is formed in the center of the flat upper surface 35a of the enlarged part 35 and the terminal 37 for supplying current to the coil 13 of the stator 12 is inserted into the receptacle 36 from the inside of the cylindrical housing 5. The terminal 36 for the terminal block 37 is positioned against the lower end 13b of the coil 13, as a result of which the terminal block 37 is also opposite the outer circumference of the lower end 13b of the coil 13. The terminal 37 is therefore located in the space surrounded by the cylindrical housing 5. and a lower end 13b of the spool 13 and is arranged in an outwardly extended position spaced from the cylindrical the housing 5 by the length by which the outwardly extending portion 35 extends from the level of the housing of the cylindrical housing 5. As shown in FIG. 2, the cylindrical body 14 is inserted into the cylindrical housing 5 and then welded thereto so that the cutout 16 in the cylindrical body 14 is positioned below the terminal 37, which is inserted between the outwardly extending portion 35 and the lower end 13b of the coil 13 through the cutout 16, and it is then inserted into the socket 36.

As shown in FIG. 5 and 7, the terminal 37 comprises a metal bowl 37 in the form of a deep bowl composed of tubular portions 39 extending inwardly forming holes 40. Three metal conductive pins 41 pass through the corresponding holes and the spaces between the tubular portions 39 and the conductive pins 41 are filled under pressure with molten As a result, the conductive pins 41 are hermetically fixed in the terminal body 38 by the glass 42 and the conductive pins 41 are electrically insulated from the terminal body 38 by the glass 42. The terminal body 37 is provided with a radially outwardly extending flange 43 on its circumference. welded to the wall of the terminal 36 of the terminal block 37. The insulating cover 44 comprises a platform 45a, a rotating circumferential ring 46 surrounding the platform 45 over its entire circumference. Three projections 47 extend from the platform 45 into the interior. A small opening 45a is formed in the middle of the platform 45. Each of the protrusions 47 comprises a larger internal diameter portion 48 that is somewhat smaller than the outer diameter of the tubular portion 39. The tapered diameter portion 49 has an internal diameter slightly smaller than the outer diameter of the conductive pin 41 and the truncated joint portion 50. a cone between the enlarged diameter portion 48 and the reduced diameter portion 49. In addition, the diameter of the rotating peripheral ring 46 is slightly larger than the inner diameter of the cylindrical portion of the terminal block body 38. The insulating cover 44 is connected to the terminal block body 38 such that especially the tapered diameter portions 49 are slid onto the corresponding conductive pins 41. As shown. FIG. 8, the larger diameter portions 48 are slid onto the corresponding tubular portions 39. This provides a hermetic seal between the tapered diameter portions 49 and the conductive pins 41, between the larger diameter portions 48 and the tubular portions 39 and between the rotating peripheral ring 46 and the cylindrical portion In addition, at this time, a gap 51 is formed between the connecting portion 50 of the insulating cover 44 and the inner end of the glass 42. The insulating cover 44 is made of synthetic resin having properties that make it perfectly resistant to coolant and oil. In the embodiment shown in FIG. 6 to 8, the insulating cover 44 is made of polyethylene telephthalate. In fact, the insulating cover 44 is formed by molding a polyethylene telephthalate film having a thickness of about 250-300 μm in the mold after heating the film to a temperature close to the melting point of the film but at which the film is not yet expanded.

As mentioned, the hermetic space 8 is filled with gaseous coolant and the lubricating oil is contained in the lower inner space of the hermetic casing 2. This coolant and lubricating oil contains fine particles of iron, copper and the like, which arise for example by welding the hermetic casing 2 and friction when sliding The fine particles are entrained by the coolant to various locations within the hermetic space 8. Therefore, if the compressor of the invention is not provided with an insulating cover 44, the fine particles adhere to the inner end of the glass 42.

In the hermetically sealed rotary compressor 1, the conductive pins 41 are under high voltage by starting the compressor 1. At this point, if a large amount of fine particles have deposited at the inner end of the glass 42, a spark may jump between the conductive pins 41 and the tubular portion 39, causing ground contact and the conductive pins 41 damaged. However, in the embodiment of FIG. 6, fine particles cannot adhere to the inner end of the molten glass 42 because the inner end of the molten glass 42 is covered by an insulating cover 44. Furthermore, since there is a gap 51 between the inner end of the molten glass 42 and the connecting portion 50 of the insulating cover 44, distance between the conductive pin 41 and outer surface. of the coupling portion 50 increases, thereby reducing the electric field on the outer surface of the coupling portion 50. This also attenuates the force attracting the fine particles to the outer surface of the connecting portion 50 and the amount of fine particles adhering to the outer surface of the connecting portion 50 is greatly reduced. Thus, there is no risk of a spark leaking onto the outer surface of the connector portion 50. It is therefore possible to completely prevent the occurrence of a spark between the conductive pin 41 and the pipe portion 39. Moreover, since the opening 45a (Fig. 7) is formed on the platform 45 of the insulating cover 44 there is a difference in pressure between the inner and outer surfaces of the platform 45 and there is therefore no danger that the insulating cover 44 will be displaced from the tubular portion 39. Moreover, even if the coolant containing fine particles enters the space between the platform 45 and the terminal housing body 37, there is no danger that the fine particles will enter the inner end of the glass 42 because the tubular portions 48 of the expanded diameter insulating cover 44 are hermetically relative to the tubular portion 39. sealed.

To the outer surface of the cylindrical housing 5, it is above the terminal 37 as shown in FIG. 2, a fixed damper 52. In FIG. 11 and 12, the terminal block 52 is U-shaped, so that it surrounds the entire terminal block 37. The terminal block 52 is provided with a tongue 53, which is welded to the block 52. This tab 53 extends downward from the top of the barrier 52 toward the terminal block 37 and is bent inwardly. As shown in FIG. 12, a holder 54 is attached to the conductive pins 41. In FIG. 9, 10, and 12, the holder 54 includes a lower box-shaped portion 55 and an upper cylindrical portion 56, the two portions 55, 56 being integral. At the bottom 55 there is a not shown trigger relay connected to two of the three conductive pins 41 used to supply the stator coil 13 with increased energy when the electric motor 3 is started. The top 56 includes an overload safety relay (not shown) connected to the remaining guide pin 41. and provided with a temperature sensitive surface 57. When the holder 54 is attached to the conductive pins 41, the safety relay contacts the tab 53. The safety relay operates in dependence on the temperature of the temperature sensitive surface 57 and serves to interrupt the power supply to the coil 13, stator 12 when the temperature 53 i.e., the temperature of the hermetic casing 2, exceeds the set temperature.

FIG. 12, it is evident that it is possible to construct the holder 54 so that the temperature-sensitive surface 57 is in direct contact with the outer surface of the cylindrical housing 2, but not the outer surface of the outwardly widened portion 35. In this case as a result, the embodiment shown in FIG. 12 is provided with a tongue 53 in order to reduce the height of the holder 54. As the height of the holder decreases, it is not possible to place the temperature sensitive surface 57 so that it is in direct contact with the cylindrical housing 5. surrounding the holder 54.

In FIG. 2, the terminal 37 is arranged inside a space surrounded by a cylindrical housing 5, a stator 12, a lower end 13b of the coil 13 and a cylindrical body 14. It is therefore possible to reduce the overall height of the rotary compressor 1 and reach its minimum height. Moreover, since the terminal 37 is positioned predominantly at the same level as the lower end 13b of the coil 13, this is because the socket 37 of the terminal 37 is drilled by the machine, the drilling force exerted on the open lower end of the cylinder 5 and on the inner peripheral wall of the cylinder 5, in which the cylindrical body 14 is attached, is reduced compared to a conventional rotary compressor. As a result, the deformation of the circularity of the open lower end of the cylindrical housing 5 and the inner peripheral wall of the housing to which the cylindrical body 14 is attached decreases, thereby reducing the deformation of the circularity of the open bottom and the danger of damage to the inner circular wall of the cylindrical housing 5. of welding efficiency and refinement of the cylindrical body 14 with the cylindrical housing 5.

The lower end 13b of the coil 13 is provided with not shown concave circumferential portions located between the main windings and the auxiliary windings. If the terminal 37 is positioned against the concave outer peripheral portion of the lower end 13b of the coil 13, it is possible to reduce the outwardly enlarged portion 35 and thereby further reduce the size of the rotary compressor 1. By shortening the length of the conductive pins 41 located in the cylinder housing 5 As the terminal box 37 is positioned relatively high, it is less detrimental to the heat generated by welding the bottom wall 7 to the cylindrical housing 5. It is therefore possible to prevent deterioration in the quality of the enamel 42 and the insulating cover 44. In addition, since the terminal 37 is positioned relatively high, it is possible to reduce the risk that the guide wires (not shown) connected to the outer conductive pins 41 come into contact with the ground and become damaged.

According to the invention, the relatively high positioning of the terminal block 37 makes it possible to increase the welding efficiency and to increase the accuracy of alignment of the cylindrical body 14 with the cylindrical housing 5, thereby reducing the overall height of the rotary compressor 1 and reducing its size.

Claims (14)

A hermetically sealed rotary compressor comprising a hermetic housing comprising a substantially cylindrical housing arranged substantially vertically, an electric motor provided with a hollow cylindrical stator having a substantially cylindrical outer periphery attached to the cylindrical housing and further provided with a spool over which the lower end is a stator lower wall, of a rotary cooling compression device arranged below the lower end of the coil inside a hermetic casing connected to an electric motor drive and provided with a cylindrical disk-shaped body having a substantially cylindrical outer periphery mounted in a cylindrical casing and a terminal block connected to an electrical terminal a cylindrical housing, characterized in that the terminal block (37) is arranged between the cylindrical body (14) and the hollow cylindrical stator (12) opposite the outer periphery of the lower end (13b) of the coil (13) and the cylindrical housing (5) is provided extended time a network (35) disposed opposite the outer periphery of the lower end (13b) of the spool (13) and extending radially outwardly from the cylindrical housing (5), the terminal block (37) being connected through this extended portion (35) and secured to its outer side. A hermetically sealed rotary compressor according to claim 1, characterized in that the radially outwardly extending portion (35) has a bowl shape and comprises a central flat top (35a) and a frustoconical peripheral portion (35b) arranged around the flat top. (35a) provided with a socket (36) of the terminal block (37). Hermetically sealed rotary compressor according to claim 2, characterized in that the terminal block (37) can comprise a metal body (38) inserted into a socket (36) from inside the cylindrical housing (5) and provided with a flange (43) on its outer periphery. welded to the wall of the socket (36) of the terminal block (37). A hermetically sealed rotary compressor according to claim 1, characterized in that the radially outwardly extending portion (35) is circular and occupies a portion of the vertical wall of the cylindrical housing (5) between the lower wall of the cylindrical body (14) and the lower wall of the stator (12). A hermetically sealed rotary compressor according to claim 1, characterized in that the upper end (13a) of the coil (13) of the electric motor (3) extends upwardly from the top wall of the stator (12), the outer diameter of the lower end (13b) of the coil (13). ) is smaller than the diameter of the upper end (13a) of the coil (13). A hermetically sealed rotary compressor according to claim 1, characterized in that a cutout (16) is provided on the periphery of the cylindrical body (14) below the terminal block (37). A hermetically sealed rotary compressor according to claim 1, characterized in that the terminal block (37) is provided with several outwardly projecting conductive pins (41) to which a holder (54) is attached, provided with a temperature-sensitive surface (57) and comprising triggering a reed and a safety relay, wherein a tongue (53) is provided on the outer wall of the cylindrical housing contacting the temperature-sensitive holder surface (54) when the holder (54) is connected to the conductive pins (41). A hermetically sealed rotary compressor according to claim 1, characterized in that a barrier (52) surrounding the terminal block (37) is fastened to the outer wall of the cylindrical housing (5) above the terminal block (37), the tongue (53) being the total portion of the block ( 52) terminal blocks (37). A hermetically sealed rotary compressor according to claim 1, characterized in that the terminal block (37) comprises a bowl-shaped metal body (38) attached to the cylindrical housing (5), a plurality of tubular portions (39) extending from the body (38) a terminal block (37) and forming openings (40) therein for a plurality of conductive pins (40) passing through openings (40) provided in corresponding tubular portions (39), the openings (40) being filled with glass (42) to achieve a hermetic seal between the tubular portions (39) and the conductive pins (41), an insulating cover (44) disposed within the body (38) of the terminal block (37) for hermetically covering a portion of the inner wall of the body (38) of the terminal block (37); ), the inner ends of the holes (40) filled with glass (42) and parts of the conductive pins (41). A hermetically sealed rotary compressor according to claim 9, characterized in that the insulating cover (44) is spaced from the inner surfaces of the openings (40), forming gaps between them. A hermetically sealed rotary compressor according to claim 9, characterized in that the insulating cover (44) comprises a platform (45) provided with a rotating ring (46) hermetically slid onto the inner wall of the terminal block body (38) and a plurality of parts extending therefrom. of the inwardly extending platform (45), each of the inwardly extending portions having a larger diameter corresponding to the outer wall of the tubular portion (39), the tapered diameter portion corresponding to the conductive pin (41) and the connecting portion (50) of the larger diameter connecting portion and portions with a tapered diameter, it covers the inner ends of the holes (40) filled with enamel (42). A hermetically sealed rotary compressor according to claim 11, characterized in that the platform (45) of the insulating cover (44) is provided with a through hole (45a). A hermetically sealed rotary compressor according to claim 9, characterized in that the insulating cover (44) is made of a synthetic resin resistant to the effects of coolant and oil. A hermetically sealed rotary compressor according to claim 13, characterized in that the insulating cover (44) is a thin film of polyethylene telephthalate. 6 of the drawings, FIG. 1, FIG. 2 SK 278782 obr6 fig. 4A FIG. 4B FIG. 4C FIG. 5, FIG. 8