ITRM970582A1 - DEVICE TO PREVENT OSCILLATIONS IN A CLOSED TYPE COMPRESSOR - Google Patents

Description

DESCRIPTION of the industrial invention entitled:

"DEVICE TO PREVENT OSCILLATIONS IN A CLOSED TYPE COMPRESSOR"

DESCRIPTION

Basis of the invention

1. Field of the invention

The present invention relates to a compressor for compressing a high temperature refrigerant I with a high pressure, and more particularly 'to a device for preventing oscillations' in a closed-type compressor, in which the weight of the rotating shaft of the compressor to reduce the rotating load, thus being able to increase the efficiency of the compressor.

2. Description of the prior art A conventional compressor as shown in Figure 1, has a main body 1 constituting its external appearance, and a top cover 2 is matedly installed on the top side to cover the top side of the body. main body 1. A stator 3, which receives an external electrical energy to form a magnetic field, is installed inside the main body 1. A rotor 5 is installed on the inside of the stator 3 to be rotated under the influence of the magnetic field formed at the stator 3. Furthermore, a rotating shaft 9 rotated together with the stator 5 is installed on the inner side of the rotor 5, and a connecting rod 11 for converting the rotational movement of the shaft 9 into a movement alternative is installed on one end of the rotating shaft 9.

A piston 13 is installed on the end of the connecting rod 11 to effect reciprocating movement interconnected with the reciprocating movement of the connecting rod 11, and a cylinder block 15 is installed on the outer side of the piston 13 to drive the python 13 to reciprocate. while forming a space for compressing the refrigerant. A bearing 17 for rotatably supporting the rotating shaft 9 is installed on one side of the outer periphery of the rotating shaft 3, and an oil pick-up element 19 is installed on the lower end of the rotating shaft 9 to take underlying oil in the part. lower main body 1. In addition, a rocking preventer unit 30 is installed inside the top cover 2 to prevent damage to the internal structure resulting from abrupt rocking during the delivery, operation and shutdown of the compressor.

The unity of; oscillation prevention 30 is formed by a fixing cover 31 installed on the inner side of the upper cover 2 to be coupled inwardly with the upper end side of the rotating shaft 9.

An oil hole 9a into which the oil taken from the oil pickup member 19 is introduced is formed inside the lower end of the rotating shaft 9, and an oil groove 9b is formed along the circumferential plane of the rotating shaft 9 to continuously raise the oil drawn through the oil hole 9a to prevent friction with the inner side of the bearing 17. An oil pan 9c to store the oil raised along the oil groove 9b for bringing it up again to the uppermost end part of bearing 17 is linearly formed on one side of the outer periphery of the rotating shaft 9.

In the conventional closed-type compressor structured as above, when electrical energy is applied, a magnetic field is formed at the stator 3 and the rotor 5 begins to rotate by means of the magnetic field formed at the stator 3. Then, the rotor is made to rotate. The rotating shaft 9 integrally coupled to the rotor 5. Following the rotation of the rotor 5, the connecting rod 11 installed on one end of the rotor 5 moves with a linear reciprocating motion. Together with the linear reciprocating movement of the connecting rod 11, the piston 13 installed on one end of the connecting rod 11 and on the inner side of the cylinder block 15 moves linearly in reciprocating motion so as to be actuated in a first direction, thus leading the coolant to enter inside the cylinder block 15. Since the piston 13 is moved linearly in the opposite direction to the aforementioned direction, the refrigerant compressed inside the cylinder block 15 is discharged out of the cylinder block 15 through an ejection hole not shown.

Meanwhile, the oil pick-up element 19 rotated by the connection with the rotation of the rotating shaft 9 picks up the underlying oil in the lower part of the main body 1, and the drawn oil is lifted through the oil hole 9a formed in the lower inner part of the rotating shaft 9 to be fed primarily to the piston 13 via the connecting rod 11, and, secondarily, the oil lifted through the oil hole 9a is lifted further along the oil groove 9b formed along the outer periphery of the rotating shaft 9 to feed the oil inside the bearing 17 in order to effect the lubrication action.

At this point, the raised oil is returned to the oil pan 9c formed on the outer periphery of the rotating shaft 9, and the oil repeats the further lifting operation to rise to the upper end of the bearing 17 and descend downwards, thereby effecting the lubrication action.

On the other hand, the compressor operated as above is made to arrange the upper end portion of the rotating shaft 9 on the inner side of the rocking preventer 30, i.e., the fixing cover 31, so that it is prevented the internal structure of the compressor from being damaged due to oscillation when the compressor is dispensed, operated and stopped.

However, the conventional closed type compressor formed as above has the rotating shaft 9 which is extended to insert the upper end of the shaft 9 inside the fixing cover 31 to prevent oscillation of the internal structure. Thus, the weight of the rotating shaft is increased to require further increased pressure, thereby reducing the efficiency of the compressor.

Summary of the invention

Therefore, it is an object of the present invention to provide a device for preventing oscillation in a closed-type compressor capable of reducing the rotating load by forming an oscillation impeding unit such as to shorten the length of the rotary shaft of the compressor and effectively prevent its rotation. swing.

To achieve the above object of the present invention, a device for preventing rocking in a closed-type compressor installed with a rocking preventer unit in a predetermined part of an upper cover disposed on the upper side of the main body of the compressor, includes a fixing shaft formed by shortening the length of the rotating shaft of the compressor. The rotating shaft is formed with a passage hole in the shaft in a predetermined part of its upper end so that the fixing shaft is inserted inside.

Preferably, the securing shaft is coupledly installed in a predetermined portion of the interior of the top cover.

Brief description of the drawings

The above objects and other advantages of the present invention will become more evident from the detailed description of its embodiments referred to with reference to the annexed drawings in which:

Figure 1 is a vertical sectional view schematically showing the overall structure of a conventional closed-type compressor; And

figure, 2 is a vertical sectional view showing; schematically the overall structure of a closed-type compressor according to an embodiment of the present invention.

Detailed description of the preferred embodiment

A device for preventing oscillations in a closed-type compressor according to a preferred embodiment of the present invention will now be described in detail with reference to Figure 2. Here, parts identical to those shown in Figure 1 will be indicated with the same reference numbers and signs. The compressor to which the present invention refers, as shown in Figure 2, has a main body 1 which constitutes the external aspect of the compressor, and an upper cover 2 to cover the upper side is installed in a coupled manner on the upper side of the main body 1. A stator 3 which receives external electrical energy to form a magnetic field is installed inside the main body 1. A rotor 5 is installed on the internal side of the stator 3 to be rotated by the influence of the magnetic field formed at the stator '3. Furthermore, a rotating shaft 110 rotated together with the rotor 5 is installed on the inner side of the rotor 5 and a connecting rod 11 for transforming the rotational movement of the rotating shaft 110 into a reciprocating movement is installed on one end of the rotating shaft 110 A piston 13 is installed on one end of the connecting rod 11 'so as to effect a reciprocating movement connected to the reciprocating movement of the connecting rod 11, and a cylinder block 15 is installed on the. outer side of the piston 13 for guiding the piston 13 in the reciprocating manner while forming a space for compressing a coolant. A bearing 7 for pivotally supporting the rotary shaft 9 is installed on one side of the outer periphery of the rotary shaft 110, and an oil pick-up member 19 is installed on the lower end of the rotary shaft 110 for drawing the underlying oil. in the lower part of the main body 1. In addition, a rocking preventer unit 100 is installed inside the upper cover 2 and the upper end portion of the rotary shaft 110 to prevent damage to the apparatus resulting from abrupt rocking during the 'compressor delivery, operation or stop.

The rocking preventer unit 100 is formed to have a prescribed length L such as to reduce the rotating weight by shortening the length of the rotating shaft 110 by including a securing shaft 120 installed inside the top cover 2 and the Rotating shaft 110 formed with a hole 114 along the shaft in a predetermined portion of the upper end for receiving the fixing shaft 120 inside.

An oil hole 111 into which the oil taken from the oil pick-up element 19 is introduced is formed inside the lower end of the shaft, rotating 110, and an oil groove 112 is formed along the circumferential plane rotary shaft 110 to continuously lift the oil rising through the oil hole 111 to prevent friction on the inner side of the bearing 17. An oil pan 113 to store the oil raised along the groove for oil 112 so as to raise it again to the uppermost end portion of the bearing 17 is formed on one side of the outer periphery of the rotating shaft 110.

The operation and effect of the device for preventing oscillations in the closed-type compressor according to an embodiment of the present invention will be described below.

First, once electrical energy is applied (not shown), the magnetic field is formed at the stator 3, and the rotor 5 begins to rotate by the magnetic field formed at the stator 3. Then, it is rotated the rotating shaft 110 integrally coupled with the rotor 5. Following the rotation of the rotor 5, the connecting rod 11 installed on one end of the rotor 5 moves linearly with reciprocating motion. Together with the linear reciprocating movement of the connecting rod 11, the piston 13 installed on one end of the connecting rod 11 and on the inner side of the cylinder block 15, moves linearly in reciprocating motion so as to be actuated in a first direction, thereby bringing the coolant to enter inside the cylinder block 15. Since the piston 13 is moved linearly in the opposite direction to the aforementioned direction, the refrigerant compressed inside the cylinder block 15 is discharged under the high pressure outside the cylinder block 15 through a ejection hole not shown.

Meanwhile, the oil pick-up element 19 rotated by the connection with the rotation of the rotating shaft 110 picks up the underlying oil in the lower part of the main body 1, and the drawn oil is lifted through the oil hole 111 formed in the lower inner part of the rotating shaft 110 to be fed primarily to the piston 13 through the connecting rod 11, and, in a secondary manner, the oil raised through the oil hole 111 is raised further along the groove: for oil 112 formed on the outer periphery of the rotating shaft 110 to feed the oil inside the bearing 17 so as to effect the lubrication action.

At this point, the raised oil is returned to the oil pan 113 formed on the outer periphery of the rotating shaft 110, and the oil repeats the further lifting operation i so as to rise to the upper end of the bearing 17 and descend downwards, thereby effecting the lubrication action.

The closed type compressor operated as above has the rotating shaft 110 with the total length shortened so as to reduce the weight of the rotating part, as well as the operating load during compressor operation to improve; the performance of a single product. In addition, the securing shaft 120 is inserted into the upper end of the rotating shaft 110 to prevent probable damage to the internal structure (e.g., rotor, stator, rotating shaft, and so on) due to abrupt oscillation upon dispensing. , '' compressor running and stopping.

The device for preventing oscillations in the closed type compressor according to the present invention as described above is formed with the fastening shaft extended into the upper internal part of the main body. Thus, the length of the rotating shaft is shortened so as to reduce the weight of the rotating part, thereby reducing the rotating load. As a result, compressor efficiency can be increased by saving energy consumption during compressor operation.

While the present invention has been shown and described especially with reference to a particular embodiment thereof, it will be understood by those skilled in the art that various changes in form and detail can be made therein without departing from the spirit and scope of the invention as defined. from the attached claims.

Claims (2)

CLAIMS 1. A device for preventing oscillations in a closed-type compressor installed in a predetermined part of an upper cover disposed on the upper side of the main body of said compressor, said device for preventing oscillations in a closed-type compressor comprising: a fastening shaft formed by shortening the length of the rotary shaft of said compressor; And said rotating shaft being formed with a hole along the shaft in a predetermined part of its upper end for the insertion of said fixing shaft. 2. Device to prevent oscillations in a compressor! of the closed type as claimed in claim 1, wherein said fixing shaft is installed in a coupled manner on a predetermined part of the interior of said upper cover.