KR100845943B1 - Oil pumping system for a reciprocating hermetic compressor - Google Patents

Abstract

A cell 1 defining an oil sump 5 therein; A motor-compressor assembly; Oil pump means (10) connected to the compressor by at least one cushioning elastic means (20), wherein the cushioning elastic means (20) comprises a resonant natural frequency (Wn) of the oil pump means (10); The displacement of the oil pump means 10 to a value calculated such that the ratio of the displacement of the oil pump means 10 to the displacement of the compressor by a ratio with the operating frequency W of the compressor is less than one. An oil pumping system for hermetic reciprocating compressors, dimensioned to reduce amplitude.

Hermetic reciprocating compressors, shock absorbing means, oil pump means, resonant natural frequency

Description

OIL PUMPING SYSTEM FOR A RECIPROCATING HERMETIC COMPRESSOR}

The present invention is in particular a refrigerator, which is driven by a linear motor and which is applied, for example, to an oil pump of the type described in the applicant's Brazilian patent application PI0004286.2 (PCT / BR01 / 00113). And an oil pumping system for a hermetic reciprocating compressor of the type used in small refrigeration appliances such as freezers, chillers and the like.

In commercially available hermetic compressors for domestic cooling, an important factor for its correct operation is the proper lubrication of moving parts relative to one another. The difficulty in achieving this lubrication is related to the fact that oil must flow upward to lubricate relatively moving parts. Among the known solutions for achieving this lubrication are the use of the principle of centrifugal force and mechanical drag.

Of these solutions, which are used in both linear and reciprocating compressors, in order to supply oil to the piston / cylinder assembly, a gas flow that causes a small pressure differential with respect to the oil sump flows from the compressor inlet and The oil needs to be sucked through the capillary and mixed with the gas drawn by the compressor. The mixture of gas and oil is introduced into the cylinder by the intake valve, allowing the oil to lubricate the contact portion between the piston and the cylinder. In some situations, depending on the low gas flow drawn by the compressor, this structure is not always efficient.

In another known structure (WO97 / 01033), the lubricating oil is displaced from the oil sump formed in the lower part of the compressor shell to the upper reservoir formed around the cylinder of the compressor, using the compression force and the suction force of the piston. The upper reservoir is connected to the inside of the cylinder by a plurality of orifices formed in the wall of the cylinder, and when the piston performs the suction movement, the lubricant is introduced into the piston-cylinder clearance, and when the piston performs the reverse movement, the lubricant Serves to discharge. Lubricant is discharged into a set of channels formed in the valve plate of the compressor to further increase suction flow and reintroduce the lubricant into the cylinder.

Another known solution (WO97 / 01032) uses a resonant mass that reciprocates in a cavity formed on the outside of the cylinder. This resonant mass sucks lubricant oil from the oil sump while moving in one direction. The lubricant passes through a tube and a check valve that only allows the introduction of lubricant into the cavity. The cavity is connected to the inside of the cylinder by a plurality of orifices formed in the wall of the cylinder. Lubricant in the cavity is discharged when the resonant mass moves in the other direction and passes through a check valve allowing only the discharge of the lubricant from the cavity. This solution is functional, but difficult to manufacture, and its structure has many components.

The above-mentioned patent application PI0004286 of the present applicant discloses the oil pump means driven by the reciprocating motion of a piston and a cylinder, This oil pump means is formed by the plunger, The main body of an oil pump means inside the plunger. There is provided a movable seal that is displaceable between a closed position seated on a valve seat disposed adjacent to an oil introduction orifice formed therein and an open position moved away from the valve seat. The closed position and the open position are axially separated from each other, for example, the maximum spacing is obtained when the seal reaches a stop provided inside the body of the oil pump means. When the oil pump moves in a defined direction (as shown in FIG. 1), the seal is displaced toward the stop, so that lubricating oil enters through the introduction orifice and pushes the oil column in the opposite direction to the movement of the oil pump means. When the oil pump is moved in the opposite direction as described above, as shown in Fig. 2, the seal moves toward the valve seat to block the entry of oil into the body of the oil pump means, and the introduced oil causes the introduction orifice to To prevent it from exiting. Thus, by the continuous reciprocating motion of the oil pump means, the oil is continuously introduced and discharged through the body of the oil pump means toward the movable part of the compressor to be lubricated.

In a linear compressor, the oil pump means are mounted in the same direction of movement as the resonant assembly. Such movement causes the mechanical assembly disposed on the suspension system to reciprocate to drive the oil pump means.

The solution uses reciprocating motion of one of the compressor's resonant assembly and the non-resonant assembly to supply lubricant by inertia to the moving parts of the compressor that require lubrication to and from the oil pump means.

Nevertheless, the reciprocating motion in a compressor driven by a linear motor is generally known to have a large amplitude.

Moreover, in the specific structure of the oil pump means of the above-mentioned patent application PI0004286.2, a large amplitude of vibration causes a strong impact of the seal of the oil pump means on the displacement stop and on the valve seat of the oil pump means. Continuous operation of these components causes damage to these components, which in turn hinders the reliability of the compressor and increases the noise level during operation.

It is therefore an object of the present invention to control the amplitude of the oscillating motion of an oil pump and to maintain the amplitude substantially unchanged independently of the amplitude of the oscillating motion during operation of the compressor. To provide a system.

Another object of the present invention is to facilitate the manufacture and to achieve adequate lubrication of the relative moving parts of the compressor, without the low efficiency and low reliability in the known prior art, such that damage to the component parts of the oil pump means and during operation of the compressor It is an object of the present invention to provide an oil pumping system of the above type which makes it possible to prevent an increase in the noise level.

The above and other objects are lubricated by a shell defining an oil sump therein, a motor-compressor assembly, an oil pump means connected to the compressor to be displaced in a reciprocating motion in a predetermined direction, and the oil pump means. An oil pumping system for a hermetic reciprocating compressor comprising fluid communication means for connecting to a compressor component to be constructed, wherein the oil pump means is connected to the compressor by at least one cushioning elastic means, and the cushioning elastic means, Displacement of the oil pump means to a value calculated such that the ratio of the displacement of the oil pump means to the displacement of the compressor is less than 1 by the ratio of the resonance natural frequency of the oil pump means to the operating frequency of the compressor. For hermetic reciprocating compressors, characterized in that they are dimensioned to reduce the amplitude of the One is achieved by the pumping system.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a schematic longitudinal cross-sectional view of a portion of a hermetic reciprocating compressor with a linear motor, having a piston with a vertical axis and an oil pump means constructed according to the prior art disclosed in the aforementioned patent application PI0004286.2;

2a and 2b schematically show the operation of the oil pump means as shown in FIG.

3 is a longitudinal sectional view schematically showing the structure of the oil pump shown in FIG. 2A with the improvement of the invention shown in FIG.

4 shows the variation of the ratio between the vibration displacement of the oil pump means and the vibration displacement of the compressor in relation to the ratio of the resonance natural frequency Wn of the cushioning elastic means improved according to the present invention and the operating frequency W of the compressor. Graph representing.

The invention has a shell (1) for accommodating a cylinder (2), and in the cylinder (2) a piston connected to the drive mechanism via a piston rod, which also functions, for example, as a connecting rod (4). (3) reciprocates, the oil sump 5 is defined inside the cell 1, and the lubricating oil is lubricated by the oil pump means 10 from this oil sump 5 It is described in the context of a hermetic reciprocating compressor (e.g., of a type applied to a cooling system) that is pumped into movable parts of a compressor to be used. The oil pumping system of the present invention comprises a fluid communication means (6) connecting the oil pump means (10) to the parts to be lubricated, in order to supply lubricating oil from the oil sump (5) to the parts of the compressor to be lubricated. .

In a hermetic reciprocating compressor with a linear motor, the reciprocating motion of the piston 3 is effected by an actuator 7 which bears the magnetic element and is driven by a linear motor.

The piston 3 is connected to the resonant spring 8, for example by a connecting rod, and together with the magnetic element forms a resonant assembly of the compressor. The non-resonant assembly of the compressor includes a cylinder 2, a suction and discharge system of the compressor, and a linear motor.

In the structural example as shown, the oil pump means 10 is propelled by the resonant mass of the compressor and vibrates, for example, in the reciprocating direction of the piston 3. In another known structure of the oil pump means (not shown), the compressor is associated with a vibration amplitude which is a function of the ratio of the mass of the piston 3 (and integrated parts) to the mass of the compressor, When vibrating as a function of the interaction of force, the oil pump means are arranged to be propelled by the non-resonant mass of the compressor or by the movement of the compressor during operation.

In the structure in which the oil pump means 10 is attached to the piston 3, the movement of the piston is obtained when the oil pump means 10 is attached to the cylinder 2, for example, and as a result, It may cause displacement of the oil pump means 10 with a much larger amplitude (about 3 times larger) than to lead to the disadvantages described above.

As shown, the oil pump means 10 comprises a tubular pump body 11, which is open to an oil sump 5, for example an oil inlet contained in oil. It has an end 12 and an oil outflow end 13 connected to the fluid communication means 6.

According to the invention, the oil pump means 10 is connected to the compressor by means of cushioning elastic means 20, such as at least one spiral spring, which is adapted for oil pump means 10. Amplitude of the displacement of the oil pump means 10 to a value calculated such that the ratio between the displacement of the oil pump means 10 and the displacement of the compressor is less than 1 by the ratio of the resonance natural frequency of the compressor to the operating frequency of the compressor. It is dimensioned to reduce.

In order for the cushioning elastic means 20 of the present invention to operate so as to reduce the operating amplitude of the oil pump means 10 to a desired value, the cushioning elastic means 20 has a resonance natural frequency of the buffering elastic means ( The predetermined elastic constant K calculated by the ratio between Wn) and the operating frequency W of the compressor so that the ratio of the displacement X of the oil pump means 10 to the displacement Y of the compressor is less than one. Should have Such a ratio is obtained by the formula Wn = (K / Mb) (1/2), where Mb is the mass of the oil pump means 10. 3 shows the direction and meaning of each of the displacement X of the oil pump means and the displacement Y of the compressor.

The ratio (X / Y) of the decrease in the amplitude of the movement of the oil pump means 10 to the amplitude of the movement of the tube, as shown in FIG. 4, is the resonance natural frequency Wn in relation to the operating frequency W of the compressor. Can be defined by defining a predetermined ratio (K / Mb) between the elastic constant K of the cushioning elastic means 20 and the mass Mb of the oil pump means 10. This graph schematically shows the ratio between the displacement of the oil pump means 10 and the displacement of the connecting rod 4 as a function of the ratio W / Wn, where the area where the reduction of the motion amplitude is achieved is X / Y <1. Is represented. Where X is the amplitude of the movement of the oil pump means 10 and Y is the amplitude of the movement of the connecting rod 4.

According to the invention, the connecting rod 4 has a first end 4a connected to the compressor and a second end 4b opposite the first end 4a and connected to the oil pump means 10. And the connecting rod 4 is connected so as to be telescopically fitted to at least one of the compressor and the oil pump means 10, at least one of which is achieved via the cushioning elastic means 20. do.

In the configuration shown here, the connecting rod 4 is hollow, and therein forms a part of the fluid communication means 6 between the oil pump means 10 and the compressor part to be lubricated, A resilient means 20 is mounted around the end of the connecting rod 4. The oil pump means 10 is coupled to the outside of the end of the connecting rod 4, and the cushioning elastic means 20 is located outside the oil pump means 10.

In another embodiment of the invention (not shown), the connecting rod 4 supports the oil pump means 10 inside its end adjacent to the oil sump 5, and the cushioning elastic means 20 is connected. It is provided on the outside of the oil pump means 10 inside the rod 4.

According to the invention, the oil pump means 10 has at least one check valve 30 between the oil inlet end 12 and the oil outlet end 13, which check valve, for example, described above. In the form of a movable sealing means as disclosed in patent application PI0004286.2, between the valve seat and the internal stop 31 formed at the oil inlet end 12 of the pump body 11 of the oil pump means 10; Is displaced from

In another arrangement of the check valve 30, the check valve is provided at at least one of the oil inlet end 12 and the oil outlet end 13 of the oil pump means 10, or the oil inlet end 12 and the oil thereof. It is provided in the region of the pump body 11 between the outlet ends 13.

The pumping system of the present invention comprises, for example, at least one stop mounted to the connecting rod 4 between the oil pump means 10 and the compressor, in order to limit the maximum displacement of the cushioning elastic means 20. 40) may be provided.

Claims (11)

A shell 1 defining an oil sump 5 therein; A motor-compressor assembly; Oil pump means (10) connected to the compressor so as to be displaced in a reciprocating motion in a predetermined direction; And fluid communication means (6) connecting the oil pump means (10) to the compressor parts to be lubricated. The oil pump means 10 is connected to the compressor by at least one shock absorbing elastic means 20, and the shock absorbing elastic means 20 has a resonance natural frequency Wn of the oil pump means 10. ) By the ratio of the operating frequency (W) of the compressor to the value of the displacement of the oil pump means 10 and the displacement of the compressor to a value calculated to be less than one. An oil pumping system for a hermetic reciprocating compressor, characterized in that it is dimensioned to reduce the amplitude of the displacement. 2. The connecting rod (4) according to claim 1, further comprising a connecting rod (4) with one end connected to the cylinder (2) of the compressor and the opposite end connected to the oil pump means (10), at least one of which being connected An oil pumping system for a hermetic reciprocating compressor, characterized in that it is made through a cushioning elastic means (20). 3. The hermetic reciprocating compressor oil according to claim 2, wherein the connecting rod (4) is connected so as to be telescopically fitted into at least one of the cylinder (2) and the oil pump means (10) of the compressor. Pumping system. 4. A hermetic reciprocating method according to claim 3, characterized in that the connecting rod (4) is hollow and forms part of the fluid communication means (6) between the oil pump means (10) and the compressor part to be lubricated. Oil pumping system for the compressor. 5. The connecting rod (4) according to claim 4, wherein the connecting rod (4) supports the oil pump means (10) outside its one end (4b), and the cushioning elastic means (20) of the oil pump means (10). Oil pumping system for a hermetic reciprocating compressor, characterized in that it is mounted around the end (4b) from the outside. 5. The connecting rod (4) according to claim 4, wherein the connecting rod (4) supports the oil pump means (10) inside one end (4b) thereof, and the cushioning elastic means (20) is inside of the connecting rod (4). Oil pumping system for a closed reciprocating compressor, characterized in that provided in the outer side of the oil pump means (10). 5. The motor-compressor assembly according to claim 4, wherein the motor-compressor assembly comprises a piston (3), which is connected to the drive mechanism via a rod of the piston, and the connecting rod (4) is a piston rod. An oil pumping system for a hermetic reciprocating compressor. 2. The oil pumping system for a hermetic reciprocating compressor according to claim 1, wherein the cushioning elastic means (20) is in the form of a spiral spring. The oil pumping system of claim 1, further comprising one or more check valves (30) provided on the oil pump means (10). 10. The oil pump means (10) according to claim 9, wherein the oil pump means (10) is connected between the oil inlet end (12) opened by the oil sump (5) and the cylinder (2) of the compressor and the oil pump means (10). Having an oil outlet end 13 which is open to one end 4b of the connecting rod 4, wherein the check valve 30 has an oil inlet end 12 and an oil outlet end of the oil pump means 10. An oil pumping system for a hermetic reciprocating compressor, which is provided on one or both of (13). 11. The oil pumping system for a reciprocating compressor according to claim 10, wherein the connecting rod (4) has at least one stop (40) for limiting the maximum displacement of the cushioning elastic means (20). .

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