KR20020092553A - Linear compressor - Google Patents

Abstract

PURPOSE: A linear compressor is provided to improve life and reliability of a resonant spring. CONSTITUTION: A compressor includes a cylinder block(22) forming a compression chamber(21); a piston(23) installed in the compression chamber to reciprocate; a mover(44) joined to the piston to reciprocate together with the mover; a plurality of spring spacers(46) placed on an outside of the mover parallel to direction of movement of the piston; and a resonant spring(50) doubling reciprocation of the piston and the mover and having a first joining part joined to the mover and a second joining part joined to the spring spacers and formed at height different from the first joining part.

Description

Linear Compressor {LINEAR COMPRESSOR}

The present invention relates to a linear compressor, and more particularly, to a linear compressor having an improved structure of a resonant spring.

In the conventional linear compressor, as shown in FIG. 5, the linear compressor includes a sealed outer casing 110, a compression unit 120 that sucks and compresses and discharges a refrigerant, and a driving unit 130 that generates power. Have

The compression unit 120 supports a lower end of the outer core 133, which will be described later, and a cylinder block 122 forming a compression chamber 121, a piston 123 installed in the compression chamber 121 so as to reciprocate; And a cylinder head 124 provided in a lower region of the cylinder block 122 and provided with an intake valve for sucking refrigerant and a discharge valve for discharging the refrigerant.

The drive unit 130 surrounds the inner core 131 provided on the outer side of the cylinder block 122 and the outer circumferential surface of the inner core 131 at a predetermined interval, and the coil 132 is wound in an annular shape therein. A mark net provided between the core 133 and the inner core 131 and the outer core 133 to electromagnetically interact with the magnetic fields of the inner core 131 and the outer core 133 to reciprocate in the vertical direction. 134 and an inner core support 135 provided between the inner core 131 and the cylinder block 122 to support the inner core 131 and installed on the cylinder block 122. Upper and lower ends of the outer core 133 are provided with a holder 140 and a cylinder block 122 for supporting the outer core 133.

The outer core 133 is stacked with a plurality of core steel plates, and the stacked core steel sheets penetrate through the plurality of core fastening bolts 142 disposed at predetermined intervals at positions spaced apart from the outer circumferential surface of the outer core 133. The holder 140 and the cylinder block 122 are coupled to the core fastening bolt 142.

On the upper end of the piston 123 of the compression unit 120, one region is provided with a mark net 134 provided while maintaining a predetermined distance between the inner core 131 and the outer core 133 of the drive unit 130. The mover 144 for supporting and fixing is coupled. The mover 144 is interlocked with the above-mentioned up and down movement of the mark net 134, whereby the piston 123 performs the up and down movement in the compression chamber 121.

In the upper region of the mover 144 and the holder 140, a resonant spring 150 for doubling the up and down movement of the piston 123 is provided. The resonant spring 150 is coupled to a plurality of spring spacers 146 and bolts 148 that are alternately erected with the core fastening bolts 142 at the upper end of the holder 140 to the axial direction of the piston 123. It is installed in the transverse direction with respect to, and is connected to one end of the mover 144 and the fixed shaft (149). In addition, a bias washer 157 is disposed in the fixed shaft 149 to adjust the center of the piston 123 and the driving unit 130.

By such a configuration, when power is applied to the coil 132 of the outer core 133, the magnetic flux induced therefrom interacts with the magnetic field by the mark net 134 connected to the mover 144 to open the piston 123. Reciprocate in the vertical direction.

When the piston 123 is reciprocating up and down, the cooling gas sucked into the compression chamber 121 through the intake valve is discharged to the discharge valve through the compression process continuously to obtain the required cooling performance.

However, in the conventional linear compressor, as shown in FIG. 5, when the resonant spring assembled in a flat state starts to operate, as shown in FIG. 5, when the compressor starts to operate, as shown in FIG. Thereby deforming the piston in the opposite direction and then moving the given stroke in the deformed position.

As a result, in a structure in which the average stress and the cyclic stress are simultaneously applied, the bias spring becomes large, as in the conventional resonance spring, as shown in the Goodman Diagram shown in FIG. There is a disadvantage that the reliability is deteriorated.

Accordingly, it is an object of the present invention to provide a linear compressor capable of improving the lifetime and reliability of a resonant spring.

1 is a longitudinal cross-sectional view of a state in which the resonant spring pressure of the linear compressor according to the present invention does not work;

Figure 2 is a longitudinal sectional view of the average position state at the time of operation with the resonant spring of the linear compressor according to the present invention,

3 is a perspective view of a resonant spring applied to FIGS. 1 and 2;

4 is a Goodman diagram of a resonant spring according to repetitive stress and average stress,

5 is a longitudinal sectional view of an installation state of a conventional linear compressor;

FIG. 6 is a longitudinal cross-sectional view of an average position state during operation of FIG. 5. FIG.

* Explanation of symbols for the main parts of the drawings

20: compression 23: piston

30: drive unit 44: mover

50: resonant spring 52: protrusion

The object of the present invention is to provide a cylinder block for forming a compression chamber, a piston that is reciprocally installed in the compression chamber, a mover coupled to the piston and reciprocating together with the piston, In a linear compressor having a plurality of spring spacers disposed on the outside in parallel with the direction of movement of the piston, and a resonant spring for doubling the reciprocating motion of the piston and the mover, the resonant spring is coupled to the mover. It is achieved by a linear compressor characterized by having a first coupling portion and a second coupling portion coupled to each of the spring spacers and having a height difference in a thickness direction with respect to the plate surface of the first coupling portion.

Here, further comprising a fixed shaft for interconnecting and fixing the mover and the resonant spring, wherein the first coupling portion to form a protrusion protruding at a predetermined height toward the cylinder block with respect to the plate surface of the second coupling portion.

Bolting holes for bolting between the fixed shaft and the spring spacer are formed in the first and second coupling parts. At least one through hole is formed in the plate surface of the resonance spring.

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

In the linear compressor according to the present invention, as shown in FIG. 1, the linear compressor includes a sealed outer casing 10, a compression unit 20 for sucking and compressing and discharging refrigerant, and a driving unit 30 for generating power. Has

The compression unit 20 supports a lower end of the outer core 33 to be described later, and includes a cylinder block 22 forming a compression chamber 21, a piston 23 installed in the compression chamber 21 so as to reciprocate. And a cylinder head 24 provided in a lower region of the cylinder block 22 and provided with a suction valve (not shown) and a discharge valve (not shown) for sucking and discharging the refrigerant.

The drive unit 30 surrounds the inner core 31 provided on the outer side of the cylinder block 22 and the outer circumferential surface of the inner core 31 at a predetermined interval, and the coil 32 is wound in an annular shape therein. A magnet provided between the core 33 and the inner core 31 and the outer core 33 to electromagnetically interact with the magnetic fields of the inner core 31 and the outer core 33 to reciprocate along the vertical direction. 34 and an inner core support part 35 provided between the inner core 31 and the cylinder block 22 to support the inner core 31 and installed on the cylinder block 22. The upper and lower ends of the outer core 33 are provided with a holder 40 and a cylinder block 22 for supporting the outer core 33.

The outer core 33 is laminated with a plurality of core steel sheets. The laminated core steel sheets penetrate through the plurality of core fastening bolts 42 disposed at predetermined intervals at positions spaced apart from the outer circumferential surface of the outer core 33, and the core fastening bolts are formed on the holder 40 and the cylinder block 22. 42).

At an upper end of the piston 23 of the compression unit 20, one region supports a magnet 34 provided while maintaining a predetermined distance between the inner core 31 and the outer core 33 of the driving unit 30. The movable movable member 44 is engaged. The mover 44 is coupled to the piston 23 to perform the up and down reciprocating motion in the compression chamber 21 together with the piston 23.

In the upper region of the movable member 44 and the holder 40, a resonant spring 50 for doubling the up and down movement of the piston 23 is provided. The resonant spring 50 is formed in a disk shape in which a plurality of through holes 53 are formed in the plate surface such that a region coupled to the movable member 44 is curved with a predetermined curvature toward the cylinder block 22.

That is, as shown in Figure 3, the resonant spring 50, the first coupling portion is coupled to the end of the fixed shaft 49, each spring spacer 46 is coupled to the thickness of the plate surface of the first coupling portion The second coupling part 51 has a height difference along the direction different from each other. In the present embodiment, since the first engaging portion forms a protrusion protruding at a predetermined height toward the cylinder block 22 with respect to the plate surface of the second engaging portion 51, the reference numeral for the first engaging portion is omitted and the protrusion ( 52 only.

The second coupling portion 51 is formed with a bolt hole 54 for coupling the bolts 48 with the spring spacers 46, and the bolt 52 for coupling with the fixed shaft 49 is also formed in the protrusion portion 52. The ball 55 is formed.

Here, the shape change according to the height difference of the protrusion 52 with respect to the second coupling portion 51 can be obtained as follows. First, assuming that the linear compressor reaches a steady state, the gas force is averaged by one or more cycles, and the average force is obtained. The average force is divided by the total stiffness of the resonance spring 50, and then the amount of bias obtained is the resonance spring. The center of (50) is strained and the strain is applied to the resonant spring 50 as a result of the analysis.

When the protrusion 52 of the resonance spring 50 formed by the above method is coupled to the end of the fixed shaft 49, as shown in FIG. 2 together with the operation of the compressor, the resonance spring 50 is in a flat state. Since the compressor can be operated in the state of maintaining, the bias of the resonance spring 50 that doubles the movement of the piston 23 can be reduced to improve the reliability of the resonance spring 50. In addition, according to the present invention, an additional effect of not using a separate bias washer can be expected.

By this configuration, when power is applied to the coil 32 of the outer core 33, the magnetic flux induced therefrom interacts with the magnetic field by the magnet 34 connected to the mover 44 to move the piston 23 up and down. Reciprocate in the direction.

When the piston 23 moves up and down, the cooling gas sucked into the compression chamber 21 through the intake valve is discharged to the discharge valve through the compression process continuously, thereby obtaining the required cooling performance.

At this time, the mass of the piston 23 and the natural frequency of the resonant spring 50 are made to substantially correspond to the frequency of the power source to be applied, thereby ensuring a large driving force due to resonance.

On the other hand, since a general linear compressor has a free-piston structure, unlike a reciprocating compressor, there is no connecting rod that constrains the movement of the piston 23 and the movement of the piston 23 is caused by pressure and resonance in the compression chamber 21. It is determined by the rigidity of the spring 50, the mass of the piston 23, the excitation force of the drive unit 30.

In addition, since the pressure inside the compression chamber 21 has a highly nonlinear characteristic with respect to the displacement of the piston 23, the pressure inside the compression chamber 21 may cause a stiffness softening phenomenon when the discharge valve is opened. Have That is, the refrigerant gas inside the compression chamber 21 is changed in a direction of increasing stiffness during compression and in a direction of decreasing stiffness during discharge.

In the present invention, as shown in Figure 1, before the operation of the compressor, the compressor in the state that the pressure of the resonant spring 50, which is assembled in a flat state with the center portion curved toward the cylinder block 22 does not work, As shown in FIG. 2, as shown in FIG. 2, the pressure of the refrigerant causes the resonant spring 50 to deform into a flat state in an average position state, and then moves a given stroke in the deformed position, thereby reducing the bias. Can be.

As a result, the resonance spring 50 according to the present invention in the structure that receives the average stress and the repeated stress at the same time, as shown in the Goodman diagram (Goodman Diagram) shown in Figure 4, because it can achieve a structure that does not increase the bias compared to the conventional, resonance Fatigue and breaking life of the spring 50 is prevented from being shortened, and high reliability can be maintained. The diagram in FIG. 4 shows that when the cyclic stress is the same, the safety ratio is higher as the average stress is closer to zero.

As described above, in the present invention, the resonance spring 50 is formed such that a region coupled to the piston 23 is curved with a predetermined curvature toward the cylinder block 22, thereby improving reliability of the resonance spring 50. Can be.

As described above, according to the present invention, there is provided a linear compressor capable of improving the life and reliability of the resonant spring.

Claims (4)

A cylinder block forming a compression chamber, a piston installed reciprocally in the compression chamber, a mover coupled to the piston and reciprocating together with the piston, and parallel to a direction of movement of the piston outside the mover. In a linear compressor having a plurality of spring spacers arranged so as to be arranged, and a resonant spring for doubling the reciprocating motion of the piston and the mover, The resonant spring may include a first coupling part coupled to the mover and a second coupling part coupled to each of the spring spacers and having a height difference in a thickness direction with respect to a plate surface of the first coupling part. Linear compressor. The method of claim 1, Further comprising a fixed shaft for interconnecting and fixing the mover and the resonant spring, The first coupling unit is a linear compressor, characterized in that for forming a protrusion protruding toward the cylinder block with a predetermined height with respect to the plate surface of the second coupling unit. The method of claim 2, The first and second coupling portion is a linear compressor, characterized in that the bolt hole for the bolt coupling between the fixed shaft and the spring spacer. The method according to any one of claims 1 to 3, The resonant spring is a linear compressor, characterized in that at least one through-hole is formed in the plate surface.