KR0118459B1 - Scroll compressor - Google Patents

Abstract

The present invention relates to a swing scroll driving device of a scroll compressor, and in particular, to prevent friction wear and gap between the fixed scroll wheel and the swing scroll blade and to allow the swing scroll to rotate smoothly when the rotational speed of the motor is changed (3). The blade protection means 6 for generating a centrifugal force proportional to the direction opposite to the centrifugal force due to the revolution of the) is characterized in that formed between the rotating shaft 210 and the turning scroll.

Description

Swivel scroll drive device of scroll compressor

1 is a partial cross-sectional perspective view of a typical turning scroll.

2 is a plan view of a state in which the conventional turning scroll is separated.

3 is a cross-sectional view of a conventional state between the rotating scroll and the rotating shaft.

4 is a plan view of the rotating scroll of the present invention in a separated state.

Figure 5 is a cross-sectional view of the coupling state of the present invention the rotating scroll and the rotating shaft.

* Explanation of symbols for main parts of the drawings

1: housing 2: motor

210: rotating shaft 220: movement guide groove

3: turning scroll 300: wing

310: boss 330: pivot

4: fixed scroll 400: wing

6: wing protection means 600: mobile body

601: fastening hole 610: damping weight

620: elastic member

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a swing scroll driving device of a scroll compressor, and more particularly, to a swing scroll driving device of a scroll compressor which improves compression efficiency by eliminating blade distortion or gap between the swing scroll and the fixed scroll due to overload during compression. .

Typically, the scroll compressor is provided with a housing (1) having an oil storage part (103) separated by an oil plate (102) at the top and the bottom of the scroll compressor, as shown in FIG. Each of the fixed scroll (4) and the swinging scroll (3) having an invoke-shaped blade (400, 300) is installed 180 degrees to each other, the fixed scroll (4) is fixed to the housing (1) on one side , A suction pipe 100 for introducing a refrigerant gas, and a rotating shaft connected to the rotor 200 of the motor 2 including the stator 201 and the rotor 200 at a lower portion of the turning scroll 3. 210 is connected.

The upper end portion of the rotating shaft 210, that is, the portion connected to the turning scroll 3 is formed by the driving pin 212 so that the turning scroll 3 pivots with respect to the fixed scroll 4 to achieve compression.

In addition, a frame 6 for supporting the rotating shaft 210 is provided, and an old hem ring (oldham-ring) 500 is provided between the lower portion of the turning scroll 3 and the frame 5 so as to provide the turning scroll 3. To prevent rotation.

Thus, as the shaft 210 rotates as the rotor 200 rotates, the turning scroll 3 pivots the fixed scroll 4 to compress the refrigerant gas sucked into the suction pipe 100 at high temperature and high pressure to discharge the discharge hole 101. The inside of the housing 1 is filled with the high temperature and high pressure refrigerant gas, and in this state, the high temperature and high pressure refrigerant gas is discharged to the discharge tube 101 connected to the lower part of the housing 1.

On the other hand, the oil 104 provided under the housing 1 rises along the oil passage 211 penetrating from the lower portion of the shaft 210 to the upper portion due to the centrifugal force caused by the rotation of the shaft 210 to the back pressure chamber 11. It rises and again rises along the side of the turning scroll 3 to lubricate and cool the frictional portion.

Referring to the coupling relationship between the driving pin 212 and the turning scroll 3 of the conventional rotary shaft 210 in detail as shown in Figures 2 to 3, the driving pin 212 eccentric to one side on the top of the rotary shaft 210 And, it is composed of a swing scroll (3) having a bush 320 and a boss 310 to which the bush 320 is fitted, while being coupled to the drive pin 212.

Therefore, when the rotating shaft 21 rotates at a high speed, the turning scroll 3 rotates without rotation by the driving pin 212.

However, when the refrigerant is introduced into the compression chamber 120 formed by the turning scroll 3 and the fixed scroll 4 during the initial operation of the compressor, or when foreign matter is introduced, each blade 300 ( Excessive load was applied to the blades 400, causing the blade to be broken or deformed.

In addition, as the gap between the blades 300 and 400 increases, refrigerant leakage increases, so that the compression efficiency decreases.

In addition, in the inverter type compressor in which the rotational speed of the motor 2 is changed to improve the compression efficiency, the centrifugal force of the turning scroll 3 increases rapidly as the rotational speed of the motor 2 increases, so that the blades 300, 400 There is a problem in that the friction force and contact force between the) to shorten the life of the blade (300, 400).

This is explained by the equation of motion.

(Where F _C is the centrifugal force due to the orbiting scroll, F _gr is the radial refrigerant gas compressive force generated during refrigerant gas compression, F _g is the gas compression force of the component orthogonal to the radial direction generated during gas compression, F _R Is the contact force and sealing force generated by contacting the swing scroll and the fixed scroll by the centrifugal force acting on the swing scroll, F _n is the vertical force generated between the driving pin 212 and the bush 320, μ _n F _n is the driving pin ( 212) and the friction between the bush 320.)

Summarizing the above formulas ① and ② with respect to F _R ,

In this case, substituting μ _R = μ _n = 0.1 and Fgr / Fg = 0.1 in the above formula under the standard condition of an indoor air conditioner is as follows. (However, μ _R is the coefficient of friction between the fixed scroll and the rotating scroll blade. , μ _n is the coefficient of friction between the drive pin 212 and the bush 320)

Since Fn / Fg is always positive for any value of Fc in Fc / Fg, F _R is always present so that there is no gap between the turning scroll blade and the fixed scroll blade, thereby preventing leakage.

However, if the rotation speed of the motor is variable, Fc is increased to increase the contact force, thereby increasing the friction loss.

The graph is as follows.

That is, in the inverter-type compressor that changes the rotational speed of the motor, as the centrifugal force increases, the contact force increases, causing excessive friction and wear between the blades.

The present invention was developed to reduce the above points, the object of which is to maintain a constant contact force between the swing scroll and the fixed scroll to eliminate the gap generated between the blades and at the same time to minimize the friction and wear between the blades It is to provide a swing scroll driving device of a scroll compressor by maintaining it to improve the efficiency and reliability of the compressor.

The present invention for achieving the above object is characterized in that the blade protection means for generating a centrifugal force proportional to the direction opposite to the centrifugal force due to the revolution of the swinging scroll between the rotating shaft and the swinging scroll.

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

5 is a cross-sectional view of the rotational state of the present invention between the rotating stroke and the rotating shaft, the blade protection means 6 for generating a proportional centrifugal force in a direction opposite to the centrifugal force due to the revolution of the rotating scroll (3) and the rotating shaft (210) It is formed between (3).

That is, the blade protection means 6 maintains a constant contact force between the blades 300, 400 and eliminates the gap between the blades to prevent leakage of the refrigerant gas.

In the embodiment of the blade protection means 6 forms a predetermined length of the movement guide groove 220 passing through the center of the rotary shaft in the upper end of the rotary shaft 212.

On the other hand, the damping weight that is inserted into the movable guide groove 220 is movable to one side and has a steelmaking hole 601 in the center, and is inserted into the movable guide groove 220 to the other side of the movable guide groove 220 610 is provided.

In addition, the damping weight 610 and the movable member 600 is interposed between the elastic member 620 to push each other.

On the other hand, the lower portion of the turning scroll (3) is formed with a turning pin 330 to be fitted to the fastening hole 220 of the moving body (600).

As described above, the operation of the present invention will be described with reference to FIG. 4.

As it rotates on the rotating shaft 210, the turning scroll 3 is coupled with the turning pin 330 to the fastening hole 601 of the movable body 600 to perform an eccentric revolution. Accordingly, the turning scroll 3 has a centrifugal force of Fc ₁ . By receiving the moving body 600 is moved by the turning radius (r ₁ ) determined in the blades 300, 400 shape and makes an orbital movement.

Therefore, when the swing scroll 3 is eccentric and swings, the refrigerant gas compressive force due to the compression action with the fixed scroll 4 is generated as the Fg and Fgr components.

In addition, the vertical force (-Fn) and friction force (μ _n F _n ) is generated between the moving body 600 and the movement guide groove 220 in the force of Fg.

On the other hand, the turning scroll (3) fitted in the fastening hole (601) of the moving body 600 moves in a direction in which the turning radius is increased and stops at the turning radius (r ₁ ) where the blades (300, 400) contact occurs. In the vane, contact force (F _R ) and friction force (μ _R F _R ) are generated.

In addition, the damping weight 610 connected through the movable body 600 and the elastic member 620 has a turning radius (r ₂ ) in which the rotating shaft 210 is separated from the movable body 600 about the center point O according to the rotational force (W). Direction and centrifugal force of Fc ₂ is generated.

At this time, the centrifugal force Fc ₂ of the damping weight 610 increases proportionally with the increase in the rotational speed W, thereby reducing the centrifugal force Fc ₁ of the movable body 600 and the turning scroll 3 and thereby the wing. Reduces contact force (F _R ) and friction force (μ _R F _R ) between (300) and (400).

In addition, when the overload occurs due to the introduction of a liquid refrigerant or phosphorous material into the compression chamber 120 in both shafts, the moving body 600 prevents the occurrence of overload by actively moving in a direction in which the turning radius r ₁ decreases. .

The above process is described as an equation of motion.

(Wherein m ₁ is the mass of the turning scroll and the mass of the moving body 600, m ₂ is the mass of the damping part 610)

Where r ₁ is always kept constant as the turning radius (distance between the turning scroll and the fixed scroll), but m ₂ is the length of the elastic member 620 increases with the increase of w to increase the turning radius (r ₂ ). .

Therefore, while the centrifugal force Fc ₁ increases only the rotational speed w as the rotational speed w increases, the centrifugal force Fc ₂ increases the rotational radius r ₂ together with the rotational speed w. ₂ ) As compared with the centrifugal force (Fc ₁ ), the increase rate increases more as the number of revolutions (w) increases (Fc ₁ -Fc ₂ ). The value is displayed.

Explain this in terms of,

If you summarize ①, ② for F _R ,

On the other hand, in a room air conditioner under standard conditions, μ _R = μ _n = 0.1 and Fgr / Fg = 0.1 are substituted into the above equations.

(However, the constant 1 is a value of F _R 0.99 / Fg irrespective of w).

The turning radius r ₂ which can be designed from the above equation is as follows.

(Wmax is the maximum variable speed, r ₂ max is the maximum turning radius, F´ _R is a constant contact force.)

Since the maximum turning radius (r ₂ max) for the damping weight mass (m ₂ ) given in the above equation is calculated, the length of the movement guide groove 220 can be designed accordingly, and the force according to m ₂ r ₂ maxW ² max The elastic member 620 can be designed such that the displacement becomes (r ₁ + r ₂ max) with respect to it. (However, m ₂ is set to be Fc ₁ Fc ₂ at all times.)

Meanwhile, at a constant value of (Fc ₁ -Fc ₂ ) / Fg, F _R / Fg is always positive and F _R is always constant, so there is no gap between the turning scroll 300 and the fixed scroll 400, As a result, no refrigerant gas leakage occurs, thereby improving compressor efficiency.

In addition, since the contact force F _R is constantly maintained at a constant value according to the increase in the rotational speed (F _C1 -F _C2 ), there is no problem that the vane friction loss is increased even if the rotation speed of the motor is variable.

The graph is as follows.

That is, the centrifugal force is increased when the rotation speed W is changed to solve the problem that the friction and wear between the contact force F _R and the blade are increased, thereby obtaining the reliability and good compression efficiency of the compressor.

As described above, according to the present invention, the contact force generated between the turning scroll and the fixed scroll is kept constant when the rotational speed of the motor is changed, thereby preventing excessive friction and wear, and preventing leakage of refrigerant by eliminating gaps between vanes. .

It also has the effect of preventing overloading during compression to prevent blade deformation or breakage.

Claims (2)

A rotating scroll driving device for driving a rotating scroll by a rotational axis of a motor, wherein a blade protection means for generating a proportional centrifugal force in a direction opposite to the centrifugal force due to the revolution of the rotating scroll is formed between the rotating shaft and the rotating scroll. It is a swing scroll drive of the compressor. According to claim 1, wherein the blade protection means is a movement guide groove formed on the upper end of the rotating shaft, a movable body fitted to one side of the movement guide groove and formed a fastening hole in the center, and the damping to be fitted to the other side of the movement guide groove It is a swing scroll driving window of a scroll compressor, characterized by consisting of a weight, an elastic member interposed between the movable body and the damping weight, and a turning pin at a lower portion of the turning scrill fitted in the fastening hole of the movable body.