DE19643951A1 - Linear gas compressor - Google Patents

Abstract

The compressor comprises a horizontally arranged sealed casing, an elastic component formed in each of a number of the lower areas of the casing, and a compression unit which is horizontally supported by the elastic component. The compression unit has a direction of vibration which is orthogonal to a vibration direction of the elastic mounting, through which the amplitude of the sealed casing is reduced. The elastic element has a rigidity in the horizontal X-direction.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to a linear ver denser with minimal vibrations during operation.

2. Description of the Prior Art

Usually a crankshaft is used to create a Rotary motion of an engine in a linear reciprocating motion convert movement, and there are many parts like one Connecting rods and bearings are required, and high knock-out results most while reducing productivity.

There are also many parts that are in operation during a Compressor are in frictional contact, resulting in an increased Power consumption and reduced efficiency of the Compressor leads.

To the problems of the conventional Solving the crankshaft-driven compressor is a knock-out most economical linear motor has been introduced, which consists of few ger parts, with a linear motor instead of a Crankshaft is used to reciprocate a piston move. As a result, fewer parts are required, and it is less friction occurs when operating the conventional line aren compressor, which increases the efficiency and electricity consumption drops.

As shown in Fig. 1, a compression unit 2 is provided inside a hermetic container 1 of the conventional linear compressor, which is elastically supported by a plurality of mounting springs 3 .

In particular, a piston spring 4 is provided on the plurality of mounting springs 3 , and a cylinder 5 is provided on the piston spring 4 in an upright position.

Inside the cylinder 5 there is a piston 6 which slides back and forth therein, and outside the cylinder 5 a linear motor 7 consisting of a coil and a magnet is provided to actuate the cylinder 5 .

On an upper surface of the cylinder 5 , a Ven tileinheit 8 is attached, and on both sides of the valve unit 8 , an intake damper 9 and a discharge damper 10 are mounted.

The compression unit 2 includes the piston spring 4 , the cylinder 5 , the piston 6 , the linear motor 7 , the Ven tileinheit 8 , the intake damper 9 and the output damper 10th Reference character S denotes a refrigerant compression chamber defined by the cylinder 5 and the piston 6 , and the chamber S changes size during operation.

In the conventional linear compressor thus composed, the piston 5 repeatedly makes a linear reciprocating movement in the cylinder 6 in accordance with the operation of the linear motor 9 and serves to refrigerate a seal in the valve unit 8 through a suction valve (not shown) formed in the valve unit Refrigerant compression chamber 5 to suck and discharge the refrigerant through the outlet valve (not shown).

Here, the intake damper 9 and the output damper 10 each serve to reduce noise during suction and the delivery of the refrigerant.

However, the compression unit 2 is vertically provided in the hermetic container 1 , so that the direction of movement of the linear motor 7 speaks to that of the piston E, thereby causing a considerable noise of the hermetic container 1 during operation of the compressor.

With reference to the accompanying drawings the disadvantages of the conventional linear Ver be described in more detail.

As shown in FIG. 2, the vibration of the hermetic container 1 occurs due to the movement of the compression unit 2 therein.

More specifically, the acceleration of the compression unit 2 , which is vibrated according to the operation of the linear compressor with a certain amplitude along the vertical direction Y of FIG. 3, causes the hermetic container 1 to vibrate along the direction Y of FIG. 3. Here, the amplitudes of the compression unit 2 and the hermetic container 1 and the stiffness of the mounting spring 3 are proportional to each other. The reduced amplitude of the compression unit 2 serves to reduce the amplitude of the hermetic container 1 , and thus the stiffness of the mounting spring 3 to reduce the amplitude of the hermetic container 1 . In fig. 2 also denotes the reference numeral 14 a Mon day rubber.

In the conventional linear compressor, as shown in Fig. 3, assuming an excitation force F of fsinωt, there is a stiffness of the assembly line 3 in the Y direction of K _Y and a stiffness in the X direction of K _Y the following equation (1):

F = M + K _Y Y = fsinωt (1)

(M: weight,: acceleration, M: inertial energy of compression unit 2 , Y: movement distance, K _Y Y: term of potential energy with one dimension [MLT ^-2 ]).

The vibration largely depends on the size of an amplitude, and in order to obtain a size Y of an amplitude, a homogeneous solution Yh and a particulate solution Yp (Y = Yh + Yp) are calculated; here Yh = C₁cosω _n t + C₂sinω _n t (values of C₁ and C₂ are given by an initial value) and Yp = Ycosωt, which gives the following second equation (2):

(here δ _ST (static deflection) = F / K _Y , ω: frequency of the force exerted, (ω _n : natural frequency of the compression unit 2 ).

Now the value of the homogeneous solution Yh exists in an initial operating value of the compressor, but not when the operation changes to a normal state, so that a movement distance Y (= Yh + Yp) of the compression unit 2 is determined by a particulate solution Yp.

If Y / δ _ST and ω / ω _n are replaced by R and r in equation (2), the following equation (3) is obtained:

The relationship between a gain factor R, which corresponds to the ratio of a movement distance Y to the static deflection δ _ST , and a frequency ratio r (= ω / ω _n can be graphically represented as shown in FIG. 4, where a plurality of test values for the loading drawing with different damping factors ζ from zero (0) to 2.0 are shown.

Now in the expression F = fsinωt ω) denotes a frequency which corresponds to that of a supply voltage, so that there is a fixed expression (ω = 2πs = 2π × 60), where r (= ω / ω _n ) in a conventional compressor is greater than 1. That is, if the compression unit 2 is significantly light in weight and the coefficient of elasticity of the mounting spring 3 is extremely small, then the value r ranges from 0 to 1, and since the mounting spring 3 in the linear compressor has to carry the considerably heavy compression unit 2 and if, in view of the static penetration δ _ST, a vertical stiffness KY of the mounting spring 3 cannot be reduced below a certain limit, then the value of r remains greater than 1.

As described above, the amplification factor R, which serves as a measure for measuring the amplitude, becomes smaller in an interval in which r is greater than 1, whereby the value of ω is determined. Consequently, when the natural frequency ω _{n of} the compression unit 2 is reduced, the value of R used for Y / δ _ST becomes smaller, whereby the amplitude of the container is reduced.

SUMMARY OF THE INVENTION

It is therefore an object of the present invention to to create a linear compressor where the vibration is effectively reduced during its operation.

To achieve this goal, the linear ver denser with minimal vibrations a horizontally hermetic container, an elastic element that on each of a plurality of lower regions of the hermeti the container is formed, and a compression unit horizontally abge from the elastic element is supported.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a cross sectional view of a conventional linear compressor;

Fig. 2 is a simplified view showing an arrangement of the conventional linear compressor;

Fig. 3 is a schematic view of the conventional linear compressor;

Fig. 4 is a graph showing the relationship between a gain of a vibration system and a frequency ratio of a linear compressor;

Fig. 5 is a partially cross-sectional side view of a linear compressor according to the present invention; and

Fig. 6 is a cross sectional top view of the linear compressor of the invention;

Fig. 7 is an enlarged view showing a composition of an elastic member of the linear compressor according to the invention; and

Fig. 8 is a schematic view of the linear compressor according to the Invention.

DETAILED DESCRIPTION OF THE PRESENT INVENTION

As shown in Fig. 5-7, is in the inventive linear compressor with minimized Vibratio NEN in several lower areas of a horizontally installed hermetic container 21 serving as an elastic element mounting spring 22nd A compression unit 23 is supported horizontally by the mounting spring 22 .

The linear compressor according to the invention with minimized vibrations is installed so that the vibration by orthogonal crossover of the vibration direction of the Mon day spring 22 and the direction of excitation vibration of the compression unit 23 is considerably reduced. Over a bottom surface of the hermetic container 21 is the same at each of four predetermined locations a plate 21 a formed. On the upper surface of the plate 21 a, a first holding projection 21 b is formed on a surface of the plate 21 a, as shown in Fig. 7. A second holding projection 23 a is formed on a certain area of the compression unit 23 that it is opposite the plate 21 a accordingly.

On the first retaining projection 21 b, which is formed on the upper surface of the container 21 , a lower part of a mounting spring 22 is attached, and on the second retaining projection 23 a, an upper part of the mounting spring 22 is attached to elastically support the compression unit 23 .

The mounting of the mounting spring 22 is not limited to the areas shown in the accompanying drawings. The compression unit 23 can also be mounted on any area in the hermetic container 21 if it can only be supported effectively and elastically.

It will now be the operation of the invention linear compressor with minimized vibrations be.  

First, the rigidity of the mounting spring 22 is converted into K _X , which means a rigidity in the horizontal X direction.

In the case of an ordinary coil spring, the value of K _{X is} less than a third of KY, so that r (= ω / ω _n ) becomes larger than that of the conventional vertical sealing arrangement of FIG. 3.

If the value of K _X now becomes larger - ie softer - the value of r increases.

Therefore, an increased value of r produces a reduced value of R (= Y / δ _ST ) regardless of the size of the attenuation, thereby reducing the amplitude of the container 21 .

The relationship between the rigidity of the mounting spring 23 and the amplitude of the compression unit 22 is contained in an equation (4) as follows:

(force exerted on the container 21 ) force = stiffness (the assembly spring 23 ) × amplitude (the compression unit) (4)

If the rigidity of the mounting spring 13 is softer - that is, larger - the amplitude of the compression unit 22 becomes smaller.

Remains Thus, when the compression unit is hori zontal mounted in the vessel 21 22, the rigidity K _X of the mounting spring 23 is less than a third of the stiffness of a conventional vertical compression means so that in the case of the horizontal linear compressor, the force applied to the hermetic vessel 21 force is reduced by a third compared to the vertical compressor. The horizontally mounted compression unit 22 thus serves to reduce the amplitude of the container 21 during the operation of the compressor.

As described above, the linear compression decreases ter according to the present invention by orthogonal Crossing the direction of vibration of the elastic Ele ment and the direction of an excitation vibration of the compression  tion unit advantageous unwanted vibrations during of its operation.

Claims (3)

1. Linear compressor with minimal vibrations, which includes:
a hermetic container provided horizontally;
an elastic means formed in each of a plurality of lower portions of the hermetic container; and
a compression unit which is supported horizontally by the elastic means, wherein the compression unit has a direction of vibration which is orthogonal to a direction of vibration of the elastic means, where is reduced by an amplitude of the hermetic vessel. 2. Linear compressor according to claim 1, wherein the elasti element has a stiffness in the horizontal X direction having. 3. Linear compressor according to claim 1, wherein over a Bottom surface of the hermetic container before several plates are seen, on each of which a first retaining projection is formed with a corresponding part of the ela tical element is connected, and on a specific Area of the compression unit a second holding projection is designed so that it against the plate accordingly overlaps.