KR20010026157A - Structure for engaging spring - Google Patents

Abstract

PURPOSE: A spring coupling structure is provided to prevent noise and damage to components by preventing each turn of the spring from contacting with each other. CONSTITUTION: A mass body(20) causing vibration has a support section(22) formed at a portion of the mass body. The mass body is an assembly of parts constituting an electric motor device for generating a driving force, and a compression device for compressing gas by the driving force from the electric motor device. The support section has at an outer periphery thereof a spiral coupling section(23) having a spiral protrusion. A spring(40) for supporting the mass body against to other component is formed of a wire having a plurality of turns. The spring includes a coupling section(41) formed at both ends of the spring to correspond to the support section of the mass body, and an effective turn section(42) taken up several turns so as to allow the wire forming the coil has a predetermined inner diameter. The coupling section of the spring is formed to have a predetermined spacing like the effective turn section.

Description

Spring fastening structure {STRUCTURE FOR ENGAGING SPRING}

The present invention relates to a spring fastening structure, in particular to the noise generated in the spring during operation of the spring to prevent the vibration generated in the mass body is transmitted to the other parts by shrinking and relaxing by connecting the mass generating vibration with other parts. It relates to a spring fastening structure that can be prevented.

In general, the compressor constituting the refrigeration cycle device is a device for compressing the refrigerant flowing from the evaporator to discharge the high temperature and high pressure.

The compressor includes a hermetically sealed container having a predetermined internal space, an electric mechanism part mounted in the hermetic container to generate a driving force, and a compressor mechanism part compressing the refrigerant gas by receiving the driving force of the electric mechanism part. When the power source is applied to generate a driving force in the electric mechanism unit, the compressor receives the driving force to suck, compress and discharge the refrigerant gas in the compression mechanism unit.

As such, vibration noise is generated in the process of repeatedly inhaling, compressing, and discharging the refrigerant gas, and when the vibration noise is transmitted to the airtight container and waved to the outside, a very unpleasant feeling is caused. This will lead to poor coupling. In this way, in order to minimize the transmission of vibration noise generated in the power mechanism and the compressor mechanism to the sealed container during the suction / compression and discharge of the refrigerant gas is supported by a spring that is a shock absorbing member.

FIG. 1 shows the sealed container 10 constituting the compressor, and the electric mechanism part and the compressor mechanism part installed inside the sealed container 10 to compress the refrigerant gas as one mass body 20. 20 is a structure coupled to the sealed container 10 by a spring 30 is a buffer member.

As shown in FIG. 1, the conventional structure in which the mass body 20 representing the electric mechanism part and the compression mechanism part as one is connected to the sealed container 10 by a spring 30 has a constant outer diameter on the bottom surface of the sealed container 10. A plurality of container side coupling protrusions 11 protruding to have a length and a length are formed, and a mass body side coupling protrusion 21 protruding to have a predetermined outer diameter and a length is formed at one side of the mass body 20. The container side engaging protrusion 11 and the mass body side engaging protrusion 21 are formed to correspond to each other. The coil spring 30 having an inner diameter corresponding to the outer diameter of the container side engaging projection 11 and the mass body side engaging projection 21 is press-fitted into the container side engaging projection 11 and the mass body side engaging projection 21, respectively. It is fixed. As shown in FIG. 2, the coil spring 30 is wound to have a plurality of turns such that a wire having a predetermined length has a predetermined inner diameter, and a close winding portion at which both ends are wound tightly. 31 is formed in the center thereof, and the wire is wound at regular intervals to form an effective winding part 32 having elastic force. The close contact portion 31 of the coil spring 30 is press-fitted into the container side engaging projection 11 and the mass body engaging projection 21, respectively, so that the mass 20 is sealed by the coil spring 30. Will be supported.

In the structure as described above, when the vibration occurs in the mass body 20 in the process of sucking, compressing and discharging the refrigerant gas from the mass body 20 including the electric mechanism part and the compression mechanism part, the vibration of the coil spring 30 By absorbing the buffer by the contraction-relaxing movement and minimizing the transmission of the vibration to the sealed container 10, the occurrence of vibration noise outside the sealed container 10 is suppressed.

However, the conventional structure as described above has a coupling spring (11, 21) protruding in a cylindrical form coil spring 30 that acts as a buffer so that the vibration generated in the mass body 20 is not transmitted to the sealed container (10). Since it is coupled in a press-fit state, as shown in FIG. 3, between the wires constituting the tight winding portion 31 of the coil spring 30 and the wires constituting the effective winding 32 during the contraction and relaxation movement of the coil spring 30. Not only contact noise is generated, but also friction noise is generated between the coupling protrusions 11 and 21 and the coil spring 30, thereby reducing the reliability.

The object of the present invention devised in view of the problems described above is to connect the mass generating vibrations with other parts to reduce the contraction and relaxation, so that the spring generated from the mass body is prevented from being transmitted to the other parts. It is to provide a spring fastening structure to prevent the noise generated.

1 is a front sectional view showing a state in which a mass body and a sealed container of a conventional compressor are fastened by a spring;

2 is an exploded front view showing a conventional spring fastening structure;

3 is a front view showing an operating state of a conventional spring fastening structure,

4 is a cross-sectional view of a compressor having a spring fastening structure according to the present invention;

5 is an exploded front view showing the spring fastening structure of the present invention;

Figure 6 is an exploded front view showing another embodiment of the spring fastening structure of the present invention.

(Explanation of symbols for the main parts of the drawing)

20; Mass 12,22; Support

13,23; Coupling part 40; spring

41; Fastening

In order to achieve the object of the present invention as described above, a cone-shaped support portion is formed on one side of the mass generating vibration, and a spiral-shaped coupling portion is formed on an outer surface of the support portion, and the wire is conical to correspond to the coupling portion. Spring fastening structure is provided, characterized in that the fastening portion of the spring provided with a fastening portion wound at regular intervals is fastened and fixed to the engaging portion of the support.

Hereinafter, described in accordance with an embodiment shown in the accompanying drawings the spring fastening structure of the present invention.

4 and 5 illustrate an example of the spring fastening structure of the present invention. Referring to this, first, the support part 22 having a conical shape is formed on one side of the mass 20 that generates vibration. The mass body 20 is composed of an assembly of components constituting a power mechanism for generating a driving force and a compression mechanism for compressing the gas by receiving the driving force of the power mechanism. In addition, a spiral coupling part 23 is formed on an outer surface of the support part 22, and the coupling part 23 is formed by protruding protrusions having a predetermined height and width in a spiral shape. And the spring 40 for supporting the mass body 20 to the other parts is made of a plurality of turns of a wire having a predetermined length to have a plurality of turns, both ends of the spring 40 formed to have a plurality of turns A fastening part 41 wound at regular intervals in a conical shape is formed to correspond to the support part 22 formed on the mass body 20, and the effective part is wound several times so that the wire has a predetermined inner diameter following the fastening part 41. It consists of a winding part 42. The fastening portion 41 is formed to have a predetermined interval like the effective winding portion 42 is not made in the form of the turn portion in contact with each other like the conventional close winding portion 31.

The fastening portion 41 of the spring 40 is screwed to the coupling portion 23 of the support portion 22 is formed in the form of a spiral screw.

In addition, in another embodiment of the present invention, as shown in Figure 6, the coupling portion 23 formed in the support portion 22 so that the groove corresponding to the outer diameter of the wire forming the spring 40 to form a spiral form Is formed. The fastening portion 41 of the spring 40 is screwed to the coupling portion 23 made of the spiral groove is screwed.

The mass body 20 is coupled to the container side support part 12 in the same form as the support part 22 and the coupling part 23 of the mass body 20 on one side of the sealed container 10 supported by the spring 40. The part 13 is formed. And the fastening portion 41 of the spring 40 is fixedly coupled to the container side support portion 12 and the coupling portion (13). That is, one side fastening portion 41 of the spring 40 is fixedly coupled to the support portion 22 and the coupling portion 23 of the mass body 20 and the other side fastening portion 41 of the spring 40 is the container side support portion ( 12) and fixedly coupled to the coupling portion 13, the mass 20 is fixedly supported in the sealed container 10 by the spring (40).

Hereinafter, the operation and effect of the spring fastening structure of the present invention will be described.

First, the driving force is generated by the power applied from the power mechanism of the mass body 20 constituting a single assembly including components constituting the power mechanism and the compressor mechanism, and the driving force is transmitted to the compressor mechanism to continuously suck the refrigerant gas. And compress. As such, vibration is generated in the mass 20 in the process of sucking and compressing the refrigerant gas, and the generated vibration is alleviated by repeated contraction-relaxing motion of the spring 40 to minimize the transfer to the sealed container 10. . At this time, since the fastening portion 41 of the spring 40 is screwed to the coupling portion 13, 23 of the support portion 12, 22 in the contraction and relaxation movement of the spring 40 spring 40 The contact between the turn part constituting the fastening part 41 and the turn part constituting the effective winding part 42 is suppressed, thereby preventing contact noise (called a rug) between the turn part and the turn part. In addition, the fastening portion 41 of the spring 40 is coupled to the coupling portion 13, 23 formed in a spiral form on the outer surface of the support portion 12, 22 formed in a conical shape, the support portion 12, 22 and the spring The frictional contact between the fastening portions 41 of the 40 is prevented.

In addition, the contact portion 31 of the conventional spring 30 is excluded, so that the production of the spring can be simplified, thereby increasing productivity. In addition, it is possible to further secure the mating state of the parts.

As described above, the spring fastening structure according to the present invention prevents contact noise by suppressing contact between the turn part and the turn part of the spring that connects the mass generating vibration to be supported by other parts, that is, the contact between the wires. In addition, by preventing the frictional contact between the fastening portion of the spring and the support for supporting it to suppress the friction noise has the effect of preventing the damage of the parts and increase the reliability.

Claims (1)

A conical support is formed on one side of the mass generating vibration, and a spiral coupling part is formed on an outer surface of the support, and a wire having a fastening part wound at regular intervals in a conical shape is formed to correspond to the coupling part. Spring fastening structure characterized in that the fastening portion is fastened and fixed to the engaging portion of the support.