KR101166291B1 - Variable displacement swash plate type compressor - Google Patents

Abstract

The present invention relates to a variable displacement swash plate compressor. According to the present invention, a drive shaft 161 rotated by an external driving force, a rotor 170 that rotates together with the drive shaft 161, and a drive shaft 161 are installed on the drive shaft 161 and reciprocally slide in a longitudinal direction of the drive shaft 161. A movable sleeve 165 and a swash plate 180 hinged to the rotor 170 and rotatably supported by the sleeve 165 so that the inclination angle with respect to the drive shaft 161 is variable. The swash plate hub 181 coupled to the surface of the swash plate 180 facing the rotor 170 is provided with a balance maintaining part 188 protruding toward the rotor 170. The distance U between the center C of the drive shaft 161 and the outer surface 188 ′ of the balance maintaining unit 188 is smaller than or equal to the radius SPr of the swash plate hub 181. According to the present invention having such a configuration, the center of gravity of the swash plate is concentrated in the direction of the center of the drive shaft, thereby reducing the variation in the amount of eccentricity generated during rotation of the drive shaft, the rotor, and the swash plate, and improving the vibration of the compressor during initial driving. do.

Compressor, swash plate, rotor, variable, eccentric, center of gravity

Description

Variable displacement swash plate type compressor

The present invention relates to a variable displacement swash plate compressor, and more particularly, to a variable displacement swash plate compressor in which the eccentricity variation of the driving unit is reduced to reduce vibration during initial operation.

1 shows an internal configuration of a variable displacement swash plate compressor according to the prior art in cross section, and FIG. 2 shows an exploded perspective view of the drive shaft, the rotor and the swash plate of the prior art.

As shown therein, the variable displacement swash plate compressor 1 is coupled to a cylinder block 10 having a plurality of cylinder bores 11 radially formed in front of the cylinder block 10 and a crank chamber 21. Front housing 20 to form a) and the rear housing 30 is coupled to the rear of the cylinder block 10 to form the suction chamber 31 and the discharge chamber 33.

Pistons 40 are respectively accommodated in the cylinder bore 11, and the piston 40 is linearly reciprocated to compress the working fluid introduced into the cylinder bore 11.

And between the cylinder block 10 and the rear housing 30 to control the flow of the refrigerant from the suction chamber 31 to the cylinder bore 11, from the cylinder bore 11 to the discharge chamber 33 The valve assembly 50 is installed.

On the other hand, a drive unit 60 for reciprocating the piston 40 is installed in the crank chamber 21.

As shown in FIGS. 1 and 2, the driving unit 60 is installed through the center of the front housing 20 and the cylinder block 10 and rotates by a driving force transmitted from an external power source. And a sleeve 65 coupled reciprocally to the drive shaft 61, a rotor 70 coupled to the drive shaft 61 in the crank chamber 21 to rotate together with the drive shaft 61, and the sleeve. The swash plate 80 is pivotally coupled to the rotor 65 and hinged to the rotor 70 so that the inclination angle of the rotor 70 is variable, and the swash plate 80 is elastically pressurized with respect to the rotor 70. It consists of a pressure spring (90).

The rotor 70 has a hinge arm 75 for hinge coupling with the swash plate 80. The hinge arm 75 is formed with a long slot shape hinge slot 76. On the other hand, the swash plate 80 is integrally coupled to the swash plate 80, the swash plate hub 81 is formed with a swash plate arm 85 is hinged by the hinge arm 75 and the hinge pin (P) do.

When the drive shaft 61 is rotated by a driving force transmitted from an external power source, the rotor 70 also rotates with the drive shaft 61. When the rotor 70 rotates, the swash plate 80 reciprocates along the longitudinal direction of the drive shaft 61 together with the sleeve 65 by the set pressure of the crank chamber 21 and the elastic pressing action of the pressure spring 90. At the same time, the angle of inclination rotates with variable angle.

When the swash plate 80 rotates in an inclined state, the circumferential region of the swash plate 80 reciprocates the pistons 40 as it passes between the shoes 44 interposed between the connecting portions 42 of the piston 40. Will be moved.

In the conventional rotor 70, the hinge arm 75 for hinge coupling of the swash plate 80 protrudes outward from the outer circumference of the rotor 70. In addition, when the swash plate 80 is inclined, the swash plate hub formed integrally with the swash plate 80 is in close contact with the seating groove 71 of the rotor 70 to support the swash plate 80. It is formed, the edge of the support plate 83 protrudes from the outer peripheral surface of the swash plate hub 81.

However, according to the prior art, the center of gravity of the driving unit 60 is distributed in the centrifugal direction with respect to the driving shaft 41 according to the shape and structure of the hinge arm 75 and the support plate 83, and thus the angle of the swash plate 80 changes. The amount of change in the eccentricity is increased. For this reason, there is a problem that the vibration and noise increase during the initial operation of the compressor.

An object of the present invention is to solve the problems of the prior art as described above, to concentrate the center of gravity of the drive unit in the center of the drive shaft to minimize the vibration and noise of the compressor.

According to a feature of the present invention for achieving the above object, the present invention is a drive shaft rotated by an external drive force, a rotor that rotates together with the drive shaft, installed in the drive shaft and reciprocating in the longitudinal direction of the drive shaft A variable displacement swash plate type compressor comprising: a slidable movable sleeve and a swash plate hinged to the rotor so that the inclination angle with respect to the drive shaft is variable and rotatably supported on the sleeve; A balance holding part protruding toward the rotor is formed in the swash plate hub coupled to the surface of the swash plate toward the rotor, and the distance between the center of the drive shaft and the outer surface of the balance holding part is smaller than or equal to the radius of the swash plate hub.

A hinge arm for hinge coupling with a hub arm protruding from the swash plate hub is formed on a surface facing the swash plate of the rotor, and the hinge arm has a hinge slot for changing the inclination of the swash plate in a long hole shape. Hinge pins are installed in the hinge slots to hinge the hub arms. When the swash plate is parallel to the rotor, the distance between the center of the hinge pin and the center of the drive shaft is 1.6 cm or more and 2.0 cm or less (1.6 cm ≤). T≤2.0cm).

 The distance between the outer surface of the hinge arm and the center of the drive shaft is characterized in that less than or equal to the radius of the rotor.

Protruding jaw is formed on the opposite side of the hinge arm around the drive shaft in the rotor, characterized in that the eccentric prevention portion is relatively thick in the rotor is formed in the region between the protruding jaw and the center of the drive shaft.

According to the present invention, the center of gravity of the drive unit is concentrated in the center of the drive shaft by the shape design of the rotor and the swash plate. Accordingly, the variation in the amount of eccentricity generated during rotation of the drive shaft, the rotor, and the swash plate is reduced, thereby improving the vibration of the compressor during the initial driving, thereby reducing the noise.

Hereinafter, a preferred embodiment of a variable displacement swash plate compressor according to the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, since the rest of the configuration of the variable displacement swash plate compressor excluding the driving unit is substantially the same as that of the conventional variable displacement swash plate compressor, the detailed description thereof is omitted, and reference numerals for components other than the driving unit are shown in FIG. Quotation marks are used.

FIG. 3 is a side view of a drive unit constituting an embodiment of the present invention, and FIG. 4 is an exploded perspective view of a drive shaft, a rotor, and a swash plate constituting the drive unit of FIG. 3.

As shown in the drawing, the drive unit 160 of the variable displacement swash plate compressor according to the present invention includes a drive shaft 161 which rotates by receiving a driving force from an external power source, and a sleeve reciprocally sliding with respect to the drive shaft 161. 165, a rotor 170 coupled to the drive shaft 161 in the crank chamber 21 and rotating together with the drive shaft 161, and rotatably coupled to the sleeve 165 and hinged to the rotor 170. And a swash plate 180 having a variable inclination angle with respect to the rotor 170, and a pressing spring 190 for elastically pressing the swash plate 180 to its original position with respect to the rotor 170.

First, the drive shaft 161 is rotatably installed through the center of the front housing 20 and the cylinder block 10. The rotor 170 is integrally coupled to the drive shaft 161 so that the rotor 170 also rotates when the drive shaft 161 rotates. The rotor 170 is formed in a substantially disc shape.

The hinge arm 175 for hinge coupling with the swash plate 180 is formed on the surface of the rotor 170 facing the swash plate 180. The hinge arm 175 has a hinge slot 176 through which a hinge pin P is installed. The hinge slot 176 is formed in a long hole shape to accommodate the angular change of the swash plate 180, it is formed to be inclined downward toward the drive shaft 161.

In the present embodiment, the outer surface 175 ′ of the hinge arm 175 is formed such that there is no portion protruding outside the edge of the rotor 170. That is, the distance S from the center C of the drive shaft 161 to the outer surface 175 ′ of the hinge arm 175 is the radius Rr of the rotor 170 of the portion where the hinge arm 175 is formed. Is less than or equal to

In addition, the concave surface 177 on which the balance holding part 188 of the swash plate 180 is seated on the surface facing the swash plate 180 of the rotor 170 when the inclination angle of the swash plate 180 is maximum. The support part 177a for supporting the balance maintaining part 188 protrudes from the recessed surface 177. In addition, a protruding jaw 177b is formed at an opposite side from which the hinge arm 175 is formed based on the driving shaft 161 on the recessed surface 177 of the rotor 170.

In addition, an eccentric prevention portion 179 is formed at the edge of the rotor 170 to prevent the eccentricity of the rotor 170, wherein the eccentric prevention portion 179 has a relatively thick thickness of the rotor 170. It is thickened. In the present embodiment, the eccentric prevention portion 179 is formed in the region between the protruding jaw 177b and the center C of the drive shaft 161. This is to concentrate the center of gravity of the rotor 170 in the centripetal direction of the drive shaft 161.

On the other hand, on the surface facing the rotor 170 of the swash plate 180, a substantially cylindrical swash plate hub 181 is fixed. The swash plate hub 181 is formed with a hub arm 186 hinged to the hinge slot 176 by a hinge pin (P). In the state where the swash plate 180 and the rotor 170 are parallel to each other, the hinge pin P is located at a position close to the drive shaft 161 in the hinge slot 176, where the center of the hinge pin P ( The distance T between Pc) and the center C of the drive shaft 161 is designed to be 1.6 cm or more and 2.0 cm or less (1.6 cm ≤ T ≤ 2.0 cm).

In addition, the swash plate hub 181 is integrally formed with a balance maintaining part 188 to prevent eccentricity of the swash plate 180. The balance maintaining unit 188 is formed on the opposite side of the swash plate hub 181 where the hub arm 186 is formed around the driving shaft 161. The balance maintaining part 188 protrudes from the swash plate hub 181 toward the rotor 170 and does not protrude outward from an outer circumferential surface of the swash plate hub 181. That is, the distance U between the center C of the drive shaft 161 and the outer surface 188 ′ of the balance maintaining part 188 is designed to be smaller than or equal to the radius SPr of the swash plate hub 181. . This is to concentrate the center of gravity of the swash plate 180 in the centripetal direction of the drive shaft 161.

On the other hand, the center of the balance maintaining part 188 is formed with a avoidance groove 189 for preventing the interference with the protrusion 177b.

Hereinafter, the operation of the drive unit constituting the embodiment of the present invention will be described.

First, when the drive shaft 161 of the drive unit 160 rotates, the rotor 170 rotates together with the drive shaft 161, and when the rotor 170 rotates, the swash plate 180 also rotates with the drive shaft 161, The inclination angle of the swash plate 180 is reciprocated along the longitudinal direction of the drive shaft 161 together with the sleeve 165 by the set pressure of the crank chamber 21 and the elastic pressing action of the pressure spring 190. Here, the inclination angle is an angle formed by the drive shaft 161 and the swash plate 180.

When the swash plate 180 rotates in a state in which the inclination angle is variable, as the edge portion of the swash plate 180, that is, the outer circumferential portion, passes between the shoes 44 placed on the connecting portion 42 of the piston 40. The piston 40 compresses the working fluid in the cylinder bore 11 in a linear reciprocating motion.

In the rotor 170 of the present invention, the outer surface of the hinge arm 175 does not protrude outward from the radius of the rotor 170, and the eccentric prevention portion 179 of the rotor 170 is driven by the drive shaft 161 and the protruding jaw ( 177b), the center of gravity of the rotor 170 is concentrated in the centripetal direction of the drive shaft 161. In addition, in the swash plate hub 181 of the present invention, the balance maintaining part 188 does not protrude from the outer surface of the swash plate hub 181, and also concentrates the center of gravity of the swash plate 180 in the centripetal direction of the drive shaft 161. I was. When the swash plate 180 is parallel to the rotor 170, that is, when the inclination angle of the swash plate 180 is 0 °, the center Pc of the hinge pin P and the center of the driving shaft 161 are provided. The distance T between (C) was set to be 1.6 cm or more and 2.0 cm or less (1.6 cm ≤ T ≤ 2.0 cm).

According to the present invention having such a configuration, the variation in the amount of eccentricity generated during rotation of the drive shaft 161, the rotor 170, and the swash plate 180 is reduced, thereby improving the vibration of the compressor during the initial driving, thereby reducing the noise. There is an advantage.

5 is a result of measuring a change in the amount of eccentricity of the driving unit according to the change of the swash plate angle. First, the amount of eccentricity of the driving unit 60 of the related art is changed from -40gcm to + 60gcm, while the amount of eccentricity of the driving unit 160 according to the embodiment of the present invention is measured to change from -45gcm to + 45gcm. As described above, it can be seen that the variation in the eccentric amount of the driving unit 160 of the present invention is smaller than that of the related art.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self-evident.

1 is a cross-sectional view showing the internal configuration of a variable displacement swash plate compressor according to the prior art.

Figure 2 is an exploded perspective view showing a drive shaft, a rotor and a swash plate of the prior art.

Figure 3 is a side view showing a drive unit constituting an embodiment of the present invention.

Figure 4 is an exploded perspective view showing a drive shaft, a rotor and a swash plate constituting the drive unit of FIG.

5 is a graph measuring a change in the amount of eccentricity of the driving unit according to the change of the swash plate angle.

Explanation of symbols on the main parts of the drawings

160: drive unit 161: drive shaft

165: sleeve 170: rotor

175: hinge arm 175 ': exterior

176: hinge slot 177: recessed surface

177a: support portion 177b: protruding jaw

179: anti-eccentric 180: swash plate

180: Saphan Herb 186: Herb Arm

188: balancing unit 188 ': outer surface

189: evasion groove 190: pressure spring

Claims (4)

A drive shaft 161 rotated by an external drive force, A rotor 170 rotating together with the drive shaft 161, A sleeve 165 mounted to the drive shaft 161 and movable reciprocally in the longitudinal direction of the drive shaft 161; A swash plate 180 hinged to the rotor 170 and rotatably supported by the sleeve 165 such that the inclination angle of the drive shaft 161 is variable; It includes a swash plate hub 181 coupled to the surface facing the rotor 170 of the swash plate 180, and a balance maintaining portion 188 protruding toward the rotor 170 in the swash plate hub 181 Become; Variable capacitance, characterized in that the distance (U) between the center (C) of the drive shaft 161 and the outer surface (188 ') of the balance maintaining portion 188 is less than or equal to the radius (SPr) of the swash plate hub 181 Type swash plate compressor. The hinge arm 175 for hinge coupling with the hub arm 186 protruding from the swash plate hub 181 is formed on a surface of the rotor 170 facing the swash plate 180. The hinge arm 175 has a hinge slot 176 to allow a change in the inclination of the swash plate 180 is formed in a long hole shape, A hinge pin (P) for hinge coupling the hub arm 186 is installed in the hinge slot 176, When the swash plate 180 is in parallel with the rotor 170, the distance T between the center Pc of the hinge pin P and the center C of the driving shaft 161 is 1.6 cm or more and 2.0 cm. A variable displacement swash plate compressor, characterized in that (1.6cm≤T≤2.0cm). 3. The distance S between the outer surface 175 ′ of the hinge arm 175 and the center C of the driving shaft 161 is less than or equal to the radius Rr of the rotor 170. Variable displacement swash plate compressor characterized in that. According to any one of claims 1 to 3, Protruding jaw 177b is formed on the opposite side of the hinge arm 175 around the drive shaft 161 in the rotor 170, A variable displacement swash plate type compressor comprising: an eccentric prevention portion (179) having a relatively thick thickness in the rotor (170) is formed in an area between the protrusion (177b) and the center (C) of the drive shaft (161).

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