KR101201905B1 - Scroll compressor with function for adjusting oil supply quantity - Google Patents

Abstract

The present invention relates to a scroll compressor having a lubrication amount control function, and to adjust the lubrication amount supplied to the compression mechanism according to the operating conditions during operation of the compressor, thereby reducing the performance caused by the excessive flow of oil during high speed operation The present invention relates to a scroll compressor having a lubrication amount adjusting function which can prevent and improve reliability by maintaining an optimum lubrication state for each operating condition.

To this end, the present invention, the casing is filled with a predetermined amount of oil therein; A rotating scroll which is engaged with a fixed scroll fixedly installed in the casing and forms two pairs of compression chambers continuously moving; A drive motor installed inside the casing to generate a driving force; One side is coupled to the drive motor and the other side is coupled to the swing scroll so that the driving force of the drive motor is transmitted to the swing scroll, the oil is sucked along the longitudinal direction therein and each bearing of the swing scroll A drive shaft having an oil passage so as to be supplied to the surface, and a bypass hole communicating with the outside so that some of the oil drawn up may be bypassed; And a bypass valve for selectively opening and closing the bypass hole by centrifugal force according to the rotational speed of the drive shaft so that the amount of oil supplied to each bearing surface of the swing scroll can be kept constant. Provided is a scroll compressor with a flow control function.

Scroll compressor, oil supply, bypass hole, bypass valve, eccentric, spring

Description

SCROLL COMPRESSOR WITH FUNCTION FOR ADJUSTING OIL SUPPLY QUANTITY}

1 is a cross-sectional view showing the structure of a conventional scroll compressor

Figure 2 is a conventional scroll compressor, a cross-sectional view showing an oil supply state

3 is a cross-sectional view showing the structure of a scroll compressor having an oil supply flow rate adjusting function according to the present invention;

4 is an enlarged cross-sectional view illustrating main parts of FIG. 3.

5 to 6 is a cross-sectional view showing the operation structure of the bypass valve as a scroll compressor having an oil supply control function according to the present invention

7 is a cross-sectional view showing another embodiment of a scroll compressor having a fuel supply flow adjustment function according to the present invention;

<Description of the symbols for the main parts of the drawings>

111: casing 112,113: upper and lower frames

114: drive motor 115: fixed scroll

116: turning scroll 117: drive shaft

117a: oil path 117b: bypass hole

118: Old Daming 119: high and low pressure separator                 

120: pump 130: check valve

140: bypass valve 141: valve member

141a: bearing water 142: spring member

143: support member 144: eccentric load

The present invention relates to a scroll compressor having a lubrication amount adjustment function, and more particularly, the lubrication amount supplied to the compression mechanism part can be adjusted according to the operating conditions during operation of the compressor, so that oil is excessively introduced during high speed operation. The present invention relates to a scroll compressor having a lubrication amount control function, which can prevent the performance deterioration and improve reliability by maintaining an optimum lubrication state for each operating condition.

Generally, a compressor is a device that compresses a fluid such as refrigerant gas, and the compressor is classified into a rotary compressor, a reciprocating compressor, a scroll compressor, and the like according to a method of compressing the fluid.

The scroll compressor is a high-efficiency low noise compressor widely applied to the air conditioner field, and the two scrolls move relative to each other to form a plurality of compression chambers in pairs between the scrolls, and the compression chamber continuously moves in the center direction to have a volume. As the size decreases, the refrigerant is continuously sucked and compressed and discharged.

1 is a cross-sectional view showing the structure of a conventional scroll compressor, Figure 2 is a conventional scroll compressor, a cross-sectional view showing an oil supply state.

As shown in FIGS. 1 and 2, the conventional scroll compressor includes a gas suction pipe SP and a gas discharge pipe DP on one side to form a sealed receiving space therein so that refrigerant gas may be sucked and discharged. A casing 11 and an upper frame 12 and a lower frame 13 which are respectively fixed to upper and lower sides of the casing 11 and between the upper frame 12 and the lower frame 13. The driving motor 14 and the driving motor 14 generating the rotational force is pressed into the center of the rotor 14b of the driving motor 14 and passed through the upper frame 12 and coupled to the turning scroll 16 to be described later drive motor 14 A fixed scroll 15 fixed to the upper portion of the upper frame 12 and having an involute-shaped wrap 15a and an involute-shaped wrap 16a. Two pairs of compression chambers engaged with the fixed scroll 15 and continuously moving ( A pivoting scroll 16 which is coupled to form P) and compresses the refrigerant while moving relative to the fixed scroll 15, and is provided between the pivoting scroll 16 and the upper frame 12 to pivot the scroll 16; It includes an Oldham's ring 18 for turning while preventing rotation of the vehicle.

A shaft hole 12a for radially supporting the drive shaft 17 is formed in the center of the upper frame 12, and the boss portion 16b of the turning scroll 16 is formed at the upper end of the shaft hole 12a. The boss accommodating groove 12b is extended to be pivotal.

The drive shaft 17 is press-fitted to the rotor 14b of the drive motor 14 so that the upper and lower sides thereof are supported by the upper frame 12 and the lower frame 13, respectively, and the lower end thereof receives oil in the casing 11. As a pump device for forced suction, a volumetric pump 20 is provided, and inside the drive shaft 17, the oil sucked through the volumetric pump 20 is sucked up to lubricate each bearing surface. The oil flow path 17a is formed long along the axial direction.

A wrap 15a constituting two pairs of compression chambers P is formed in an involute shape on the bottom surface of the hard plate part of the fixed scroll 15, and the suction pressure side space S is provided on the side of the hard plate part through a gas suction pipe SP. _A suction port (not shown) is formed to allow the refrigerant sucked into _ps ) to be sucked into the compression chamber P, and the compressed gas compressed in the final compression chamber P is discharged at the upper pressure center in the upper surface of the hard plate portion S. _A discharge port 15b is formed to be discharged to _pd ).

In addition, the upper surface of the fixed scroll 15 is provided with a check valve 30 for selectively opening and closing the discharge port (15b) to prevent the back flow of the refrigerant gas, the upper portion of the fixed scroll (15) of the casing (11) The high and low pressure separating plate 19 which separates the internal space into the discharge pressure side space S _pd and the suction pressure side space S _ps is combined.

On the upper surface of the hard plate portion of the turning scroll 16, the wrap 16a constituting a pair of compression chambers P together with the wrap 15a of the fixed scroll 15 is formed in an involute shape, and the bottom of the hard plate portion In the center, the boss shaft 16b is coupled to the drive shaft 17 to receive the power of the driving motor 14, and the boss portion 16b is a boss receiving groove of the upper frame 12. It is inserted into 12b) to make turning motion.

On the other hand, reference numeral 14a denotes a stator of the drive motor 14.                         

Hereinafter, an operation structure of a conventional scroll compressor having the above structure will be described.

When power is applied to the drive motor 14, the rotating shaft 16 is rotated with the rotor 14b of the drive motor 14, the turning scroll 16 by the old dam ring 18, the upper frame 12 The pivoting movement is made from the upper surface of the eccentric distance, and the turning scroll 16 continuously forms a pair of compression chambers P between the wraps 15a and 16a with the fixed scroll 15. The compression chamber P is moved to the center by the continuous turning motion of the turning scroll 16 and the refrigerant gas is continuously sucked and compressed as the volume is reduced.

Here, the refrigerant gas is sucked into the suction pressure side space S _ps through the gas suction pipe SP, sucked into the compression chamber P through the suction port, and is compressed, and then discharged through the discharge port 15b of the fixed scroll 15. It is discharged to the pressure side space S _pd , and this refrigerant gas is discharged to a refrigeration cycle system (not shown) through the gas discharge pipe DP.

On the other hand, the oil in the casing 11 is forcibly sucked by the volumetric pump 20 and then sucked up through the oil passage 17a of the drive shaft 17 by centrifugal force due to the rotation of the drive shaft 17, and a part of the upper frame. While lubricating the shaft hole 12a of the part 12, a part is supplied between the thrust bearing surface of the turning scroll 16 and the thrust bearing surface of the upper frame 12, and each bearing surface, and lubrication is performed.

However, in the conventional scroll compressor, as the amount of oil supplied to each bearing surface of the turning scroll 16 during the high speed rotation of the drive shaft increases rapidly, the amount of oil discharge is increased and the performance and reliability of the compressor are deteriorated.

That is, the amount of oil supplied to each bearing surface through the oil passage 17a increases in proportion to the rotational speed of the drive shaft 17. When the drive shaft rotates at a high speed due to an overload driving condition, Due to the centrifugal force, the amount of oil drawn up through the oil flow path 17a is rapidly increased. Accordingly, the amount of oil discharged is rapidly increased, resulting in an oil shortage in the compressor, and an increase in friction loss. There was a problem.

Therefore, the present invention has been made in order to solve the above problems, by adjusting the amount of oil supplied to the compression mechanism according to the operating conditions during operation of the compressor, the performance according to the excessive flow of oil during high speed operation It is an object of the present invention to provide a scroll compressor having a lubrication amount control function which can prevent the deterioration and improve the reliability by maintaining an optimum lubrication state for each operating condition.

The present invention for achieving the above object is a casing filled with a predetermined amount of oil therein; A rotating scroll which is engaged with a fixed scroll fixedly installed in the casing and forms two pairs of compression chambers continuously moving; A drive motor installed inside the casing to generate a driving force; One side is coupled to the drive motor and the other side is coupled to the swing scroll so that the driving force of the drive motor is transmitted to the swing scroll, the oil is sucked along the longitudinal direction therein and each bearing of the swing scroll A drive shaft having an oil passage so as to be supplied to the surface, and a bypass hole communicating with the outside so that some of the oil drawn up may be bypassed; And a bypass valve for selectively opening and closing the bypass hole by a centrifugal force according to the rotational speed of the drive shaft so that the amount of oil supplied to each bearing surface of the swing scroll can be kept constant.

In addition, the bypass valve is rotatably coupled to the periphery of the drive shaft and coupled relative to the drive shaft in the radial direction of the drive shaft selectively by the centrifugal force according to the rotational speed of the drive shaft selectively with respect to the drive shaft A valve member eccentrically moved to open and close the bypass hole; And a spring member elastically disposed at one side of the valve member and applying an elastic force to move the valve member to a position to block the bypass hole.

In addition, the valve member is characterized in that the bearing hole is formed eccentrically with respect to the center thereof.

In addition, the valve member is characterized in that the eccentric load portion is provided integrally so that the center of gravity of the valve member.

In addition, the drive shaft and the valve member is in surface contact with each other, characterized in that the rotation engaging surface is formed so that the relative rotation can be restrained.

In addition, the valve member is characterized in that the axial flow is constrained by the support member coupled to the drive shaft.                     

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

3 is a cross-sectional view showing the structure of a scroll compressor having a fuel supply amount adjusting function according to the present invention, Figure 4 is an enlarged cross-sectional view showing the main portion of FIG.

5 to 6 are cross-sectional views illustrating an operation structure of a bypass valve as a scroll compressor having an oil supply amount adjusting function according to the present invention.

On the other hand, Figure 7 is a cross-sectional view showing another embodiment of a scroll compressor having a fuel supply flow adjustment function according to the present invention.

However, in describing the present invention, a detailed description of known functions or configurations will be omitted to clarify the gist of the present invention.

As shown in Figures 3 to 4, the scroll compressor having a lubrication flow rate adjustment function according to the present invention, while forming a sealed receiving space therein one side gas suction pipe (SP) so that the refrigerant gas can be sucked and discharged And a casing 111 having a gas discharge pipe DP, an upper frame 112 and a lower frame 113 fixed to upper and lower sides of the casing 111, respectively, and the upper frame 112. Drive motor 114 is mounted between the lower frame 113 to generate a rotational force, and is pressed in the center of the rotor 114b of the drive motor 114, and also passed through the upper frame 112, the rotating scroll (to be described later) 116 is coupled to the drive shaft 117 for transmitting the rotational force of the drive motor 114, the fixed scroll 115 is fixed to the upper portion of the upper frame 112 having an involute wrap (115a), An involute wrap 116a is provided to the fixed scroll 115. Slewing scroll 116 is coupled to form a pair of two compression chamber (P) to move in succession and compresses the refrigerant while moving relative to the fixed scroll 115, the turning scroll 116 and the upper frame ( Oldham's ring 118, which is installed between 112 and prevents the rotation of the swing scroll 116, and is provided on the drive shaft 117 is supplied to each bearing surface of the swing scroll 116 It is configured to include a bypass valve 140 for bypassing some of the oil drawn through the oil flow path (117a) to be described later so that the amount of oil to be kept constant.

A shaft hole 112a for supporting the drive shaft 117 in the radial direction is formed at the center of the upper frame 112, and the boss portion 116b of the turning scroll 116 is formed at the upper end of the shaft hole 112a. The boss accommodating groove 112b is extended to be pivotal.

The drive shaft 117 is pressed into the rotor 114b of the drive motor 114 so that the upper and lower sides are supported by the upper frame 112 and the lower frame 113, respectively, and the lower end of the oil in the casing 111 As a pump device for forced suction, a volumetric pump 120 is provided, and a shaft for lubricating each bearing surface by sucking oil sucked through the volumetric pump 120 inside the drive shaft 117. The oil passage 117a is formed long along the direction.

In addition, one side of the oil passage 117a has a bypass hole 117b communicated to the outside so that some of the oil sucked through the oil passage 117a is formed through the radial direction of the drive shaft. The bypass valve 140 selectively bypasses some of the oil sucked into the oil passage 117a through the bypass hole 117b and maintains a constant amount of oil supplied to each bearing surface of the turning scroll 116. It is installed on the drive shaft 117 so as to be configured to selectively open and close the bypass hole 117b by the centrifugal force according to the rotational speed of the drive shaft 117.

The bypass valve 140 is integrally rotatably coupled to the circumference of the drive shaft 117, and coupled to be movable relative to the radial direction of the drive shaft 117 so that the centrifugal force according to the rotational speed of the drive shaft 117 is achieved. The valve member 141 is selectively eccentrically moved with respect to the drive shaft 117 and opens and closes the bypass hole 117b, and the valve member 141 is elastically disposed at one side of the valve member 141. It is configured to include a spring member 142 for applying an elastic force to move to the position to block the bypass hole (117b).

That is, the valve member 141 passes through the driving shaft 117 and is integrally rotatably coupled with the shaft receiving hole 141a in the thickness direction thereof so that the valve shaft 117 can be moved relatively in the radial direction of the driving shaft 117. The inner wall surface of the bearing hole 141a is selectively in close contact with the outer circumferential surface of the drive shaft where the bypass hole 117b is formed and formed to have a hollow cylindrical shape so that the bypass hole 117b can be blocked, the valve The member 141 is formed so that the bearing hole 141a is eccentric with respect to the center so that its center of gravity is eccentric to one side.

In addition, the valve member 141 and the drive shaft 117 is in surface contact with the outer circumferential surface of the drive shaft 117 and the inner wall surface of the bearing hole 141a of the valve member 141 so that the valve member 141 and the drive shaft 117 can be integrally rotatable. Rotation catching surfaces 117c and 141b are formed to be restrained, respectively.                     

By such a structure, the valve member 141 may be integrally rotated together with the drive shaft 117 so that the eccentric mass side of the valve member 141 is rotated apart from the drive shaft 117 by the centrifugal force. Eccentric can be moved.

At this time, the bypass hole 117b is blocked when the eccentric mass part side of the valve member 141 is in close contact with the drive shaft 117, and the eccentric mass part side of the valve member 141 is spaced apart from the drive shaft 117. In this state, the bypass hole 117b is opened.

The spring member 142 is a "C" -shaped leaf spring, which is disposed inside the bearing hole 141a so that the valve member 141 blocks the bypass hole 117b, that is, the eccentricity of the valve member 141. An elastic force is applied to move the mass portion side to a position in close contact with the drive shaft, and the bypass hole 117b can be blocked.

In addition, a general spring (not shown) such as a coil spring may be applied as the spring member 142 as well as a leaf spring.

On the other hand, the valve member 141 described above is supported so that the axial flow is constrained by the support member 143 coupled to the drive shaft 117, the support member 143 as a ring (C-Ring) and O-ring A ring-shaped support member 143 such as (O-Ring) may be applied.

Meanwhile, a wrap 115a constituting two pairs of compression chambers P is formed in an involute shape on the bottom surface of the hard plate part of the fixed scroll 115, and the suction plate side space is formed on the side of the hard plate part through a gas suction pipe SP. An inlet port (not shown) is formed to allow the refrigerant sucked into S _ps to be sucked into the compression chamber P, and the compressed gas compressed in the final compression chamber P is centered on the upper surface of the hard plate portion at the discharge pressure side space. A discharge port 115b is formed to be discharged to S _pd .

In addition, the upper surface of the fixed scroll 115 is provided with a check valve 130 for selectively opening and closing the discharge port 115b to prevent the back flow of the refrigerant gas, the upper portion of the fixed scroll 115 of the casing 111 The high and low pressure separating plate 119 which separates the internal space into the discharge pressure side space S _pd and the suction pressure side space S _ps is combined.

On the upper surface of the hard plate portion of the turning scroll 116, the wrap 116a forming two pairs of compression chambers P together with the wrap 115a of the fixed scroll 115 is formed in an involute shape, and the bottom of the hard plate portion The boss portion 116b is formed at the center so that the drive shaft 117 is coupled to receive the power of the drive motor 114, and the boss portion 116b is a boss accommodating groove of the upper frame 112. 112b) to make pivotal movement.

Meanwhile, reference numeral 114a denotes a stator of the drive motor 114.

Hereinafter, the operation structure of the scroll compressor having the oil supply flow rate adjusting function made as described above is as follows.

When the power is applied to the drive motor 114, the rotating shaft 116 is rotated with the rotor 114b of the drive motor 114, the turning scroll 116 is the upper frame 112 by the old dam ring 118 In the upper surface of the pivoting movement by an eccentric distance, and the turning scroll 116 is to form a pair of compression chamber (P) in succession between the wrap (115a, 116a) with the fixed scroll 115, Compression chamber (P) is moved to the center by the continuous turning movement of the turning scroll 116 and the refrigerant gas is continuously sucked and compressed as the volume is reduced.

Here, the refrigerant gas is sucked into the suction pressure side space (S _ps ) through the gas suction pipe (SP), is sucked into the compression chamber (P) through the suction port is compressed and discharged through the discharge port 115b of the fixed scroll 115 It is discharged to the pressure side space S _pd , and this refrigerant gas is discharged to a refrigeration cycle system (not shown) through the gas discharge pipe DP.

On the other hand, the oil in the casing 111 is forcibly sucked by the volumetric pump 120 and then sucked up through the oil passage 117a of the drive shaft 117 by centrifugal force due to the rotation of the drive shaft 117, and a part of the upper frame. While lubricating the shaft hole 112a of 112, a part is supplied between the thrust bearing surface of the turning scroll 116 and the thrust bearing surface of the upper frame 112 and each bearing surface, and lubrication is performed.

Meanwhile, the amount of oil supplied to each bearing surface of the oil flow passage 117a to the turning scroll 116 may be adjusted by the bypass valve 140 of the present invention according to the operating conditions of the compressor.

That is, as shown in Figure 5, in the low-speed operating conditions of the compressor, the appropriate amount of oil is supplied through the oil flow path (117a), in this case the valve member 141 of the bypass valve 140 of the spring member 142 Pressurized by the elastic force and blocks the bypass hole 117b.

On the other hand, under the high speed operation condition of the compressor, the amount of oil supplied to each bearing surface of the turning scroll 116 is increased by the centrifugal force due to the high speed rotation of the drive shaft 117. In this case, the drive shaft 117 as shown in FIG. The spring member 142 opens in a state in which the elastic force is accumulated by the centrifugal force caused by the high speed rotation of the valve, and the valve member 141 of the bypass valve 140 moves eccentrically with respect to the drive shaft 117 in the radial direction. In addition, the bypass hole 117b may be opened so that some of the oil drawn through the oil passage 117a may be bypassed.

In this case, the timing at which the bypass hole 117b is opened and closed can be controlled by applying a spring member 142 having a spring constant value k appropriate thereto according to the capacity and operating conditions of the compressor.

On the other hand, Figure 7 is attached to show another embodiment of the scroll compressor having an oil supply flow control function according to the present invention, the eccentric load portion 144 so that the center of gravity of the above-described valve member 141 can be eccentric It is integrally provided and comprised.

That is, the eccentric load portion 144 is integrally provided on one side of the valve member 141 so that the center of gravity of the valve member 141 may be eccentric. When integrally rotated with the drive shaft, the eccentric load portion 144 side of the valve member 141 may be eccentrically moved so as to be spaced apart from the drive shaft by the centrifugal force.

In addition, since other components except for the eccentric load unit 144 are the same as the above-described embodiment, the same reference numerals are given to the same parts, and detailed description thereof will be omitted.

As described above, the present invention enables the oil supply amount supplied to the compression mechanism unit to be adjusted according to the operating conditions of the compressor, thereby preventing the performance deterioration due to the excessive inflow of oil during the high speed operation, and is optimized for each operating condition. It is possible to improve the reliability by maintaining the lubrication state of.

Although the preferred embodiments of the present invention have been described above by way of example, the scope of the present invention is not limited to these specific embodiments, and may be appropriately changed within the scope described in the claims.

As described above, according to the scroll compressor having the oil supply flow rate adjusting function according to the present invention, the oil supply amount to be supplied to the compression mechanism can be adjusted according to the operating conditions during the operation of the compressor, so that the oil excessively at high speed operation It is possible to prevent the performance deterioration due to the inflow, and to improve the reliability by maintaining the optimum lubrication state for each operating condition.

Claims (7)

A casing filled with a predetermined amount of oil therein; A rotating scroll which is engaged with a fixed scroll fixedly installed in the casing and forms two pairs of compression chambers continuously moving; A driving motor installed inside the casing to generate a driving force; One side is coupled to the drive motor and the other side is coupled to the swing scroll so that the driving force of the drive motor can be transmitted to the swing scroll, the oil flow path is formed along the longitudinal direction therein and the radius of the oil flow path A driving shaft in which a bypass hole is formed in a direction; And And a bypass valve for selectively opening and closing the bypass hole by centrifugal force according to the rotational speed of the drive shaft. The bypass valve, An axis receiving hole is formed to be inserted into the drive shaft to move in a radial direction of the drive shaft according to the rotational speed of the drive shaft, and one side surface of the axis receiving hole is formed to correspond to the outer circumferential surface of the drive shaft to selectively open and close the bypass hole. A valve member having a valve surface formed thereon; And And a spring member disposed between the valve member and the drive shaft so that the valve member exerts an elastic force in a direction of blocking the bypass hole on the opposite side of the valve face of the valve member. Having scroll compressor. delete delete The method of claim 1, The valve member has a lubrication flow rate adjustment function, characterized in that the eccentric load unit is integrally provided so that the center of gravity of the valve member. The method of claim 1, The drive shaft and the valve member is in surface contact with each other and the scroll compressor having a fuel flow rate adjustment function, characterized in that the rotation engaging surface is formed so that relative rotation can be restrained. The method of claim 1, And the valve member is configured to restrain axial flow by a support member coupled to the drive shaft. The method of claim 1, The spring member is a scroll compressor having a lubrication flow rate adjustment function, characterized in that the "C" shaped leaf spring.

Images