KR100246422B1 - Oil supplying device for linear compressor - Google Patents

Abstract

The present invention relates to an oil supply device for a linear compressor, and in the related art, a process for assembling each part, such as an elastic member mounted on both sides of the mass body, is not easy, and the productivity is lowered, and the volume of the mass body is more than necessary. There was a risk of abnormal noise due to the friction with the oil supply pipe, the present invention is an oil supply pipe filled with oil, and an elastic member for providing a surging effect on the oil filled in the oil supply pipe, A first cover fixed to the suction side of the oil supply pipe and having an oil suction port formed thereon, and a second cover fixed to the discharge side of the oil supply pipe and connected to an oil suction flow path of the flange communicating with the oil pocket; An oil discharge hole communicating with the oil discharge port of the second cover is formed, and the discharge plug is pressed into the discharge side of the oil supply pipe. A suction valve fixed to the inner side of the first cover to open and close the outlet portion of the oil inlet, and a discharge valve fixed to the outer side of the discharge stopper to open and close the oil discharge hole at the central portion thereof, or By omitting the intake valve, the assembly process of the oil supply device is simplified, productivity is improved, production costs are reduced, and the coil spring is used as the mass body, and the oil supply pipe is caused by friction with the mass body during the reciprocating motion. The abnormal noise is reduced to a minimum.

Description

Oil supply of linear compressor

The present invention relates to an oil supply device for a linear compressor, and more particularly, to an oil supply device for a linear compressor intended to suck and discharge oil through a coil spring for an extender in an oil supply pipe.

In a general compressor, supplying a sufficient amount of oil between a common cylinder and a sliding part acts as a main factor for improving efficiency, in particular, mechanical efficiency. Therefore, a linear compressor having an oil supply device according to the prior art is provided. An example will be described with reference to the accompanying drawings.

As shown in FIG. 1, a sealed container C having a predetermined shape, a compressor unit 10 installed transversely inside the sealed container C, and fixed to the outside of the compressor unit 10. It is composed of the oil supply means 30 and the oil pocket (P) is formed to communicate with the oil supply means 30 in the compressor unit 10 is supplied to the sliding portion between the cylinder and the piston It is.

The compressor unit 10 includes a cylinder 11 having a plurality of oil inlet holes 11a for communicating with the inside and the outside, a flange 12 coupled to and fixed to the cylinder 11, and the flange 12. A stator core (or out lamination) provided with an inner lamination 13 fixed to an inner wall of the crankshaft and a stator coil 14a fixed at predetermined intervals with an inner lamination 13 at the periphery of the flange 12. 14, a spring support 15 fixed to the opposite side of the flange 12, a piston spring 16 fixed to the spring support 15, and an inner middle portion of the piston spring 16. The piston 17 is coupled to the cylinder 11 to be linearly reciprocated, and is fixed to the outer circumferential edge of the piston 17 so that the inner lamination 13 and the stator core 14 are moved by the movement of the piston 17. Magnet 18 moving in a straight line between and one side of the cylinder 11 The valve assembly 19 and the silencer 20 fixed to and installed in the silencer 20, and the refrigerant suction pipe 21 is installed in the silencer 20 to guide the refrigerant gas into the valve assembly 19.

The oil supply means 30 and the oil pocket P are connected to communicate with the oil suction passage 12a formed on one side of the flange 12, and the oil pocket P on the other side of the flange 12. An oil discharge passage 12b connected to the air passage is formed.

Here, the oil supply means is inserted in the cylindrical oil supply pipe 31 with an empty inside, and the inside of the oil supply pipe 31 is inserted to enable a linear reciprocating movement by the set vibration. Mass cover 32 having an oil passage 32a formed therein, and a first cover fixed to one end of the oil supply pipe 31 and supported by a spring support 15 and having an oil suction port 33a formed at a predetermined portion. (33) and fixedly coupled to the other end of the oil supply pipe (31) and fixed to the flange 12 by several fixing screws (not shown) and communicate with the oil suction passage (12a) of the flange 12 therein. Interposed between the second cover 34 having the oil discharge port 34a and the mass body 32 and the first cover 33 to selectively open and close the oil suction port 33a of the first cover 33. An oil suction valve 35 having a plurality of oil passage grooves (not shown) in the edge thereof and the oil An oil discharge port of the second cover 34 is interposed between an elastic member 36 such as a compression coil spring that elastically supports the suction valve 35 and the mass 32 and the second cover 34. An oil discharge valve 37 for selectively opening and closing 34a) and an elastic member 38 such as a compression coil spring for elastically supporting the oil discharge valve 37 are constituted.

In the drawings, reference numerals 39 and 39 'are oil suction pipes and oil discharge pipes.

In the linear compressor equipped with the conventional oil supply means configured as described above, the piston is linearly reciprocated while the compressor unit is operated to compress the refrigerant gas, and the set is vibrated by the linear reciprocating motion of the piston. The mass in the oil supply pipe fixed to the outside of the compressor unit is moved left and right.

Here, when the mass moves in the direction indicated by the arrow Q, as shown in FIG. 3A, the discharge side elastic member 38 of the oil supply pipe 31 is contracted and the oil discharge valve 37 of the mass 32 is moved. It is in close contact with one end to suppress the oil from being discharged to the oil pocket (P), and at the same time the mass 32 exerts an inertial force, the opposite elastic member 36 is tensioned so that the oil suction valve 35 is the first cover ( 33) a little off.

At this time, since the oil suction valve 35 and the oil discharge valve 37 are in a low pressure state, oil accumulated at the bottom of the sealed container C is transferred to the first cover 33 through the oil suction pipe 39. It is sucked into the inside, and again passes through the oil passage groove (not shown) formed in the outer periphery of the oil suction valve 35 into the oil supply pipe 31, the introduced oil is the oil flow path of the mass body 32 ( It was conveyed along 32a) to fill the oil passage 32a.

On the contrary, when the mass moves in the direction of arrow P shown in FIG. 3B, as shown in FIG. 3B, the suction side elastic member 36 of the oil supply pipe 31 is contracted and the oil suction valve 35 is closed by the first cover 33. ), The suction of oil is suppressed, and at the same time, the oil discharge valve 37 is slightly separated from the mass 32 while the opposite elastic member 38 is tensioned, and at this time, the oil flow path 32a of the mass 32 Filled oil passes through an oil passage groove (not shown) formed in the outer periphery of the oil discharge valve 37, and the oil suction flow path of the flange 12 through the inner oil discharge hole 34a of the second cover 34 ( 12a) was introduced into the oil pocket (P).

As described above, the oil filled in the oil pocket P flows into the cylinder 11 through the oil inlet hole 11a of the cylinder 11, and is supplied to the piston 17 and the sliding part of the cylinder 11. A portion of the oil filled in the oil pocket P by the repeated movement of the oil supply pipe 31 is transferred along the oil discharge passage 12b of the flange 12 and through the oil discharge pipe 39 '. It was discharged to the outside.

However, in the conventional oil supply device as described above, the oil suction in the oil supply pipe 31 is provided at both ends of the oil supply pipe 31 in the process of linearly reciprocating left and right by the vibration of the oil supply pipe 31 set. Intake and discharge through the valve 35 and the discharge valve 37, which is mounted between the oil supply pipe 31 and both sides of the mass body 32, the elastic members 36 and 38, respectively, the elastic member 36 The first and second covers 33 and 34 are required to prevent the separation of the parts 38 and 38, so that the production cost is increased and the first and second parts are provided with sufficient elastic force. Since the covers 33 and 34 must be press-fitted, there is a problem in that the workability is not easy and productivity is lowered.

In addition, as the oil supply pipe 31 reciprocates, friction between the mass 32 and the oil supply pipe 31 may cause abnormal noise.

Therefore, the present invention has been made in view of the above-mentioned problems with the oil supply apparatus of the conventional linear compressor as described above, and the linear compressor can simplify the assembly process of the oil supply apparatus to improve productivity as well as reduce the production cost. To provide an oil supply system for the purpose.

It is also an object of the present invention to provide an oil supply device for a linear compressor such that abnormal noise caused by friction with the mass is generated while the oil supply pipe reciprocates.

1 is a longitudinal sectional view showing an example of a linear compressor equipped with a conventional oil supply device.

Figure 2 is a longitudinal sectional view showing an enlarged configuration of a conventional oil supply device.

Figure 3a is a longitudinal sectional view showing a state at the time of oil suction in the conventional oil supply device.

3B is a longitudinal sectional view showing a state at the time of oil discharge in a conventional oil supply device.

4 is a longitudinal sectional view showing an example of a linear compressor equipped with an oil supply device of the present invention.

Figure 5 is a longitudinal sectional view showing an enlarged configuration of the oil supply apparatus of the present invention.

Figure 6a is a longitudinal sectional view showing the state at the time of oil suction in the oil supply device of the present invention.

6B is a longitudinal sectional view showing a state at the time of oil discharge in the oil supply apparatus of the present invention.

7 is a front view of a suction valve constituting the oil supply device of the present invention.

Figure 8 is an enlarged longitudinal sectional view of another embodiment of the oil supply device of the present invention.

<Description of the reference numerals for the main parts of the drawings>

10: compressor unit 110: oil supply pipe

120: coil spring 130: first cover

131: oil inlet 140: second cover

141: oil discharge outlet 160: discharge cap

161: oil discharge hole 170: suction valve

171: oil suction opening and closing 180: discharge valve

181: oil discharge opening and closing part

In order to achieve the object of the present invention, the compressor unit is installed in the transverse direction in the interior of the sealed container, and is fixed to the outside of the compressor unit is filled in the process in the process of linear reciprocating movement according to the vibration of the compressor unit In the oil supply device of the linear compressor comprising an oil supply means for the oil to be sucked, discharged to be introduced into the oil pocket in communication with the sliding portion; The oil supply means includes a cylindrical oil supply pipe filled with a predetermined amount of oil therein, an elastic member interposed in the oil supply pipe to provide a surging effect to the oil filled while acting as a mass body, and the oil. A first cover coupled and fixed to the suction side of the supply pipe and having an oil suction port penetrated to a predetermined portion, and an oil discharge port formed to be connected to the discharge side of the oil supply pipe and to communicate with an oil suction channel of the flange communicating with the oil pocket; 2 a cover, an oil discharge hole communicating with the oil discharge port of the second cover is formed, the discharge stopper is pressed into the discharge side of the oil supply pipe, and fixed to the inner side of the first cover to open and close the outlet portion of the oil suction port in the center A suction valve and a discharge valve fixed to an outer surface of the discharge stopper to open and close an oil discharge hole at a central portion thereof The oil supply unit of the near-compressor is provided.

Hereinafter, a linear compressor according to the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

Figure 4 is a longitudinal sectional view showing an example of a linear compressor with an oil supply device of the present invention, Figure 5 is a longitudinal sectional view showing an enlarged configuration of the oil supply device of the present invention, Figure 6a is an oil supply device of the present invention Fig. 6B is a longitudinal sectional view showing a state at the time of oil suction, and Fig. 6B is a longitudinal sectional view showing a state at the time of oil discharge in the oil supply device of the present invention, and Fig. 7 is a suction constituting the oil supply device of the present invention. Front view of the valve.

As shown therein, the linear compressor according to the present invention includes a compressor unit 10 installed in the transverse direction inside the sealed container C having a predetermined shape, and an oil supply fixed to the outside of the compressor unit 10. Oil pocket (P) which is formed to communicate with the oil supply means (100) in the means 100 and the compressor unit 10 is supplied to the sliding portion between the cylinder 11 and the piston 17 (P) It is composed of

Here, since the compressor unit 10 is configured in the same manner as in the prior art, a separate description will be omitted, and the following will be described only with respect to the oil supply means 100 according to the present invention.

As shown in FIG. 4 or 5, the cylindrical unit is fixed to the outside of the compressor unit 10 to linearly move according to the vibration of the compressor unit 10, and a predetermined amount of oil is filled therein. An oil supply pipe 110 and a coil spring 120 interposed in the oil supply pipe 110 to provide a surging effect to the oil filled while acting as a mass body, and coupled to the suction side of the oil supply pipe 110. The oil intake flow path of the flange 12 fixed and coupled to the first cover 130 through which the oil suction port 131 is formed at the center and the discharge side of the oil supply pipe 110 and communicating with the oil pocket P ( A second cover 140 having an oil discharge port 141 formed therein and an oil discharge hole 161 communicating with the oil discharge port 141 of the second cover 140 are formed to communicate with the oil supply pipe 110. A discharge stopper 160 press-fitted to the discharge side of the first cover 130 and an inner surface of the first cover 130. A suction valve 170 configured to open and close an outlet of the oil inlet 131 at a central portion thereof, and a discharge valve 180 fixed to an outer surface of the discharge plug 160 to open and close an oil discharge hole 161 at a central portion thereof. It is composed of

As shown in FIG. 7, the suction valve 170 and the discharge valve 180 are attached to and fixed to an inner side surface of the first cover 130 and an outer side surface of the discharge stopper 160. 130 and the oil suction opening / closing portion 171 and the oil larger than the diameters of the oil suction opening 131 and the oil discharge hole 161 at the central portion facing the oil suction opening 131 and the oil discharge hole 161 of the discharge plug 160. Discharge opening and closing portions 181 are formed, respectively.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

In the drawings, reference numeral C denotes a sealed container, 12b is oil discharge oil, 13 is inner lamination, 14 is out lamination, 14a is coil, 15 is spring support, 16 is piston spring, 18 is magnet, 19 is valve assembly, 20 is a silencer, 21 is a refrigerant suction pipe, 39 and 39 'are an oil suction pipe and an oil discharge pipe, respectively.

In the linear compressor provided with the oil supply means of the present invention as described above, the oil suctioned and discharged from the oil supply means is supplied to the sliding parts of the cylinder and the piston by the operation of the compressor unit as well as the operation of the compressor unit. Since the process is the same as that of a conventional compressor, instead of omitting, the following description will be given only in detail of the mechanisms for the intake and discharge of oil in the oil supply means.

6A and 6B, when the set is vibrated by continuous linear reciprocation of the piston (shown in FIG. 4) 17 for the compression of the refrigerant gas, the compressor unit (shown in FIG. 4) The oil supply pipe 110 fixed to the outside of the 10 is moved to the left and right. At this time, since the coil spring 120 serving as a mass body is interposed in the oil supply pipe 110, the oil supply pipe 110 moves to the left and right to close the container by the inertia force of the coil spring 120. The oil contained in (C) is sucked into the oil supply pipe 110 and is discharged into the oil pocket P.

First, as shown in Figure 6a, when the oil supply pipe 110 moves in the direction of the arrow A shown, the coil spring 120 therein is inertial force to maintain the current position while both sides are expressed Since the oil supply pipe 110 having a volume defined by the first cover and the discharge stoppers 130 and 160 is moved to the right side of the drawing, the oil filled therein is left of the drawing by the inertia force with the coil spring 120. The oil is concentrated in the oil discharge hole 161 of the discharge plug 160 and the oil of the second cover 140 while pushing down the oil discharge opening and closing portion 181 formed in the center portion of the discharge valve 180 The oil is discharged to the outside of the oil supply pipe 110 through the discharge port 141, and the ejected oil passes through the oil suction passage (shown in FIG. 4) 12a of the flange (shown in FIG. 4) 12 in order. The cylinder (shown in FIG. 4) 11 and the piston flow into the pocket (shown in FIG. 4) P (Shown in Fig. 4) flows into the sliding section between the 17.

In addition, the pressure of the oil supply pipe 110 is lowered as a predetermined amount of oil is ejected from the oil supply pipe 110 so that the external oil having a relatively high pressure may open and close the oil suction opening / closing portion 171 of the suction valve 170. In this case, the oil suction opening / closing portion 171 formed at the center portion of the suction valve 170 is opened while being inclined to the inside of the oil supply pipe 110 so that the oil of the sealed container C is naturally in the first cover 130. The oil inlet 131 and the oil inlet 131 of the first cover 130 is introduced into the oil supply pipe 110.

On the other hand, as shown in Figure 6b, when the oil supply pipe 110 is moved in the direction of the arrow B of the figure, the coil spring 120 therein while the inertial force to maintain the current position is expressed on both sides Since the oil supply pipe 110 whose volume is limited by the first cover and the discharge cap 130 and 160 is moved to the left side of the drawing, the oil in the oil supply pipe 110 is concentrated to the right side of the drawing. The oil is blocked by the oil suction opening and closing portion 171 of the suction valve 170 to prevent the oil is sucked, at this time the oil suction opening and closing portion 171 than the oil suction opening 131 of the first cover 130 Since the diameter is large, the oil suction opening and closing portion 171 is prevented from being flipped to the right side of the drawing.

A small amount of oil flows back from the compressor unit 10 through the oil discharge hole 141 of the second cover 140 and the oil discharge hole 161 of the discharge stopper 160, but the oil discharge plug 160 Closing the oil discharge opening and closing portion 181 of the discharge valve 180 attached to the outer surface of the end will be the oil is not introduced back into the oil supply pipe (110).

If there is another embodiment according to the present invention is as follows.

In the above-described example, the coil spring 120 serving as a mass is interposed in the oil supply pipe 110 sealed by the first cover and the discharge plug 130 and 160 having oil inlets and oil discharge holes 131 and 161 formed on both sides thereof. In the process of moving the oil supply pipe 110 to the left and right by the vibration of the set so that the oil is sucked and discharged by the coil spring 120 and its inertia, which is the reverse flow of oil, that is, the oil supply pipe 110 6) moves in the direction of arrow B of FIG. 6B in order to prevent a part of the oil filled therein from leaking into the sealed container C through the oil inlet 131 of the first cover 130. The suction valve 170 having the oil suction opening / closing part 171 formed on the inner side of the first cover 130 was fixed in close contact.

Thus, in the present embodiment, the oil supply means omits the suction valve that is fixed to the inner surface of the suction plug, and as shown in FIG.

That is, the cylindrical oil supply pipe 110 is fixed to the outside of the compressor unit 10 and linearly reciprocates according to the vibration of the compressor unit 10, and a predetermined amount of oil is filled therein, and the oil. A coil spring 120 interposed inside the supply pipe 110 to provide a surging effect to the oil filled while acting as a mass body, and is fixedly coupled to the suction side of the oil supply pipe 110 and has an oil suction port 131 at the center thereof. And an oil discharge port 141 which is coupled to and fixed to the discharge side of the oil supply pipe 110 and the oil suction passage 12a of the flange 12 communicating with the oil pocket P is formed. Is formed therein, and an oil discharge hole 161 communicating with the oil outlet 141 of the second cover 140 is formed, and the discharge plug 160 press-fitted to the discharge side of the oil supply pipe 110. And the oil discharge hole 161 is fixed to the outer surface of the discharge plug 160 at the center thereof. The discharge valve 180 is opened and closed.

Since the operation of the oil supply means according to the present embodiment configured as described above is the same as in the above-described embodiment, a detailed operation description thereof will be omitted.

However, in the above-described embodiment, when the oil supply pipe 110 moves in the direction of arrow A of FIG. 6A, oil is discharged by the inertia force of the coil spring 120 interposed in the oil supply pipe 110. While pushing the oil discharge opening / closing portion 181 of 180 and being discharged to the oil pocket (P), a part of the oil filled in the sealed container (C) is pushing the oil suction opening and closing portion 171 of the suction valve 170 while the oil supply pipe ( When the oil supply pipe 110 moves in the direction of arrow B of FIG. 6B, the discharge valve 180 is caught and closed by the discharge plug 160, and the suction valve 170 is also closed. The first cover 130 was closed while being caught.

At this time, when a separate intake valve is not provided as in the present embodiment, when the oil supply pipe 110 moves in the direction of arrow A of FIG. 6A, the oil has the same flow as in the above-described embodiment. On the other hand, when the oil supply pipe 110 moves in the direction of arrow B of FIG. 6B, a portion of the oil filled in the oil supply pipe 110 is opened by its own inertia and the coil spring 120. The oil inlet 131 of the 130 is leaked to the outside of the oil supply pipe 110, but the leakage amount is not much, as well as the oil supply pipe 110 again moved to the oil supply pipe 110 in the direction of arrow A of FIG. 6A. Since it is introduced, there is no difference in the behavior of the set.

As described above, the oil supply apparatus of the linear compressor according to the present invention includes a cylindrical oil supply pipe filled with a predetermined amount of oil therein, and an oil filled in the oil supply pipe while acting as a mass body. An elastic member that provides a surging effect, a first cover coupled to the suction side of the oil supply pipe and having an oil suction port formed at a predetermined portion, and coupled to the discharge side of the oil supply pipe, and the flange oil communicating with the oil pocket A second cover having an oil discharge port formed therein to communicate with the suction passage, an oil discharge hole communicating with the oil discharge hole of the second cover formed therein, a discharge stopper press-fitted to the discharge side of the oil supply pipe, and fixed to an inner surface of the first cover; A suction valve for opening and closing the oil suction port at a central portion thereof, and fixed to an outer surface of the discharge stopper to open and close the oil discharge hole at the central portion thereof. Is composed of a discharge valve or the intake valve is omitted, the assembly process of the oil supply device is simplified to improve productivity as well as to reduce the production cost, and also to use the coil spring as a mass body so that the oil supply pipe There is an effect that the abnormal noise due to friction with the mass during reciprocating movement is minimized.

Claims (5)

Compressor unit installed in the transverse direction in the sealed container, and the oil is fixed to the outside of the compressor unit in the process of linear reciprocating movement according to the vibration of the compressor unit is sucked and discharged to communicate with the sliding part In the oil supply device of the linear compressor comprising an oil supply means for flowing into the oil pocket has been prepared; The oil supply means includes a cylindrical oil supply pipe filled with a predetermined amount of oil therein, an elastic member interposed in the oil supply pipe to provide a surging effect to the oil filled while acting as a mass body, and the oil. A first cover coupled to the suction side of the supply pipe and having an oil suction port formed at a predetermined portion thereof, and a second discharge port configured to be fixed to the discharge side of the oil supply pipe and to communicate with an oil suction path of a flange communicating with the oil pocket A cover, an oil discharge hole communicating with the oil discharge port of the second cover is formed, a discharge stopper press-fitted to the discharge side of the oil supply pipe, and a suction fixed to the inner side of the first cover to open and close the outlet portion of the oil suction port at the center thereof. A valve and a discharge valve fixed to an outer surface of the discharge stopper and configured to open and close an oil discharge hole at a central portion thereof. Oil supply unit of the compressor. Compressor unit installed in the transverse direction in the sealed container, and the oil is fixed to the outside of the compressor unit in the process of linear reciprocating movement according to the vibration of the compressor unit is sucked and discharged to communicate with the sliding part In the oil supply device of the linear compressor comprising an oil supply means for flowing into the oil pocket has been prepared; The oil supply means includes a cylindrical oil supply pipe filled with a predetermined amount of oil therein, an elastic member interposed in the oil supply pipe to provide a surging effect to the oil filled while acting as a mass body, and the oil. A first cover coupled to the suction side of the supply pipe and having an oil suction port formed at a predetermined portion thereof, and a second discharge port configured to be fixed to the discharge side of the oil supply pipe and to communicate with an oil suction path of a flange communicating with the oil pocket An oil discharge hole communicating with the cover, an oil discharge hole of the second cover, and a discharge stopper press-fitted to the discharge side of the oil supply pipe, and a discharge valve fixed to an outer surface of the discharge stopper to open and close the oil discharge hole at the center thereof. Oil supply of the linear compressor, characterized in that configured. The oil supply device of a linear compressor according to claim 1 or 2, wherein the elastic member is a coil spring. The oil supply device of the linear compressor of claim 1, wherein the suction valve has an oil suction opening / closing portion formed at an intermediate portion of the first cover opposite to the oil suction opening of the first cover. 3. The oil supply apparatus of claim 1 or 2, wherein the discharge valve has an oil discharge opening / closing portion formed larger than a diameter of the oil discharge hole at an intermediate portion facing the oil discharge hole of the discharge stopper.

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