KR20190142037A - Relief valve and oil pump comprising the same - Google Patents

Abstract

The present invention is accommodated in the valve receiving space formed in the pump housing of the oil pump, pressurized from the upper side to the lower side by the oil flowing into the bypass flow passage branched from the discharge port of the pump housing, the pressure of the oil discharged from the pump housing By adjusting the, a high pressure groove is formed on the outer circumferential surface and in communication with the high pressure discharge passage formed on the inner wall of the valve receiving space, a low pressure groove is formed below the high pressure groove, the surface on which the high pressure groove is formed, the high pressure It provides a relief valve comprising a flat surface and a high-pressure inclined surface extending from the lower side of the high-pressure flat surface to be inclined outward in a radial reference toward the lower side and an oil pump comprising the same.
According to the relief valve and the oil pump including the same according to the present invention, before the oil introduced into the upper space of the relief valve is supplied to the high pressure discharge flow path, the oil introduced into the valve flow path in advance into the high pressure discharge flow path through the high pressure groove. By being supplied, it is possible to prevent a sudden increase in the amount of oil returned to the inlet of the pump housing through the high pressure discharge passage. Accordingly, according to the relief valve and the oil pump including the same according to the present invention, it is possible to prevent the vibration and noise generated inside the oil pump as the relief valve operates.

Description

Relief valve and oil pump comprising the same

The present invention relates to a relief valve and an oil pump including the same, and more particularly, to a relief valve for adjusting the pressure of oil discharged from the oil pump and an oil pump including the same.

In general, an oil flow path called a main gallery is formed in a cylinder block of an automobile engine. The engine of a motor vehicle is a power engine that moves a piston by the expansion force of gas generated by burning fuel charged in a cylinder, and is characterized by being exposed to a high temperature and high pressure environment. Therefore, an automobile engine must be supplied with oil so that various parts thereof can be smoothly lubricated and cooled.

The oil pump refers to a device for sucking oil from an oil pan in which oil is stored and then supplying it to the main gallery of the engine. Such an oil pump allows oil to be supplied to each part of the engine through the main gallery of the engine so that the parts constituting the engine can be lubricated and cooled.

As related to such an oil pump, Korean Patent No. 10-1491175 discloses a variable oil pump.

The conventional oil pump is provided with a relief valve therein to adjust the pressure of oil discharged from the oil pump. Such a relief valve returns a part of the oil discharged from the oil pump to the inlet side of the oil pump, thereby preventing the pressure of the oil discharged from the oil pump from increasing rapidly.

At this time, the relief valve, there is a limit to operate so that the oil returned to the inlet side of the oil pump suddenly supplied to the inlet side of the oil pump at any moment. Therefore, according to the conventional oil pump, there is a problem that the vibration and noise are severely generated in the oil pump as the relief valve operates.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a relief valve and an oil pump including the same, which prevents the amount of oil returned to the inlet side of the oil pump from being sharply increased.

Relief valve according to an aspect of the present invention is accommodated in the valve receiving space formed in the pump housing of the oil pump, pressurized from the upper side to the lower side by the oil introduced into the bypass flow passage branched from the discharge port of the pump housing, By regulating the pressure of the oil discharged from the housing, a high pressure groove is formed on the outer circumferential surface and in communication with the high pressure discharge passage formed on the inner wall of the valve accommodation space, a low pressure groove is formed below the high pressure groove, The groove-formed surface may include a high pressure flat surface and a high pressure inclined surface extending from the lower side of the high pressure flat surface so as to be inclined outward in a radial reference direction toward the lower side.

The surface on which the low pressure groove is formed may include a low pressure flat surface and a low pressure inclined surface extending from an upper side of the low pressure flat surface so as to be inclined outward in a radial reference direction toward the upper side.

According to another aspect of the present invention, the suction and supply of the oil to the engine, the inlet and discharge port for the oil is sucked and discharged is formed, the pump housing is formed with a bypass flow passage for branching some of the oil discharged to the discharge port; A stator accommodated in the pump housing; A rotor accommodated in the stator and configured to suck and discharge oil through rotation; And a relief valve accommodated in the valve accommodation space formed inside the pump housing, pressurized from the upper side to the lower side by the oil introduced into the bypass flow passage, and formed with a high pressure groove on an outer circumferential surface of the pump housing space. Therein, a valve flow passage communicating with the bypass flow passage, and a high pressure discharge flow passage selectively communicating with the valve flow passage through the high pressure groove are formed, and the outer circumferential surface of the relief valve is formed with an outer surface and the high pressure groove. According to the radial direction of the relief valve according to the high pressure inner surface formed to be recessed to the inside of the outer surface, and cut to a plane including a virtual center line penetrating the center of the relief valve up and down When viewed, the uppermost point of the outer surface and the point where the high pressure inner surface and the outer surface meet The length of the straight line connecting the points on the side is an upper side among the points where the inner wall of the high pressure discharge flow path and the inner wall of the valve accommodation space meet, and an upper side of the point where the inner wall of the valve flow path and the inner wall of the valve accommodation space meet. An oil pump is provided, characterized in that it is longer than the length of a straight line connecting the points of.

On the outer circumferential surface of the relief valve, a low pressure groove is formed below the high pressure groove, and on the inner wall of the valve accommodation space, a low pressure discharge passage selectively communicating with the valve passage through the low pressure groove below the high pressure discharge passage. Is formed, and the valve flow passage may be formed between the high pressure discharge passage and the low pressure discharge passage.

The high pressure inner surface includes a high pressure flat surface and a high pressure inclined surface extending from the lower side of the high pressure flat surface so as to be inclined outward from the radial reference direction of the relief valve toward the lower side, wherein the high pressure inner surface meets the outer surface. The lower point of the point may be a point where the high pressure inclined surface and the outer surface meet.

The outer circumferential surface of the relief valve further includes a low pressure inner surface formed to be recessed to the inside of the outer surface when the low pressure groove is formed based on the radial direction of the relief valve, wherein the low pressure inner surface is low pressure. It may include a flat surface and a low pressure inclined surface extending from the upper side of the low pressure flat surface to be inclined toward the outer side of the relief valve toward the upper side.

The relief valve may be disposed such that an outer surface thereof contacts the inner wall of the valve accommodation space.

A valve spring accommodated in the valve accommodation space and disposed below the relief valve to apply an elastic restoring force to the relief valve, wherein the valve accommodation space is formed between the bypass flow path and the stator, The bypass flow passage may be formed to surround the valve accommodation space to supply oil to an upper side of the relief valve.

According to the relief valve and the oil pump including the same according to the present invention, before the oil introduced into the upper space of the relief valve is supplied to the high pressure discharge flow path, the oil introduced into the valve flow path in advance into the high pressure discharge flow path through the high pressure groove. By being supplied, it is possible to prevent a sudden increase in the amount of oil returned to the inlet of the pump housing through the high pressure discharge passage. Accordingly, according to the relief valve and the oil pump including the same according to the present invention, it is possible to prevent the vibration and noise generated inside the oil pump as the relief valve operates.

1 is a view showing an oil pump according to an embodiment of the present invention.
2 and 3 are enlarged views of the relief valve shown in FIG.
4 to 7 are views showing the operation of the oil pump shown in FIG.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 to 3, the oil pump 100 according to an embodiment of the present invention, the pump housing 110, the stator 120, the rotor 130, the relief valve 140 and the valve spring 150 ).

The pump housing 110 accommodates the stator 120, the rotor 130, the relief valve 140, and the valve spring 150 therein, and an intake port 111 through which oil is sucked, and the rotor ( The discharge port 112 through which the oil is discharged to the engine by the rotation of the 130 is formed. In addition, the pump housing 110 is formed with a bypass passage 113 through which a portion of the oil branched from the discharge port 112 and discharged to the discharge port 112 flows.

The pump housing 110 has a valve accommodation space 114 in which the relief valve 140 and the valve spring 150 are accommodated. In addition, a valve flow path 115 communicating with the bypass flow passage 113 is formed on an inner wall of the valve accommodation space 114. On the inner wall of the valve accommodation space 114, a high pressure discharge passage 116 and a low pressure discharge passage 117 are respectively provided on the upper and lower portions of the valve passage 115 when the valve accommodation space 114 is used as a reference. Is formed. The oil flowing into the valve accommodation space 114 from the bypass passage 113 through the valve passage 115 is the inlet 111 through the high pressure discharge passage 116 or the low pressure discharge passage 117. Will return).

The stator 120 is accommodated in the pump housing 110. The rotor 130 is accommodated in the stator 120 and sucks and discharges oil through rotation. The relief valve 140 is accommodated in the valve accommodation space 114, and adjusts the pressure of the oil discharged to the discharge port 112 by the rotor 130. The valve spring 150 is accommodated in the valve accommodation space 114 and disposed below the relief valve 140 to apply an elastic restoring force to the relief valve 140.

In this case, the valve accommodation space 114 is formed between the bypass passage 113 and the stator 120, the relief valve 140 and the valve spring 150 also the bypass passage 113. And may be disposed between the stator 120. In addition, the bypass passage 113 may be formed to surround the valve accommodation space 114, as shown in FIG. 1, so that oil may be supplied to the upper side of the relief valve 140. In this case, the relief valve 140 receives an elastic restoring force in an upward direction by the valve spring 150 disposed below, and is operated to gradually move downward by being pressed downward by an oil supplied upward. Done.

The relief valve 140, the high pressure groove 141 and the low pressure groove 142 is formed on the outer peripheral surface. The high pressure groove 141 is selectively communicated with the valve passage 115 and the high pressure discharge passage 116, and the low pressure groove 142 is the valve passage 115 and the low pressure discharge passage 117. And optionally communicate with. Accordingly, in the high pressure groove 141, the oil flowing into the bypass flow passage 113 sequentially passes through the valve flow passage 115, the high pressure groove 141, and the high pressure discharge passage 116. The low pressure groove 142, the oil flowing into the bypass flow passage 113 in turn through the valve flow path 115, the low pressure groove 142 and the low pressure discharge flow path 117. Return to the suction port 111.

Referring to FIG. 3, the outer circumferential surface of the relief valve 140 may include an outer surface 143, a high pressure inner surface 144, and a low pressure inner surface 145. The outer surface 143 is in contact with the inner wall of the valve accommodation space 114, is formed to be parallel to the center line of the relief valve 140 penetrating up and down the center of the relief valve 140. As the high pressure groove 141 is formed, the high pressure cabinet surface 144 is formed to be recessed inward of the outer surface 143 when the high pressure groove 141 is formed based on the radial direction of the relief valve 140. The low pressure inner surface 145 is formed to be recessed inwardly of the outer surface 143 when the low pressure groove 142 is formed, based on the radial direction of the relief valve 140.

At this time, the high pressure cabinet surface 144 may be further divided into a high pressure flat surface 146 and a high pressure slope surface 147. The high pressure flat surface 146 is formed to be parallel to the outer surface 143. The high pressure inclined surface 147 extends from the lower side of the high pressure flat surface 146 to be inclined outward in the radial reference direction of the relief valve 140 toward the lower side.

As such, when the high-pressure cabinet surface 144 includes the high-pressure flat surface 146 and the high-pressure inclined surface 147, the relief valve 140 is moved downward so that the valve flow path 115 and the high pressure groove ( The moment 141 is in communication, the oil introduced into the valve flow path 115 may be smoothly introduced into the high pressure groove 141 along the high pressure slope 147 of the high pressure groove 141. That is, the cross-section of the high pressure groove 141 receiving the oil through the valve flow path 115 is gradually increased, so that the amount of oil supplied to the high pressure groove 141 through the valve flow path 115 is increased. Can be increased gradually.

Like the high pressure cabinet surface 144, the low pressure cabinet surface 145 may be divided into a low pressure flat surface 148 and a low pressure slope surface 149. The low pressure flat surface 148 is formed in parallel with the outer surface 143 and the high pressure flat surface 146. The low pressure inclined surface 149 extends from the upper side of the low pressure flat surface 148 to be inclined outward in the radial direction of the relief valve 100 toward the upper side.

As such, when the low pressure inner surface 145 is formed of the low pressure flat surface 148 and the low pressure inclined surface 149, the valve flow path 115 in communication with the low pressure groove 142 is the relief valve. In the case of being sealed by the outer surface 143 disposed between the high pressure groove 141 and the low pressure groove 142 as the 140 is moved downward, through the valve flow path 115 The amount of oil supplied to the low pressure groove 142 may be gradually reduced.

Therefore, according to the relief valve 140 and the oil pump 100 including the same according to an embodiment of the present invention, the valve flow path 115 is the high pressure groove 141 as the relief valve 140 moves downward In the case of being in communication with the c) or not being in communication with the low pressure groove 142, vibration, noise, etc. can be prevented from occurring in the oil pump 100.

On the other hand, when the reference to Figure 2 (when cut and viewed in a plane including a virtual center line penetrating the center of the relief valve 140 up and down), the relief valve 140, the outer surface ( The length L1 of a straight line connecting the uppermost point of the uppermost point and the lower point among the points where the high-pressure inner surface 144 and the outer surface 143 meet is formed of the high-pressure discharge passage 116. A straight line connecting an upper point among points where an inner wall meets an inner wall of the valve accommodation space 114 and an upper point where an inner wall of the valve flow path 115 and an inner wall of the valve accommodation space 114 meet each other. It may be designed to be formed longer than the length (L2). Here, the lower point among the points where the high pressure inner surface 144 and the outer surface 143 meet may be a point where the high pressure inclined surface 147 and the outer surface 143 meet.

In this case, when the relief valve 140 is pressurized by the oil supplied upward and moved downward, the high pressure groove before the upper space of the relief valve 140 and the high pressure discharge passage 116 communicates with each other. A space of the valve accommodation space 113 in which the 114 is formed may be in communication with the valve flow path 115 first. That is, a small amount of oil supplied to the valve passage 115 is first introduced into the high pressure discharge passage 116 through the high pressure groove 114, and then a large amount of oil supplied to the upper side of the relief valve 140. The high pressure discharge passage 116 may be introduced.

Therefore, according to the relief valve 140 and the oil pump 100 including the same according to an embodiment of the present invention, before the upper space of the relief valve 140 and the high pressure discharge passage 116, the valve The amount of oil returned to the suction port 111 through the high pressure discharge passage 116 by first supplying a small amount of oil through the flow path 115 and the high pressure groove 141 to the high pressure discharge passage 116. This can be increased gradually rather than rapidly.

Accordingly, according to the relief valve 140 and the oil pump 100 including the same according to an embodiment of the present invention, the amount of oil returned to the inlet 111 through the high pressure discharge passage 116 is rapidly increased. As it increases, problems such as vibration and noise that may occur inside the oil pump 100 may be solved.

Hereinafter, the operation of the relief valve 140 and the oil pump 100 including the same according to an embodiment of the present invention will be described in detail with reference to FIGS. 4 to 7. In this case, as shown in FIG. 4 to FIG. 7, the rotation speed of the rotor 130 may be gradually increased.

Referring to FIG. 4, at the start of the oil pump 100, the relief valve 140 is maintained in close contact with the upper side by the force applied by the valve spring 150. The oil branched from the discharge port 112 through the bypass passage 113 exerts a force on the upper side of the relief valve 140, but is pressurized by the rotor 130 to discharge the discharge port 112. Since the pressure of the oil itself is not large, the relief valve 140 is to be kept fixed without moving downward. At this time, since the oil returned from the bypass passage 113 to the suction port 111 does not exist, the pressure of the oil discharged to the discharge port 112 by the rotor 130 is gradually increased.

Referring to FIG. 5, when the rotation speed of the rotor 130 is gradually increased and the pressure of the oil discharged to the discharge port 112 increases, branching from the discharge port 112 flows into the bypass channel 113. The pressure of the oil is also increased. That is, the pressure applied to the oil flowing into the bypass passage 113 to the upper side of the relief valve 140 is increased. In this case, as the relief valve 140 moves downward, the valve passage 115 and the low pressure discharge passage 117 communicate with each other through the low pressure groove 142, and the bypass passage 113. The oil introduced into the inlet is returned to the inlet 111 through the valve passage 115, the low pressure groove 142, and the low pressure discharge passage 117. Accordingly, the increase rate of the pressure of the oil discharged to the outside through the discharge port 112 is maintained in a somewhat lower state than before.

Meanwhile, in FIG. 5, the oil supplied from the bypass passage 113 to the valve passage 115 is shown to flow across the relief valve 140, which flows oil into the low pressure groove 142. This does not mean that the valve flows back into the valve flow path 115.

The valve flow path 115 may be formed to surround the relief valve 140 along the circumferential direction of the relief valve 140, and the oil introduced into the bypass flow passage 113 may be the valve flow path 115. It may be supplied to the low pressure groove 142 while flowing to surround the relief valve 140 along. That is, in FIG. 5, the flow path of the oil supplied from the bypass passage 113 to the valve passage 115 surrounds the relief valve 140 along the circumferential direction of the relief valve 140. It may be said to flow along the inner wall of the accommodation space 114.

Referring to FIG. 6, when the rotation speed of the rotor 130 further increases, the relief valve 140 moves further downward. The valve flow path 115 is sealed by the outer surface 143 disposed between the high pressure groove 141 and the low pressure groove 142. In this case, the valve flow path 115 and the low pressure groove 142 are no longer maintained in communication with each other, and the oil returned to the suction port 111 through the bypass flow passage 113 is no longer present. You will not. Therefore, the pressure of the oil discharged through the discharge port 112 is rapidly increased again.

Referring to FIG. 7, when the rotation speed of the rotor 130 increases to the maximum, the relief valve 140 also moves downward to the maximum. The valve flow path 115 communicates with the high pressure discharge flow path 116 through the high pressure groove 141, and the upper space of the relief valve 140 also communicates with the high pressure discharge flow path 116. In this case, as the oil introduced into the bypass passage 113 is returned to the suction port 111 through the high pressure discharge passage 116, the pressure of the oil discharged through the discharge port 112 increases. Once again, it will remain somewhat lower than before.

In this case, the valve flow path 115 and the high pressure discharge flow path 116 are first communicated with each other, and then the upper space of the relief valve 140 and the high pressure discharge flow path 116 communicate with each other. That is, after the oil is first supplied to the high pressure discharge passage 116 through the valve passage 115 and the high pressure groove 141, the high pressure discharge passage 116 through the upper space of the relief valve 140. Oil is supplied.

Accordingly, according to the relief valve 140 and the oil pump 100 including the same according to the present invention, before the oil introduced into the upper space of the relief valve 140 is supplied to the high pressure discharge passage 116, the valve passage ( By supplying a small amount of oil introduced into the 115 to the high pressure discharge flow path 116 through the high pressure groove 141 in advance, the oil returned to the inlet 111 of the pump housing 110 through the high pressure discharge flow path 116. It is possible to prevent the amount from increasing drastically. Accordingly, according to the relief valve 140 and the oil pump 100 including the same according to the present invention, the vibration and noise can be prevented from occurring inside the oil pump 100 as the relief valve 140 operates. have.

100: oil pump 110: pump housing
120: stator 130: rotor
140: relief valve 150: valve spring

Claims (8)

In the oil pump which sucks oil and supplies it to the engine,
A pump housing having a suction port and a discharge port through which oil is sucked and discharged, and a bypass passage through which a part of the oil discharged to the discharge port is branched;
A stator accommodated in the pump housing;
A rotor accommodated in the stator and configured to suck and discharge oil through rotation; And
It is accommodated in the valve receiving space formed inside the pump housing, and is pressed from the upper side to the lower side by the oil introduced into the bypass flow path, and includes a relief valve formed with a high-pressure groove on the outer peripheral surface,
On the inner wall of the valve accommodation space, a valve flow passage communicating with the bypass flow passage, and a high pressure discharge flow passage selectively communicating with the valve flow passage through the high pressure groove,
The outer circumferential surface of the relief valve includes an outer surface and a high pressure inner surface formed to be recessed to the inner side of the outer surface when the high pressure groove is formed based on the radial direction of the relief valve.
When cut and viewed in a plane including an imaginary center line penetrating the center of the relief valve up and down, the uppermost point of the outer surface and the lower point of the point where the high pressure inner surface and the outer surface meet The length of the straight line connecting the upper part of the point where the inner wall of the high pressure discharge passage and the inner wall of the valve accommodation space meets, and the upper point of the point where the inner wall of the valve flow path and the inner wall of the valve accommodation space meet. Oil pump, characterized in that longer than the length of the straight line to connect. The method according to claim 1,
On the outer circumferential surface of the relief valve, a low pressure groove is formed below the high pressure groove, and a low pressure discharge passage selectively communicates with the valve flow path through the low pressure groove below the high pressure discharge passage on the inner wall of the valve accommodation space. Is formed,
The valve flow path, an oil pump formed between the high pressure discharge flow path and the low pressure discharge flow path. The method according to claim 1,
The high pressure inner surface includes a high pressure flat surface and a high pressure inclined surface extending from the lower side of the high pressure flat surface so as to be inclined outwardly in a radial direction of the relief valve toward the lower side.
An oil pump, characterized in that the lower point of the point where the high pressure inner surface and the outer surface meet, the point where the high pressure inclined surface and the outer surface meets. The method according to claim 2,
The outer circumferential surface of the relief valve further includes a low pressure inner surface formed to be recessed inwardly of the outer surface when the low pressure groove is formed in the radial direction of the relief valve.
The low pressure inner surface is an oil pump comprising a low pressure flat surface and a low pressure inclined surface extending from the upper side of the low pressure flat surface to be inclined outward in the radial direction of the relief valve toward the upper side. The method according to any one of claims 1 to 4,
The relief valve is an oil pump disposed so that the outer surface is in contact with the inner wall of the valve accommodation space. The method according to any one of claims 1 to 4,
A valve spring accommodated in the valve accommodation space and disposed below the relief valve to apply an elastic restoring force to the relief valve;
The valve receiving space is formed between the bypass passage and the stator, the bypass passage is formed so as to surround the valve receiving space to supply oil to the upper side of the relief valve. Relief accommodated in the valve receiving space formed in the pump housing of the oil pump, pressurized from the upper side to the lower side by the oil flowing into the bypass flow passage branched from the discharge port of the pump housing, and controls the pressure of the oil discharged from the pump housing In the valve,
On the outer circumferential surface is formed a high pressure groove which is selectively in communication with the high pressure discharge passage formed on the inner wall of the valve accommodation space, a low pressure groove is formed below the high pressure groove,
The high pressure groove surface is formed, the relief valve including a high pressure flat surface, and a high pressure inclined surface extending from the lower side of the high pressure flat surface to be inclined outward in the radial direction toward the lower side. The method according to claim 7,
The low pressure groove surface is formed, the relief valve comprising a low pressure flat surface and a low pressure inclined surface extending from the upper side of the low pressure flat surface inclined outward in the radial direction toward the upper side.

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