KR102373362B1 - Lubricating oil supply system and a control method of the same - Google Patents

Abstract

The present invention provides a lubricating oil supply system for lubricating and cooling a plurality of rotating bodies, comprising: a main supply oil through which lubricating oil flows; a main pump provided in the main supply passage to pump lubricating oil; a plurality of individual supply passages communicating with the main supply passage and supplying lubricating oil to each of the plurality of rotating bodies; an oil pan accommodating the lubricating oil that has passed through the plurality of rotating bodies; an oil storage tank for supplying lubricating oil to the main supply passage; a discharge passage for communicating the oil pan and the oil storage tank; and a drain pump provided in the discharge passage and forcibly draining the lubricating oil accommodated in the oil pan into the storage tank.

Description

Lubricating oil supply system and a control method of the same

The present invention relates to a lubricating oil supply system and a method for controlling the same.

Since a rotating body such as a drive shaft of a molding machine tool rotates at high speed and high load by a motor, etc., lubricating oil must be continuously and properly supplied for lubrication and cooling of the rotating body, and for this purpose, a lubricating oil supply system is used.

The existing lubricant supply system can be largely divided into a quantitative lubricant distribution system and a proportional lubricant distribution system according to the distribution method, and the flow rate of the lubricant is adjusted by the discharge pressure of the pump and the opening/closing degree of the flow valve.

1 shows a conventional quantitative lubricating oil distribution system. The quantitative lubricating oil distribution system is branched from the main supply passage 91 provided with a main pump 92, the main supply passage 91, and a distribution passage valve 94. ) is provided with a distribution passage 93 , and a distribution valve 95 for distributing the lubricating oil introduced through the distribution passage 93 to an individual supply passage 96 .

2 is a conventional proportional lubricating oil distribution system. Like the quantitative lubricating oil distribution system, the flow rate of the lubricant supplied through the main supply passage 91 is adjusted only by the distribution oil passage valve 94 .

That is, all of these individual supply passages 96 are provided with a flow rate fixing unit 96a provided as a screw valve or orifice, and the flow rate of the individual supply passage 96 is initially designed by the flow rate fixing unit 96a. The flow rate set at that time is maintained.

The flow rate is adjusted in units of distribution oil connected to a number of individual lubrication units, not in units of individual lubrication units, and it is impossible to check whether the flow rate of each individual lubrication unit is in a steady state. In this case, there is a fundamental limitation in having to replace the flow rate fixing part 96a.

Accordingly, in order to adjust the flow rate of a specific individual supply flow path 96, the flow rate of the entire distribution flow path 93 must be adjusted. Accordingly, there is a problem in that the energy loss increases.

In addition, it is impossible to check whether the flow rate of the lubricant supplied to each individual supply channel 96 is appropriate, so it is inevitable to adjust the flow rate inaccurately according to the experience value. This is not constant and the required amount of lubricant to be supplied is different, so it is inevitably difficult to supply lubricant at the optimal flow rate.

Therefore, there is a problem in that when the equipment operation speed is increased or the load is increased in the field, seizure or oil leakage of the bush frequently occurs, causing a great hindrance to production, such as the equipment operation being stopped.

On the other hand, in the case of the conventional lubricating oil discharge and recovery method, as can be seen in FIGS. 1 and 2 , lubricant oil is supplied to each rotating body through an individual supply passage 96 , and then from each rotating body to the oil pan 97 . It falls and is recovered back to the oil storage tank 99 through the discharge passage 98 .

Lubricating oil flows in the discharge path 98 only by the pressure and weight of the lubricating oil accumulated in the oil pan 97. It has to be initially designed according to the return time to the oil storage tank (99).

Therefore, in the conventional method of discharging and recovering lubricating oil, it is not possible to adjust the amount of discharge and recovery of lubricating oil as needed, and the oil pan 97 and the oil storage tank 99 are used to increase the flow rate of lubricating oil when the facility operation speed is increased. It has a serious problem of having to re-produce it in a larger size.

In addition, when the system is designed so that the flow rate is high from the beginning, the size of the oil pan 97 and the oil storage tank 99 increases, which increases the manufacturing cost and lowers the space utilization, and the maintenance cost of the facility as the amount of lubricating oil increases increase and cause environmental pollution.

The present invention has been devised to solve the problems of the prior art, and it is an object to monitor the oil supply state in units of individual lubricating units and individually adjust the flow rate accordingly.

In addition, the present invention has an object to smoothly drain the lubricating oil that has passed through the rotating body, and more specifically, to selectively adjust the amount of oil drained through forced draining.

According to an embodiment of the present invention, in a lubricating oil supply system for lubricating and cooling a plurality of rotating bodies, the lubricating oil flows through a main supply oil path; a main pump provided in the main supply passage to pump lubricating oil; a distribution passage branching from the main supply passage; a plurality of individual supply passages communicating with the distribution passage and supplying lubricant to each of the plurality of rotating bodies; and a plurality of individual supply passage flow rate valves provided in each of the plurality of individual supply passages to selectively adjust the flow rate of lubricating oil supplied to each of the plurality of rotating bodies through the plurality of individual supply passages. A lubricating oil supply system can be provided.

In an exemplary embodiment, a plurality of individual supply passage pressure measuring units provided in each of the plurality of individual supply passages to measure the internal pressure of each of the plurality of individual supply passages may be further included.

In an exemplary embodiment, the individual supply passage pressure measuring unit is a pressure sensor, and the plurality of individual supply passage flow valves may adjust the flow rate according to the pressure measured by the pressure sensor.

In an exemplary embodiment, a plurality of non-return valves provided in each of the plurality of individual supply passages to prevent the lubricating oil from flowing back from the plurality of rotating bodies to the flow valves of the plurality of individual supply passages; may further include there is.

In an exemplary embodiment, the distribution flow passage first valve is provided in the distribution passage to selectively adjust the flow rate of the lubricant supplied to the plurality of individual supply passages through the distribution passageway; and a distribution passage second valve provided in the distribution passage to periodically open and close the distribution passage.

In an exemplary embodiment, it further comprises; an auxiliary supply passage branched from the main supply passage and through which lubricant oil flows, wherein the plurality of individual supply passages communicate with the distribution passage, and lubricating oil is applied to each of the plurality of rotating bodies. a plurality of first individual supply passages for supplying; and a plurality of second individual supply passages in communication with the auxiliary supply passage and connected to each of the plurality of first individual supply passages, wherein the plurality of individual supply passage flow valves are disposed in the plurality of second individual supply passages. can be provided.

In an exemplary embodiment, the auxiliary supply passage first valve is provided in the auxiliary supply passage and selectively adjusts the flow rate of lubricating oil supplied to the plurality of second individual supply passages through the auxiliary supply passage. can do.

In an exemplary embodiment, a distribution valve for uniformly distributing the lubricant oil introduced through the distribution passage to each of the plurality of first individual supply passages; may further include.

In an exemplary embodiment, an oil pan for accommodating the lubricating oil that has passed through the plurality of rotating bodies; an oil storage tank for supplying lubricating oil to the main supply passage; a discharge passage for communicating the oil pan and the oil storage tank; and a drain pump provided in the discharge passage and forcibly flowing the lubricating oil accommodated in the oil pan to the storage tank, wherein the flow rate of the discharge passage may be adjusted according to the total flow rates of the plurality of individual supply passages.

According to an embodiment of the present invention, there is provided a control method for controlling the lubricant supply system, comprising: a flow state detection step of measuring the internal pressure of each of the plurality of individual supply passages through the pressure measuring unit of the plurality of individual supply passages; a flow state determination step of determining whether the internal pressure of each of the plurality of individual supply passages is within a preset range; When the internal pressure of at least one of the plurality of individual supply paths is out of a preset range, individual control of a flow valve for adjusting the flow rate with individual supply channel flow valves provided in the individual supply channels whose internal pressure is out of the preset range It is possible to provide a control method of the lubricating oil supply system comprising;

According to an embodiment of the present invention, in a lubricating oil supply system for lubricating and cooling a plurality of rotating bodies, the lubricating oil flows through a main supply oil path; a main pump provided in the main supply passage to pump lubricating oil; a plurality of individual supply passages communicating with the main supply passage and supplying lubricating oil to each of the plurality of rotating bodies; an oil pan accommodating the lubricating oil that has passed through the plurality of rotating bodies; an oil storage tank for supplying lubricating oil to the main supply passage; a discharge passage for communicating the oil pan and the oil storage tank; and a drain pump that is provided in the discharge passage and forcibly drains the lubricating oil accommodated in the oil pan into the storage tank.

In an exemplary embodiment, the discharge passage includes a first discharge passage provided with the drain pump; and a second discharge passage having a discharge valve selectively opening and closing the flow passage.

In an exemplary embodiment, when the discharge valve opens the second discharge passage, a load applied to the drain pump provided in the first discharge passage may be reduced.

In an exemplary embodiment, the discharge valve may be provided as a manual valve.

In an exemplary embodiment, a discharge passage filter provided in the first discharge passage and filtering foreign substances included in the lubricant flowing toward the drain pump may be further included.

In an exemplary embodiment, the drain pump may be periodically turned on/off.

In an exemplary embodiment, the discharge passage may further include a connection passage connecting the first and second discharge passages to the oil pan.

In an exemplary embodiment, a plurality of individual supply flow flow valves provided in each of the plurality of individual supply passages to selectively adjust the flow rate of lubricating oil supplied to each of the plurality of rotating bodies through the plurality of individual supply passages; may further include.

In an exemplary embodiment, a plurality of individual supply passage pressure measuring units provided in each of the plurality of individual supply passages to measure the internal pressure of each of the plurality of individual supply passages may be further included.

According to an embodiment of the present invention, a flow state detection step of measuring the internal pressure of each of the plurality of individual supply passages through the plurality of individual supply passage pressure measuring unit; a flow rate change determination step of determining whether the total flow rate is changed as the internal pressure of each of the plurality of individual supply passages is changed; and a drain pump adjustment step of adjusting a driving cycle of the drain pump provided in the discharge passage when the total flow rate is changed.

The present invention has an effect of monitoring each oil supply state with individual supply oil for supplying lubricating oil to a rotating body, and supplying lubricating oil with a flow rate optimized for each individual supply oil.

In addition, the present invention has the effect of reducing the amount of lubricating oil used, increasing the lubricating oil supply speed, and reducing the volume of the oil draining facility by selectively controlling the amount of oil drain and recovery amount of the lubricant oil that has passed through the rotating body.

1 is a schematic diagram showing a conventional quantitative lubricating oil distribution system.
2 is a schematic diagram illustrating a conventional proportional lubricating oil distribution system.
3 is a schematic diagram illustrating a lubricating oil supply system according to an embodiment of the present invention.
4 is a lubricating oil supply system according to an embodiment of the present invention, and is an example of applying the lubricating oil supply system of FIG. 3 to an existing quantitative type lubricating oil distribution system.
5 is a lubricating oil supply system according to another embodiment of the present invention, an example of applying the lubricating oil supply system of FIG. 3 to the conventional proportional lubricating oil distribution system.
6 is a flowchart illustrating a control method of a lubricant supply system according to an embodiment of the present invention.
7 is a flowchart illustrating a control method of a lubricant supply system according to another embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described with reference to the drawings.

First, a lubricant supply system according to an embodiment of the present invention will be described with reference to FIG. 3 .

A lubricating oil supply system according to an embodiment of the present invention for performing lubrication and cooling of a plurality of rotating bodies is a main supply passage 11 through which lubricating oil flows, and is provided in the main supply passage 11 to pump lubricating oil and operate a motor. A main pump 12 including, a main supply passage pressure measuring unit 13 for measuring the internal pressure of the main supply passage 11, a pressure switch 14 for selectively opening and closing the main supply passage 11, and, It may include a filter 15 that filters foreign substances of the lubricating oil flowing into the main supply passage 11 .

The operation mode of the main pump 12 may be determined according to the internal pressure of the mail supply passage 11 measured by the pressure measuring unit 13, and when the entire system is turned off, the pressure switch 14 By this, the main supply passage 11 may be closed.

In addition, the lubricating oil supply system according to an embodiment of the present invention includes a distribution passage 21 branched from the main supply passage, and a plurality of distribution passages branched from the distribution passage 21 and supplying lubricant to each of the plurality of rotating bodies. It may include an individual supply passage 31 .

The distribution passage 21 is provided in the distribution passage first valve 22 and the distribution passage 21 for selectively adjusting the flow rate of lubricating oil supplied to the plurality of individual supply passages to periodically open and close the distribution passage. A distribution passage second valve 23 may be provided, and the distribution passage second valve 23 may be provided as a solenoid valve, and an opening/closing cycle may be determined by the distribution passage timer 24 .

A distribution valve 25 may be provided between the distribution passage 21 and the individual supply passage 31 to uniformly distribute the lubricant oil introduced through the distribution passage 21 to each of the plurality of individual supply passages. , the lubricating oil introduced into the distribution valve 25 may flow to the individual supply passages 31 in an even manner.

Each of the plurality of individual supply passages 31 may be provided with a plurality of individual supply passage flow valves 32 for selectively adjusting the flow rate of lubricating oil supplied to each of the plurality of rotating bodies, and the individual supply passage flow valves ( 32) can selectively adjust the flow rate of each individual supply flow path (31).

Even a rotating body supplied with lubricating oil through the same distribution flow path may have different sizes and clearances depending on processing quality. In this case, it is necessary to differentially supply lubricant to each rotating body.

Therefore, unlike the prior art of adjusting the flow rate in units of distribution oil passages, the present invention allows to set the optimum flow rate for each individual supply passage 31, so that lubricating oil is wasted and seizing occurs in the rotating body due to lack of lubricating oil. It has an excellent effect of preventing problems.

In addition, the lubricating oil supply system according to an embodiment of the present invention is provided in each of the plurality of individual supply passages 31 to measure the pressure of a plurality of individual supply passages for measuring the internal pressure of each of the plurality of individual supply passages 31 . It may further include a part (33).

The plurality of individual supply passage flow valves 32 may adjust the flow rate of the individual supply passage 31 according to the pressure measured by the individual supply passage pressure measuring unit 33 .

That is, when the measured internal pressure of the specific individual supply flow path 31 does not reach the reference pressure, the individual supply flow flow valve 32 expands the flow path opening range of the specific individual supply flow path 31 to increase the lubricating oil flow rate. there is.

Conversely, even when the internal pressure of a specific individual supply passage 31 exceeds a predetermined appropriate pressure, the individual supply passage flow rate valve 32 may be operated to return to a predetermined appropriate pressure.

The individual supply passage pressure measuring unit 33 may be any one of a pressure gauge and a pressure sensor, but is provided as the pressure sensor in that it can detect the individual supply passage flow valve 32 by automatically detecting the internal pressure. It is preferable to be

When provided with a pressure sensor, the individual supply flow flow valve 32 can be controlled through a control unit (not shown) in real time, and problems such as pipe blockage/short circuit/connection instability can be detected in real time, so that the facility is maintained The level of management can be dramatically increased.

The lubricant supply system according to an embodiment of the present invention is provided in each of the plurality of individual supply passages 31 and is provided between the rotation body and the individual supply passage flow valve 32, so that the lubricating oil is supplied from the plurality of rotation bodies. It may further include a plurality of non-return valves 34 to prevent backflow to the plurality of individual supply flow flow valves 32 .

The non-return valve 34 may be provided as a check valve, and it is possible to effectively prevent the problem of lubricating oil from flowing back to the flow valve 32 side of the individual supply path due to hydraulic pressure fluctuations inside the rotating body.

Hereinafter, with reference to FIG. 3, the configuration of the drain of the lubricant supply system according to an embodiment of the present invention will be described.

The lubricating oil supply system according to an embodiment of the present invention includes an oil pan 41 in which the lubricating oil passing through the plurality of rotating bodies is dropped and accommodated, a storage oil tank 51 for supplying lubricating oil to the main supply passage 11, A discharge passage 42 for guiding the lubricating oil contained in the oil pan 41 to the oil storage tank 51, and a lubricant oil provided in the discharge passage 42 and accommodated in the oil pan 41 to the oil storage tank 51 ) may include a drain pump 43 for forced outflow.

The drain pump 43 includes a motor, and may be periodically turned on/off by the discharge flow timer 44 , and the cycle may be changed according to the flow rate of the circulating lubricant.

In addition, the drain pump 43 may control the flow rate of the discharge passage 42 through pump pressure control instead of cycle.

This allows the lubricating oil accommodated in the oil pan 41 to forcibly flow out into the oil storage tank 51, unlike the conventional natural fall method, to increase or decrease the lubricating oil recovery rate, so that it can be selectively adjusted.

Therefore, the present invention has an excellent effect of increasing the circulating speed of lubricating oil in an existing facility to improve the operating speed of the entire facility without replacing the oil pan 41 and the oil storage tank 51 with a large size.

In addition, from the initial design, the volume of the oil pan 41 and the oil storage tank 51 can be significantly reduced compared to the prior art, thereby reducing the manufacturing cost, and even with a small total amount of lubricating oil, the amount of lubrication supplied to the rotating body per hour can be increased. Therefore, environmental pollution can be prevented, and the level of facility maintenance and performance can be dramatically improved.

On the other hand, the discharge passage 42 includes a first discharge passage 421 equipped with the drain pump 43, a second discharge passage 422 equipped with a discharge valve 46 for selectively opening and closing the passage, and the second discharge passage. A connection passage 423 for communicating the first discharge passage 421 and the second discharge passage 422 with the oil pan 41, and the first discharge passage 421 and the second discharge passage 422 A discharge flow path 424 communicating with the oil storage tank 51 may be included.

The discharge valve 46 may selectively open and close the second discharge flow path 422 , and when the discharge valve opens the second discharge flow path 422 , the first discharge flow path 421 includes the The load applied to the drain pump 43 can be reduced.

The discharge valve 46 reduces the load applied to the drain pump 43, so that the drain pump 43 can be provided as a small-sized and inexpensive pump, and the flow rate is high and the first discharge passage 421 ), it is reduced when the internal resistance is severe, and there is no need to use a large-size flow path, so it reduces the manufacturing cost and has the effect of making it easy to apply to existing facilities without large volume change.

The discharge valve 46 may be provided as either an automatic valve or a manual valve as long as the second discharge flow path 422 can be opened and closed, but in an emergency, the operator manually opens the second discharge flow path 422 easily. It is preferable to be provided with a valve.

The first discharge passage 421 may be provided with a discharge passage filter 45 for filtering foreign substances contained in the lubricant flowing toward the drain pump 43, and the discharge passage filter 45 may include a drain pump ( 43) should not be damaged by foreign substances.

4 is an example of applying the system for individually managing the lubricant and the system for facilitating the drain described in FIG. 3 to the existing quantitative lubricating oil distribution system. explained in the center.

According to this embodiment, by adding a facility to the existing quantitative lubricating oil distribution system, it is possible to more precisely manage the lubricating oil supply and increase the lubricating oil circulation.

Specifically, the lubricating oil supply system according to another embodiment of the present invention may further include an auxiliary supply passage 61 branched from the main supply passage 11 and through which lubricating oil flows.

In addition, the plurality of individual supply passages 31 communicate with the distribution passage 21 and provide a plurality of first individual supply passages 311 for supplying lubricant to each of the plurality of rotating bodies, and the auxiliary supply passage 61 . and may include a plurality of second individual supply passages 312 connected to each of the plurality of first individual supply passages 311 .

At this time, the plurality of individual supply passage flow valves 32 are provided in the plurality of second individual supply passages 312 to each first individual supply passage 311 through the second individual supply passages 312 . The flow rate of the supplied lubricating oil can be selectively adjusted.

That is, the plurality of first individual supply passages 311 are existing facilities connected to the distribution valve 25 , and thus the auxiliary supply passage 61 , the second individual supply passage 312 , and the individual supply passage flow valve 32 . By additionally installing the lubricating oil, it is possible to manage the lubricant individually.

Similarly, the plurality of individual supply passage pressure measuring units 33 for measuring the internal pressure of the second individual supply passage 312, and the lubricating oil backflow from the first individual supply passage 311 to the auxiliary supply passage 61 A plurality of non-return valves 34 that are check valves for preventing the above may be provided in the second individual supply passage 312 .

In addition, the lubricant supply system according to another embodiment of the present invention is provided in the auxiliary supply flow path 61 to selectively control the flow rate of lubricating oil supplied to the plurality of second individual supply passages through the auxiliary supply flow path 61 . It may include an auxiliary supply passage first valve 62 to adjust, and an auxiliary supply passage second valve 63 provided in the auxiliary supply passage 61 to selectively open and close the auxiliary supply passage 61 .

Accordingly, it is possible to adjust the flow rate by the first valve 62 of the auxiliary supply oil, and supply and stop the supply of lubricating oil to the second valve 63 as the auxiliary supply oil.

In addition, the auxiliary supply passage second valve 63 may be periodically turned on/off, and for this purpose, a timer (not shown) may be connected.

Similarly in this embodiment, the lubricant oil directly introduced into the first individual supply passage 311 and passed through the rotating body and the first individual supply passage 311 through the second individual supply passage 312 are directly introduced into the All of the lubricating oil passing through the rotating body may be guided to the oil storage tank 51 when the drain pump 43 operates or the discharge valve 46 opens the first discharge passage 412 .

5 is an example of applying the system for individually managing the lubricating oil and the system for facilitating the drain described with reference to FIG. 3 to the existing proportional lubricant distribution system, except for the proportional distribution valve, it is the same as the technical content shown in FIG. .

That is, since only the flow rate fixing part 96a provided with a screw type valve or orifice is provided in the first individual supply flow path 311, it is difficult to flexibly control the flow rate as needed. Two separate supply passages 312 and individual supply passage flow rate valves 32 complement each other.

6 is a view showing a control method of a lubricant supply system according to an embodiment of the present invention.

Specifically, the control method of the lubricating oil supply system includes a flow state detection step (S11) of measuring the internal pressure of each of the plurality of individual supply passages through the pressure measuring unit 33 of the plurality of individual supply passages, and the plurality of individual supply passages. It may include a flow state determination step (S12) of determining whether the internal pressure of each of the flow passages 31 is within a preset range.

Thereafter, when it is determined in S12 that the internal pressure of at least one of the plurality of individual supply passages is out of the preset range, the individual supply passages provided in the individual supply passages 31 whose internal pressures are out of the preset range A flow valve individual adjustment step (S13) of adjusting the flow rate with the flow valve 32 may be performed.

On the other hand, when it is determined in S12 that the pressures of all of the plurality of individual supply passages are within a preset range, the lubricating oil supply system operation end determination step (S14) may proceed.

The individual flow valve adjustment step (S13) may be performed manually, but a control unit (not shown) receives data from the individual supply passage pressure measurement unit 33 in real time to automatically control the individual supply passage flow valve 32 . In this way, proper lubricant can be supplied more effectively.

7 is a view showing a control method of a lubricant supply system according to another embodiment of the present invention.

This embodiment relates to the control of the drain pump 43, and the control method of the lubricant supply system is a flow state that measures the internal pressure of each of the plurality of individual supply passages 31 through the plurality of pressure measuring units 33 It may include a detection step (S21) and a flow rate change determination step (S22) of determining whether the total flow rate is changed as the internal pressure of each of the plurality of individual supply passages 31 is changed.

When it is determined that the total flow rate has changed in the flow rate change determination step S22, the drain pump adjustment step S23 of adjusting the driving cycle of the drain pump 43 provided in the first discharge passage 421 may be performed. If not, the lubricating oil supply system operation end determination step (S24) may proceed.

Similarly, although the drain pump adjustment step S23 may be performed manually, a control unit (not shown) receives data from the individual supply passage pressure measurement unit 33 in real time to automatically control the drain pump 43 . In this way, the circulation speed of the lubricant can be adjusted more flexibly.

Even if the effect is not described in this specification, the present invention may additionally have different effects of each of the above-described components, and derive a new effect that cannot be seen in the prior art according to the organic coupling relationship between each of the above-described components can do.

In addition, the embodiments shown in the drawings may be modified and implemented in other forms, and if implemented including the configuration claimed in the claims of the present invention or implemented within the scope of equivalents, it should be regarded as belonging to the scope of the present invention. something to do.

Main supply channel 11 Main pump 12
Main supply channel pressure measuring section 13 Pressure switch 14
Main supply channel filter 15 Distribution channel 21
Distribution flow path 1st valve 22 Distribution flow path 2nd valve 23
Distribution flow timer 24 Distribution valve 25
Individual supply channel 31 First individual supply channel 311
2nd individual supply path 312 Individual supply path flow valve 32
Individual supply path pressure measuring unit 33 Non-return valve 34
Oil pan 41 Discharge passage 42
1st discharge path 421 2nd discharge path 422
Connection channel 423 Discharge channel 424
Drain pump 43 Drain flow timer 44
Discharge path filter 45 Discharge valve 46
Oil Reservoir 51 Auxiliary Supply Channel 61
Auxiliary supply path 1st valve 62 Auxiliary supply path 2nd valve 63

Claims (10)

In the lubricating oil supply system for lubricating and cooling a plurality of rotating bodies,
a main supply oil through which lubricating oil flows;
a main pump provided in the main supply passage for pumping lubricating oil;
a plurality of individual supply passages communicating with the main supply passage and supplying lubricating oil to each of the plurality of rotating bodies;
an oil pan accommodating the lubricating oil that has passed through the plurality of rotating bodies;
an oil storage tank for supplying lubricating oil to the main supply passage;
a discharge passage for communicating the oil pan and the oil storage tank;
a drain pump provided in the discharge passage and forcibly draining the lubricating oil accommodated in the oil pan into the storage tank; and
an exhaust oil filter that filters out foreign substances contained in the lubricating oil;
including,
The discharge path is
a first discharge passage provided with the drain pump; and
a second discharge passage having a discharge valve that is a manual valve for selectively opening and closing the flow passage;
includes,
The exhaust flow filter is
Lubricating oil supply system, characterized in that it is disposed before the drain pump based on the flow direction of the lubricant in the first discharge passage
delete The method of claim 1,
When the discharge valve opens the second discharge passage, a load applied to the drain pump provided in the first discharge passage is reduced.
delete delete The method of claim 1,
The drain pump is periodically turned on/off. The method of claim 1,
The discharge path
and a connection passage connecting the first discharge passage and the second discharge passage to the oil pan. The method of claim 1,
A plurality of individual supply passage flow valves provided in each of the plurality of individual supply passages to selectively adjust the flow rate of lubricating oil supplied to each of the plurality of rotating bodies through the plurality of individual supply passages; characterized by further comprising: lubricating oil supply system. 9. The method of claim 8,
The lubricating oil supply system further comprising: a plurality of individual supply passage pressure measuring units provided in each of the plurality of individual supply passages to measure the internal pressure of each of the plurality of individual supply passages. In the control method for controlling the lubricating oil supply system of claim 9,
a flow state detection step of measuring the internal pressure of each of the plurality of individual supply passages through the plurality of individual supply passage pressure measuring units;
a flow rate change determination step of determining whether the total flow rate is changed as the internal pressure of each of the plurality of individual supply passages is changed; and
and a drain pump adjustment step of adjusting a driving cycle of the drain pump provided in the discharge passage when the total flow rate is changed.

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