CN111258359A - Automatic air supplement and exhaust system of hydraulic power plant high-pressure oil tank based on PLC control - Google Patents

Abstract

The utility model provides an automatic mend exhaust system of hydraulic power plant high-pressure oil tank based on PLC control, including PLC the control unit, PLC the control unit control connection has air feed mechanism and detection mechanism, air feed mechanism includes air compressor machine and high-pressure gas pitcher that are linked together through the gas transmission pipeline, high-pressure gas pitcher is linked together through parallelly connected trunk line and auxiliary pipeline and high-pressure oil tank, high-pressure gas inlet valve has set gradually on the trunk line, automatic gulp valve and tonifying qi inlet valve, be provided with manual gulp valve on the auxiliary pipeline, detection mechanism is including the first pressure sensor who is used for detecting high-pressure gas pitcher internal gas pressure and the second pressure sensor who is used for detecting high-. The invention provides a hydraulic power plant high-pressure oil tank automatic air supply and exhaust system based on PLC control, which can efficiently ensure the stable operation of a high-pressure oil tank.

Description

Automatic air supplement and exhaust system of hydraulic power plant high-pressure oil tank based on PLC control

Technical Field

The invention relates to the technical field of hydroelectric power generation, in particular to a hydraulic power plant high-pressure oil tank automatic air supply and exhaust system based on PLC control.

Background

The pressure oil in the hydraulic power plant pressure oil tank provides a power source for hydraulic systems such as machine set guide vanes and blades, the medium in the pressure oil tank is pressure oil and compressed air, and the volume ratio of the oil in the pressure oil tank to the compressed air is usually kept to be 1:2 under rated pressure.

The oil return tank is used for receiving pressure oil in an oil return pipeline of a hydraulic system of the unit, and after a part of pressure oil is consumed by the action of the hydraulic systems such as guide vanes and blades of the unit, the pressure oil pump can drive the turbine oil in the oil return tank into the pressure oil tank again in order to maintain rated working oil pressure (6.4 MPa). Due to the technical performance of equipment, high-pressure gas in the oil pressing tank slightly loses, so that the proportion of oil in the oil pressing tank is gradually increased and exceeds the normal oil-gas proportion range, and further danger is caused.

At present, most of automatic air supply devices applied to high-pressure oil tanks of hydraulic power plants only have an automatic air supply function and do not have automatic exhaust, remote control, fault tolerance and error correction functions. The existing automatic air supply device cannot detect the pressure of front and rear air pipelines of the automatic air supply device, and the phenomenon of unsuccessful air supply or reverse air supply can be caused during the overhaul of the high-pressure air tank.

According to the mole law of gas, PV = nRT, in the gas supplementing process, the gas pressure P in the oil pressing tank is increased, meanwhile, the unit continuously uses the pressure oil in the oil pressing tank, the oil level can continuously descend, the V in the oil pressing tank is increased, the gas temperature T in the oil pressing tank can be increased, and therefore the oil temperature in the oil pressing tank is increased. And the rotation of the unit generates heat, so that return oil of each part of the unit is gathered to the oil return tank, and the oil temperature in the oil return tank is increased. The oil tank is required to maintain rated oil pressure, the oil pump pumps the turbine oil in the oil return tank to the oil tank, so that the oil temperature in the oil tank is continuously increased, the temperature can reach 50-60 ℃ in summer operation, and the turbine oil is accelerated to deteriorate due to overhigh oil temperature, so that the normal operation of a unit is influenced.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention provides the hydraulic power plant high-pressure oil tank automatic air supply and exhaust system based on PLC control, which can efficiently ensure the stable operation of the high-pressure oil tank.

In order to achieve the purpose, the invention adopts the specific scheme that: the utility model provides an automatic mend exhaust system of hydraulic power plant high-pressure oil tank based on PLC control, including PLC the control unit, PLC the control unit control connection has air feed mechanism and detection mechanism, air feed mechanism includes air compressor machine and high-pressure gas pitcher that are linked together through the gas transmission pipeline, high-pressure gas pitcher is linked together through parallelly connected trunk line and auxiliary pipeline and high-pressure oil tank, high-pressure gas inlet valve has set gradually on the trunk line, automatic gulp valve and tonifying qi inlet valve, be provided with manual gulp valve on the auxiliary pipeline, detection mechanism is including the first pressure sensor who is used for detecting high-pressure gas pitcher internal gas pressure and the second pressure sensor who is used for detecting high-.

As a preferable scheme, a check valve is further arranged between the automatic air supply valve and the air supply inlet valve.

As a preferred scheme, the auxiliary pipeline is also communicated with a pressure relief pipeline, and an automatic exhaust valve is arranged on the pressure relief pipeline.

Preferably, the detection mechanism further comprises a flow sensor disposed on the main pipe and close to the high-pressure oil tank.

As a preferred scheme, a temperature adjusting unit for adjusting the gas temperature is further arranged between the air compressor and the high-pressure gas tank, and the PLC control unit is in control connection with the temperature adjusting unit.

As a preferred scheme, the temperature control unit comprises a heat exchanger sleeved on the gas transmission pipeline, and a technical water supply pipeline is arranged in the heat exchanger in a penetrating manner.

Preferably, the technical water supply pipeline is provided with a technical water supply valve.

Preferably, the detection mechanism further includes a temperature sensor provided on the gas supply line and near the high-pressure gas tank.

As a preferred scheme, the PLC control unit is electrically connected with a control panel, and an automatic mode knob switch, a manual mode knob switch and a power supply knob switch are arranged on the control panel.

As a preferable scheme, the detection mechanism further comprises a high oil level air supplementing liquid level switch, a low oil level stopping liquid level switch, a high oil level alarming liquid level switch and a low oil level alarming liquid level switch which are arranged in the high pressure oil tank.

Has the advantages that:

1. the automatic air supplement system can execute automatic air supplement or manual air supplement, can realize automatic control of air pressure in the high-pressure oil tank through the automatic air supplement mode, effectively improve control efficiency and reduce manual pressure, and can supplement the automatic air supplement mode through the manual air supplement mode so as to avoid danger caused by failure of the automatic air supplement mode due to faults of an automatic air supplement valve and the like;

2. the invention can automatically detect the faults of gas backflow, valve damage, gas leakage of the high-pressure oil tank and the like;

3. the invention can automatically exhaust to avoid danger caused by faults and is convenient to overhaul.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic structural view of the dehumidifying mechanism.

Reference numerals: 1-air compressor, 2-heat exchanger, 3-technical water supply pipeline, 4-temperature sensor, 5-high pressure gas tank, 6-first pressure sensor, 7-high pressure gas inlet valve, 8-manual air supplement valve, 9-automatic air supplement valve, 10-check valve, 11-air supplement inlet valve, 12-automatic exhaust valve, 13-flow sensor, 14-second pressure sensor, 15-high pressure oil tank, 16-PLC control unit, 17-technical water supply valve, 18-first motor, 19-rotary table, 20-connecting rod, 21-dryer, 22-mounting plate, 23-second motor, 24-driving gear, 25-driven gear, 26-internal thread sleeve, 27-external thread sleeve, 28-sealing ring, 29-connecting pipe, 30-water absorbing material, 31-steel net, 32-dehumidification unit.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Please refer to fig. 1, an automatic air supply and exhaust system of a high-pressure oil tank of a hydraulic power plant based on PLC control, including a PLC control unit 16, the PLC control unit 16 is in control connection with an air supply mechanism and a detection mechanism, the air supply mechanism includes an air compressor 1 and a high-pressure air tank 5 which are communicated through an air delivery pipeline, the high-pressure air tank 5 is communicated with a high-pressure oil tank 15 through a main pipeline and an auxiliary pipeline which are connected in parallel, a high-pressure gas inlet valve 7, an automatic air supply valve 9 and an air supply inlet valve 11 are sequentially arranged on the main pipeline, a manual air supply valve 8 is arranged on the auxiliary pipeline, and the detection mechanism includes a first pressure sensor 6 for detecting the air pressure in the high-pressure air tank 5 and.

In order to ensure the safe operation of the high-pressure oil tank 15, the air pressure in the high-pressure oil tank 15 needs to be controlled between 6.0 MPa and 6.4MPa, and correspondingly, in order to ensure smooth air supply to the high-pressure oil tank 15, the air pressure in the high-pressure air tank 5 should be kept between 6.7 and 7.0MPa, the first pressure sensor 6 and the second pressure sensor 14 respectively detect the air pressure in the high-pressure air tank 5 and the high-pressure oil tank 15, when the difference between the detection value of the first pressure sensor 6 and the detection value of the second pressure sensor 14 is greater than 0.3MPa, the gas supply is started and the gas in the high-pressure gas tank 5 is sent to the high-pressure oil tank 15, because the air pressure in the high-pressure oil tank 15 is constantly decreased and the air pressure in the high-pressure air tank 5 is constantly increased in the normal operation state, therefore, the situation that the difference is larger than 0.3MPa and the high-pressure oil tank 15 does not need air supplement does not occur. In addition, considering that the air supply process is not continuously performed, air supply is performed only when needed, and therefore, the automatic air supply valve 9 and the manual air supply valve 8 are both normally closed valves, and the high-pressure gas inlet valve 7 and the air supply inlet valve 11 may be normally open or normally closed valves. When air is supplemented, two modes of automatic air supplement and manual air supplement can be adopted, the PLC control unit 16 controls the automatic air supplement valve 9 to be opened and the manual air supplement valve 8 to be kept closed during automatic air supplement, the gas in the high-pressure gas tank 5 is sent into the high-pressure oil tank 15 through the main pipeline to be supplemented, the PLC control unit 16 controls the manual air supplement valve 8 to be opened and the automatic air supplement valve 9 to be kept closed during manual air supplement, and the gas in the high-pressure gas tank 5 is sent into the high-pressure oil tank 15 through the auxiliary pipeline to be supplemented. Through the automatic air supply mode, can realize the automatic control to the internal gas pressure of high-pressure oil tank 15, effectively improve control efficiency, reduce artificial pressure, and can supply the automatic air supply mode through manual air supply mode to avoid causing the automatic air supply mode to become invalid and then causing danger because of reasons such as automatic air supply valve 9 trouble.

Further, a check valve 10 is arranged between the automatic air supply valve 9 and the air supply inlet valve 11. The check valve 10 plays a role of protection, avoids danger caused by the fact that the pressure in the high-pressure gas tank 5 exceeds the upper limit of 7.0MPa due to gas backflow in the main pipeline,

furthermore, the auxiliary pipeline is also communicated with a pressure relief pipeline, and an automatic exhaust valve 12 is arranged on the pressure relief pipeline. Check valve 10 closes in order to protect high-pressure gas tank 5 when gaseous production refluence in the trunk line, but this can lead to trunk line internal gas pressure to rise, if pressure is too high and causes several valve trouble on the trunk line easily, and then lead to high-pressure gas tank 5 or high-pressure oil tank 15 to take place dangerously, again because trunk line and auxiliary duct are parallelly connected, the import of trunk line and auxiliary duct's import intercommunication promptly, the export of trunk line and auxiliary duct's export intercommunication, consequently set up the pressure release pipeline with auxiliary duct intercommunication and set up automatic exhaust valve 12, can lead to the internal gas pressure of trunk line to rise through automatic exhaust valve 12 when taking place gaseous refluence and pass through auxiliary duct and pressure release pipeline and discharge with the gas in the trunk line, protect trunk line and each valve. In addition, if the automatic air compensating valve 9 fails, and the pressure in the main pipeline is continuously increased due to continuous gas flowing from the high-pressure gas tank 5 into the main pipeline, the automatic air exhausting valve 12 can be used for exhausting. Finally, if the high pressure gas tank 5 or the high pressure oil tank 15 needs to be serviced, the system is stopped completely and all gas is vented, also by means of the automatic vent valve 12 and the pressure relief pipe.

Further, the detection mechanism further comprises a flow sensor 13, and the flow sensor 13 is arranged on the main pipeline and close to the high-pressure oil tank 15. The flow sensor 13 is used to detect a forward gas compensation amount, i.e., a gas amount compensated into the high-pressure oil tank 15, to ensure the safety of the high-pressure oil tank 15, and is used to detect a reverse gas compensation amount, i.e., a backflow gas amount when gas backflow occurs, so that the PLC control unit 16 can accurately control the opening or closing of the automatic exhaust valve 12.

Further, a temperature adjusting unit for adjusting the gas temperature is further arranged between the air compressor 1 and the high-pressure gas tank 5, and the PLC control unit 16 is in control connection with the temperature adjusting unit. Since the temperature of the oil in the high-pressure oil tank 15 needs to be kept within a safe range to ensure the quality of the pressure oil, the pressure oil will be deteriorated if the temperature is too high, and the fluidity of the pressure oil will be deteriorated if the temperature is too low, a temperature control unit is further provided to control the temperature of the pressure oil by controlling the temperature of the gas, thereby further ensuring the safety of the pressure oil tank 15.

Further, the temperature control unit comprises a heat exchanger 2 sleeved on the gas transmission pipeline, and a technical water supply pipeline 3 is arranged in the heat exchanger 2 in a penetrating mode. Wherein the technical water supply pipeline 3 is used for supplying high-temperature water or low-temperature water, and the heat of the water is transferred to the gas in the gas transmission pipeline by the heat exchanger 2, thereby changing the temperature of the gas.

Further, a technical water supply valve 17 is provided on the technical water supply pipeline 3. The technical water supply valve 17 is used to control the opening or closing of the technical water supply pipeline 3, and the technical water supply pipeline 3 can be closed when the control of the gas temperature is not required, thereby producing the effect of saving water.

Further, the detection mechanism further includes a temperature sensor 4, and the temperature sensor 4 is provided on the gas supply line and near the high-pressure gas tank 5. The temperature sensor 4 is used to detect the gas temperature so that the PLC control unit 16 can precisely control the opening or closing of the technical water supply valve 17.

Further, the PLC control unit 16 is electrically connected to a control panel, and the control panel is provided with an automatic mode knob switch, a manual mode knob switch and a power knob switch. The automatic mode knob switch is used for controlling the automatic air supply mode to be turned on or turned off, the manual mode knob switch is used for controlling the manual air supply mode to be turned on or turned off, under the normal condition, the automatic mode knob switch is in an on state, the system runs according to the automatic air supply mode, and when the manual mode knob switch is turned on, the PLC control unit 16 automatically turns off the automatic mode knob switch to enter the automatic air supply mode. The power knob switch is used for controlling the system to be turned on or turned off, when the power knob switch is in a turned-off state, all the valves are turned off, the system stops running, and no operation is performed.

Further, the detection mechanism further comprises a high-oil-level air-supplementing liquid level switch, a low-oil-level stop liquid level switch, a high-oil-level alarm liquid level switch and a low-oil-level alarm liquid level switch which are arranged in the high-pressure oil tank 15. The high oil level air supplementing liquid level switch and the low oil level stopping liquid level switch are used for controlling starting and stopping of the automatic air supplementing mode, and the high oil level alarming liquid level switch and the low oil level alarming liquid level switch are used for dealing with system faults. Specifically, when the automatic air supplement valve 9 or the manual air supplement valve 8 leaks air slightly, the flow sensor 13 may not detect the air leakage due to a small flow, and at this time, the high-pressure air in the high-pressure oil tank 15 is continuously increased, so that the oil level is continuously reduced, and at this time, air supplement is not required, the system automatically stops running and cannot be processed in time, so that a low-oil-level alarm liquid level switch is provided, and when the low-oil-level alarm liquid level switch is triggered, the PLC control unit 16 closes the high-pressure air inlet valve 7 and opens the automatic exhaust valve 12 to exhaust the air. And calculating the amount of high-pressure gas to be exhausted according to the installation distance between the low-oil-level alarm liquid level switch and the low-oil-level stop liquid level switch and the sectional area of the oil pressure tank, automatically closing the automatic exhaust valve 12 and opening the high-pressure gas inlet valve 7 after the flow sensor 13 detects that the exhaust amount reaches a calculated value, and recovering to the automatic air supplement mode when the exhaust process is finished. The working process of the high oil level alarm liquid level switch is similar to that of the low oil level alarm liquid level switch, only the exhaust process is changed into the air supplementing process, the specific air supplementing mode is the same as the automatic air supplementing mode, and the detailed description is omitted. In addition, when the high oil level alarm liquid level switch or the low oil level alarm liquid level switch is triggered, the PLC control unit 16 sends out an alarm signal to prompt that a valve with air leakage possibly exists in the system, so that maintenance personnel can timely handle the valve.

Further, PLC the control unit 16 can select arbitrary PLC that can realize valve control and data processing, and the technical staff in the art can select according to the demand, and all valves and sensor and the equal electric connection of PLC the control unit 16, and the connected mode can be confirmed according to PLC's selection, all belongs to conventional means, no longer gives unnecessary details.

Further, if the humidity of the gas supplied to the high-pressure oil tank 15 is too high, the moisture contained therein is liable to deteriorate the pressure oil in the high-pressure oil tank 15, and in order to avoid this, the present invention is provided with a dehumidifying mechanism for absorbing the moisture in the air delivered from the air compressor 1. The dehumidifying mechanism comprises a first motor 18 and a dryer 21 which are arranged on the side of the gas transmission pipeline, the first motor 18 is connected with a rotating disc 19 in a driving way, the rotating disc 19 is fixedly connected with a plurality of connecting rods 20 which are uniformly distributed along the circumferential direction and extend along the radial direction, each connecting rod 20 is fixedly connected with a dehumidifying unit 32, meanwhile, the gas transmission pipeline is cut off to leave a vacant position, in the rotating process of the rotating disc 19 driven by the first motor 18, the dehumidifying units 32 alternately enter the vacant positions to communicate the cut gas transmission pipelines, after the communication, the air compressor 1 acts to send high-pressure gas into the gas transmission pipeline, the moisture of the high-pressure gas is absorbed by the dehumidifying units 32 when passing through the dehumidifying units 32, then the air compressor 1 is temporarily stopped, the first motor 18 removes the used dehumidifying units 32 from the vacant positions, the unused dehumidifying units 32 are moved into the vacant positions, the air compressor 1 can be started again, and the used dehumidifying units 32 are gradually conveyed to the upper part of the dryer 21, and after drying, the product can be prepared for reuse. Through dehumidification mechanism, can detach the moisture in the high-pressure air effectively, avoid pressure oil to receive moisture pollution and deteriorate to dehumidification mechanism need not suspend frequently and changes the material, can continuous cycle work, and dehumidification is efficient. It should be noted that, during the alternation of the dehumidification unit 32, the process of supplying the high-pressure air to the high-pressure air tank 5 is suspended, but because the high-pressure air tank 5 is used for storing the high-pressure air, the suspended process does not affect the normal operation of the high-pressure air tank 5, and therefore, the dehumidification mechanism does not adversely affect the overall function of the system.

Further, the dehumidifying unit 32 comprises a connecting pipe 29, the connecting pipe 29 is filled with a water absorbing material 30, and two ends of the connecting pipe 29 are fixedly connected with a steel mesh 31; both ends of gas transmission pipeline fracture respectively are provided with a sealing device, sealing device is including fixed mounting disc 22 of establishing on output pipeline of cover, the fixed second motor 23 that is provided with on mounting disc 22, and the output shaft of second motor 23 is towards the fracture, fixed cover is equipped with driving gear 24 on the output shaft of second motor 23, driving gear 24 meshes has driven gear 25, and driven gear 25 rotates the cover and establishes on gas transmission pipeline, driven gear 25 is coaxial to be linked firmly internal thread sleeve 26, internal fit connection of internal thread sleeve 26 has external screw thread sleeve 27, and external screw thread sleeve 27 laminates with gas transmission pipeline mutually, it is equipped with sealing washer 28 to inlay on external screw thread sleeve 27's the inner wall, and sealing washer 28 is close to the fracture. After first motor 18 drive dehumidification unit 32 reachs the vacancy, two sealing device simultaneous action, specifically speaking is second motor 23 starts, second motor 23 drives driving gear 24 and rotates, and then drive driven gear 25 by driving gear 24 and rotate, driven gear 25 rotates the in-process and drives internal thread sleeve 26 and rotate, and then drive external thread sleeve 27 by internal thread sleeve 26 and remove to the fracture direction, until external thread sleeve 27 remove to the cover establish connecting pipe 29 on, external thread sleeve 27 seals gas transmission pipeline and connecting pipe 29 this moment, in order to guarantee that high-pressure air can not take place to leak when passing dehumidification unit 32, sealing washer 28 is used for guaranteeing sealed effect.

Further, annular spout can be seted up towards one side of fracture to mounting disc 22, and the spout is coaxial with gas transmission pipeline, and the spout sets up to the dovetail, and driven gear 25 is coaxial to be linked firmly a plurality of forked tail sliders, and the forked tail slider slides and sets up and makes driven gear 25 can not follow axial displacement in the spout, and corresponding mounting disc 22 needs to be formed by a plurality of monomer concatenations to the assurance can be with in the forked tail slider installs the spout.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The utility model provides an automatic mend exhaust system of hydraulic power plant high pressure oil tank based on PLC control which characterized in that: including PLC the control unit (16), PLC the control unit (16) control connection has air feed mechanism and detection mechanism, air feed mechanism includes air compressor machine (1) and high-pressure gas pitcher (5) that are linked together through the gas transmission pipeline, high-pressure gas pitcher (5) are linked together through parallelly connected trunk line and auxiliary line and high-pressure oil tank (15), high-pressure gas inlet valve (7), automatic gulp valve (9) and tonifying qi inlet valve (11) have set gradually on the trunk line, be provided with manual gulp valve (8) on the auxiliary line, detection mechanism is including first pressure sensor (6) that are used for detecting high-pressure gas pitcher (5) internal gas pressure and second pressure sensor (14) that are used for detecting high-pressure oil tank (15) internal gas pressure.

2. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: a check valve (10) is also arranged between the automatic air supply valve (9) and the air supply inlet valve (11).

3. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: the auxiliary pipeline is also communicated with a pressure relief pipeline, and an automatic exhaust valve (12) is arranged on the pressure relief pipeline.

4. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: the detection mechanism further comprises a flow sensor (13), and the flow sensor (13) is arranged on the main pipeline and close to the high-pressure oil tank (15).

5. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: the air compressor machine (1) with still be provided with the temperature regulation unit that is used for adjusting gas temperature between high-pressure gas pitcher (5), PLC the control unit (16) is connected with temperature regulation unit control.

6. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: the temperature control unit comprises a heat exchanger (2) sleeved on the gas transmission pipeline, and a technical water supply pipeline (3) is arranged in the heat exchanger (2) in a penetrating mode.

7. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: and a technical water supply valve (17) is arranged on the technical water supply pipeline (3).

8. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: the detection mechanism further comprises a temperature sensor (4), and the temperature sensor (4) is arranged on the gas supply pipeline and is close to the high-pressure gas tank (5).

9. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: the PLC control unit (16) is electrically connected with a control panel, and an automatic mode knob switch, a manual mode knob switch and a power supply knob switch are arranged on the control panel.

10. The PLC-based hydraulic power plant high-pressure oil tank automatic air supply and exhaust system is characterized in that: the detection mechanism further comprises a high-oil-level air supplementing liquid level switch, a low-oil-level stopping liquid level switch, a high-oil-level alarming liquid level switch and a low-oil-level alarming liquid level switch which are arranged in the high-pressure oil tank (15).

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