CN212272346U - Two-stage variable pump control system based on single feedback cavity - Google Patents
Two-stage variable pump control system based on single feedback cavity Download PDFInfo
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- CN212272346U CN212272346U CN202021275969.7U CN202021275969U CN212272346U CN 212272346 U CN212272346 U CN 212272346U CN 202021275969 U CN202021275969 U CN 202021275969U CN 212272346 U CN212272346 U CN 212272346U
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Abstract
The utility model provides a two-stage variable pump control system based on single feedback chamber, which comprises a main oil duct, an oil pan, a variable displacement vane pump and a solenoid valve with a safety mode, wherein the variable displacement vane pump comprises a pump body, a variable spring, a rotor, a variable slider and a feedback oil chamber; the electromagnetic valve is provided with a port P, a port A and a port T, wherein the port P is communicated with the main oil gallery, the port A is communicated with the feedback oil cavity, and the port T is communicated with the oil pan. The utility model discloses only make up the application through single feedback chamber and the solenoid valve that has the safe mode, just can make single chamber feedback vane pump realize the variable discharge capacity of two-stage, make entire control system's structure greatly simplify, and control is simple, and the response is timely.
Description
Technical Field
The utility model relates to an internal-combustion engine lubricating system technical field, in particular to control system of single-action chamber feedback variable displacement vane pump.
Background
The oil pump is used for supplying lubricating oil to all sliding parts of the engine to ensure the normal work of the sliding parts, the power source of the oil pump is from the engine, the flow rate of the oil at the outlet end of the oil pump is proportional to the rotating speed of the engine, and the rotating speed of the engine is a variable, so that the required flow rate of the lubricating oil is not in direct proportion to the rotating speed of the engine, and therefore when the engine works in a high-speed section, the problem of excessive oil flow rate can occur, and the waste of the power of the engine is caused.
In the prior art, the flow control of the oil pump mainly has two modes, one mode is that a pressure release valve is arranged at the outlet end of the pump, so that when an engine works in a low rotating speed section, the oil pressure at the outlet of the oil pump is gradually increased along with the gradual increase of the rotating speed; when the engine enters a high-speed section, the outlet oil pressure of the engine oil pump is higher than the preset pressure value of the pressure relief valve, the pressure relief valve starts to work, and partial engine oil is discharged, so that the engine oil pressure is maintained at a constant value.
Another type of variable flow pump is a mechanical flow control mechanism that is typically driven by oil pressure feedback from the outlet end of the pump, such as a vane-type variable flow pump. Compared with the first scheme, the variable-flow oil pump is beneficial to improving the lubricating performance of the high-speed section of the engine, but the lubricating problem or the waste problem of the power of the engine during the high-speed rotation of the engine cannot be completely solved because the adjusting sections are few, the flow change reaction of the oil pump is delayed in the operation process, and the pressure fluctuation range of the oil is large.
With the increasing development and popularization of the variable displacement technology of the engine lubricating system oil pump, the vane type oil pump is widely applied, the existing vane pump comprises two variable forms of single-acting cavity feedback and double-acting cavity feedback, wherein the single-acting cavity feedback can be designed into a one-stage variable displacement mode, MAP control can be realized through an electro-hydraulic proportional control valve, and the double-acting cavity feedback can be designed into a two-stage variable displacement mode.
SUMMERY OF THE UTILITY MODEL
The to-be-solved technical problem of the utility model is to provide a second grade variable pump control system based on single feedback chamber, this control system can realize the variable displacement mode of single chamber two-stage.
In order to solve the technical problem, the utility model discloses a following technical scheme: a two-stage variable pump control system based on a single feedback cavity comprises a main oil duct, an oil pan, a variable displacement vane pump and an electromagnetic valve with a safety mode, wherein the variable displacement vane pump comprises a pump body, a variable spring, a rotor, a variable slider and a feedback oil cavity; the electromagnetic valve is provided with a port P, a port A and a port T, wherein the port P is communicated with the main oil gallery, the port A is communicated with the feedback oil cavity, and the port T is communicated with the oil pan.
The working process of the utility model is as follows: in the first-stage variable displacement stage, the electromagnetic valve is electrified, the port P is communicated with the port A, the port A is not communicated with the port T, the main oil duct pressure oil enters the feedback oil cavity through the electromagnetic valve, and in the stage, the feedback oil cavity is filled with the main oil duct pressure oil all the time; before the engine oil pressure of the main oil duct does not reach the set low-pressure variable pressure point, the pressure oil in the feedback oil cavity cannot push the variable slide block to compress the variable spring, and the eccentric quantity of the variable slide block and the rotor is maximum at the moment; when the engine oil pressure of the main oil duct reaches a set low-pressure variable pressure point, the oil pressure in the feedback oil cavity is increased, so that the variable slide block is pushed to compress the variable spring, the eccentric quantity of the variable slide block and the rotor is reduced, and the output displacement is reduced; when the electromagnetic valve is powered off, the port P of the electromagnetic valve is not communicated with the port A, the port A is communicated with the port T, the system enters a two-stage variable displacement stage, no oil pressure is supplied in the feedback oil cavity at the stage, and the eccentric quantity of the variable slide block and the rotor is maximum at the moment; when the engine oil pressure of the main oil duct reaches a set high-pressure variable pressure point, the engine oil pressure from the main oil duct can push open an internal plunger of the electromagnetic valve to enable the port P to be communicated with the port A, and the pressure oil of the main oil duct enters the feedback oil cavity through the electromagnetic valve to push the variable sliding block to compress the variable spring, so that the eccentric quantity of the variable sliding block and the rotor is reduced, and the output displacement is reduced.
Preferably, the solenoid valve is a proportional solenoid valve.
Wherein the variable displacement vane pump is a direct push type or a slider type vane pump.
The utility model discloses only make up the application through single feedback chamber and the solenoid valve that has the safe mode, just can make single chamber feedback vane pump realize the variable discharge capacity of two-stage, make entire control system's structure greatly simplify, and control is simple, and the response is timely.
Drawings
Fig. 1 is a schematic structural diagram of a control system of the present invention;
the reference signs are:
10-variable displacement vane pump 11-pump body 12-variable spring
13-rotor 14-variable slide block 15-feedback oil chamber
20-proportional solenoid valve.
Detailed Description
In order to facilitate understanding of those skilled in the art, the present invention will be further described with reference to the following examples and drawings, which are not intended to limit the present invention.
In the description of the present invention, it is to be understood that the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise. In the description of the present invention, it should be noted that, unless otherwise specified and limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, mechanically or electrically connected, or interconnected between two elements, directly or indirectly through intervening media, and the specific meaning of the terms may be understood by those skilled in the art according to their specific situation.
As shown in fig. 1, the preferred embodiment of the present invention is: a two-stage variable displacement pump control system based on a single feedback cavity comprises a main oil gallery, an oil sump, a variable displacement vane pump 10 and a solenoid valve 20 with a safety mode, wherein the variable displacement vane pump 10 can be a direct-push type or a slide block type vane pump, and the solenoid valve 20 is preferably a proportional solenoid valve; the variable displacement vane pump 10 comprises a pump body 11, a variable spring 12, a rotor 13, a variable slider 14 and a feedback oil cavity 15; the electromagnetic valve 20 is provided with a port P, a port A and a port T, wherein the port P is communicated with the main oil gallery, the port A is communicated with the feedback oil cavity 15, the port T is communicated with the oil pan,
the working process of the utility model is as follows: in the stage of first-stage variable displacement, the electromagnetic valve 20 is powered on, the port P is communicated with the port A, the port A is not communicated with the port T, the main oil gallery pressure oil enters the feedback oil cavity 15 through the electromagnetic valve 20, and in the stage, the feedback oil cavity 15 is filled with the main oil gallery pressure oil all the time; before the engine oil pressure of the main oil duct does not reach the set low-pressure variable pressure point, the pressure oil in the feedback oil cavity 15 cannot push the variable slide block 14 to compress the variable spring 12, and the eccentric amount of the variable slide block 14 and the rotor 13 is maximum at the moment; when the engine oil pressure of the main oil duct reaches a set low-pressure variable pressure point, the oil pressure in the feedback oil cavity 15 is increased, so that the variable slide block 14 is pushed to compress the variable spring 12, the eccentric quantity of the variable slide block 14 and the rotor 13 is reduced, and the output displacement is reduced; when the electromagnetic valve 20 is de-energized, the port P of the electromagnetic valve 20 is not communicated with the port A, the port A is communicated with the port T, the system enters a two-stage variable displacement stage, no oil pressure is supplied in the feedback oil cavity 15 at the stage, and the eccentric quantity of the variable slide block 14 and the rotor 13 is maximum at the moment; when the engine oil pressure of the main oil gallery reaches a set high-pressure variable pressure point, the engine oil pressure from the main oil gallery can push open an internal plunger of the electromagnetic valve 20, so that the port P is communicated with the port A, the pressure oil of the main oil gallery enters the feedback oil cavity 15 through the electromagnetic valve 20, the variable sliding block 14 is pushed to compress the variable spring 12, the eccentric quantity of the variable sliding block 14 and the rotor 13 is reduced, and the output displacement is reduced.
The utility model discloses only make up the application through single feedback chamber and the solenoid valve that has the safe mode, just can make single chamber feedback vane pump realize the variable discharge capacity of two-stage, make entire control system's structure greatly simplify, and control is simple, and the response is timely.
The above-mentioned embodiment is the utility model discloses the implementation scheme of preferred, in addition, the utility model discloses can also realize by other modes, any obvious replacement is all within the protection scope of the utility model under the prerequisite that does not deviate from this technical scheme design.
In order to make it easier for those skilled in the art to understand the improvement of the present invention over the prior art, some drawings and descriptions of the present invention have been simplified, and in order to clarify, some other elements have been omitted from this document, those skilled in the art should recognize that these omitted elements may also constitute the content of the present invention.
Claims (4)
1. The utility model provides a two-stage variable pump control system based on single feedback chamber which characterized in that: the variable displacement vane pump comprises a main oil channel, an oil pan, a variable displacement vane pump (10) and a solenoid valve (20) with a safety mode, wherein the variable displacement vane pump (10) comprises a pump body (11), a variable spring (12), a rotor (13), a variable slider (14) and a feedback oil cavity (15); the electromagnetic valve (20) is provided with a port P, a port A and a port T, wherein the port P is communicated with the main oil gallery, the port A is communicated with the feedback oil cavity (15), and the port T is communicated with the oil pan.
2. The single feedback chamber based two stage variable pump control system of claim 1, wherein: in the stage of first-stage variable displacement, the electromagnetic valve (20) is electrified, the port P is communicated with the port A, the port A is not communicated with the port T, the main oil gallery pressure oil enters the feedback oil cavity (15) through the electromagnetic valve (20), and in the stage, the feedback oil cavity (15) is filled with the main oil gallery pressure oil all the time; before the engine oil pressure of the main oil duct does not reach the set low-pressure variable pressure point, the pressure oil in the feedback oil cavity (15) cannot push the variable slide block (14) to compress the variable spring (12), and the eccentric quantity of the variable slide block (14) and the rotor (13) is maximum at the moment; when the engine oil pressure of the main oil duct reaches a set low-pressure variable pressure point, the oil pressure in the feedback oil cavity (15) is increased, so that the variable slide block (14) is pushed to compress the variable spring (12), the eccentric quantity of the variable slide block (14) and the rotor (13) is reduced, and the output displacement is reduced;
when the electromagnetic valve (20) is powered off, the port P of the electromagnetic valve (20) is not communicated with the port A, the port A is communicated with the port T, the system enters a two-stage variable displacement stage, no oil pressure is supplied in the feedback oil cavity (15) at the stage, and the eccentric quantity of the variable sliding block (14) and the rotor (13) is maximum at the moment; when the engine oil pressure of the main oil duct reaches a set high-pressure variable pressure point, the engine oil pressure from the main oil duct can push open an inner plunger of the electromagnetic valve (20) to enable the port P to be communicated with the port A, and the pressure oil of the main oil duct enters the feedback oil cavity (15) through the electromagnetic valve (20), so that the variable sliding block (14) is pushed to compress the variable spring (12), the eccentric amount of the variable sliding block (14) and the rotor (13) is reduced, and the output displacement is reduced.
3. A single feedback chamber based two stage variable pump control system according to claim 1 or 2, wherein: the electromagnetic valve (20) is a proportional electromagnetic valve.
4. A single feedback chamber based two stage variable pump control system according to claim 1 or 2, wherein: the variable displacement vane pump (10) is a direct push type or a slide block type vane pump.
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CN202021275969.7U CN212272346U (en) | 2020-07-03 | 2020-07-03 | Two-stage variable pump control system based on single feedback cavity |
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CN202021275969.7U CN212272346U (en) | 2020-07-03 | 2020-07-03 | Two-stage variable pump control system based on single feedback cavity |
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