JP2014190181A - Electronic hydraulic governor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic hydraulic governor which is compact in size.SOLUTION: An electronic hydraulic governor 1 comprises: a gear pump 7 having a power piston 11, an input shaft 3, a drive gear 5 and a driven gear 6 bitten to the drive gear 5, and pressure-sending working oil; a control valve having a valve bushing 8 fixed to the driven gear 6 of the gear pump 7 and a spool 9 inserted into the valve bushing 8, and switching an oil passage of the working oil to the power piston 11 according to a slide of the spool 9; an actuator 10 which is electronically driven for sliding the spool 9; and a speed sensor 16 for detecting the number of revolutions of the valve bushing 8. A sensor gear 15 being an object to be sensed by the speed sensor 16 is arranged at the valve bushing 8.

Description

  The present invention relates to an electrohydraulic governor that controls the amount of fuel supplied to an engine by electronic control.

Conventionally, a technique of an electrohydraulic governor that controls the fuel supply amount to the engine by electronic control is known (for example, Patent Document 1). The electrohydraulic governor disclosed in Patent Document 1 switches between an electronically controlled electronic spool valve and a mechanically controlled mechanical spool valve to increase or decrease the fuel injection amount.
Regarding small engines, there is a demand to make the electrohydraulic governor to be mounted compact.

JP-A-11-241619

  An object of the present invention is to provide a compact electrohydraulic governor.

The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.
The electrohydraulic governor according to claim 1 is engaged with a power piston connected to an engine fuel supply device, an input shaft connected to the engine, a drive gear fixed to the input shaft, and the drive gear. A gear pump having a driven gear for pumping hydraulic oil; a valve bushing fixed to the driven gear of the gear pump; and a spool inserted into the valve bushing, and operating according to sliding of the spool A control valve for switching an oil path to the power piston of oil, an electronically controlled actuator for sliding the spool, and a speed sensor for detecting the rotation speed of the valve bushing, and detecting the speed sensor The power piston is operated by sliding the spool with the actuator according to the value. To the an electronic hydraulic governor for controlling the fuel supply to the engine, and providing a sensor gear which is the object of sensing of the speed sensor to the valve bushing.

  The electrohydraulic governor according to claim 2 is engaged with a power piston connected to a fuel supply device of an engine, an input shaft connected to the engine, a drive gear fixed to the input shaft, and the drive gear. A gear pump having a driven gear for pumping hydraulic oil; a valve bushing fixed to the driven gear of the gear pump; and a spool inserted into the valve bushing, and operating according to sliding of the spool A control valve for switching an oil path to the power piston of oil, an electronically controlled actuator for sliding the spool, and a speed sensor for detecting the rotation speed of the valve bushing, and detecting the speed sensor The power piston is operated by sliding the spool with the actuator according to the value. To the an electronic hydraulic governor for controlling the fuel supply to the engine, and providing a longitudinal groove which is the object of sensing of the speed sensor to the valve bushing.

  According to the present invention, by making the electrohydraulic governor compact, it is possible to effectively use the space, and in particular, it can be applied to a small engine having a limited arrangement space.

It is a perspective view which shows the internal structure of an electrohydraulic governor. (A) is sectional drawing of the electrohydraulic governor in the state where the power piston 11 is moving downward, (b) is sectional drawing of the electrohydraulic governor in the state where the power piston 11 is moving upward. It is a figure which shows another embodiment of an electrohydraulic governor, and shows embodiment which provided the vertical groove in the valve bushing.

The electrohydraulic governor 1 will be described with reference to FIGS. 1, 2 (a), and 2 (b).
The electrohydraulic governor is attached to an engine such as a diesel engine or a gasoline engine mounted on a vehicle, a work machine, a ship, or the like, and controls the amount of fuel supplied to the engine.
In this embodiment, an electrohydraulic governor attached to a diesel engine will be described.

The electrohydraulic governor 1 includes a housing that accommodates components. The housing is composed of a main body 2a and a lid 2b. In FIG. 1, drawing of the side wall portion of the main body 2a is omitted.
An input shaft 3 for driving the electrohydraulic governor 1 and an output shaft 4 for transmitting the operation of the electrohydraulic governor 1 are provided. The input shaft 3 is connected to the crankshaft of the diesel engine, and the electrohydraulic governor 1 is driven by the rotation of the crankshaft.
The input shaft 3 is extended from the outside to the inside of the main body 2a of the housing. A drive gear 5 is fixed to the input shaft 3 on the inner side. A driven gear 6 that meshes with the drive gear 5 is provided in the main body 2a. The drive gear 5 and the driven gear 6 constitute a gear pump 7. The gear pump 7 is a hydraulic pump provided in the electrohydraulic governor 1 and pumps hydraulic oil.

A lower end portion of the valve bushing 8 is fixed to the driven gear 6. The valve bushing 8 is a rotating body that is arranged in parallel with the input shaft 3 and is rotated along with the rotation of the driven gear 6.
The valve bushing 8 is a cylindrical member, and a spool 9 is inserted therein so as to be slidable in the axial direction. A plurality of annular grooves are provided on the outer periphery of the valve bushing 8, and ports that connect the outer peripheral surface and the inner peripheral surface are provided. An actuator 10 is connected to the spool 9, and the spool 9 is slid up and down by its operation. Thereby, opening and closing of the port of the valve bushing 8 is controlled, and the oil passage of the hydraulic oil is switched. The actuator 10 is arranged on the upper surface of the lid 2b of the housing.
Thus, the valve bushing 8, the spool 9, and the actuator 10 constitute a control valve.

A power piston 11 is connected to the output shaft 4. The power piston 11 moves up and down in accordance with the supply and discharge of the hydraulic oil that is switched by the vertical sliding of the spool 9. The vertical motion of the power piston 11 is transmitted as the rotational motion of the output shaft 4, and the fuel supply amount is increased or decreased according to the rotational direction of the output shaft 4.
The output shaft 4 is connected to an output lever 12 extending outside the housing (see FIGS. 2A and 2B). The output lever 12 is linked to a control rack of a fuel supply device (not shown). As described above, in the electrohydraulic governor 1, the power piston 11 is moved up and down (operated), the output shaft 4 is rotated, and the output lever 12 is moved to reduce the fuel supply amount from the fuel supply device to the engine. Increase or decrease.

A sensor gear 15 is fixed to the upper end of the valve bushing 8. The sensor gear 15 is a sensing target of the speed sensor 16 and rotates integrally with the valve bushing 8. The speed sensor 16 detects the number of rotations of the valve bushing 8 by detecting pulses generated as the sensor gear 15 rotates.
The speed sensor 16 is disposed in the vicinity of the sensor gear 15 and is fixed to the side wall portion of the main body 2a of the housing.

  The speed sensor 16 and the actuator 10 are connected to an appropriate control device (operation panel). The control device receives a detection signal from the speed sensor 16 and transmits a signal to the actuator 10. That is, the control device controls the fuel supply amount by electronically controlling the operation of the actuator 10 based on the rotation speed detected by the speed sensor 16.

  In this way, by providing the valve bushing 8 with the sensor gear 15 that is the sensing target of the speed sensor 16, there is no need to newly add a rotating shaft or the like for providing the sensor gear 15 for detecting the rotation speed, and the constituent members A compact arrangement is possible. Thereby, the electrohydraulic governor 1 can be made compact. Therefore, the electrohydraulic governor 1 can be applied to a small diesel engine.

As shown in FIGS. 2A and 2B, the valve bushing 8 is provided with three types of ports 20, 21, and 22. A plurality of these ports 20, 21 and 22 are provided in the circumferential direction, and annular grooves are formed around them. The inside of the valve bushing 8 can communicate with the outside through the ports 20, 21, 22 and the annular groove.
The high-pressure port 20 communicates with a high-pressure oil passage 24 fed from the gear pump 7 and a high-pressure oil chamber 25 facing the upper side of the power piston 11. The control port 21 communicates with a control oil chamber 26 facing the lower side of the power piston 11. The drain port 22 leads to a drain oil passage 27. The pressure receiving area on the high pressure oil chamber 25 side partitioned by the power piston 11 is set smaller than that on the control oil chamber 26 side.
In addition, a relief valve 28 is provided in the high-pressure oil passage 24 and is set so that the pressure of the high-pressure oil pumped by the gear pump 7 is constant.

The diameter of the spool 9 is set smaller than the inner diameter of the valve bushing 8, and a land 30 protruding in the radial direction is provided in the middle of the spool 9. The land 30 is in sliding contact with the inner peripheral surface of the valve bushing 8. That is, the spool 9 is formed in a shape having a step in the middle portion by having the land 30. Further, the positional relationship between the spool 9 and the valve bushing 8 is determined so that the land 30 is disposed in the vicinity of the control port 21 of the valve bushing 8.
A high pressure passage 31 is formed above the land 30 and a low pressure passage 32 is formed below the land 30 between the inner peripheral surface of the valve bushing 8 and the spool 9.

As shown in FIG. 2A, when the land 30 is above the control port 21, the control oil chamber 26 communicates with the drain oil passage 27 via the low pressure passage 32. As a result, the power piston 11 moves downward by the high pressure oil supplied to the high pressure oil chamber 24.
As shown in FIG. 2B, when the land 30 is below the control port 21, the control oil chamber 26 communicates with the high pressure oil passage 24 via the high pressure passage 31. As a result, high pressure oil of the same pressure is supplied to the control oil chamber 26 and the high pressure oil chamber 24. Due to the difference in pressure receiving area of the power piston 11, the power piston 11 moves upward.
In the present embodiment, the movements of the output shaft 4 and the output lever 12 are set so that the fuel supply amount increases when the power piston 11 moves upward and the fuel supply amount decreases when it moves downward.

As shown in FIG. 3, a plurality of vertical grooves 40 may be formed in the upper end portion of the valve bushing 8 without providing the sensor gear 15. The longitudinal grooves 40 are arranged at intervals in the circumferential direction of the valve bushing 8. The speed sensor 16 detects the number of rotations of the valve bushing 8 by detecting a pulse generated as the vertical groove 40 rotates.
In this way, the number of parts can be reduced by forming the vertical groove 40 in the valve bushing 8 instead of the sensor gear 15.

  1: electrohydraulic governor, 3: input shaft, 7: gear pump, 8: valve bushing, 10: actuator, 11: power piston, 15: sensor gear, 16: speed sensor

Claims (2)

A power piston connected to the engine fuel supply;
An input shaft connected to the engine;
A gear pump that has a drive gear fixed to the input shaft and a driven gear meshing with the drive gear, and that pumps hydraulic oil;
A control valve that has a valve bushing fixed to the driven gear of the gear pump, and a spool inserted into the valve bushing, and switches an oil path of the hydraulic oil to the power piston in accordance with sliding of the spool; ,
An electronically controlled actuator for sliding the spool;
A speed sensor for detecting the rotational speed of the valve bushing,
An electro-hydraulic governor that controls the amount of fuel supplied to the engine by operating the power piston by sliding the spool by the actuator according to a detection value of the speed sensor,
An electrohydraulic governor, wherein a sensor gear which is a sensing target of the speed sensor is provided on the valve bushing. A power piston connected to the engine fuel supply;
An input shaft connected to the engine;
A gear pump that has a drive gear fixed to the input shaft and a driven gear meshing with the drive gear, and that pumps hydraulic oil;
A control valve that has a valve bushing fixed to the driven gear of the gear pump, and a spool inserted into the valve bushing, and switches an oil path of the hydraulic oil to the power piston in accordance with sliding of the spool; ,
An electronically controlled actuator for sliding the spool;
A speed sensor for detecting the rotational speed of the valve bushing,
An electro-hydraulic governor that controls the amount of fuel supplied to the engine by operating the power piston by sliding the spool by the actuator according to a detection value of the speed sensor,
An electrohydraulic governor, wherein the valve bushing is provided with a longitudinal groove which is a sensing target of the speed sensor.

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