RU49138U1 - AXIAL PISTON MACHINE WITH PISTON CONTROL CONVERTER PISTON - Google Patents

Abstract

The utility model relates to the field of adjustable hydraulic machines, namely: to axial piston machines with variable displacement. The problem solved by the utility model is to reduce the dimensions of the axial piston machine and increase the reliability of its operation. The problem is solved in that in an axial-piston machine with a control piston stroke converter comprising a pumping unit and a control mechanism with a piston for controlling the position of the pumping unit, the control piston stroke converter contains a Hall sensor mounted above the control piston, between the control mechanism housing or other emphasis rigidly connected with the body of the control mechanism and the control piston two springs are sequentially installed: the first spring of greater stiffness and the second spring of a smaller tkosti installed between the first spring and the control piston, piston stroke control transmitter further comprises a permanent magnet associated with the first spring to provide a coordinated movement of the first spring and the permanent magnet.

Description

The utility model relates to the field of adjustable hydraulic machines, namely: to axial piston machines with variable displacement.

Known axial piston machine (patent DE No. 10119236, F 04 B 1/30), selected for the prototype, with an inclined block rotating around the axis of the Central pin. The inclined block includes pistons pivotally supported on the shaft flange, which is mounted on bearings in the housing. On the opposite side of the bearings, the inclined block rests on a distributor with channels for supplying and discharging fluid to the cylinders. The distributor rotates on the surface of rotation of the housing of the control mechanism by means of a finger kinematically connecting the distributor and the control piston located in the housing of the control mechanism. The finger is mounted transversely in the control piston and is connected on one side with the distributor, and on the opposite side, with a rotary link connected to the angle sensor.

A disadvantage of the known machines are significant overall dimensions; inaccuracy and unreliability of measurement of the angle sensor due to possible backlash of the sensor drive mechanism, which are, in turn, a result of the double conversion of the movement of the machine distributor. In addition, the angle sensor located at the end of the machine limits the possibility of placing channels for supplying and discharging the working medium to the machine.

Known variable displacement pump (RF patent No. 2155275), selected for the prototype, containing a pumping unit, a piston for controlling the position of the pumping unit, located in the cylinder body. In this case, the pump is equipped with a piston position sensor made in the form of a linear transformer, moreover, a groove is made in the control piston in which a position sensor coil is attached to the cylinder body cover, and the movable sensor core is connected to the piston.

The disadvantage of the prototype is the significant amount of stroke of the piston position sensor, which determines the significant dimensions of a known machine (since this sensor occupies a significant place in the machine body).

The disadvantage is the fact that the sensor winding is in the working cavity under the pressure of the working medium. As a result, the pressure in the working cavity is reduced relative to the working pressure. To compensate for the decrease in pressure in the working cavity, the diameter of the control piston is increased, which also determines the significant dimensions of the machine as a whole.

Finding the sensor winding under the pressure of the working medium leads to increased requirements for the insulation of the winding and for the arrangement of the winding leads outward to the measuring technique.

The problem solved by the utility model is to reduce the dimensions of the axial piston machine and increase the reliability of its operation.

The problem is solved in that in an axial-piston machine with a control piston stroke converter comprising a pumping unit and a control mechanism with a piston for controlling the position of the pumping unit, according to a utility model, the control piston stroke converter comprises a Hall sensor mounted above the control piston between the control mechanism body or another emphasis rigidly connected with the control mechanism housing and the control piston, two springs are installed in series: the first spring of greater stiffness and Thoraya lesser spring stiffness, installed between the first spring and the control piston, piston stroke control transmitter further comprises a permanent magnet associated with the first spring to provide a coordinated movement of the first spring and the permanent magnet.

The presence of a permanent magnet in the control piston stroke transducer is necessary for the Hall sensor to respond to a change in the magnetic field created by this magnet.

A feature of the Hall sensor is that it reacts to a change in the magnetic field only in a limited space around itself. The control piston stroke is disproportionately larger in size of the Hall sensor; therefore, the Hall sensor will respond to a change in the magnetic field only within a part of the possible movement of the control piston. In order to measure and respond to the entire range of the control piston stroke, it is necessary to convert the full stroke of the control piston into another variable parameter to which the Hall sensor will respond. Such a changing parameter will be the stroke of the first spring, which is more rigid in comparison with the second spring.

The permanent magnet must be installed in such a way that it is connected with the first spring of less rigidity with the possibility of providing

coordinated movement of the first spring and the permanent magnet. When moving the first spring, the permanent magnet will also move accordingly. When moving a permanent magnet, a change in the magnetic field will be created by this magnet around the Hall sensor.

When the stroke of the control piston changes, the state of the springs changes (they are either compressed or expanded depending on the direction of the piston stroke). Moreover, since the first spring has a greater stiffness compared to the second spring, when the piston stroke changes, a larger stroke (corresponding to its stiffness) of the first spring will correspond to a larger stroke of the second spring. Thus, a certain stroke of the second spring and a corresponding stroke of the first spring will correspond to a certain stroke of the control piston, smaller than the stroke of the second spring.

Thus, the control piston stroke is converted to the first spring stroke. The stiffness of the first spring is selected so that its stroke corresponds to the sensitivity of the Hall sensor, which has the ability to respond to changes in the magnetic field around itself only in a small space.

A change in the course of the first spring causes a change in the magnetic field around the Hall sensor, which responds to this change, converting the magnitude of this change in the magnetic field into an electrical signal at its output. A specific position of the first spring (and, accordingly, the position of the control piston) will correspond to a well-defined signal at the output of the Hall sensor.

The Hall sensor is installed in the housing of the control mechanism and it is possible to place the Hall sensor in an airtight housing. Therefore, the negative impact of the working environment on the parameters of the Hall sensor, i.e. on the quality and reliability of the measurement.

The possibility of placing the Hall sensor in a sealed housing allows the working medium to be supplied under the working pressure into the cavity above the piston. The presence of a working pressure in the cavity above the piston allows minimizing the dimensions of the control piston. Placing a permanent magnet and both springs in a cavity under working pressure in no way affects the reliability of their operation, as These are not live parts.

The Hall sensor is small and placed in the housing of the control mechanism above the control piston. The introduction of a Hall sensor in no way entails an increase in the size of the machine. Two mounted above the control piston

springs - of greater and lesser stiffness also do not entail an increase in the overall dimensions of the machine, because Hall sensor, springs and permanent magnet are located in the existing working space of the machine.

A control piston stroke transducer containing a Hall sensor, two springs and a magnet is simple in design and manufacturing, does not require special equipment.

The simplicity of the design of the piston stroke converter determines the reliability of its operation, the accuracy of measurements.

To establish a permanent magnet so that it is connected with the first spring with the possibility of ensuring coordinated movement of the first spring and the permanent magnet can, for example, as follows. At the junction of the first and second springs, place a supporting element (ring or plate) on which a permanent magnet will be mounted; the supporting element can also be attached directly to the first spring.

Figure 1 presents the electro-hydro-kinematic diagram of the inventive machine.

Figure 2 presents the inventive axial piston machine

The axial piston machine with a control piston stroke converter comprises a housing 1 in which a shaft 3 with a flange 4 is mounted on the bearings 2. The flange 4 is pivotally connected to the pistons 5 and the central pin 6. The pistons 5 are located in the cylinders 7 of the block rotating around the axis of the central pin 6 8, which is driven into rotation by the flange 4 of the shaft 3 and the pistons 5. The stroke of the pistons 5 is determined by the angle of rotation formed by the axis of rotation of the block 8 and the axis of rotation of the shaft 3. Block 8 is supported by a distributor 9 adjacent to the housing 10 of the mechanism egulirovaniya. The distributor 9 is pressed against the housing 10 under the action of the force of the spring 11 and hydraulic pressure in the cylinders 7 of the block 8.

The regulation of the working volume of the machine is ensured by the sliding of the distributor 9 along the supporting surface of rotation of the housing 10 along the guides 12. The movement of the distributor 9 along the supporting surface of the housing 10 is carried out by a differential (step) piston 13 by means of a pin 14 entering the opening 15 of the distributor 9. The piston 13 is placed in cylindrical cavities 16 and 17 (cylinders 16 and 17). The cylinders 16 and 17 are located on opposite sides with respect to the finger 14, while the cylinder 16 has a part of the piston having a smaller diameter, and the cylinder 17 has a part of the piston 13 having a larger diameter. A spring 18 is mounted in the cylinder 16, abutting against the piston 13,

sequentially resting through the washer 19 on the spring 20, which, in turn, resting on the cover 21 of the housing 10, which covers the cylinder 16. The spring 18 has a stiffness lower than the stiffness of the spring 20. The stiffness of the spring 20 is selected based on the condition that the entire stroke of the piston 13, the spring 20 changed its position (compressed or expanded), while both extreme positions of the spring 20 (in the most compressed and maximally unclenched position) should be within the response zone of the Hall sensor 31.

A permanent magnet 22 is fixed on the washer 22. The cylinder 16 is connected by a channel 23 to a hydraulic distributor 26 controlled by an electromagnet 27. A hydraulic distributor 26 connected by a channel 28 to a drain into a tank 29, depending on the magnitude and potential of the control electric power on electromagnet 27, controls the pressure in the cylinder 17 is a larger diameter of the piston 13. To control the electromagnet 27 there is an amplifier 30 having a circuit for comparing the electric potential of the Hall sensor 31, depending on the position of the piston 13 and setting the electric device 32. When moving the piston 13, the spring 18 is compressed, compressing the spring 20, which is compressed by an amount proportional to the stroke of the piston 13 with a conversion coefficient equal to the ratio of the stiffnesses of the springs 18 and 20. A permanent magnet 22 fixed to the same value moves the washer 19, and accordingly, the electric potential of the Hall sensor 31 changes.

The axial piston machine according to the claimed solution has smaller overall dimensions. Because the Hall sensor 31 is not affected by the working medium and pressure, it is more reliable in operation, and there is no problem of sealing contact elements of electrical connections. In addition, the springs 18 and 20 can be used to remove the pumping unit from the zero working volume, and they also perform the function of tracking and contactless conversion of the piston stroke into an electrical signal.

The fulfillment of several functions by the springs 18 and 20 simultaneously allows to simplify the design of the machine, as it is not required to introduce additional structural elements into the machine that perform the above functions.

The inventive machine operates as follows.

The machine functionally consists of two nodes: the pumping node and the regulation mechanism.

The pumping unit consists of a shaft 3 with bearings 2 and an inclined block 8 with pistons 5 rotating on the central axle 6, a distributor 9, kinematically connected with the piston 13.

The regulation mechanism is designed to change the working volume of the axial piston machine by changing the angle of inclination of the block 8 to the axis of the shaft 3.

The control mechanism includes a piston 13, a pin 14, which enters the hole 15 of the distributor 9 and is installed transversely in the piston 13. The piston 13 is installed in the cylinders 16 and 17 of the housing 10 of the control mechanism. The cylinders 16 and 17 are located on opposite sides of the finger 14.

In the neutral position of the hydraulic distributor 26, the pressure forces acting on the piston 13 are equal. During operation, changing the position of the hydraulic distributor 26 leads to a change in pressure in the cylinder 17 with a larger diameter, the ratio of forces on the piston 13 changes, which causes the latter to move. When moving the piston 13 associated with the distributor 9 with the finger 14, there is a change in the angle of inclination of the block 8 to the axis of the shaft 3 and a change in the working volume of the machine.

In the process of moving the piston 13, the stress state of the spring 18 and 20 changes. When the state of the spring 20 changes, the magnetic field changes near the Hall sensor 31, which reacts to this change in the magnetic field and accordingly changes its output electrical signal.

Claims (1)

An axial piston machine with a control piston stroke converter comprising a pumping unit and a control mechanism with a piston for controlling the position of the pumping unit, characterized in that the control piston drive converter comprises a Hall sensor mounted above the control piston between the control mechanism body or another stop rigidly connected with the control mechanism housing and the control piston, two springs are installed in series: the first spring of greater stiffness and the second spring of lower stiffness, installed between the first spring and the control piston, the control piston travel transducer also comprises a permanent magnet connected to the first spring with the possibility of coordinated movement of the first spring and the permanent magnet.