RU66448U1 - AXIAL PISTON HYDRAULIC MACHINE - Google Patents

Abstract

The utility model relates to hydraulic engineering and can be used in a volumetric hydraulic drive of machines to synchronize the movement of executive bodies.

The problem solved by the utility model is to increase the reliability of the axial piston hydraulic machine

The axial piston hydraulic machine contains a shaft, a cylinder block mounted on the outer forming surface in the sliding bearing, pistons interacting with the inclined washer, forming working cavities connected by radial channels in the cylinder block with cavities of half-ring grooves made on the forming surface of the sliding bearing, connected with inlet and outlet channels of the housing, and the hydraulic machine is additionally equipped with a divider - flow adder, including a group of longitudinal grooves, uniformly executed data on the outer forming surface of the cylinder block, interconnected by an annular groove that is connected through the channel and the groove in the sliding bearing and through the channels in the body of the hydraulic machine with the outlet channel, groups of longitudinal channels - one group per circuit of each consumer, with the number of channels in each a group equal to the number of longitudinal grooves of the cylinder block uniformly made within each group along the inner surface of the sliding bearing, and the groups of longitudinal channels are offset relative to each other Line sliding bearing and a corner and are connected with channels connecting consumers, formed in the housing of the hydraulic machine, as well as cyclic groups of cavities are communicated with longitudinal grooves during rotation of the cylinder block. 1 n.p. f-ly, 11 ill.

Description

The utility model relates to hydraulic engineering and can be used in a volumetric hydraulic drive of machines to synchronize the movement of executive bodies.

Known axial piston hydraulic machine containing a drive shaft installed in the bearing assemblies in the housing of the hydraulic machine, and a cylinder block connected to it by means of a spline connection, pistons interacting with an inclined hydraulic machine washer, forming working cavities connected by channels in the cylinder block with the cavities of the groups of semicircular grooves of the hydraulic distributor connected to the inlet and outlet channels [1].

The well-known hydraulic machine has wide functionality due to the use of multi-motor drives of the working bodies without the use of additional hydraulic units for dividing the flow of the working fluid.

A disadvantage of the known hydraulic machines is the low reliability. This is due to the fact that when the axial piston hydraulic machine is operated with high loads, the working fluid pressure increases in the working cavities of the hydraulic machine, which leads to an increase in the flow of working fluid in the mating zone: cylinder block - support and distribution disk. The volumetric efficiency of the hydraulic machine is reduced. An increase in the stiffness of the spring pressing the cylinder block against the support and distribution disk, along with the possibility of improving the seal, leads to increased wear and loss of seal density.

Known axial piston hydraulic machine containing a shaft and a cylinder block mounted on the outer forming surface in

the sliding bearing of the hydraulic machine housing, pistons interacting with the inclined washer of the hydraulic machine, forming working cavities connected by channels in the cylinder block with cavities of half-ring grooves made on the forming surface of the sliding bearing, connected to the inlet and outlet channels of the hydraulic machine housing [2].

The well-known axial piston hydraulic machine has wide functionality due to the provision of several flows, the use of multi-motor drives of the working bodies without the use of additional hydraulic units for dividing the flow of the working fluid. The use of an axial-piston hydraulic control valve according to the shaft-sleeve design provides increased reliability of the hydraulic machine at high loads due to efficient sealing of the mating surfaces of the cylinder block and hydraulic control valve, reduction of overflows from the high pressure zone, and increase in volumetric efficiency of the hydraulic machine.

A disadvantage of the known axial piston hydraulic machines is the low reliability. This is because the hydraulic machine, working in the circuits of several consumers, does not provide the necessary degree of uniformity of the supply of working fluid. So, uniformity is determined by the number of cylinders of the hydraulic machine, and the number of consumer circuits. With a given number of cylinders, an increase in the number of consumer circuits leads to an increase in the degree of unevenness of the supply of working fluid to the pressure lines of consumers. The pulsation of the flow rate of the working fluid increases the dynamic loading of the hydraulic machine parts, and reduces the reliability of the axial piston hydraulic machine.

The task to which the utility model is directed is to increase the reliability of the axial piston hydraulic machine.

The solution to this problem is achieved by the fact that the axial-piston hydraulic machine containing a shaft, a cylinder block mounted on the outer forming surface in the sliding bearing of the hydraulic machine housing, pistons interacting with an inclined washer of the hydraulic machine, forming working cavities connected by radial channels in the cylinder block with cavities of semi-rings grooves made on the outer forming surface of the sliding bearing, connected to the inlet and outlet channels of the hydraulic machine housing, is additionally equipped the divider is a flow adder, including a group of longitudinal grooves uniformly made on the outer forming surface of the cylinder block, interconnected by an annular groove, the annular groove connected through a channel and a groove in the sliding bearing and through channels in the housing of the hydraulic machine with the outlet channel of the hydraulic machine, a group of longitudinal channels , - one group per circuit of each consumer, with the number of channels in each group equal to the number of longitudinal grooves of the cylinder block uniformly made within each group according to the inner surface of the sliding bearing, and the groups of longitudinal channels are displaced relative to each other along the length of the sliding bearing and the angle, are connected to consumer channels formed in the housing of the hydraulic machine, and are cyclically communicated with the cavities of the groups of longitudinal grooves during rotation of the cylinder block.

What is new is that the hydraulic machine is additionally equipped with a divider - flow adder, including a group of longitudinal grooves uniformly made on the outer forming surface of the cylinder block, interconnected by an annular groove, and the annular groove is connected through a channel and a groove in the sliding bearing and through channels in the housing hydraulic machines with a discharge channel hydraulic machines, groups of longitudinal channels, one group per circuit

each consumer, with the number of channels in each group equal to the number of longitudinal grooves of the cylinder block, uniformly made within each group along the inner surface of the sliding bearing, and the groups of longitudinal channels are offset relative to each other along the length of the sliding bearing and the corner, connected with the consumer connection channels, formed in the body of the hydraulic machine, and also cyclically communicate with the cavities of the groups of longitudinal grooves during rotation of the cylinder block.

The proposed technical solution allows to reduce the unevenness of the supply of the working fluid along the consumer circuits by increasing the number of servings of the working fluid supplied to the pressure line of each consumer for one revolution of the axial piston hydraulic machine shaft, while reducing the volume of each portion. Reducing the pulsation of the flow rate of the working fluid reduces the dynamic loads of the parts, and, accordingly, increases the reliability of the axial piston hydraulic machine.

Figure 1 presents a longitudinal section of a two-line axial-piston hydraulic machine; figure 2 is a section aa in figure 1; figure 3 is a section bB in figure 1; figure 4 is a section bb in figure 1; figure 5 section GG in figure 1; figure 6 is a section DD in figure 1; in Fig.7 is a section EE in Fig.1; on Fig presents a longitudinal section of a three-line axial-piston hydraulic machine; in Fig.9 - section FJ in Fig.8; figure 10 is a section ZZ in figure 8; figure 11 is a section II in figure 8.

The axial piston hydraulic machine includes a drive shaft 1 installed in the bearing assembly 2 of the hydraulic machine housing 3, a cylinder block 4 connected by a spline connection 5 to the shaft 1. The cylinder block 4 is mounted on the outer forming surface in the sliding bearing 6 of the hydraulic housing 3, and is supported by thrust roller bearing 7 mounted on the cover 8 of the housing 3.

The pistons 9 form the working cavity 10. The cylinder block 4 is spring 11 and the pressure of the working fluid is pressed against the thrust rolling bearing 7.

The pistons 9 are pressed against the surface of the inclined washer 12 with the help of bronze shoes 13, rolled on their spherical heads, a pressure disk 14, a spherical sleeve 15 and a spring 11.

In the axial piston hydraulic machine, the working cavities 10 are connected by means of radial channels 16 in the cylinder block with cavities of half-ring grooves 17, 18, made on the forming surface of the sliding bearing. The cavity of the semi-annular grooves 17, 18 are connected with the supply 19 and the 20 channels of the working fluid in the working cavity 10 of the hydraulic machine. The channel 19 of the hydraulic machine is inlet when the hydraulic machine is in pump mode, and the outlet when the hydraulic machine is in hydraulic mode.

The flow divider includes an annular groove 21 made on the outer forming surface of the cylinder block 4, the cavity of which is connected to the outlet channel 20 of the hydraulic machine through a pipe 22, a channel 23 made in the housing 3 of the hydraulic machine, an annular groove 24, and channels 25 made in a sliding bearing 6. On the outer forming surface of the cylinder block 4, a group of evenly spaced longitudinal grooves 26 is made, interconnected by an annular groove 21.

On the forming surface of the sliding bearing 6, groups of 27, 28, 29 longitudinal channels are formed. The cavities of the groups 27, 28, 29 of the longitudinal channels are connected respectively with the cavities of the annular grooves 30, 31, 32, made on the outer surface of the sliding bearing 6, and with the channels 33, 34, 35 connecting consumers formed in the housing of the hydraulic machine.

Longitudinal grooves 26, longitudinal channels in groups 27, 28, 29 are evenly distributed around the circles. Groups 27, 28, 29 longitudinal

channels are offset relative to each other by the calculated angle. The number of longitudinal grooves 26 is equal to the number of longitudinal channels in each group 27, 28, 29.

Axial piston hydraulic machine operates as follows.

When the axial-piston hydraulic machine is in pump mode, the shaft 1 rotates from the engine (not shown), and drives the cylinder block 4 by means of a spline connection 5. The pistons 9 reciprocate in the cylinder block 4.

When the pistons 9 are extended from the cylinder block 4, the volumes of the working cavities 10 increase. The fluid through the channel 19 enters the cavity of the semicircular groove 17, and through the radial channels 16 into the working cavity 10 of the cylinder block 4.

When the pistons 9 move inside the cylinder block 4, the working fluid through the radial channels 16 enters the cavity of the floor of the annular groove 18, and then through the channel 20 into the pipe 22. Through the pipe 22, the working fluid enters through the channel 23 into the cavity of the annular groove 24, and further, through the channels 25 - in the cavity of the annular groove 21 and the longitudinal grooves 26 of the cylinder block 4.

In a two-line hydraulic machine (see Fig. 1), the working fluid from the cavities of the longitudinal grooves 26 periodically flows to the groups of channels 27, 28 formed in the sliding bearing 6 of the divider - flow adder. From the cavity of the channels of groups 27, 28, the working fluid enters the annular grooves 30, 31 formed on the outer surface of the sliding bearing 6, and then into the channels 33, 34 connecting the pressure lines of two consumers.

In a three-flow hydraulic machine (see Fig. 8), the working fluid from the cavities of the longitudinal grooves 26 periodically flows to the groups of channels 27, 28, 29 formed in the sliding bearing 6 of the divider - flow adder. From the cavities of the channels of groups 27, 28, 29, the working fluid

enters the annular grooves 30, 31, 32, and further, in the channels 33, 34, 35 connecting the pressure lines of three consumers.

The hydraulic machine, operating in pump mode, supplies the working fluid to the pressure lines of two, three consumers periodically, in small discrete portions. This ensures the independence of the flow rate of the working fluid along the pressure lines of consumers from the modes of loading them. In each pressure line for one revolution of the rotor of the cylinder block 4 is fed five servings of the working fluid. The number of servings of the working fluid per revolution of the cylinder block is determined by the number of longitudinal channels 27, 28, 29 in each group formed in the sliding bearing 6.

The higher the degree of discretization of the flow of the working fluid, the less the degree of unevenness of the supply of working fluid along the pressure pipelines of consumers, the dynamic loading of hydraulic machine parts. The degree of discretization is not related to the number of consumers, and is set for a specific design solution of the hydraulic machine.

The number of hydraulic machine flows can be increased by the formation of additional groups of channels on the forming surface of the sliding bearing 6.

If it is necessary to use an axial piston hydraulic machine in single-threaded mode, channel 23 is closed by a plug (not shown), and channel 20 is connected to a pressure line of one consumer.

When the axial piston hydraulic machine (see Fig. 1, Fig. 8) is in the hydraulic motor mode, the working fluid from the pump (not shown) through channels 33, 34, 35, ring grooves 30, 31, 32, channel groups 27, 28, 29, cyclically enters the cavity of the longitudinal grooves 26, and the annular grooves 21, 24. From the cavity of the annular groove 24, the working fluid through the channel 23, the pipe 22 enters the cavity of the semicircular groove 18, and

further, through the channels 16 into the working cavities 10 of the cylinder block 4. The shaft 1 is rotated, and the working fluid from the cavities 10 through the radial channels 16 enters the cavity of the semicircular groove 17, and through the channel 19 to drain into the hydraulic tank. The power taken from the shaft 1 is spent on the drive of consumers.

The axial piston hydraulic machine also provides volumetric division of the flow of the working fluid, working in the hydraulic motor mode. At the outlet of the hydraulic motor, flows of working fluid with stable characteristics are formed.

Thus, the proposed technical solution reduces the unevenness of the supply of working fluid along the consumer circuits by increasing the number of servings of the working fluid supplied to the pressure line of each consumer for one revolution of the axial piston hydraulic machine shaft, while reducing the volume of each portion. Reducing the pulsation of the flow rate of the working fluid reduces the dynamic loads of the parts, and, accordingly, increases the reliability of the axial piston hydraulic machine.

Sources of information taken into account:

1. Axial piston hydraulic machine. RB patent No. 1543U dated February 18, 2004, IPC F03С 1/00, F15В 11/00. Published: Afitsyiny Bulletin No. 3 (42) 2004, p. 249.

2. Axial piston hydraulic machine. RB patent No. 2840U dated November 9, 2005, IPC, F15В 11/22. Published: Afitsyiny Bulletin No. 3 (50) 2006 p. 197.

Claims (1)

An axial piston hydraulic machine comprising a shaft, a cylinder block mounted on an outer forming surface in a sliding bearing of a hydraulic machine housing, pistons interacting with an inclined hydraulic machine washer, forming working cavities connected by radial channels in the cylinder block with cavities of half-ring grooves made on the forming surface of the bearing sliding connected to the inlet and outlet channels of the body of the hydraulic machine, characterized in that the hydraulic machine is additionally equipped with a divider-adder n current, including a group of longitudinal grooves uniformly made on the outer forming surface of the cylinder block, interconnected by an annular groove, the annular groove connected through a channel and a groove in the sliding bearing and through channels in the housing of the hydraulic machine with the outlet channel of the hydraulic machine, groups of longitudinal channels - one at a time group per circuit of each consumer, with the number of channels in each group equal to the number of longitudinal grooves of the cylinder block, uniformly made within each group on the inner surface dshipnika slip, the group of longitudinal channels are offset relative to each other along the length of the sliding bearing and a corner and are connected with channels connecting consumers, formed in the housing of the hydraulic machine, as well as cyclic groups of cavities are communicated with longitudinal grooves during rotation of the cylinder block.