RU74428U1 - GEAR PUMP (OPTIONS) - 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 expand the functionality of the gear pump. The gear pump is equipped with a flow divider, made in the form of or equipped with an additional flow regulator with a rotor with the possibility of axial movement, made with a group of segment grooves with central angles that vary along the length of the groove. The cavities of the flow controller are connected to the supply channel connected to the pump and to the consumer connection channels. In a single-flow pump, the consumer pressure line has adjustable parameters of the flow of working fluid. In two-flow, the following options are possible: the first - when both pressure lines of consumers have adjustable parameters of the flow of working fluid and the second - with constant parameters of the flow of working fluid of the pressure line of one, and adjustable parameters of the flow of working fluid of the pressure line of the second consumer. The gear pump can be equipped with a three-, four-flow flow divider with appropriate structural study. The proposed technical solution provides smooth control of the pump fluid flow parameters along the pressure pipelines of consumers, and, accordingly, expand the functionality of the gear pump. 2 s.p. f-ly, 4 z.p. f-ly, 21 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 gear pump containing a housing, gears mounted on shafts, forming a cavity of low and high pressure, and a valve made in the form of two channels in the shafts, with axes oriented perpendicular to the axis of the shafts and each other, the pressure line of each consumer is connected through a channel a shaft and a central channel formed in the cover of the pump housing with a high-pressure cavity of the pump [1].

The known pump provides operation in a dual-flow pump mode, realizing the possibility of using in twin-engine drives with synchronous movement of the working bodies.

A disadvantage of the known gear pump is its limited functionality. This is due to the fact that the well-known gear pump can work with only two, and no more, consumers.

A gear pump is known, comprising a housing, a drive shaft, gears forming cavities, a flow divider with a rotor mounted in a sliding bearing, capable of rotation from the pump shaft and equipped with a cavity connected to the supply channel with a pressure source, and the outlet channels of the flow divider, periodically, with channels for connecting consumers [2].

The known gear pump is closest to both versions of the claimed technical solution for the combination of essential features and is selected as a prototype. It implements the possibility of using in multi-motor drives with simultaneous movement of the working bodies, providing work in the multi-threaded pump mode.

A disadvantage of the known gear pump is its limited functionality. This is because the gear pump, working in the circuits of several consumers, does not provide the ability to control the parameters of the flow of the working fluid of the pump along the pressure lines of consumers.

The problem solved by the utility model is to expand the functionality of the gear pump, the technical result in this case, in comparison with the prototype, will be expressed in the possibility of regulating the parameters of the flow of the pump fluid along the pressure lines of consumers.

The solution to this problem is achieved by the fact that in the first embodiment, the gear pump contains a housing, a drive shaft, gears forming cavities, a flow divider with a rotor mounted in a sliding bearing, capable of rotation from the pump shaft and equipped with a cavity connected by a supply channel to a pressure source and outlet channels of the flow divider, periodically, with consumer connection channels. In this case, the flow divider is made in the form of a fluid flow regulator, the rotor is mounted with the possibility of axial movement and is fixed in the extreme position by means of a spring, and with its end face it forms an end control cavity, on the forming surface of the rotor is made a group of longitudinal segment grooves evenly spaced along the forming surface , the central angle of each of which varies along the length of the groove, increasing from the minimum value at the periphery to the maximum at the center of the rotor, with cavities, nnym by annular grooves in the outer and inner surfaces of the sliding bearing and the feeding channel flow controller in the pump housing with the discharging

pump channel, and on the forming surface of the sliding bearing - two groups of channels evenly spaced along the forming surface and offset relative to each other along the angle and length of the sliding bearing so that one group of channels is located in the initial position of the rotor in the minimum zone, and the second in the zone of maximum values of the central angles of the segment grooves. In this case, the outlet channel of the pump can be connected to the inlet channel of the flow regulator, and one outlet channel of the flow regulator can be connected to the driving channel of the pump.

In the second embodiment of the proposed technical solution, the gear pump comprises a housing, a drive shaft, gears forming cavities, a flow divider with a rotor installed in a sliding bearing, capable of rotation from the pump shaft and equipped with a cavity connected by a supply channel to a pressure source and outlet channels of the flow divider , periodically, with channels connecting consumers. Moreover, the gear pump is additionally equipped with a fluid flow regulator, including a flow regulator rotor, connected to the pump shaft, mounted with the possibility of axial movement and fixed in the extreme position by means of a spring, and the flow regulator rotor forming an end control cavity with its end face, and made on its generatrix surface a group of longitudinal segment grooves evenly spaced along the generatrix surface, the central angle of each of which varies along the length of the groove, increase ranging from a minimum value at the periphery to a maximum value in the center of the rotor of the flow regulator, with cavities connected by annular grooves on the outer and inner surfaces of the sliding bearing and the inlet channel of the flow regulator in the pump housing with the outlet channel of the pump, and two on the generatrix surface of the sliding bearing channel groups

evenly spaced along the generatrix surface and offset relative to each other by the angle and length of the sliding bearing in such a way that one group of channels is located in the initial position of the rotor in the zone of minimum, and the second in the zone of maximum values of the central angles of the segment grooves.

In this case, according to option 2, with a dual-flow gear pump of variable capacity, the discharge channel of the pump can be connected to the supply channel of the flow regulator, one output channel of the flow controller is connected to the supply channel of the pump, and the second output channel of the flow controller is connected to the supply channel of the flow divider. And for a gear pump according to option 2 with a two-flow pump with constant parameters of the flow rate of the working fluid of the pressure line of one, and the adjustable flow rate of the working fluid of the pressure line of the second consumer, the pump discharge channel can be connected to the feed channel of the flow divider, one discharge channel of the flow divider is connected to the channel connecting the consumer, the second outlet channel of the flow divider is connected to the inlet channel of the flow regulator, and one outlet channel of the flow regulator is connected to the inlet by the channel of the pump.

The gear pump according to 1 or 2 variant may contain a rotor, additionally equipped with longitudinal grooves made in segment grooves.

The gear pump according to embodiment 1 is characterized in that the flow divider is made in the form of a fluid flow regulator, including a flow regulator rotor, connected to the pump shaft, axially mounted and fixed in the extreme position by means of a spring, and the flow regulator rotor forms an end rotor with its end face a control cavity, and on its forming surface, a group of longitudinal segment grooves is made evenly spaced along the forming surface, the central angle of each

the segment groove varies along the length of the groove, increasing from the minimum value on the periphery to the maximum in the center of the rotor of the flow regulator, with cavities connected by annular grooves on the outer and inner surfaces of the sliding bearing and inlet channel of the flow regulator in the pump casing with the pump outlet channel, and on the forming surface of the sliding bearing - two groups of channels evenly spaced along the forming surface and offset relative to each other in angle and length of the bearing Thus, one group of channels is located in the initial position of the rotor in the zone of minimum, and the second in the zone of maximum values of the central angles of the segment grooves. In this case, the outlet channel of the pump can be connected to the inlet channel of the flow regulator, and one outlet channel of the flow regulator can be connected to the driving channel of the pump.

The gear pump according to option 2 is characterized in that it is additionally equipped with a fluid flow regulator, including a flow regulator rotor, connected to the pump shaft, mounted with axial movement and locked in the extreme position by means of a spring, and the flow regulator rotor with its end face forming an end control cavity and on its forming surface a group of longitudinal segment grooves is made evenly spaced along the forming surface, the central angle of each segment groove varies along the length of the groove, increasing from the minimum value at the periphery to the maximum in the center of the rotor of the flow regulator, with cavities connected by annular grooves on the outer and inner surfaces of the sliding bearing and the inlet channel of the flow regulator in the pump housing with the outlet channel of the pump, and on the generatrix sliding bearing surfaces - two groups of channels evenly spaced along the generatrix surface and

offset relative to each other in the angle and length of the sliding bearing so that one group of channels is located in the initial position of the rotor in the minimum zone, and the second in the zone of maximum values of the central angles of the segment grooves. In this case, according to the variant with a dual-flow gear pump of variable capacity, the discharge channel of the pump can be connected to the supply channel of the flow controller, one output channel of the flow controller is connected to the supply channel of the pump, and the second output channel of the flow controller is connected to the supply channel of the flow divider. And for a gear pump according to the variant with a two-flow pump with constant parameters of the flow rate of the working fluid of the pressure line of one, and adjustable flow rates of the working fluid of the pressure line of the second consumer, the pump discharge channel can be connected to the feed channel of the flow divider, one output channel of the flow divider is connected to the connection channel consumer, the second outlet channel of the flow divider is connected to the inlet of the flow regulator, and one outlet channel of the flow regulator is connected to the inlet m pump channel.

The gear pump according to 1 or 2 variant may contain a rotor, additionally equipped with longitudinal grooves - made in segment grooves.

Significant distinguishing features of the proposed technical solutions for both options provide smooth control of the parameters of the pump fluid flow along the pressure lines of consumers, and, accordingly, expand the functionality of the gear pump.

Figure 1 shows a section along the plane of the shafts of a single-flow gear pump;

figure 2 is a hydraulic diagram of a single-flow gear pump;

figure 3 is a section aa in figure 1;

figure 4 is a section bB in figure 1;

figure 5 is a section bb in figure 1;

in Fig.6 is a section GG in Fig.1;

in Fig.7 is a section DD in Fig.1;

on Fig - section along the plane of the shafts of the dual-flow pump gear with adjustable parameters of the flow rate of the working fluid of the pump;

figure 9 is a hydraulic diagram of a dual-flow gear pump with adjustable parameters of the flow rate of the pump fluid;

figure 10 is a section EE in figure 8;

in Fig.11 - section FJ in Fig.8;

in Fig.12 is a section 3-3 in Fig.8;

on Fig - section II in Fig;

on Fig - section KK on Fig;

on Fig - section LL in Fig;

on Fig - section MM in Fig;

on Fig - section along the plane of the shafts of the dual-flow gear pump with constant flow rate of the working fluid of the pressure line of one, and adjustable flow rate of the working fluid of the pressure line of the second consumer;

in Fig.18 is a hydraulic diagram of a dual-flow gear pump with constant flow rate parameters of the working fluid of the pressure line of one, and adjustable flow rate parameters of the working fluid of the pressure line of the second consumer;

in Fig.19 is a section HH in Fig.17;

in Fig.20 is a section OO in Fig.17;

on Fig - section PP in Fig.

The gear pump comprises a housing 1, gears 2, 3 formed on the drive 4 and driven 5 shafts. Shafts 4, 5 are mounted in bearings

sliding 6, 7 of the housing 1. Gears 2, 3 form the cavity of low 8 and high 9 pressure. The low pressure cavity 8 is connected to the hydraulic tank (not shown) through the supply channel 10 of the housing 1.

The gear pump according to the first embodiment is equipped with a flow divider made in the form of a flow regulator for the working fluid, including a rotor 11 of the flow regulator installed in the sliding bearing 12 of the housing 1 coaxially with the pump shaft 4. The rotor 11 of the flow controller is connected to the shaft 4 by means of a spline connection and mounted with the possibility of axial movement, and in the extreme position it is fixed by means of a spring 13. The rotor 11 of the flow controller with its end forms an end control cavity 14.

On the forming surface of the rotor 11 of the flow regulator, a group of longitudinal segment grooves 15 is made uniformly spaced along the forming surface. The central angle of each segment groove 15 varies along the length of the groove, increasing from a minimum value at the periphery to a maximum in the center of the rotor 11 of the flow regulator. To increase the bore sections of the segment grooves 15, the rotor 11 can be additionally equipped with longitudinal grooves 16. The cavities of the segment grooves 15 are connected by annular grooves 17, 18, on the inner and outer surfaces of the sliding bearing 12, channels 19, with the inlet channel 20 of the flow regulator in the housing 1 .

On the inner forming surface of the sliding bearing 12 of the flow controller, two groups of channels 21, 22 are formed, evenly spaced along the forming surface. The groups of channels 21, 22 are offset relative to each other in angle and the length of the sliding bearing 12, so that the group of channels 21 is located in the initial position of the rotor 11 in the zone of minimum, and the group of channels 22 is in the zone of maximum values of the central angles of the segment grooves 15. The cavity of the channels 21, 22 are combined in groups by annular grooves 23, 24,

made on the outer surface of the sliding bearing 12, and are connected with the discharge channels 25, 26 of the flow controller in the pump housing 1.

The gear pump according to the second embodiment (see Fig. 8, Fig. 17) is made two-flow and, in addition to the flow rate controller, is also equipped with a pump fluid flow divider, including a rotor 27 installed in the sliding bearing 12 of the pump housing 1. The rotor 27 is connected to the shaft 4 by means of a spline connection. On the outer forming surface of the rotor 27, a group of longitudinal grooves 28 is made, the cavities of which are connected with the cavities of the annular grooves 29, 30 formed on the inner and outer surfaces of the sliding bearing 12, interconnected by channels 31. The cavity of the annular groove 30 is connected to the inlet channel 32 of the divider pump fluid flow in pump housing 1.

On the inner surface of the sliding bearing 12, groups of channels 33, 34 are formed. The cavities of the groups of channels 33, 34 are connected with the cavities of the annular grooves 35, 36 made on the outer surface of the sliding bearing 12 and the outlet channels 37, 38 of the pump fluid flow divider in the housing 1 pump.

Longitudinal grooves 28, channels 33, 34 in groups are evenly distributed around the circles. Channels 33, 34 of the groups are offset relative to each other by the calculated angle. The number of longitudinal grooves 28 and channels 33, 34 in the groups is the same.

The pump housing 1 is equipped with a drainage system 39.

In the first embodiment, in a single-threaded gear pump of variable capacity (see FIGS. 1, 2), the high-pressure cavity of pump 9 is connected through a channel 40 of the housing 1, a pipe 41 with a supply channel 20 of the flow regulator. The outlet channel 25 of the flow controller is connected by a pipe 42 to the inlet channel 10 of the pump, and the channel 43 in

pipeline 42 connecting the pump to the hydraulic tank (not shown). The discharge channel 26 of the flow controller is connected to the consumer circuit.

In the second embodiment, in a dual-flow gear pump of variable capacity (see Figs. 8, 9), the high-pressure cavity of the pump 9 is connected through a channel 40 of the housing 1, a pipe 41 to a supply channel 20 of the flow regulator. The discharge channel 25 of the flow controller is connected by a pipe 42 to the pump inlet 10, and a channel 43 in the pipe 42 connecting the pump to the hydraulic tank (not shown). The outlet channel 26 of the flow controller is connected by a pipe 44 to the inlet channel 32 of the flow divider. The outlet channels 37, 38 of the flow divider are connected to the connection channels of two consumers.

In the second embodiment, in a two-flow pump with constant parameters of the flow rate of the working fluid of the pressure line of one, and adjustable flow rates of the working fluid of the pressure line of the second consumer (see Fig. 17), the high-pressure cavity of the pump 9 is connected through the channel 40 of the housing 1, the pipeline 41 to the supply channel 32 stream dividers. The outlet channel 38 of the flow divider is connected to the consumer connection channel. The outlet channel 37 of the flow divider is connected by a pipe 44 to the inlet channel 20 of the flow controller. The discharge channel 25 of the flow controller is connected by a pipe 42 to the pump inlet 10, and a channel 43 in the pipe 42 connecting the pump to the hydraulic tank (not shown). The discharge channel 26 of the flow controller is connected to the consumer connection channel.

The gear pump operates as follows.

When the pump is operating, the gear shaft 4 rotates from the engine (not shown), and drives the gears 2, 3. The rotors 11 of the flow controller and 27 of the flow divider are driven from the shaft 4 through a spline connection.

The working fluid through the channels 43, 10 comes from the tank of the hydraulic system

into the low-pressure cavity 8. Further, the liquid in the cavities of the gears 2, 3 is transferred to the high-pressure cavity 9.

In a single-flow gear pump (see Fig. 1), the working fluid from the cavity 9 through the channel 40, pipeline 41, channel 25 of the housing 1 enters the cavity of the annular groove 18 of the flow regulator. From the cavity of the annular groove 18 through the channels 19, the fluid enters the cavity of the annular groove 17 of the rotor 11, and then into the cavity of the segment grooves 15 and the longitudinal grooves 16.

The working fluid from the cavities of the segment grooves 15 periodically flows to the groups of channels 21, 22 of the sliding bearing 12. From the cavities of the channels of the groups 21, 22, the working fluid enters the annular grooves 23, 24 on the outer surface of the sliding bearing 12, and then into the channels 25, 26 pump housing 1. From the channel 26, the working fluid enters the pressure line of the consumer, and from the channel 25, through the pipe 42 to drain into the hydraulic tank (not shown).

In the initial position of the rotor 11 of the flow controller, the control cavity 14 is connected to the drain, and the rotor 11, pressed by the spring 13, is in the extreme right position. The central angle of the segment groove 15 in the zone of the channel 21 is zero, and in the zone of the channel 22 it is maximum (360 °), and the entire pump fluid flow is directed through the channels 22 into the annular groove 24, the channel 26 for connecting the consumer pressure line. The gear pump provides the maximum flow rate of the working fluid to the consumer pressure line.

To reduce the flow of working fluid in the pressure line of the consumer in the control cavity 14 is supplied with a working fluid. The rotor 11 moves (to the left in the drawing), deforming the spring 13. When the desired position is reached, the cavity 14 is locked. In this case, the working fluid from the cavities of the segment grooves 15 periodically enters the channels 21, 22. The flow rate of the working fluid is proportional to

the Central angle of the segment groove 15 in the area of this channel. The flow of the working fluid through the channels 21 enters the cavity of the annular groove 23, and, through the channel 25, the pipe 42, the channel 10 into the low-pressure cavity 8. The flow of the working fluid entering through the channels 22, the annular groove 24, the channel 26 into the consumer pressure line decreases.

When the rotor 11 is moved to the extreme left position, the central angle of the segment groove 15 in the zone of the channel 22 is zero, and in the zone of the channel 21 it is maximum (360 °), and the entire pump fluid flow is directed through the channels 21 into the annular groove 23, channel 25, pipeline 42, channel 10 into the low-pressure cavity 8. The gear pump provides a minimum (zero) flow rate of the working fluid to the consumer pressure line.

Drainage 39 provides a reduction in resistance to movement of the rotor 11 of the flow controller.

The design scheme allows you to change the algorithm of the pump. So, by connecting channel 25 to the consumer circuit and channel 26 to drain into the tank, an operating algorithm is achieved in which the pump in the initial position provides zero flow, and when the fluid is supplied to the control cavity, the pump flow increases.

In a dual-flow gear pump of variable capacity (see Fig. 8), the fluid flow of the pump is directed through channels 22 into the annular groove 24, channel 26, pipe 44 into the inlet channel 32 of the flow divider. From the cavity of the channel 32, the working fluid enters the cavity of the annular groove 30, and then, through the channels 31 into the cavity of the annular groove 29, and the cavity of the longitudinal grooves 28 of the rotor 27 of the flow divider. From the cavities of the longitudinal grooves 28, the working fluid periodically flows to the groups of the longitudinal channels 33, 34 of the sliding bearing 12. From the cavities of the channels of the groups 33, 34, the working fluid flows into the annular grooves 35, 36 on the outer surface of the sliding bearing 12, and then into the channels 37, 38 connection of pressure lines of two consumers.

When changing the position of the rotor 11 of the flow controller by changing the volume of the control cavity 14, the gear pump feed changes, and the resulting flow of the working fluid with the given characteristics is divided into two flow divider.

The gear pump can be equipped with a three-, four-threaded flow divider with an appropriate design study.

In a two-flow gear pump with constant flow rate of the working fluid of the pressure line one, and adjustable flow rate of the second consumer (see Fig. 17), the pump fluid from the cavity 9 through channel 40, the pipeline 41 enters the receiving channel 32 of the flow divider, and further, into the cavity of the annular groove 30. From the cavity of the annular groove 30, the working fluid through the channels 31 enters the cavity of the annular groove 29. and the cavity of the longitudinal grooves 28 of the rotor 27 of the flow divider. From the cavities of the longitudinal grooves 28, the working fluid periodically flows to the groups of the longitudinal channels 33, 34 of the sliding bearing 12. From the cavities of the channels of the groups 33, 34, the working fluid flows into the annular grooves 35, 36 on the outer surface of the sliding bearing 12, and then into the channels 37, 38 of the housing 1. From the cavity of the channel 38, the working fluid enters the pressure line of the consumer. The flow of the working fluid is characterized by constant flow rate of the working fluid. From the cavity of the channel 37, the working fluid through the pipe 44 enters the inlet channel 20 of the flow regulator, and then, into the cavity of the annular grooves 18, 17. From the cavity of the annular groove 17, the working fluid enters the cavity of the segment grooves 15 and longitudinal grooves 16.

The working fluid from the cavities of the segment grooves 15 periodically flows to the groups of channels 21, 22 of the sliding bearing 12. From the cavities of the channels of the groups 21, 22, the working fluid enters the annular grooves 23, 24 on the outer surface of the sliding bearing 12, and then into the channels 25,

26 pump housing 1. From the channel 26, the working fluid enters the pressure line of the consumer, and from the channel 25, through the pipe 42 to drain into the hydraulic tank (not shown). When changing the position of the rotor 11 of the flow controller by changing the volume of the control cavity 14, the flow rate of the working fluid into the pressure line of the consumer.

The flow of the working fluid of the gear pump is divided into two, with constant and variable flow characteristics along the pressure pipelines of consumers.

The use of a flow regulator provides smooth control of the flow rate of the working fluid along the pressure lines of consumers, thus expanding the functionality of the gear pump.

The pump supplies the working fluid to the pressure lines of two consumers periodically, in small discrete portions. This ensures that the flow rate of the working fluid along the pressure pipelines of consumers from their loading modes. In each pressure line for one revolution of the rotors 11, 27 four, five servings of the working fluid are supplied. The number of servings of working fluid per revolution of the cylinder block is determined by the number of segment grooves 15, longitudinal grooves 28 and channels 21, 22, 33, 34 in each group formed in the sliding bearing 12. Equal numbers of segment grooves 15 and channels 21, 22 in the rotor groups 11, longitudinal grooves 28 and channels 33, 34 in each group provides the maximum flow area of the lines, and the minimum resistance to the flow of the working fluid in the flow regulator and flow divider.

Thus, the proposed technical solution provides smooth control of the flow parameters of the pump fluid along the pressure lines of consumers, and, accordingly, expand the functionality of the gear pump.

Sources of information taken into account when filling out the application:

1. Gear pump: patent of the Republic of Belarus for utility model No. 1930, class. IPC 7 F15B 11/22; publ. 06/30/05 // Afitsyiny bulletin / Natsiyanalny tsentr iintel'tsual'nyi ulasnaststi / - 2005. - №2. - S.198.

2. Gear pump: patent of the Republic of Belarus for utility model No. 2772, cl. IPC 7 F15B 11/22, F04C 2/04; publ. 06/30/06 // Afitsyiny bulletin / Natsiyanalny tsentr iintelyshentalny ulasnaststi / - 2006. - №3. - S.199.

Claims (6)

1. A gear pump containing a housing, a drive shaft, gears forming cavities, a flow divider with a rotor mounted in a sliding bearing, capable of rotation from the pump shaft and equipped with a cavity connected to the supply channel with a pressure source, and the outlet channels of the flow divider periodically with channels for connecting consumers, characterized in that the flow divider is made in the form of a regulator for the flow of working fluid, the rotor is mounted with the possibility of axial movement and is fixed in the extreme position by means of a spring, and with its end face it forms an end control cavity, on the forming surface of the rotor is made a group of longitudinal segment grooves evenly spaced along the forming surface, the central angle of each of which varies along the length of the groove, increasing from the minimum value at the periphery to the maximum at the center of the rotor, with cavities connected by means of annular grooves on the outer and inner surfaces of the sliding bearing and the inlet channel of the flow regulator in the pump housing with a discharge chamber pump, and on the forming surface of the sliding bearing - two groups of channels evenly spaced along the forming surface and offset relative to each other along the angle and length of the sliding bearing so that one group of channels is located in the initial position of the rotor in the minimum zone, and the second in the zone of maximum values of the central angles of the segment grooves. 2. The gear pump according to claim 1, characterized in that the outlet channel of the pump is connected to the inlet channel of the flow controller, and one outlet channel of the flow controller is connected to the driving channel of the pump. 3. A gear pump, comprising a housing, a drive shaft, gears forming cavities, a flow divider with a rotor mounted in a sliding bearing, which can be rotated from the pump shaft and equipped with a cavity connected by a supply channel to a pressure source, and the discharge channels of the flow divider periodically with channels for connecting consumers, characterized in that the gear pump is additionally equipped with a flow rate regulator, including a flow regulator rotor, connected to the pump shaft, installed with the possibility of axial movement and in the extreme position is fixed by means of a spring, and the rotor of the flow regulator forms an end control cavity with its end face, and on its forming surface there is a group of longitudinal segment grooves evenly spaced along the forming surface, the central angle of each of which varies along the length of the groove, increasing from the minimum value at the periphery to the maximum at the center of the rotor of the flow regulator, with cavities connected by means of annular grooves on the outer and the surface of the sliding bearing and the inlet channel of the flow regulator in the pump housing with the outlet channel of the pump, and on the forming surface of the sliding bearing - two groups of channels uniformly spaced along the forming surface and offset relative to each other in angle and length of the sliding bearing so that one group channels is located in the initial position of the rotor in the zone of minimum, and the second in the zone of maximum values of the central angles of the segment grooves. 4. The gear pump according to claim 1 or 3, characterized in that the rotor of the flow regulator is additionally equipped with longitudinal grooves made in segment grooves. 5. The gear pump according to claim 3, characterized in that the outlet channel of the pump is connected to the inlet of the flow regulator, one outlet channel of the flow regulator is connected to the inlet of the pump, the second outlet channel of the flow regulator is connected to the inlet of the flow divider. 6. The gear pump according to claim 3, characterized in that the outlet channel of the pump is connected to the inlet channel of the flow divider, one outlet channel of the flow divider is connected to the consumer connection channel, the second outlet channel of the flow divider is connected to the inlet channel of the flow regulator, and one outlet channel the flow regulator is connected to the inlet of the pump.