CN203783998U - Hydraulic-controlfeeding system - Google Patents

Abstract

The utility model relates to a hydraulic-controlfeeding system, wherein the system comprises a hydraulic pump assembly, a first executive component, a second executive component, a pulley assembly and a feeding device; a second reversing valve is arranged on an oil way where the hydraulic pump assembly is connected with the first executive component, and the oil way between the hydraulic pump assembly and the first executive component is controlled to be connected, disconnected and reversed through the second reversing valve; a fifth reversing valveis arranged on an oil way where the hydraulic pump assembly is connected with the second executive component, and the oil way between the hydraulic pump assembly and the second executive component is controlled to be connected and disconnected through the fifth reversing valve; both the first executive component and the second executive component are connected with the feeding device through the pulley assembly, and a differential relationship can be formed between the first executive component and the second executive component. According to the system, the executive components are not required to have very high corrosion resistance, sealing performance, impact resistance and the like, pressure losses are fewer, power losses are fewer, the construction cost is lower, and stable feeding of the feeding device can be guaranteed.

Description

A kind of hydraulic control feeding system

Technical field

The utility model relates to hydraulic control field, relates in particular to a kind of hydraulic control feeding system.

Background technique

Two-wheel flute milling machine, as the most advanced equipment of underground continuous construction, is more and more applied in foundation construction, and especially, when milling hard rock, its efficiency is the more than 3 times of other equipment.Nonetheless, when milling hard rock, the drilling depth of two-wheel flute milling machine also only has half meter of left and right per hour, this just requires Double-wheel milling feed mechanism can realize very slow speed feeding, and Double-wheel milling is in the process of work, for the rock stratum of different hardness, feed mechanism will be given the different pulling force of milling attachment all the time, prevents the inclined to one side slotted eye of milling attachment milling.Therefore,, when two-wheel flute milling machine feed mechanism is had to ad hoc requirement, for the accuracy of feeding hydraulic system, high efficiency also has very high requirement.

For addressing the above problem, existing scheme adopts common elevator to add oil cylinder feeding, elevator is arranged on main frame, oil cylinder is hinged on milling attachment, elevator is connected with oil cylinder by pulley, cylinder piston rod and milling attachment are hinged, and common elevator is realized the hand hoisting of milling attachment and transferred, and oil cylinder is controlled feed speed and the downforce of milling attachment.

Adopt above-mentioned oil cylinder feeding mode, oil cylinder is invaded in mud with milling attachment, this requires very high to aspects such as the sealing of oil cylinder, corrosion protection, shock resistances, once oil cylinder infiltration, to cause whole hydraulic system to be damaged, therefore, the sealing for hydraulic system and oil cylinder has very high requirement; And the length of the fuel feeding oil pipe of oil cylinder can reach tens of rice rice even up to a hundred, and its pressure loss is larger, and power loss is larger, has increased construction cost.Simultaneously in the process of cylinder replacing stroke, the withdrawal of oil cylinder needs milling attachment to be lifted to supporting surface simultaneously, after regaining completely Deng oil cylinder, descend again releasing hoister, make milling attachment contact supporting surface, start next milling stroke, in the process of this replacing stroke, not only need to consume very large power, need long time simultaneously.Analysis it seems, this scheme exists that technical difficulty is high, cost is expensive and the problem such as power loss is large.

Model utility content

For the problems referred to above, the purpose of this utility model is to propose a kind of hydraulic control feeding system, and its sealing requirements to work feeder and hydraulic system is lower, and power consumpiton is less, and cost is lower.

For achieving the above object, the utility model provides a kind of hydraulic control feeding system, and it comprises hydraulic pump module, the first executive component, the second executive component, pulley assembly and work feeder;

On the oil circuit that described hydraulic pump module is connected with described the first executive component, be provided with the second selector valve, by described the second selector valve, control break-make and the commutation of oil circuit between described hydraulic pump module and described the first executive component;

On the oil circuit that described hydraulic pump module is connected with described the second executive component, be provided with the 5th selector valve, by described the 5th selector valve, control the break-make of oil circuit between described hydraulic pump module and described the second executive component;

Described the first executive component is all connected described work feeder by described pulley assembly with described the second executive component, between described the first executive component and described the second executive component, can form differential relation.

In a preferred or optional embodiment, under the effect of identical oil pressure, the pulling force that described the first executive component produces the wire rope in described pulley assembly is greater than the pulling force that described the second executive component produces described wire rope.

In a preferred or optional embodiment, on the oil circuit that described hydraulic pump module is connected with described the second selector valve, be provided with pressure regulating mechanism.

In a preferred or optional embodiment, described hydraulic pump module comprises the first working pump and the second working pump, described pressure regulating mechanism comprises the first selector valve, the first one-way valve and proportional pressure control valve, described the first selector valve is arranged on the oil circuit that described the first working pump is connected with described the second selector valve, the filler opening of described the first one-way valve is communicated with described the first selector valve, the oil outlet of described the first one-way valve is communicated with the oil circuit between described the second working pump and described the second selector valve, the filler opening of described proportional pressure control valve is communicated with the oil circuit between described the second working pump and described the second selector valve, the oil outlet of described proportional pressure control valve is communicated with fuel tank.

In a preferred or optional embodiment, on the oil circuit between described the second selector valve and described the first executive component, be provided with for controlling the speed regulating mechanism of described the first executive component.

In a preferred or optional embodiment, oil circuit between described the second selector valve and described the first executive component comprises the first oil circuit and the second oil circuit, described speed regulating mechanism comprises proportional velocity regulating valve and the 3rd selector valve, the filler opening of described proportional velocity regulating valve is communicated with the first oil circuit between described the second selector valve and described the first executive component by described the 3rd selector valve, and the oil outlet of described proportional velocity regulating valve is communicated with fuel tank.

In a preferred or optional embodiment, on oil circuit between described the second selector valve and described the first executive component, be provided with manual release mechanism, described manual release mechanism comprises Pilot operated check valve and the 4th selector valve, and the oil circuit between described the second selector valve and described the first executive component comprises the first oil circuit and the second oil circuit; Described Pilot operated check valve is arranged on the first oil circuit between described the second selector valve and described the first executive component, the filler opening of described Pilot operated check valve is communicated with described the second selector valve, the oil outlet of described Pilot operated check valve is communicated with described the first executive component, and the control port of described Pilot operated check valve is communicated with the second oil circuit between described the second selector valve and described the first executive component by described the 4th selector valve.

In a preferred or optional embodiment, on the second oil circuit between described the second selector valve and described the first executive component, be also provided with pressure relay.

In a preferred or optional embodiment, described the second executive component also with one independently power control unit be connected, under the state cutting off at oil circuit between described hydraulic pump module and described the second executive component, by described power control unit, control the work of described the second executive component and stop.

In a preferred or optional embodiment, described power control unit comprises the 3rd working pump, the 7th selector valve, equilibrium valve, and described the 3rd working pump is communicated with described the second executive component by described the 7th selector valve and described equilibrium valve successively.

In a preferred or optional embodiment, other first relief valve that is connected on the oil circuit that described the 3rd working pump is communicated with described the 7th selector valve, the oil outlet of described the first relief valve is communicated with fuel tank.

In a preferred or optional embodiment, described the second executive component comprises the second oil hydraulic motor and the second elevator, on described the second elevator, be provided with braking device, described braking device comprises elevator brake assemblies and elevator brake valve group, described the second fluid motor-driven connects described the second elevator, described elevator brake assemblies is arranged on described the second elevator, and described the second elevator is braked, and described elevator brake valve group is controlled the braking of described elevator brake assemblies and stops.

In a preferred or optional embodiment, described elevator brake valve group comprises the shuttle valve being communicated with described the second oil hydraulic motor, the oil outlet of described shuttle valve is communicated with the filler opening of a reduction valve, the oil outlet of described reduction valve is communicated with the filler opening of one second one-way valve and the control port of one the 8th selector valve, the oil outlet of described the second one-way valve is communicated with the first hydraulic fluid port of described the 8th selector valve and the 4th hydraulic fluid port of one the 6th selector valve, the 3rd hydraulic fluid port of described the 8th selector valve is communicated with described elevator brake assemblies, the 3rd hydraulic fluid port cut-off of described the 6th selector valve, the first hydraulic fluid port of described the 6th selector valve is communicated with oil circuit interface, the second hydraulic fluid port of the second hydraulic fluid port of described the 6th selector valve and described the 8th selector valve is communicated with fuel tank.

In a preferred or optional embodiment, described the first executive component comprises the hydraulic jack being hinged in frame, and two hydraulic fluid ports of described the second selector valve are corresponding to be respectively communicated with rod chamber and the rodless cavity of described hydraulic jack.

In a preferred or optional embodiment, described pulley assembly comprises wire rope, movable pulley and static pulley, one end of described wire rope connects the traction end of described the first executive component, the other end of described wire rope is walked around described movable pulley and described static pulley successively, the traction end that connects described the second executive component, the below of described movable pulley is suspended described work feeder in midair.

In a preferred or optional embodiment, on described hydraulic jack, be provided with displacement transducer, the rounded end of described hydraulic jack and described frame is provided with bearing pin sensor.

In a preferred or optional embodiment, described the first executive component comprises the first oil hydraulic motor and the first elevator, two hydraulic fluid ports of described the second selector valve are corresponding to be respectively communicated with forward chamber and the reversion chamber of described the first oil hydraulic motor, and described the first fluid motor-driven connects described the first elevator.

In a preferred or optional embodiment, described pulley assembly comprises wire rope, movable pulley, the first static pulley and the second static pulley, one end of described wire rope connects the traction end of described the first executive component, the other end of described wire rope is walked around described the first static pulley, described movable pulley and described the second static pulley successively, the traction end that connects described the second executive component, the below of described movable pulley is suspended described work feeder in midair.

In a preferred or optional embodiment, described work feeder is two-wheel flute milling machine.

Based on technique scheme, the utility model at least has following beneficial effect:

The first executive component of the present utility model is all connected work feeder by pulley assembly with the second executive component, in feeding process, the first executive component, the second executive component and corresponding hydraulic system needn't enter feeding cutting zone, therefore, executive component needn't require to have very high corrosion resistance, sealing and impact resistance etc.; And do not need to adopt longer fuel feeding oil pipe to executive component fuel feeding, therefore, the pressure loss is less, power loss is less, construction cost is lower, moreover first can form differential relation between executive component and the second executive component, when the first executive component resets, (when the first executive component is oil cylinder, oil cylinder needs after stretching out completely to regain and carries out feeding operation again; When the first executive component is elevator, elevator releases wire rope also needs to receive wire rope reset), by differential relation, can significantly improve the reset speed of the first executive component, improve efficiency of construction, and in withdrawal process, wire rope can remain tensioning.

In a preferred embodiment, adopt hydraulic jack as the first executive component, adopt oil hydraulic motor and elevator as the second executive component, the multiplying power of hydraulic jack in feeding process is 2, be two unit lengths of hydraulic jack feeding, the descending unit length of work feeder, therefore, can more easy feed speed and the feed pressure of controlling work feeder.

Accompanying drawing explanation

Accompanying drawing described herein is used to provide further understanding of the present utility model, forms the application's a part, and schematic description and description of the present utility model is used for explaining the utility model, does not form improper restriction of the present utility model.In the accompanying drawings:

The first specific embodiment schematic diagram of the hydraulic control two-wheel flute milling machine feeding system that Fig. 1 provides for the utility model;

Fig. 2 is the hydraulic control system principle schematic in feeding system shown in Fig. 1;

Fig. 3 is the motor brake valve group schematic diagram in hydraulic control system shown in Fig. 2;

The hydraulic control two-wheel flute milling machine feeding system that Fig. 4 provides for the utility model the second specific embodiment schematic diagram;

Fig. 5 be shown in Fig. 4 in feeding system hydraulic control system principle schematic.

In figure:

X1-the first working pump; X2-the second working pump; X3-the 3rd working pump;

1-the first selector valve; The first hydraulic fluid port of P1-the first selector valve; The second hydraulic fluid port of A1-the first selector valve; The 3rd hydraulic fluid port of B1-the first selector valve;

2-proportional pressure control valve; 3-the first one-way valve;

4-the second selector valve; The first hydraulic fluid port of P4-the second selector valve; The second hydraulic fluid port of T4-the second selector valve; The 3rd hydraulic fluid port of A4-the second selector valve; The 4th hydraulic fluid port of B4-the second selector valve;

5-Pilot operated check valve; 6-hydraulic jack;

7-the 3rd selector valve; The first hydraulic fluid port of P7-the 3rd selector valve; The second hydraulic fluid port of T7-the 3rd selector valve;

8-proportional velocity regulating valve;

9-the 4th selector valve; The first hydraulic fluid port of P9-the 4th selector valve; The second hydraulic fluid port of A9-the 4th selector valve;

10-the 5th selector valve; The first hydraulic fluid port of P10-the 5th selector valve; The second hydraulic fluid port of T10-the 5th selector valve; The 3rd hydraulic fluid port of A10-the 5th selector valve; The 4th hydraulic fluid port of B10-the 5th selector valve;

11-the second elevator; 12-the second oil hydraulic motor;

13-elevator brake valve group; 1301-the 8th selector valve; The first hydraulic fluid port of P01-the 8th selector valve; The second hydraulic fluid port of T01-the 8th selector valve; The 3rd hydraulic fluid port of A01-the 8th selector valve; 1302-the second one-way valve; 1303-reduction valve; 1304-shuttle valve;

14-the 6th selector valve; The first hydraulic fluid port of P14-the 6th selector valve; The second hydraulic fluid port of T14-the 6th selector valve; The 3rd hydraulic fluid port of A14-the 6th selector valve; The 4th hydraulic fluid port of B14-the 6th selector valve;

15-equilibrium valve;

16-the 7th selector valve; The first hydraulic fluid port of P16-the 7th selector valve; The second hydraulic fluid port of T16-the 7th selector valve; The 3rd hydraulic fluid port of A16-the 7th selector valve; The 4th hydraulic fluid port of B16-the 7th selector valve;

17-the first relief valve; 18-the second relief valve; 19-pressure relay; 20-oil circuit interface; 21-elevator brake assemblies; 22-the first oil hydraulic motor; 23-the first elevator; 24-wire rope; 26-the first static pulley; 25-movable pulley; 27-the second static pulley; 30-two-wheel flute milling machine; 31-movable pulley; 32-static pulley; 33-wire rope; 61-displacement transducer; 62-bearing pin sensor.

Embodiment

Below in conjunction with the accompanying drawing in the utility model embodiment, the technological scheme in embodiment is clearly and completely described.Obviously, described embodiment is only a part of embodiment of the present utility model, rather than whole embodiments.Based on embodiment of the present utility model, those of ordinary skills are not making the every other embodiment who obtains under creative work prerequisite, all belong to the scope of the utility model protection.

The hydraulic control feeding system that the utility model provides comprises hydraulic pump module, the first executive component, the second executive component, pulley assembly and work feeder; On the oil circuit that hydraulic pump module is connected with the first executive component, be provided with the second selector valve, by the second selector valve, control break-make and the commutation of oil circuit between hydraulic pump module and the first executive component; On the oil circuit that hydraulic pump module is connected with the second executive component, be provided with the 5th selector valve, the connected sum of controlling oil circuit between hydraulic pump module and the second executive component by the 5th selector valve cuts off; The first executive component is all connected work feeder by pulley assembly with the second executive component, between the first executive component and the second executive component, can form differential relation.

Under the effect of identical oil pressure, the pulling force that the first executive component produces the wire rope in pulley assembly is greater than the pulling force that the second executive component produces wire rope.

The second selector valve in above-described embodiment and the 5th selector valve can be operated to implement:

Mode of operation, in mode of operation, hydraulic oil is directed to the first executive component from hydraulic pump module, makes work feeder carry out feeding operate by the first executive component;

Change stroke patterns, change in stroke patterns, between the first executive component and the second executive component, form differential relation, the first executive component returns to reset mode, and work feeder enters feeding standby condition.

The structural representation of the first specific embodiment when the above-mentioned hydraulic control feeding system providing for the utility model as shown in Figure 1, is hydraulic control two-wheel flute milling machine feeding system.

In the first specific embodiment shown in Fig. 1: the first executive component comprises the hydraulic jack 6 being hinged in frame; The second executive component comprises that the second oil hydraulic motor 12(is as shown in Figure 2) and second elevator 11, the second oil hydraulic motors 12 driving connection the second elevators 11; Work feeder is two-wheel flute milling machine 30; Pulley assembly comprises wire rope 33, movable pulley 31 and static pulley 32.The rod end of the piston rod of one end connecting fluid compressing cylinder 6 of wire rope 33, the other end of wire rope 33 is walked around movable pulley 31 and static pulley 32 successively, connects and is wrapped on the second elevator 11, the below of movable pulley 31 suspention two-wheel flute milling machine 30.On hydraulic jack 6, be provided with displacement transducer 61, hydraulic jack 6 can be provided with bearing pin sensor 62 with the rounded end of frame, or at the piston rod of hydraulic jack 6 and the hinged place of wire rope 33, can be provided with bearing pin sensor 62, or can be provided with bearing pin sensor 62 at the bearing pin place of static pulley 32.

Be illustrated in figure 2 the hydraulic control system principle schematic in feeding system shown in Fig. 1, in Fig. 2:

On the oil circuit that hydraulic pump module is connected with the second selector valve 4, can be provided with pressure regulating mechanism, for the input pressure of the first executive component and the second executive component is regulated.

Pressure regulating mechanism in above-described embodiment can be operated to implement:

Mode of operation, in mode of operation, pressure regulating mechanism makes the oil pressure that enters the first executive component be adjusted to different value, makes work feeder realize different feed pressures.

Emergency lifting pattern, in emergency lifting pattern, pressure regulating mechanism makes the oil pressure that enters the first executive component be adjusted to maximum, makes work feeder emergency lifting.

Hydraulic pump module can comprise the first working pump X1 and the second working pump X2, pressure regulating mechanism can comprise the first selector valve 1, proportional pressure control valve 2 and the first one-way valve 3, the first selector valve 1 is arranged on the oil circuit that the first working pump X1 is connected with the second selector valve 4, the oil outlet that the filler opening of the first one-way valve 3 is communicated with the first selector valve 1, the first one-way valve 3 is communicated with the oil circuit between the second working pump X2 and the second selector valve 4.By the break-make of the first selector valve 1, can realize the first working pump X1 and the second working pump X2 interflow is the first executive component fuel feeding, or realizes the first working pump X1 and the second working pump X2 is separately the first executive component fuel feeding.The filler opening of proportional pressure control valve 2 is communicated with the oil circuit between the second working pump X2 and the second selector valve 4, and the oil outlet of proportional pressure control valve 2 is communicated with fuel tank.Proportional pressure control valve 2, under opening state Y2, reaches maximum oil pressure relief.

In above-described embodiment, hydraulic pump module also can only include a working pump, and pressure regulating mechanism can only include proportional pressure control valve, and by regulating the delivery pressure of proportional pressure control valve, and then adjusting working pump is the pressure of the first executive component fuel feeding.

The first hydraulic fluid port P4 of the second selector valve 4 is communicated with the second working pump X2, the second hydraulic fluid port T4 of the second selector valve 4 is communicated with fuel tank by the second relief valve 18, and the 3rd hydraulic fluid port A4 of the second selector valve 4 and the 4th hydraulic fluid port B4 are communicated with rod chamber and the rodless cavity of hydraulic jack 6 by the first oil circuit and the second oil circuit correspondence respectively.

On the oil circuit that the second selector valve 4 is communicated with rod chamber and the rodless cavity of hydraulic jack 6, can also be provided with for controlling the speed regulating mechanism of the speed of stretching out of the piston rod of hydraulic jack 6.

Speed regulating mechanism can comprise proportional velocity regulating valve 8 and the 3rd selector valve 7.The first oil circuit that the filler opening of proportional velocity regulating valve 8 is communicated with between the second selector valve 2 and the rod chamber of hydraulic jack 6 by the 3rd selector valve 7, the oil outlet of proportional velocity regulating valve 8 is communicated with fuel tank, the feed speed of the piston rod that passing ratio series flow control valve 8 can regulator solution compressing cylinder 6.

On the oil circuit that the second selector valve 4 is communicated with rod chamber and the rodless cavity of hydraulic jack 6, can also be provided with for controlling the manual release mechanism of stretching out of the piston rod of hydraulic jack 6, manual release mechanism can be operated to implement:

Manual deactivation mode, in manual deactivation mode, realizes the piston rod of hydraulic jack 6 by manual release mechanism and manually stretches out.

Manual release mechanism can comprise Pilot operated check valve 5 and the 4th selector valve 9, Pilot operated check valve 5 is arranged on the first oil circuit between the second selector valve 4 and the rod chamber of hydraulic jack 6, the filler opening of Pilot operated check valve 5 is communicated with the second selector valve 4, the oil outlet of Pilot operated check valve 5 is communicated with the rod chamber of hydraulic jack 6, the control port of Pilot operated check valve 5 is communicated with the second oil circuit between the second selector valves 4 and the rodless cavity of hydraulic jack 6 by the 4th selector valve 9, can realize the stretching out of piston rod of manual tune hydraulic jack 6 by Pilot operated check valve 5.

On the second oil circuit between the second selector valve 4 and the rodless cavity of hydraulic jack 6, be also provided with pressure relay 19.Pressure relay 19 is for monitoring the oil pressure of the rodless cavity of hydraulic jack 6, and when pressure is less than certain value, work feeder quits work.Pressure relay 19 is mainly that the piston rod that prevents hydraulic jack 6 stretches out and too fastly causes rodless cavity for shortage of oil and occur inhaling empty phenomenon.

On the second elevator 11, can be provided with braking device, braking device can comprise elevator brake assemblies 21 and elevator brake valve group 13, the second oil hydraulic motor 12 drives and connects the second elevator 11, elevator brake assemblies 21 is arranged on the second elevator 11, the second elevator 11 is braked, and elevator brake valve group 13 is controlled the braking of elevator brake assemblies 21 and stops.

As Fig. 2, shown in Fig. 3, elevator brake valve group can comprise the shuttle valve 1304 being communicated with the second oil hydraulic motor 12, the oil outlet of shuttle valve 1304 is communicated with the filler opening of a reduction valve 1303, the oil outlet of reduction valve 1303 is communicated with the filler opening of one second one-way valve 1302 and the control port of one the 8th selector valve 1301, the oil outlet of the second one-way valve 1302 is communicated with the first hydraulic fluid port P01 of the 8th selector valve 1301 and the 4th hydraulic fluid port B14 of one the 6th selector valve 14, the 3rd hydraulic fluid port A01 of the 8th selector valve 1301 is communicated with elevator brake assemblies 21, the 3rd hydraulic fluid port A14 cut-off of the 6th selector valve 14, the first hydraulic fluid port P14 of the 6th selector valve 14 is communicated with oil circuit interface, oil circuit interface can be connected with oil circuit control independently, the second hydraulic fluid port T01 of the second hydraulic fluid port T14 of the 6th selector valve 14 and the 8th selector valve 1301 is communicated with fuel tank.

When the elevator brake valve group assurance in the present embodiment only has two working connections of the second oil hydraulic motor 12 to have hydraulic oil, could open, improve the reliability of the second elevator 11 work; Elevator brake valve group in the present embodiment can adopt the pressure oil of working connection to carry out elevator braking simultaneously, also can be by independently oil circuit control fuel feeding realization braking, this independently oil circuit control can save, can simplify hydraulic system, improve the reliability of hydraulic system.

The second oil hydraulic motor 12 can also with one independently power control unit be connected, under the state cutting off at oil circuit between hydraulic pump module and the second oil hydraulic motor 12, by this independently power control unit control the work of the second oil hydraulic motor 12 and stop.

Independently power control unit in above-described embodiment can be operated to implement:

Hand hoisting and lower mode playback, in hand hoisting and lower mode playback, hydraulic pump module quits work, and independently power control unit is directed to the second executive component by hydraulic oil, by the second executive component, makes work feeder realize hand hoisting or transfer.

In the present embodiment, power control unit can comprise that the 3rd working pump X3, the 7th selector valve 16, equilibrium valve 15, the three working pump X3 are communicated with A mouth and the B mouth of the second oil hydraulic motor 12 successively by the 7th selector valve 16 and equilibrium valve 15.On the oil circuit that the 3rd working pump X3 is communicated with the 7th selector valve 16, the other oil outlet that is connected to the first relief valve 17, the first relief valves 17 is communicated with fuel tank.

In above-described embodiment, each selector valve can adopt following concrete structure:

The first selector valve 1, its valve body has the first hydraulic fluid port P1, the second hydraulic fluid port A1, the 3rd hydraulic fluid port B1, and under closed condition, the first hydraulic fluid port P1 is communicated with the second hydraulic fluid port A1, and under opening state Y1, the first hydraulic fluid port P1 is communicated with the 3rd hydraulic fluid port B1.

The second selector valve 4, its valve body has the first hydraulic fluid port P4, the second hydraulic fluid port T4, the 3rd hydraulic fluid port A4, the 4th hydraulic fluid port B4.After unlatching, have two working staties, under the first working state Y3, the first hydraulic fluid port P4 is communicated with the 4th hydraulic fluid port B4, and the second hydraulic fluid port T4 is communicated with the 3rd hydraulic fluid port A4; Under the second working state Y4, the first hydraulic fluid port P4 is communicated with the 3rd hydraulic fluid port A4, and the second hydraulic fluid port T4 is communicated with the 4th hydraulic fluid port B4.Under closed condition, the first hydraulic fluid port P4, the second hydraulic fluid port T4, the 3rd hydraulic fluid port A4, the 4th hydraulic fluid port B4 are not all communicated with.

The 3rd selector valve 7, its valve body has the first hydraulic fluid port P7 and the second hydraulic fluid port T7, and under opening state Y7, the first hydraulic fluid port P7 is communicated with the second hydraulic fluid port T7, and under closed condition, the first hydraulic fluid port P7 is not communicated with the second hydraulic fluid port T7.

The 4th selector valve 9, its valve body has the first hydraulic fluid port P9 and the second hydraulic fluid port A9, and under opening state Y9, the first hydraulic fluid port P9 is communicated with the second hydraulic fluid port A9, and under closed condition, the first hydraulic fluid port P9 is not communicated with the second hydraulic fluid port A9.

The 5th selector valve 10, its valve body has the first hydraulic fluid port P10, the second hydraulic fluid port T10, the 3rd hydraulic fluid port A10 and the 4th hydraulic fluid port B10, under opening state Y10, the first hydraulic fluid port P10 is communicated with the 3rd hydraulic fluid port A10, and the second hydraulic fluid port T10 is communicated with the 4th hydraulic fluid port B10, under closed condition, the first hydraulic fluid port P10, the second hydraulic fluid port T10, the 3rd hydraulic fluid port A10, the 4th hydraulic fluid port B10 are not all communicated with each other.

The 6th selector valve 14, its valve body has the first hydraulic fluid port P14, the second hydraulic fluid port T14, the 3rd hydraulic fluid port A14, the 4th hydraulic fluid port B14, under opening state Y14, the first hydraulic fluid port P14 is communicated with the 4th hydraulic fluid port B14, and the second hydraulic fluid port T14 is communicated with the 3rd hydraulic fluid port A14, under closed condition, the first hydraulic fluid port P14 is communicated with the 3rd hydraulic fluid port A14, and the second hydraulic fluid port T14 is communicated with the 4th hydraulic fluid port B14.

The 7th selector valve 16, its valve body has the first hydraulic fluid port P16, the second hydraulic fluid port T16, the 3rd hydraulic fluid port A16, the 4th hydraulic fluid port B16, has two working staties after unlatching, under the first working state Y6, the first hydraulic fluid port P16 is communicated with the 4th hydraulic fluid port B16, and the second hydraulic fluid port T16 is communicated with the 3rd hydraulic fluid port A16; Under the second working state Y5, the first hydraulic fluid port P16 is communicated with the 3rd hydraulic fluid port A16, and the second hydraulic fluid port T16 is communicated with the 4th hydraulic fluid port B16.Under closed condition, the first hydraulic fluid port P16 is communicated with the second hydraulic fluid port T16.

The 8th selector valve 1301, its valve body has the first hydraulic fluid port P01, the second hydraulic fluid port T01, the 3rd hydraulic fluid port A01, under opening state, the first hydraulic fluid port P01 is communicated with the 3rd hydraulic fluid port A01, and under closed condition, the second hydraulic fluid port T01 is communicated with the 3rd hydraulic fluid port A01.

Below in conjunction with the concrete structure of Fig. 1 and above-mentioned each valve, the hydraulic control system shown in Fig. 2 is further described.

The filler opening of the first working pump X1 is communicated with fuel tank, the oil outlet of the first working pump X1 is communicated with the first hydraulic fluid port P1 of the first selector valve 1, the second hydraulic fluid port A1 second hydraulic fluid port T4 that is communicated with the second selector valve 4 in parallel of the first selector valve 1, the second hydraulic fluid port T10 of the 5th selector valve 10, and the filler opening of the second relief valve 18, the oil outlet of the second relief valve 18 is communicated with fuel tank.The 3rd hydraulic fluid port B1 of the first selector valve 1 receives on the fuel-displaced oil circuit of the second working pump X2 by the first one-way valve 3 sides, the filler opening of the first one-way valve 3 is communicated with the 3rd hydraulic fluid port B1 of the first selector valve 1, and the oil outlet of the first one-way valve 3 is communicated with the fuel-displaced oil circuit of the second working pump X2.

The filler opening of the second working pump X2 is communicated with fuel tank, after the oil outlet of the second working pump X2 is communicated with the oil outlet of the first one-way valve 3, and also the first hydraulic fluid port P4 that is communicated with the second selector valve 4 in parallel, and the first hydraulic fluid port P10 of the 5th selector valve 10.On the oil circuit that the oil outlet of the second working pump X2 is communicated with the oil outlet of the first one-way valve 3, also side is connected to a proportional pressure control valve 2, the filler opening of proportional pressure control valve 2 is communicated with the oil circuit between the oil outlet of the second working pump X2 and the oil outlet of the first one-way valve 3, and the oil outlet of proportional pressure control valve 2 is communicated with fuel tank.Proportional pressure control valve 2 is for regulating the outlet pressure of the second working pump X2, and proportional pressure control valve 2, under opening state, reaches maximum oil pressure relief.

The 3rd hydraulic fluid port A4 of the second selector valve 4 is communicated with the rod chamber of hydraulic jack 6, and be provided with Pilot operated check valve 5 on the first oil circuit being communicated with the rod chamber of hydraulic jack 6 at the 3rd hydraulic fluid port A4 of the second selector valve 4, the filler opening of Pilot operated check valve 5 is communicated with the 3rd hydraulic fluid port A4 of the second selector valve 4, and the oil outlet of Pilot operated check valve 5 is communicated with the rod chamber of hydraulic jack 6.Other the 3rd selector valve 7 that connects on the first oil circuit being communicated with at the oil outlet of Pilot operated check valve 5 and the rod chamber of hydraulic jack 6, the first hydraulic fluid port P7 of the 3rd selector valve 7 is communicated with the oil circuit between the oil outlet of Pilot operated check valve 5 and the rod chamber of hydraulic jack 6, the second hydraulic fluid port T7 of the 3rd selector valve 7 is communicated with the filler opening of proportional velocity regulating valve 8, and the oil outlet of proportional velocity regulating valve 8 is communicated with fuel tank.Proportional velocity regulating valve 8 is for the speed of stretching out of the piston rod of regulator solution compressing cylinder 6.The 4th hydraulic fluid port B4 of the second selector valve 4 is communicated with the rodless cavity of hydraulic jack 6, and other the 4th selector valve 9 and the pressure relay 19 of connecing on the second oil circuit being communicated with the rodless cavity of hydraulic jack 6 at the 4th hydraulic fluid port B4 of the second selector valve 4, the first hydraulic fluid port P9 of the 4th selector valve 9 is communicated with the 4th hydraulic fluid port B4 of the second selector valve 4 and the second oil circuit between the rodless cavity of hydraulic jack 6, and the second hydraulic fluid port A9 of the 4th selector valve 9 is communicated with the control port of Pilot operated check valve 5.Pilot operated check valve 5 is got oil by the 4th selector valve 9 from the rodless cavity oil circuit of hydraulic jack 6, and pressure relay 19 is for monitoring the oil pressure of the rodless cavity of hydraulic jack 6, and when pressure is less than certain value, work feeder quits work.

The filler opening of the 3rd working pump X3 is communicated with fuel tank, the oil outlet of the 3rd working pump X3 is communicated with the first hydraulic fluid port P16 of the 7th selector valve 16, and other first relief valve 17 that connects on the oil circuit being communicated with at the oil outlet of the 3rd working pump X3 and the first hydraulic fluid port P16 of the 7th selector valve 16, the filler opening of the first relief valve 17 is communicated with the oil circuit between the oil outlet of the 3rd working pump X3 and the first hydraulic fluid port P16 of the 7th selector valve 16, and the oil outlet of the first relief valve 17 is communicated with fuel tank.

The second hydraulic fluid port T16 of the 7th selector valve 16 is communicated with fuel tank.The 3rd hydraulic fluid port A16 of the 7th selector valve 16 is communicated with the A mouth of the second oil hydraulic motor 12 by equilibrium valve 15, and the 4th hydraulic fluid port B16 of the 7th selector valve 16 is communicated with the B mouth of the second oil hydraulic motor 12.

The 3rd hydraulic fluid port A10 of the 5th selector valve 10 is directly communicated with the A mouth of the second oil hydraulic motor 12, and the 4th hydraulic fluid port B10 of the 5th selector valve 10 is directly communicated with the B mouth of the second oil hydraulic motor 12.

As Fig. 2, shown in Fig. 3, the first filler opening that the A mouth of the second oil hydraulic motor 12 and B mouth draw respectively the corresponding shuttle valve 1304 with elevator brake valve group 13 of oil circuit is communicated with second filler opening with one-way valve, shuttle valve 1304 oil outlets are communicated with the filler opening of reduction valve 1303, the oil outlet of reduction valve 1303 is connected to the control mouth of the 8th selector valve 1301 and the filler opening of the second one-way valve 1302, on the one hand for controlling the commutation of the 8th selector valve 1301, on the other hand for elevator brake assemblies 21 provides pressure oil, the outlet of the second one-way valve 1302 is connected to the first hydraulic fluid port P01 of the 8th selector valve 1301 and the 4th hydraulic fluid port B14 of the 6th selector valve 14, the second hydraulic fluid port T01 of the 8th selector valve 1301 connects fuel tank, the 3rd hydraulic fluid port A01 of the 8th selector valve 1301 connects elevator brake assemblies 21, the first hydraulic fluid port P14 of the 6th selector valve 14 can be used for connecting the oil circuit interface 20 of external control oil circuit, the second hydraulic fluid port T14 of the 6th selector valve 14 connects fuel tank, the 3rd hydraulic fluid port A14 sealing of the 6th selector valve 14.

In above-described embodiment, the first selector valve 1 can adopt two-bit triplet selector valve.

In above-described embodiment, the second selector valve 4 can adopt three position four-way directional control valve.

In above-described embodiment, the 3rd selector valve 7 can adopt 2/2-way selector valve.

In above-described embodiment, the 4th selector valve 9 can adopt 2/2-way selector valve.

In above-described embodiment, the 5th selector valve 10 can adopt two position and four-way reversing valves.

In above-described embodiment, the 6th selector valve 14 can adopt two position and four-way reversing valves.

In above-described embodiment, the 7th selector valve 16 can adopt three position four-way directional control valve.

In above-described embodiment, the 8th selector valve 1301 can adopt 2/2-way pilot operated directional control valve.

In above-described embodiment, equilibrium valve 15 comprises relief valve and the one-way valve being connected in parallel, the filler opening of relief valve and the oil outlet of one-way valve are all connected the A mouth of the second oil hydraulic motor 12, the oil outlet of relief valve and the filler opening of one-way valve are all connected the 3rd hydraulic fluid port A16 of the 7th selector valve 16, and the 4th hydraulic fluid port B16 of the 7th selector valve 16 connects the control port of relief valve.

In above-described embodiment, displacement transducer 61 can be common stay-supported type displacement sensor, can be also other forms of displacement transducer, and displacement transducer 61 is for the extended position of Real-Time Monitoring oil cylinder.

In above-described embodiment, bearing pin sensor 62 is for detection of lineoutofservice signal pull.

Hydraulic control feeding method while introducing several exemplary operation state of the first specific embodiment of the hydraulic control two-wheel flute milling machine feeding system that above-described embodiment provides below.

1. when two-wheel flute milling machine 30 is normally worked (mode of operation).The second elevator 11 brakings, hydraulic jack 6 is responsible for feeding, now the second selector valve 4 unlatchings are positioned under the second working state Y4, the 3rd selector valve 7 is opened and is positioned under opening state Y7, the first working pump X1 is mainly oil cylinder rodless cavity repairing, the second working pump X2 provides pressure oil for cylinder rod chamber, and hydraulic jack 6 piston rods slowly stretch out under the Action of Gravity Field of two-wheel flute milling machine 30.For different stratum, two-wheel flute milling machine 30 needs different feed speed and feed pressure, the feed speed of the piston rod of hydraulic jack 6 can be by regulating proportional velocity regulating valve 8 to obtain, by regulating proportional pressure control valve 2 to make the second working pump X2 export different oil pressure, thereby can realize the different feed pressure of equipment;

2. a key preparatory work (replacing stroke patterns).When hydraulic jack 6 stretches out while maybe needing to regain completely, two-wheel flute milling machine 30 quits work, and be parked in bottom land, the first selector valve 1 now, proportional pressure control valve 2, the second selector valve 4, the 5th selector valve 10, the 6th selector valve 14 is opened, and the first selector valve 1 is positioned at opening state Y1, proportional pressure control valve 2 is positioned at opening state Y2, the second selector valve 4 is positioned at the second working state Y4, the 5th selector valve 10 is positioned at opening state Y10, the 6th selector valve 14 is positioned at opening state Y14, proportional pressure control valve 2 is under opening state Y2, reach maximum oil pressure relief, the first working pump X1, the A confession high pressure oil that the second working pump X2 interflow is the rod chamber of hydraulic jack 6 and the second oil hydraulic motor 12, high-pressure oil passage enters elevator brake valve group 13 simultaneously, when pressure reaches certain value, elevator brake assemblies 21 is opened, now the second oil hydraulic motor 12 has forward to receive the trend of wire rope 33, but, under same oil pressure, the pulling force that the rod chamber of hydraulic jack 6 produces is greater than the pulling force that the second oil hydraulic motor 12 produces, consider the factors such as the weight of wire rope 33 and friction, finally can depress at an equilibrium oil, the piston rod of hydraulic jack 6 is regained, the second oil hydraulic motor 12 reversions discharge wire rope 33, now between hydraulic jack 6 and the second oil hydraulic motor 12, form a kind of differential relation, the second oil hydraulic motor 12 is inhaled low pressure oil from the B mouth of the second oil hydraulic motor 12, A mouth output high pressure oil from the second oil hydraulic motor 12, the high pressure oil of output directly enters the rod chamber of hydraulic jack 6, the oil of the rodless cavity of hydraulic jack 6 is directly the B mouth repairing of the second oil hydraulic motor 12, unnecessary fluid is from the second relief valve 18 overflows, the first working pump X1, the second working pump X2 can make hydraulic jack 6 realize withdrawal fast without too large flow.After hydraulic jack 6 is regained completely, displacement transducer 61 output signals, the second selector valve 4 cuts out, the first hydraulic fluid port P4, the second hydraulic fluid port T4, the 3rd hydraulic fluid port A4, the 4th hydraulic fluid port B4 is not all communicated with, now, the first working pump X1, the second working pump X2 is only the A confession oil of the second oil hydraulic motor 12, now, the second oil hydraulic motor 12 starts forward and drives the second elevator 11 to receive wire rope 33, when showing wire rope 33 pulling force, bearing pin sensor 62 output signals are greater than after certain value, illustrate that wire rope 33 tightened completely, and when two-wheel flute milling machine 30 parts are lifted to bottom land, the 6th selector valve 14 cuts out, the second elevator 11 skiddings, the first selector valve 1, proportional pressure control valve 2, the 5th selector valve 10 cuts out, now, one key preparatory work finishes, can carry out next working feed.

The hydraulic control feeding system that the utility model provides can realize a key preparatory work, i.e. it is ready for next working stroke that the withdrawal of one-key operation hydraulic jack, two-wheel flute milling machine 30 are lifted from cutting face, operates very easy.In the process of a key preparatory work, only adopt little oil pump feed, thus can guaranteed output consumption very little.

3. emergency lifting two-wheel flute milling machine 30(emergency lifting pattern).When two-wheel flute milling machine 30 is stuck, need emergency lifting, now, the first selector valve 1, proportional pressure control valve 2, the second selector valve 4 are opened, the first selector valve 1 is positioned at opening state Y1, proportional pressure control valve 2 is positioned at opening state Y2, the second selector valve 4 is positioned at the second working state Y4, and the first working pump X1, the second working pump X2 interflow are the rod chamber fuel feeding of hydraulic jack 6.Hydraulic jack 6 can produce the gravity of the two-wheel flute milling machine 30 of at least 1.5 times when maximum oil pressure.

4. the piston rod of hydraulic jack 6 manually stretches out (manual deactivation mode).When hydraulic jack 6 need to manually stretch out, press bypass button, the first selector valve 1, the second selector valve 4, the 4th selector valve 9 are opened, the first selector valve 1 is positioned at that opening state Y1, the second selector valve 4 are positioned at the first working state Y3, the 4th selector valve 9 is positioned at opening state Y9, the first working pump X1, the second working pump X2 are the rodless cavity fuel feeding of hydraulic jack 6, and the piston rod of hydraulic jack 6 stretches out.

Hand hoisting and transfer two-wheel flute milling machine 30(hand hoisting and lower mode playback).The 3rd working pump X3 pump work, the 7th selector valve 16 is opened, and while being positioned at the second working state Y5, promoting two-wheel flute milling machine 30, the seven selector valves 16 and opens, and while being positioned at the first working state Y6, transfers two-wheel flute milling machine 30.

The structural representation of the second specific embodiment when the above-mentioned hydraulic control feeding system providing for the utility model as shown in Figure 4, is hydraulic control two-wheel flute milling machine feeding system.

In the second specific embodiment shown in Fig. 4: the first executive component comprises that the first oil hydraulic motor 22 and the first elevator 23, the first oil hydraulic motors 22 drive connection the first elevator 23; The second executive component comprises that the second oil hydraulic motor 12(is as shown in Figure 5) and second elevator 11, the second oil hydraulic motors 12 driving connection the second elevators 11; Work feeder is two-wheel flute milling machine 30; Pulley assembly comprises wire rope 24, movable pulley 25, the first static pulley 26 and the second static pulley 27.

One end of wire rope 24 connects and is wrapped on the first elevator 23, and the other end of wire rope 24 is walked around the first static pulley 26, movable pulley 25 and the second static pulley 27 successively, connects and is wrapped on the second elevator 11, the below of movable pulley 25 suspention two-wheel flute milling machine 30.The 3rd hydraulic fluid port of the second selector valve 4 and the 4th hydraulic fluid port are corresponding to be respectively communicated with A mouth and the B mouth of the first oil hydraulic motor 22.Bearing pin sensor (not shown) can be set on the bearing pin of the first static pulley 26 or the second static pulley 27.

Be illustrated in figure 5 the hydraulic control system principle schematic in feeding system shown in Fig. 4, in the hydraulic control system shown in Fig. 5 and the first specific embodiment, the hydraulic control system shown in Fig. 2 is basic identical, and distinctive points is:

The first executive component comprises the first oil hydraulic motor 22 and the first elevator 23, the first oil hydraulic motor 22 drives and connects the first elevator 23, the 3rd hydraulic fluid port of the second selector valve 4 is communicated with the A mouth of the first oil hydraulic motor 22 by the first oil circuit, and the 4th hydraulic fluid port of the second selector valve 4 is communicated with the B mouth of the first oil hydraulic motor 22 by the second oil circuit.On the oil circuit that the second selector valve 4 is communicated with A mouth and the B mouth of the first oil hydraulic motor 22, be provided with for controlling the speed regulating mechanism of the first oil hydraulic motor 22 rotating speeds, and manual release mechanism.The first oil circuit that the filler opening of proportional velocity regulating valve 8 is communicated with between the second selector valve 2 and the A mouth of the first oil hydraulic motor 22 by the 3rd selector valve 7.Pilot operated check valve 5 is arranged on the first oil circuit between the second selector valve 4 and the A mouth of the first oil hydraulic motor 22, the oil outlet of Pilot operated check valve 5 is communicated with the A mouth of the first oil hydraulic motor 22, the second oil circuit that the control port of Pilot operated check valve 5 is communicated with between the second selector valve 4 and the B mouth of the first oil hydraulic motor 22 by the 4th selector valve 9.Pressure relay 19 is arranged on the second oil circuit between the second selector valve 4 and the B mouth of the first oil hydraulic motor 22.

The hydraulic control feeding method of the hydraulic control feeding system of above-mentioned the second specific embodiment and the hydraulic control feeding method of the hydraulic control feeding system in the first specific embodiment are basic identical, specific as follows:

Wherein, the second selector valve 4 and the 5th selector valve 10 can be operated to implement:

Mode of operation, in mode of operation, hydraulic oil is directed to the first executive component from hydraulic pump module, makes work feeder carry out feeding operate by the first executive component;

Change stroke patterns, change in stroke patterns, between the first executive component and the second executive component, form differential relation, the first executive component returns to reset mode, and work feeder enters feeding standby condition.

Pressure regulating mechanism can be operated to implement:

Mode of operation, in mode of operation, pressure regulating mechanism makes the oil pressure that enters the first executive component be adjusted to different value, makes work feeder realize different feed pressures;

Emergency lifting pattern, in emergency lifting pattern, pressure regulating mechanism makes the oil pressure that enters the first executive component be adjusted to maximum, makes work feeder emergency lifting.

Speed regulating mechanism can be operated to implement:

Mode of operation, in mode of operation, speed regulating mechanism makes the fuel-flow control of flowing out the first executive component to different value, makes work feeder realize different feed speeds.

Manual release mechanism can be operated to implement:

Manual deactivation mode, in manual deactivation mode, makes the first executive component manual release by manual release mechanism.

Independently power control unit can be operated to implement:

Hand hoisting and lower mode playback, in hand hoisting and lower mode playback, hydraulic pump module quits work, and independently power control unit is directed to the second executive component by hydraulic oil, by the second executive component, makes work feeder realize hand hoisting or transfer.

The two-wheel flute milling machine that above-mentioned the first specific embodiment neutralizes in the second specific embodiment can be also other feed mechanisms, be not limited to two-wheel flute milling machine, be that the hydraulic control feeding system that provides of the utility model is except can, for the feeding of two-wheel flute milling machine, being also applied to other various occasions.

The hydraulic control feeding system structure that the utility model provides is simple, and cost is lower, and power loss is little, convenient for maintaining.

Finally should be noted that: above embodiment is only in order to illustrate that the technical solution of the utility model is not intended to limit; Although the utility model is had been described in detail with reference to preferred embodiment, those of ordinary skill in the field are to be understood that: still can modify or part technical characteristics is equal to replacement embodiment of the present utility model; And not departing from the spirit of technical solutions of the utility model, it all should be encompassed in the middle of the technological scheme scope that the utility model asks for protection.

Claims (19)

1. a hydraulic control feeding system, is characterized in that: it comprises hydraulic pump module, the first executive component, the second executive component, pulley assembly and work feeder;

On the oil circuit that described hydraulic pump module is connected with described the first executive component, be provided with the second selector valve, by described the second selector valve, control break-make and the commutation of oil circuit between described hydraulic pump module and described the first executive component;

On the oil circuit that described hydraulic pump module is connected with described the second executive component, be provided with the 5th selector valve, by described the 5th selector valve, control the break-make of oil circuit between described hydraulic pump module and described the second executive component;

Described the first executive component is all connected described work feeder by described pulley assembly with described the second executive component, between described the first executive component and described the second executive component, can form differential relation.

2. hydraulic control feeding system as claimed in claim 1, it is characterized in that: under the effect of identical oil pressure, the pulling force that described the first executive component produces the wire rope in described pulley assembly is greater than the pulling force that described the second executive component produces described wire rope.

3. hydraulic control feeding system as claimed in claim 1, is characterized in that: on the oil circuit that described hydraulic pump module is connected with described the second selector valve, be provided with pressure regulating mechanism.

4. hydraulic control feeding system as claimed in claim 3, it is characterized in that: described hydraulic pump module comprises the first working pump and the second working pump, described pressure regulating mechanism comprises the first selector valve, the first one-way valve and proportional pressure control valve, described the first selector valve is arranged on the oil circuit that described the first working pump is connected with described the second selector valve, the filler opening of described the first one-way valve is communicated with described the first selector valve, the oil outlet of described the first one-way valve is communicated with the oil circuit between described the second working pump and described the second selector valve, the filler opening of described proportional pressure control valve is communicated with the oil circuit between described the second working pump and described the second selector valve, the oil outlet of described proportional pressure control valve is communicated with fuel tank.

5. hydraulic control feeding system as claimed in claim 1, is characterized in that: on the oil circuit between described the second selector valve and described the first executive component, be provided with for controlling the speed regulating mechanism of described the first executive component.

6. hydraulic control feeding system as claimed in claim 5, it is characterized in that: the oil circuit between described the second selector valve and described the first executive component comprises the first oil circuit and the second oil circuit, described speed regulating mechanism comprises proportional velocity regulating valve and the 3rd selector valve, the filler opening of described proportional velocity regulating valve is communicated with the first oil circuit between described the second selector valve and described the first executive component by described the 3rd selector valve, and the oil outlet of described proportional velocity regulating valve is communicated with fuel tank.

7. hydraulic control feeding system as claimed in claim 1, it is characterized in that: on the oil circuit between described the second selector valve and described the first executive component, be provided with manual release mechanism, described manual release mechanism comprises Pilot operated check valve and the 4th selector valve, and the oil circuit between described the second selector valve and described the first executive component comprises the first oil circuit and the second oil circuit; Described Pilot operated check valve is arranged on the first oil circuit between described the second selector valve and described the first executive component, the filler opening of described Pilot operated check valve is communicated with described the second selector valve, the oil outlet of described Pilot operated check valve is communicated with described the first executive component, and the control port of described Pilot operated check valve is communicated with the second oil circuit between described the second selector valve and described the first executive component by described the 4th selector valve.

8. hydraulic control feeding system as claimed in claim 7, is characterized in that: on the second oil circuit between described the second selector valve and described the first executive component, be also provided with pressure relay.

9. hydraulic control feeding system as claimed in claim 1, it is characterized in that: described the second executive component also with one independently power control unit be connected, under the state cutting off at oil circuit between described hydraulic pump module and described the second executive component, by described power control unit, control the work of described the second executive component and stop.

10. hydraulic control feeding system as claimed in claim 9, it is characterized in that: described power control unit comprises the 3rd working pump, the 7th selector valve, equilibrium valve, described the 3rd working pump is communicated with described the second executive component by described the 7th selector valve and described equilibrium valve successively.

11. hydraulic control feeding systems as claimed in claim 10, is characterized in that: other first relief valve that is connected on the oil circuit that described the 3rd working pump is communicated with described the 7th selector valve, the oil outlet of described the first relief valve is communicated with fuel tank.

12. hydraulic control feeding systems as claimed in claim 1, it is characterized in that: described the second executive component comprises the second oil hydraulic motor and the second elevator, on described the second elevator, be provided with braking device, described braking device comprises elevator brake assemblies and elevator brake valve group, described the second fluid motor-driven connects described the second elevator, described elevator brake assemblies is arranged on described the second elevator, described the second elevator is braked, and described elevator brake valve group is controlled the braking of described elevator brake assemblies and stops.

13. hydraulic control feeding systems as claimed in claim 12, it is characterized in that: described elevator brake valve group comprises the shuttle valve being communicated with described the second oil hydraulic motor, the oil outlet of described shuttle valve is communicated with the filler opening of a reduction valve, the oil outlet of described reduction valve is communicated with the filler opening of one second one-way valve and the control port of one the 8th selector valve, the oil outlet of described the second one-way valve is communicated with the first hydraulic fluid port of described the 8th selector valve and the 4th hydraulic fluid port of one the 6th selector valve, the 3rd hydraulic fluid port of described the 8th selector valve is communicated with described elevator brake assemblies, the 3rd hydraulic fluid port cut-off of described the 6th selector valve, the first hydraulic fluid port of described the 6th selector valve is communicated with oil circuit interface, the second hydraulic fluid port of the second hydraulic fluid port of described the 6th selector valve and described the 8th selector valve is communicated with fuel tank.

14. hydraulic control feeding systems as described in claim 1 or 12, it is characterized in that: described the first executive component comprises the hydraulic jack being hinged in frame, two hydraulic fluid ports of described the second selector valve are corresponding to be respectively communicated with rod chamber and the rodless cavity of described hydraulic jack.

15. hydraulic control feeding systems as claimed in claim 14, it is characterized in that: described pulley assembly comprises wire rope, movable pulley and static pulley, one end of described wire rope connects the traction end of described the first executive component, the other end of described wire rope is walked around described movable pulley and described static pulley successively, the traction end that connects described the second executive component, the below of described movable pulley is suspended described work feeder in midair.

16. hydraulic control feeding systems as claimed in claim 15, is characterized in that: on described hydraulic jack, be provided with displacement transducer, the rounded end of described hydraulic jack and described frame is provided with bearing pin sensor.

17. hydraulic control feeding systems as described in claim 1 or 12, it is characterized in that: described the first executive component comprises the first oil hydraulic motor and the first elevator, two hydraulic fluid ports of described the second selector valve are corresponding to be respectively communicated with forward chamber and the reversion chamber of described the first oil hydraulic motor, and described the first fluid motor-driven connects described the first elevator.

18. hydraulic control feeding systems as claimed in claim 17, it is characterized in that: described pulley assembly comprises wire rope, movable pulley, the first static pulley and the second static pulley, one end of described wire rope connects the traction end of described the first executive component, the other end of described wire rope is walked around described the first static pulley, described movable pulley and described the second static pulley successively, the traction end that connects described the second executive component, the below of described movable pulley is suspended described work feeder in midair.

19. hydraulic control feeding systems as claimed in claim 1, is characterized in that: described work feeder is two-wheel flute milling machine.