前苏联专利SU1166669A3 Device for controlling liquid flow

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专利摘要:
A fluid controller is disclosed of the type including a primary valve member, and a follow-up valve member. The controller includes a load signal port and a load signal chamber. Fluid is communicated from the inlet port to the load signal chamber, and the valve members define a neutral orifice communicating between the load signal chamber and the return port when the valving is in neutral. The valving defines operating orifices communicating fluid from the load signal chamber to the main fluid path, downstream of the main flow control orifice, when the valving is shifted away from neutral. The operating orifices have a smaller orifice area when the valving approaches maximum deflection. The result is a substantially higher differential operating pressure, and a higher flow rate than would otherwise be possible at that particular valve deflection.
公开号:SU1166669A3
申请号:SU792720747
申请日:1979-02-05
公开日:1985-07-07
发明作者:Венделл Джонсон Оливер
申请人:Итон Корпорейшн (Фирма)；
IPC主号:

专利说明:

This invention relates to automatic servo control.
A device is known for controlling the flow of a fluid, which contains control valve elements and a pressure signal generator P.
Closest to the invention in its technical essence is a hydraulic control system comprising a load-sensing main flow control valve controlling the flow from the pump to the regulating control unit and to the auxiliary device 2.
A disadvantage of the known devices is that they cannot be used in automatic controllers, for example, in control regulating units of an automobile control control system with hydraulic connections.
The purpose of the invention is to expand the field of application of the device.
This goal is achieved by the fact that a device for controlling the flow of a liquid, having a housing with an inlet channel connected to the outlet of the source of liquid through the means for switching the flow of liquid, the drain channel connected to the tank, the first and second output channels connected respectively to the first and second servo-driven chambers, a load channel and a pressure channel connected respectively to the first and second control cavities of the means for switching over the liquid, while the housing is filled with the first and second control valves, with a load chamber formed by the first control valve and the housing, which is permanently connected to the load channel, with a flow meter in the first output channel connected to the first control valve, the housing with the control valves having first and second variable resistances located in the channel, input channel with the first channel of the flow meter, the third and fourth changes, current resistances, are sequentially located in the channel connecting the second channel of the flow meter to the first output channel, the fifth variable resistance located in the channel connecting the second output
the channel with a drain channel contains a channel connecting the input channel to the load channel — the sixth and seventh variable-resistances arranged in parallel in the channels connecting the load channel to the channel between the input channel and the first channel of the flow meter downstream, and the variable resistances are formed by profiled elements of the housing and regulating clamps. lords,
In addition, the device has an eighth variable resistance formed by the profiled elements of the housing and control valves and installed in the channel connecting the load channel to the drain channel.
At the same time, the device has a constant resistance installed in the channel connecting the input and load channels.
Moreover, the channels including the sixth and seventh variable resistances connect the load channel to the channel between the first and second variable resistances.
FIG. 1 is a schematic diagram of a device for controlling the flow of a liquid; FIG. 2 - the proposed device, cut FIG. 3 - section A-Ana of FIG. 2; in fig. 4 shows a second control valve, top view, in FIG. 5 a first control valve, top view} in FIG. 6 is a diagram of the valve system in FIG. 7 is a valve system, a cross section, in FIG. 8 the same in the neutral position}, in FIG. 9 - the same, in the normal position} in FIG. 10 - the same, with a maximum deviation} in FIG. 11 is a part of the valve system, corresponding to the position of the maximum deviation, the cross section; FIG. 12 is a plot of the orifice area versus valve deviation and variable orifices.
The device for controlling the flow of liquid comprises a housing 1 with an inlet channel 2 connected to the outlet of the source 3 of liquid through means 4 for switching the flow of liquid, a drain channel 5 connected to the reservoir 6, the first 7 and the second 8 outlets connected respectively to the first 9 and second 10 came3
The servo drive 11, the load channel 12 and the pressure channel 13, are connected to the Hbie, respectively, with the first 14 and the second one. 15 of the control cavities of the means 4 for switching the flow of fluid, wherein the housing 1 has first 16 and second 17 control valves, a load chamber 18 formed by the first control valve 16 and the housing 1, a flow meter 19 installed in the first output channel 7 and connected to the first control valve 16.
The housing 1 with control valves 16 and 17 includes the first 20 and second 21 variable resistances located in the channel 22 connecting the input channel 2 to the first channel 23 of the flow meter 19, the third 24 and fourth 25 variable resistances arranged in series in the channel 26 connecting the the second channel 27 of the flow meter 19 with the first output channel 7, the fifth variable resistance 28, located in the channel 29 connecting the second output channel 8 to the drain channel 5, channel 30 connecting the input channel 2 to the load channel 12, the sixth 31 and seventh 32 n Variable resistances are arranged in parallel in channels 33 and 34 connecting the load channel 12 to the channel between the input channel 2 and the first channel 23 of the flow meter 19.
In addition, the device contains an eighth variable resistance 35 installed in the channel 36 connecting the load channel 12 to the drain channel 5, a constant resistance 37 installed in the channel 38 connecting the input channel 2 and the load channel 12.
A flow meter 19 with a tip 39 is connected to the housing 1 (FIG. 2). The flow meter 19 includes a rotary drive unit containing a part 40 provided from the inside with teeth, fixed to housing 1 and tip 39 with bolts 41, and part 42 provided with teeth to the outside and eccentrically located within part 40, with orbital and rotational relative motion. The gearing of the parts 40 and 42 forms a plurality of chambers that increase and decrease in volume (not shown).
66669.4
In the opening 43 of the housing 1, first-16 and second 17 control valves are installed, installed with the possibility of relative rotation. 5 The second control valve 17 has a flat face part 44 for communication with a shaft (not shown). The first control valve 16 is connected to the second control valve 17 by means of
10 of a drive shaft 45, provided at the first end with a set of splines 46, meshed with a set of straight inner splines 47, formed inside the part 42. At the second
15, the end of the drive shaft 45 has a split part 48 through which the transverse drive pin 49 passes, passing through the holes in the second control valve 17 and connected to the first control valve 16. Leaf springs 50 are located at a right angle to the drive pin 49, first and second control valves
5 to a neutral position relative to each other.
An annular groove 51 is formed in the housing 1, which is connected with a plurality of holes 52 of the first regulating
JJ valve 16. The second control valve. The pan 17 bounds an annular groove 53, to the right of which there are a plurality of holes 54, between each adjacent pair of holes 54 is an axial groove 55 connected to the groove 56. And to the left there are holes 57 and 58. On the first control valve 16 there are measuring holes 59 , and in the case - channels 60 and measuring holes 61. At the second. Rum control valve 17 is provided with annular grooves 62 and holes 63, | ja with the first - holes 64-66, and in the housing - annular grooves 67-69. On
second control valve 17
There are holes 70 and 71, four radial holes 72, countersinks 73 and 74 of different sizes, and on the first control valve 16 there are g holes 75. The first control valve 16 with the housing forms a groove 76 connected through the hole 77 to the inlet channel 2.
The device for controlling the flow of fluid 5 operates as follows. Fluid from fluid source 3 through switching means 4; fluid flow enters inlet 5. . channel 2 of housing 1 and then through channel 22 with the first 20 and second 21 variable resistances and the first channel 23 to the flow meter 19, from which liquid flows out through the second channel 27 with the third 24 and fourth 25 variable resistances installed in channel 26, and goes through the first output channel 7 to the first chamber 9 of the servo drive 11. From the second chamber 10 of the servo drive 11, the liquid passes through the second output channel 8 through the fifth variable resistance 28 located in the channel 29 and through the drain channel 5 flows to the tank 6 .When rotating the second Regulator 17 (clockwise), each of the axial holes 54 connects to one of the holes 52 of the first regulator 16, forming the first variable resistance 20. Next, the fluid passes through the annular groove 53 and holes 57, each of which is connected with a pair of measuring orifices 58, which forms a second variable resistance 21. From the measuring orifices 59, the liquid enters the flow chamber 19 increasing in the chamber volume through the channels 60. The fluid returns from the flow rate decreasing in the chamber volume The tube 19 and flows through the alternating channels 60 to the measuring hole 61, each pair of which is connected to the hole 58 to form the third variable resistance 24. Then the liquid flows into the annular groove 62 and the hole 63 which with the holes .64 forms the fourth variable . resistance 25. From the openings 64, the liquid enters the annular groove 67 connected to the first exit channel 7. Liquid from the second rotary channel 8 enters the annular groove 68 and then through the openings 65 and 70, forming the fifth variable side 28, enters the internal cavity of the second control valve 17, and then through the openings 71 and 66 and the annular groove 69 into the drain channel 5. A small amount of liquid enters through the inlet 2 of the housing 1 and the orifice 77 into the groove 76 and further to the loading channel 12 and to the means 4 for switching between 9 current and liquid-4. From the groove 76, through the openings 75 and 72, which form the eighth variable resistance, the liquid enters the internal cavity of the second control valve 1 7 and then to the drain channel 5, the maximum opening area of the eighth first resistance is provided with a neutral position of the first and second control valves, and their displacement decreases (FIG. 12). When displaced, one hole 75 is aligned with smaller countersink 74, forming a sixth variable resistance, and the other holes 75 are aligned with countersink 73 Olsha size to form the 7th variable resistance. When the valve system deviates from the neutral position to angle 4, all the liquid passing through the openings 77 flows through the eighth variable resistance, with a deviation from 4 to 5 part of the liquid comes through the eighth variable resistance, and the rest through the sixth and seventh variable resistances Subscribe to the main flow of fluid, grooved. Above 5 almost all liquid flows through the sixth and seventh variable resistances. The flow area through the eighth variable resistance is four hole areas 75, while each of the sixth and seventh variable resistance holes is equal to one of hole 75, resulting in a noTOKai (neutral: working) area ratio of 2: 1. The area of flow of the sixth and seventh variable resistances continues to increase from the point at which they began to open (about. S, n 4 valve deviations) to 7 °, where the area of the flow of holes reaches its maximum (Fig. 12). FIG. 9 shows the position in which the hole 75 is fully aligned with the countersink 74, and the diametrically opposite hole 75 is aligned with the countersink 73. When the deviation of the regulating valve increases further, the area of the sixth and seventh variable resistances is maintained at a maximum as long as 7, the valve deflection will not reach 12V at this point, if the second control valve 17 is moved several clockwise from the position shown in FIG. 9, the connection between the hole 75 and the countersink 74 is no longer complete, and the flow area of the hole 33 begins to decrease. However (at the same time) the connection between the diametrically opposite radial hole 75 and the larger countersink 73 is still complete, and the flow area of the hole 34 is kept at its maximum. If the valve deviation increases further, the control valves 16 and 17 reach the relative position (Fig. 10) when the deviation reaches 15. At this point, the hole 75 and the countersink 74 are completely removed from the connection and the hole area 33 becomes zero. However, the opposite opening 75 is still in full contact with the countersink 73, and the opening area 34 is kept at its maximum. Due to the fact that the high-pressure fluid is continuously vented through the groove 76 and the opening 77, the fluid pressure in the aggro fluid channel 12 is directly related to the area of the holes allowing the fluid to pass either to the reservoir or to the main flow path -1. To deflect a valve at 0 °, the reference pressure must be equal to the minimum. When the valve deflection increases, the differential-operating pressure increases rapidly until about 3-4 when the valve deflects around 3-4, the differential pressure is at the normal operating level. Depending on the relative timing (a decrease in the variable hole 35 and an increase in the variable hole 33 and 34), the differential pressure may increase at an operating level for deviations from 3 to 4. When the valve deviation increases from 12 ° to 15 °, the total orifice area decreases until it reaches a minimum, and thereafter, if the valve deflection continues to increase to a maximum, the orifice area remains almost constant. As a result, to displace the valve over 12, the differential pressure begins to increase until it reaches the maximum level with a valve deviation of 15 ° or more. Thus, in the invention, the ratio of medada with differential working pressure and valve deflection is provided by modifying the dimensions and rates of change of the difference. measures of various variable orifices connecting the load chamber and the return opening or main flow path. The invention allows a significant increase in the maximum flow rate without increasing the size of the orifices constituting the main flow path and without creating a large differential pressure with small valve deviations, which leads to large losses of energy in the neutral position.
4S
four./
srig.g% l.Ch.gs 66 - ®
Figo
75 58 57 JJ 5S bg S8 676 / 7S I /
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74
15
75
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75

权利要求:
Claims (4)
[1]
1. A LIQUID FLOW CONTROL DEVICE, having a housing with an inlet channel connected to the outlet of the liquid source through means for switching the liquid flow, a drain channel connected to the reservoir, the cooler, the first and second output. channels connected respectively.
with the first and second chambers of the servo drive, the load channel and the pressure channel connected respectively to the first and second control cavities of the means for switching the fluid flow, while the housing is made. with the first and second control valves, with the load chamber formed by the first control valve and the casing constantly in communication with the load channel, with a flow meter in the first output channel connected to the first control valve, the casing with control valves having the first and second variable resistors located in the channel connecting the input channel to the first channel races. a third or fourth variable resistance, sequentially located in the channel connecting the second channel of the flowmeter to the first output channel, the fifth variable resistance located in the channel connecting the second output channel with the drain channel, and therefore that, in order to expand the scope of the device, it contains a channel connecting the input channel to the load channel, the sixth and seventh resistance variables located in parallel in the channels connecting the load channel to the channel m Between the inlet channel and the first channel of the flowmeter at a point lying below the first variable flow resistance, and the variable resistance is formed by profiled elements of the housing and control valves.
.
[2]
2. The device according to π. 1, cast in that it has an eighth variable resistance formed by profiled elements of the housing and control valves and installed in the channel connecting the load channel to the drain channel,
[3]
3. The device pop. It is distinguished by the fact that it has a constant resistance installed in the channel connecting the input and load channels.
[4]
4. The device according to claim 1, wherein the channels, including the sixth and seventh variable resistance, connect the load channel to the kenal between the first and second variable resistance.
»SU <w 1166669

类似技术:

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US2984215A|1958-11-25|1961-05-16|Controller for fluid pressure operated devices |

US3455210A|1966-10-26|1969-07-15|Eaton Yale & Towne|Adjustable,metered,directional flow control arrangement|

US3815477A|1973-02-06|1974-06-11|Cross Mfg Inc|Control valve instrumentality|

US3971216A|1974-06-19|1976-07-27|The Scott & Fetzer Company|Load responsive system with synthetic signal|

US4037620A|1976-04-23|1977-07-26|Eaton Corporation|Controller for fluid pressure operated devices|

US4043419A|1976-06-04|1977-08-23|Eaton Corporation|Load sensing power steering system|DE2944883C2|1979-11-07|1982-08-26|Danfoss A/S, 6430 Nordborg|Hydrostatic steering device|

DE2952674C2|1979-12-28|1983-03-24|Danfoss A/S, 6430 Nordborg|Hydraulic steering device|

US4336687A|1980-04-21|1982-06-29|Eaton Corporation|Load sensing controller|

US4665695A|1981-03-13|1987-05-19|Trw Inc.|Hydrostatic load sense steering system|

US4418710A|1981-10-05|1983-12-06|Eaton Corporation|Pilot control valve for load sensing hydraulic system|

US4454716A|1982-02-03|1984-06-19|Trw Inc.|Load sense hydrostatic vehicle steering system|

US4488569A|1982-04-23|1984-12-18|Trw Inc.|Apparatus with staged pressure differential for controlling fluid flow|

US4576003A|1982-10-29|1986-03-18|Trw Inc.|Hybrid load-sense vehicle hydrostatic steering system|

US4558720A|1983-03-17|1985-12-17|Eaton Corporation|Closed-center controller for use with unequal area cylinder|

US4781219A|1986-10-10|1988-11-01|Eaton Corporation|Fluid controller and dampening fluid path|

DE3789189T2|1986-10-10|1994-06-01|Eaton Corp|Fluid control and damped fluid path.|

US4759182A|1987-07-24|1988-07-26|Eaton Corporation|Steering control unit with flow amplification|

US4862690A|1988-10-06|1989-09-05|Eaton Corporation|Steering control unit with both flow amplification and manual steering capability|

US4958493A|1988-10-06|1990-09-25|Eaton Corporation|Open-center steering control unit with flow amplification|

EP0477370B2|1990-01-11|1998-11-04|Hitachi Construction Machinery Co., Ltd.|Hydraulic valve apparatus|

DE4410693C2|1994-03-28|1996-05-23|Hydraulik Nord Gmbh|Hydraulic steering device with load signal|

DE19505592C1|1995-02-18|1996-04-18|Hydraulik Nord Gmbh|Hydraulic steering device with load signal|

SE534002C2|2009-06-24|2011-03-29|Nordhydraulic Ab|Method and apparatus for controlling a hydraulic system|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

US05/875,714|US4167893A|1978-02-06|1978-02-06|Load sensing valve|

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