Patent Application
20210207622
The present disclosure relates to a flow control valve and a hydraulic machine including the same. More particularly, the present disclosure relates to a flow control valve with a novel structure and a hydraulic machine including the same.
A variety of machines producing power by supplying pressurized fluid are used in construction sites, industrial fields, and the like. In general, such a machine has a flow control valve regulating the flow of pressurized fluid to supply pressurized fluid along different paths, in accordance with respective requests.
A flow control valve generally includes a spool therein, with notches being formed in an outer circumferential surface of the spool. The notches are configured to gradually increase or reduce the area of a fluid path at an initial stage of opening of the fluid path or at a final stage of closing of the fluid path, thereby allowing an actuator to operate smoothly without impacts when starting or ending the operation. However, in the flow control valve having this structure, the notches performing a flow control function are formed in the outer circumferential surface of the spool, as described above. It is therefore impossible to independently regulate, for example, the flow rate of a flow directed to the actuator and the flow rate of a flow returning from the actuator. Thus, improvements in controllability and fuel efficiency are limited.
The flow control valve generally has a check valve integrated therewith. The check valve allows fluid to flow in one direction from a fluid supply to the actuator while preventing fluid from flowing in the reverse direction from the actuator to the fluid supply, when the pressure of the actuator is higher than the pressure of the fluid supply, due to a load applied to the actuator. However, the check valve can only be opened or closed to allow or cut off a flow of fluid, but does not have a flow rate control function.
In such a hydraulic machine, when fluid is supplied to a plurality of actuators by a single fluid supply, an intended amount of fluid is not supplied to an actuator among the plurality of actuators to which a relatively high pressure is applied. The actuator, to which a relatively high pressure is applied, may only be able to start work after the other actuators to which relatively lower pressures are applied have completed work.
To overcome this problem, some flow control values have a priority valve integrated therewith. For example, the priority valve may be disposed on a fluid passage of the flow control valve to restrict a flow of fluid, so that a greater amount of fluid is preferentially supplied to another flow control valve. However, the priority valve is a type of orifice, which may cause a pressure drop and lower fuel efficiency.
Therefore, a flow control value having a novel structure is demanded.
Accordingly, the present disclosure has been made in consideration of the above-described problems occurring in the related art, and the present disclosure is intended to provide a flow control valve having an improved flow rate control function to provide an actuator with fluid at an accurate flow rate, as required. Also provided is a novel flow control valve that can overcome problems occurring in flow control valves of the related art in which a flow rate greater than a requested flow rate is concentrated in a specific actuator or a pressure drop is caused by a priority valve used to prevent the concentration of the greater flow rate. Also provided is a flow control valve having a flow rate control valve to substitute for notches regulating the flow rate of fluid directed to an actuator, thereby controlling the flow rate of fluid directed to the actuator independently of the flow rate of fluid returning to the actuator. It is thereby possible to significantly improve machine controllability and fuel efficiency.
According to an aspect of the present disclosure, a flow control valve may include: a valve body configured to include an inner circumferential surface defining a bore extending in a longitudinal direction, wherein at least a portion of a first fluid passage and a second fluid passage are formed in the valve body to be connected to the bore; a spool configured to be slidably inserted into the bore, the spool movable to a position in which the spool allows a flow of fluid from the first fluid passage to the second fluid passage; and a flow rate control valve configured to be located on the first fluid passage to regulate a flow rate of fluid flowing through the first fluid passage. The inner circumferential surface may have a first seat surface located between an area in which the first fluid passage is connected to the bore and an area in which the second fluid passage is connected to the bore. At a second point in time at which the flow of fluid from the first fluid passage to the second fluid passage is initiated, an area of a gap between the first seat surface and the spool on a plane taken in a transverse direction, perpendicular to the longitudinal direction, may be 5%˜50%, preferably 10%˜20% of an area of an opening defined by the first seat surface.
A third fluid passage may be further formed in the valve body to be connected to the bore. The spool may be movable to the position in which the spool allows the flow of fluid from the first fluid passage to the second fluid passage or a position in which the spool allows a flow of fluid from the first fluid passage to the third fluid passage. The inner circumferential surface may further include a second seat surface located between an area in which the first fluid passage is connected to the bore and an area in which the third fluid passage is connected to the bore. At a third point in time at which the flow of fluid from the first fluid passage to the third fluid passage is initiated, an area of a gap between the second seat surface and the spool on a plane taken in the transverse direction may be 5%˜50%, preferably 10%˜20% of an area of an opening defined by the second seat surface.
According to an aspect of the present disclosure, a hydraulic machine may include: a fluid supply; a first flow control valve configured to be in fluid communication with the fluid supply; a first actuator configured to be in fluid communication with the first flow control valve; and a first control interface configured to generate a signal when manipulated by an operator. The first flow control valve may include: a valve body configured to include an inner circumferential surface defining a bore extending in a longitudinal direction, wherein at least a portion of a first fluid passage, a second fluid passage, and a third fluid passage are formed in the valve body to be connected to the bore; a spool configured to be slidably inserted into the bore, the spool movable to a position in which the spool allows a flow of fluid from the first fluid passage to the second fluid passage or a position in which the spool allows a flow of fluid from the first fluid passage to the third fluid passage; and a flow rate control valve configured to be located on the first fluid passage to regulate a flow rate of fluid flowing through the first fluid passage as a function of the signal generated by the first control interface. The inner circumferential surface may include a first seat surface located between an area in which the first fluid passage is connected to the bore and an area in which the second fluid passage is connected to the bore and a second seat surface located between an area in which the first fluid passage is connected to the bore and an area in which the third fluid passage is connected to the bore. At a second point in time at which the flow of fluid from the first fluid passage to the second fluid passage is initiated, an area of a gap between the first seat surface and the spool on a plane taken in a transverse direction, perpendicular to the longitudinal direction, may be 5%˜50%, preferably 10%˜20% of an area of an opening defined by the first seat surface. At a third point in time at which the flow of fluid from the first fluid passage to the third fluid passage is initiated, an area of a gap between the second seat surface and the spool on a plane taken in the transverse direction may be 5%˜50%, preferably 10%˜20% of an area of an opening defined by the second seat surface.
Hereinafter, exemplary embodiments of the present disclosure will be described in detail with reference to the accompanying drawings.
The flow control valve 10 includes a valve body 100, a spool 200, and a flow rate control valve 300.
The valve body 100 has an inner circumferential surface 101 defining a bore 103 extending in a longitudinal direction D1. A portion of a first fluid passage 111, a second flow passage 112 and a third fluid passage 113 are formed in the valve body 100. The first, second, and third fluid passages 111, 112, and 113 communicate with the bore 103. The first fluid passage 111 may be a fluid passage communicating with a fluid supply. The second fluid passage 112 and the third fluid passage 113 may be fluid passages communicating with actuators. The inner circumferential surface 101 includes a first seat surface 121 and a second seat surface 122. The first seat surface 121 is located between an area in which the first fluid passage 111 is connected to the bore 103 and an area in which the second fluid passage 112 is connected to the bore 103. The second seat surface 122 is located between an area in which the first fluid passage 111 is connected to the bore 103 and an area in which the third fluid passage 113 is connected to the bore 103. As illustrated in
A fourth fluid passage 114 and a fifth fluid passage 115 are formed in the valve body 100. The fourth fluid passage 114 and the fifth fluid passage 115 are connected to the bore 103. The fourth fluid passage 114 and the fifth fluid passage 115 may be fluid passages communicating with a tank. The inner circumferential surface 101 includes a third seat surface 123 located between an area in which the second fluid passage 112 is connected to the bore 103 and an area in which the fourth fluid passage 114 is connected to the bore 103. In addition, the inner circumferential surface 101 includes a fourth seat surface 124 located between an area in which the third fluid passage 113 is connected to the bore 103 and an area in which the fifth fluid passage 115 is connected to the bore 103.
The spool 200 is slidably inserted into the bore 103. The spool 200 can be shifted between a first position, a second position, and a third position. The first position is a neutral position. When the spool 200 is in the first position, as illustrated in
The spool 200 includes a first valley 211 and a second valley 212. The spool 200 includes a first land 221 and a second land 222. As illustrated in
The flow rate control valve 300 is located on the first fluid passage to regulate the flow rate of fluid flowing through the first fluid passage 111. As illustrated in
The flow control valve 10 may include an electro-proportional pressure reducing valve 400. The electro-proportional pressure reducing valve 400 is connected to the flow rate control valve 300 such that the electro-proportional pressure reducing valve 400 can control the flow rate control valve 300 to be opened or closed, as well as the degree of opening, by applying pilot pressure to the flow rate control valve 300. Although the electro-proportional pressure reducing valve 400 is directly connected to the flow rate control valve 300 in
Reference numeral 500 indicates a relief valve.
The flow rate control valve 300 may include a plug 301, a sleeve 302, a poppet 303, a spool 304, and a spring 305.
Working fluid drawn from a working fluid supply flows into a backpressure chamber through an orifice in the poppet 303.
When no pilot pressure is applied through a port 317 by the electro-proportional pressure reducing valve 400, a total of an amount of force by which fluid within the backpressure chamber downwardly presses the poppet 303 and an amount of force by which the spring 305 downwardly presses the poppet 303 is greater than an amount of force by which working fluid pushes the poppet 303 from below the poppet 303 upwardly, so that the poppet 303 remains closed.
When pilot pressure is applied through the port 317 by the electro-proportional pressure reducing valve 400, the spool 303 is shifted downwardly against the force of the spring 305. At this time, fluid within the backpressure chamber is drained through the port 315 after sequentially passing through the inner passage of the spool 304 and the inner passage of the plug 301, so that the pressure within the backpressure chamber is lowered. Thus, the poppet 303 is moved upwardly by the force of working fluid pushing the poppet 303 upwardly from below the poppet 303, thereby opening a port 313. Thus, working fluid sequentially flows into the first fluid passage 111 through the port 311 and the port 313. The upward displacement of the poppet 303, i.e. the degree of opening of the port 313, varies depending on the level of pilot pressure applied by the electro-proportional pressure reducing valve 400. In the case of attempting to direct fluid from the working fluid supply to the first fluid passage 111 at a greater flow rate, a control device may be only required to send a greater electric signal to the electro-proportional pressure reducing valve 400.
Reference numeral 306 indicates an O-ring.
The outer diameter of the first valley 211 is smaller than the diameter of an opening defined by the first seat surface 121, while the outer diameter 212d of the second valley 212 is smaller than the diameter 122d of an opening defined by the second seat surface 122. The outer diameter of the first land 221 is substantially the same as the diameter of the opening defined by the first seat surface 121, while the outer diameter 222d of the second land 222 is substantially the same as the diameter of the opening defined by the second seat surface 122.
The outer diameter of the first valley 211 is smaller than the diameter of the opening defined by the third seat surface 123, while the outer diameter 212d of the second valley 212 is smaller than the diameter of the opening defined by the fourth seat surface 124. The outer diameter of the third land 223 is substantially the same as the diameter of the opening defined by the third seat surface 123, while the outer diameter 222d of the fourth land 224 is substantially the same as the diameter of the opening defined by the fourth seat surface 124.
At a first point in time at which both the flow of fluid from the first fluid passage 111 to the second fluid passage 112 and the flow of fluid from the first fluid passage 111 to the third fluid passage 113 are cut off, the first land 221 overlaps (i.e. is fitted into) at least a portion of the first seat surface 121, and the second land 222 overlaps (i.e. is fitted into) at least a portion of the second seat surface 122, as illustrated in
At the second point in time at which the flow of fluid from the first fluid passage 111 to the second fluid passage 112 is initiated, the area of a gap between the first seat surface 121 and the spool 200 on a plane taken in a transverse direction, perpendicular to the longitudinal direction D1, may be 5%˜50%, preferably 10%˜20% of the area of the opening defined by the first seat surface 121. As illustrated in
The spool 200 satisfying the above-described requirements is configured such that a first notch allowing the first fluid passage and the second fluid passage to communicate with each other and a second notch 222n′, allowing the first fluid passage and the third fluid passage to communicate with each other, which exist in the related art, are removed.
However, only one of the first notch and the second notch 222′ may be removed. In the spool of the related art, the area of the gap between a portion of the spool having these notches and a seat surface is less than 5% of the area of the opening defined by the seat surface. In a flow control valve of the related art, the first notch and the second notch 222n′ serve to regulate the flow rate of fluid by initializing a flow of fluid therethrough at the second point in time and the third point in time, respectively. In contrast, exemplary embodiments according to the present disclosure increase the area of the gap to be 5%˜50%, preferably 10%˜20%, making it possible to control the flow rate of fluid directed to the second fluid passage 112 or the third fluid passage 113 by regulating the degree of opening of the flow rate control valve instead of adjusting the area of the gap. It is therefore possible to overcome the problems of the flow control valve of the related art. In addition, a flow of fluid from the first fluid passage 111 to the second fluid passage 112 and a flow of fluid from the first fluid passage 111 to the third fluid passage 113 can be individually controlled. In the related art, points in time at which a flow of fluid is allowed and cut off and a flow rate variation profile are fixed by the geometric structure of the spool. In contrast, according to exemplary embodiments, points in time at which a flow of fluid from the first fluid passage 111 to the second fluid passage 112 is allowed and cut off and a flow rate variation profile can be individually controlled by regulating the opening and closing of the flow control valve. Likewise, points in time at which a flow of fluid from the first fluid passage 111 to the third fluid passage 113 is allowed and cut off and a flow rate variation profile can also be individually controlled. The individual controllability means that the points in time at which a flow of fluid is allowed or cut off are variable as desired, and that such variations are not influenced by the other flows of fluid. (For example, for a flow from the first fluid passage to the second fluid passage 112, the other flows of fluid include i) a flow from the first fluid passage 111 to the third fluid passage 113, ii) a flow from the second fluid passage 112 to the fourth fluid passage 114, and iii) a flow from the third fluid passage 113 to the fifth fluid passage 115.) Reference numeral 224n indicates a fourth notch allowing the third fluid passage 113 and the fifth fluid passage 115 to communicate with each other.
The first valley 211 overlaps the entirety of the first seat surface 121 at the second point in time, while the second valley 212 overlaps the entirety of the second seat surface 122 at the third point in time. The second land 222 overlaps (i.e. is fitted into) at least a portion of the second seat surface 122 at the second point in time, while the first land 221 overlaps (i.e. is fitted into) at least a portion of the first seat surface 121 at the third point in time. The second valley 212 overlaps the entirety of the fourth seat surface 124 at the second point in time, while the first valley 211 overlaps the entirety of the third seat surface 123 at the third point in time.
The hydraulic machine may include a working fluid supply 23, a first flow control valve 10, a first actuator 31, and a first control interface 43. The hydraulic machine may further include at least one among an engine 21, a pilot fluid supply 25, a tank 27, a control device 51, and pressure detectors 53.
Each of the working fluid supply 23 and the pilot fluid supply 25 may be a hydraulic pump drawing fluid from the tank 27 and then discharging pressurized fluid.
The first flow control valve 10 may be a flow control valve, as described above with reference to
The first actuator 31 can communicate with the flow control valve 10. The first actuator 31 performs work when provided with working fluid. The first actuator 31 returns the working fluid (i.e. working fluid supplied from the flow control valve 10 when the first actuator 31 is a motor actuator or working fluid within an opposite chamber when the first actuator 31 is a cylinder actuator) to the first flow control valve 10 through a portion opposite to a portion through which the working fluid is provided (i.e. the portion indicated by ‘B’ or the portion indicated by ‘A’). The working fluid returns from the first actuator 31 to the tank 27, thereby forming a closed circuit of working fluid.
Likewise, pilot fluid can also form a closed circuit. The pilot fluid supply 25 can draw fluid from the tank 27 and send the fluid to a remote control valve device 41. The remote control valve device 41 provides pilot pressure to the portion indicated by ‘a’ or the portion indicated by ‘b’ of the first flow control valve 10, when the first control interface 43 (e.g. a control lever, a control pedal, or a steering wheel) is manipulated by an operator. The first flow control valve 10 is shifted by pilot pressure applied to a portion thereof (the portion indicated by ‘a’ or the portion indicated by ‘b’), and pilot fluid discharged through the opposite portion (the portion indicated by ‘b’ or the portion indicated by ‘a’) returns to the tank 27 through the remote control valve device 41, thereby forming a closed circuit of pilot fluid.
Although a single working fluid circuit is illustrated for the sake of brevity in
In addition, a plurality of remote control valve devices 41 may be disposed in parallel in the circuit of pilot fluid, thereby forming a parallel circuit. Although a hydraulic machine is generally provided with a single circuit of pilot fluid, the present disclosure is not limited thereto.
The remote control valve device 41 is generally a device having a valve (not shown) integrated with the first control interface 43 (e.g. a control lever, a control pedal, or a steering wheel) to control the first flow control valve 10 at a distance (the flow control valve 10 located within a cab is at a distance from the first flow control valve 10 located outside of the cab). The remote control valve device 41 may include a spool (not shown) moving in response to the first control interface 43 being manipulated. For example, i) when an operator manipulates the first control interface 43 of the remote control valve device in one direction, the remote control valve device 41 allows pilot fluid that has been supplied thereto by the pilot fluid supply 25 to be supplied to the portion indicated by ‘a’ of the first flow control valve 10, thereby displacing the spool in the first flow control valve 10 to the right (in the drawings). ii) In contrast, when the operator manipulates the first control interface 43 of the remote control valve device 41 in the opposite direction, the remote control valve device 41 allows pilot fluid supplied by the pilot fluid supply 25 to be supplied to the portion indicated by ‘b’ of the first flow control valve 10, thereby displacing the spool in the first flow control valve 10 to the left (in the drawings). In addition, the spool in the remote control valve device 41 can be displaced by different distances, depending on the movements of the first control interface 43 of the remote control valve device 41, thereby opening the fluid passage of the remote control valve device 41 at different degrees of opening. Consequently, different levels of pilot pressure are applied to the first flow control valve 10.
The pressure detectors 53 detect pilot pressure directed from the remote control valve device 41 to the first flow control valve 10 and send detection signals to the control device 51.
The control device 51 calculates an amount by which the first control interface 43 is manipulated, based on a detection signal, and opens the fluid passage in the electro-proportional pressure reducing valve 400 to a degree of opening, corresponding to the input. Then, the electro-proportional pressure reducing valve 400 applies a pilot pressure, corresponding to the amount by which the first control interface 43 is manipulated, to the flow rate control valve 300. Consequently, the flow rate control valve 300 is opened to a degree of opening corresponding to the input, input through the first control interface 43. The control device 51 may include an electronic control unit (ECU). The ECU may include a central processing unit, a memory, and the like.
While the flow of fluid from the first fluid passage 111 to the second fluid passage 112 is allowed, the flow rate control valve 300 may be closed when a pressure within the second fluid passage 112 is higher than a pressure within the first fluid passage 111. While the flow of fluid from the first fluid passage 111 to the third fluid passage 113 is allowed, the flow rate control valve 300 may be closed when a pressure within the third fluid passage 113 is higher than a pressure within the first fluid passage 111. That is, the flow rate control valve 300 can act as a check valve, as in the related art.
As illustrated in
The embodiment illustrated in
The second flow control valve 11 communicates with the working fluid supply 23. Although the first flow control valve 10 and the second flow control valve 11 are illustrated as being supplied with working fluid by the same working fluid supply 23 in
A second actuator 32 communicates with the second flow control valve 11. The hydraulic machine has a first actuator priority mode. In response to the first manipulator 43 being manipulated, the flow rate control valve 300 of the first flow control valve 10 is opened, such that a degree of opening when the first actuator priority mode is active is greater than a degree of opening when the first actuator priority mode is inactive. In addition, or as an alternative, the hydraulic machine has a second actuator priority mode. In response to the first control interface 43 being manipulated, the flow rate control valve 300 of the first flow control valve 10 is opened such that a degree of opening when the second actuator priority mode is active smaller than a degree of opening when the second actuator priority mode is inactive.
The hydraulic machine includes an input device 47 by which an actuator to be operated with priority is selected. For example, when the second actuator priority mode is selected using the input device 47, the second actuator priority mode is activated to open the flow rate control valve 300 of the first flow control valve 10, such that a greater amount of working fluid is supplied, at a preset ratio or a user input ratio, to the second actuator 32 instead of to the first actuator 31. In addition, or as an alternative, the hydraulic machine may be configured, by way of example, such that the second actuator priority mode is not activated until the second control interface 44 is manipulated.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/KR2017/011033 | 9/29/2017 | WO | 00 |
