JP2004019756A - Flow control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To stably control the flow of a pressure fluid by damping the pressure fluctuation such as pulsation. <P>SOLUTION: This flow control device includes a pulsation damping mechanism 24 having a plurality of wave killing projection parts 77a to 77f projected from the inner wall of a fluid passage 36, thereby, the pressure fluid circulating through the fluid passage 36 collides with the plurality of wave killing projection parts 77a to 77f to disperse the pulsation energy and dissipate the same. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a flow control device capable of stably controlling the flow rate of a pressure fluid by attenuating the pulsation of the pressure fluid flowing through a fluid passage.
[0002]
[Prior art]
FIG. 8 shows a flow control system according to the related art for controlling the flow rate of a fluid flowing through a fluid passage.
[0003]
The flow control system 1 is connected to a pump 3 for sucking and feeding a pressure fluid stored in a tank 2 and connected to a downstream side of the pump 3 via a pipe 4 such as a tube. An on-off valve 5 for opening and closing a fluid passage of a supplied pressure fluid, and a flow control connected to a downstream side of the on-off valve 5 via a pipe 6 such as a tube to control a flow rate of the pressure fluid flowing through the fluid passage. And a valve 7.
[0004]
A flow sensor 8 for detecting the flow rate of the pressure fluid flowing through the fluid passage is provided downstream of the flow control valve 7, and the pressure fluid flowing through the fluid passage is determined based on a detection signal from the flow sensor 8. Is displayed on the display 9.
[0005]
An electro-pneumatic regulator 11 that regulates the pressure of air supplied from a compressed air supply source 10 and guides a predetermined pilot pressure to a pilot chamber of the flow control valve 7 is connected to the flow control valve 7 through a pipe 12 such as a tube. Connected via The electropneumatic regulator 11 controls the air supplied from the compressed air supply source 10 to a predetermined pressure based on a control signal derived from the controller 13 and derives it as a pilot pressure.
[0006]
The general operation of the flow control system 1 according to the prior art will be described. The pressure fluid stored in the tank 2 and supplied through the pump 3 is controlled by the on-off valve 5 being opened. Introduced to valve 7. In the flow control valve 7, a pilot pressure adjusted to a predetermined pressure via an electropneumatic regulator 11 is introduced into a pilot chamber, and is supplied via the on-off valve 5 to the pilot pressure introduced into the pilot chamber. By balancing the pressure of the pressure fluid (primary pressure), the valve opening of a valve body (not shown) is controlled.
[0007]
Therefore, in the flow control valve 7, the pilot pressure controlled based on the control signal derived from the controller 13 and the primary pressure of the pressurized fluid supplied through the on-off valve 5 are balanced, so that the valve The valve opening is adjusted, and the flow is controlled and derived to a flow rate corresponding to the valve opening of the valve body.
[0008]
The flow rate of the pressure fluid derived from the flow control valve 7 is detected by a flow rate sensor 8 and the flow rate is displayed on a display 9.
[0009]
[Problems to be solved by the invention]
However, in the flow control system according to the related art, for example, pressure fluctuation such as pulsation occurs in the pressure fluid supplied through the on-off valve due to the pumping operation of the pump, so that the flow control valve Stable flow control becomes difficult.
[0010]
The present invention has been made in view of the above points, and has as its object to provide a flow rate control device capable of attenuating pressure fluctuations such as pulsation and stably controlling the flow rate of a pressure fluid. .
[0011]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides an apparatus for controlling a flow rate of a pressure fluid flowing through a fluid passage by a valve body that opens and closes a fluid passage.
A pulsation damping mechanism for damping pressure fluctuations due to pulsation of the pressure fluid flowing through the fluid passage, wherein the pulsation damping mechanism includes a plurality of protrusions provided to protrude from an inner wall of the fluid passage. .
[0012]
In this case, the plurality of protrusions may be spirally arranged along the axial direction of the fluid passage.
[0013]
According to the present invention, when pressure fluctuation such as pulsation occurs in the pressure fluid flowing along the fluid passage, the pulsating pressure fluid collides with a plurality of protrusions provided inside the fluid passage, and The pulsating energy contained in the pressure fluid is dispersed and disappears by the projections.
[0014]
Therefore, according to the present invention, it is possible to attenuate the pressure fluctuation such as the pulsation of the pressure fluid flowing through the fluid passage and stably control the flow rate of the pressure fluid.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
A preferred embodiment of a flow control device according to the present invention will be described below in detail with reference to the accompanying drawings.
[0016]
In FIG. 1, reference numeral 20 indicates a flow control device according to an embodiment of the present invention.
[0017]
The flow control device 20 includes a joint portion 22 to which a tube (not shown) is detachably connected at a predetermined interval, a pulsation damping mechanism 24 provided on one side of the joint portion 22 along the axial direction, A flow control mechanism (flow control mechanism) 26 provided on the other side of the portion 22 along the axial direction.
[0018]
The joint 22, the pulsation damping mechanism 24, and the flow rate adjusting mechanism 26 are integrally assembled.
[0019]
The joint portion 22 has a first joint body 30 having a first port 28 formed at one end thereof, and a second joint body 34 having a second port 32 formed at the other end thereof. The first and second joint bodies 30, 34 connected substantially coaxially are provided with a fluid passage 36 for communicating the first port 28 and the second port 32.
[0020]
Further, the joint portion 22 engages with the first port 28 and the second port 32, respectively, and the inner member 40 inserted into the opening of the tube 38 and the first and second joint bodies 30, 34 A lock nut 42 is provided to maintain the liquid-tightness of the connection portion of the tube 38 by screwing into a thread groove formed at the end.
[0021]
A pulsation damping mechanism 24 is provided at one of the joint portions 22 close to the first port 28, and the pulsation damping mechanism 24 is configured by integrally connecting a plurality of blocks including an upper bonnet 44. It has a housing 46.
[0022]
Air is supplied to the inside of the bonnet 44 via a pressure fluid supply port 50 connected to a compressed air supply source 48, and the air supplied from the pressure fluid supply port 50 is adjusted to a predetermined pressure. A pressure adjusting unit 54 is provided for guiding the adjusted air toward the passage 52.
[0023]
In the pressure adjusting section 54, air supplied from the pressure fluid supply port 50 is introduced into a diaphragm chamber (not shown), and the spring force of a spring member adjusted by a pressure adjusting handle (not shown) is introduced into the diaphragm chamber. The pressure of the pressure fluid supply port 50 is adjusted by balancing the pressing force for pressing a diaphragm (not shown) by the pressure of the pressurized fluid and displacing a stem and a valve body (not shown) under the bending action of the diaphragm (not shown). Can be adjusted to a desired pressure.
[0024]
On the other hand, on the lower side of the housing 46, there is provided a pulsation equilibrium part 58 for performing an on / off operation of a valve body 56 that opens and closes the fluid passage 36 based on the air derived from the pressure regulating part 54.
[0025]
As shown in FIG. 2, the pulsation equilibrium portion 58 is formed with a pressure chamber 60 into which air (pilot pressure) derived from the pressure adjusting section 54 through the passage 52 is introduced. The valve member 62 facing the fluid passage 36 is provided so as to be displaced under the action of air introduced into the fluid passage 36.
[0026]
The valve member 62 is disposed between an upper first diaphragm 64 and a lower second diaphragm 66, and is provided with a sliding plate 68, which is displaceable in a vertical direction, and the sliding plate 68. A valve body 56 connected to a lower central portion of the lower portion 68 via a screw member 70 so as to be able to approach or separate from a seat portion 72 formed in the housing 46; and an outer peripheral surface of the sliding plate 68. And an intermediate member interposed between the slide plate 68 and the valve body 56 and functioning as a stopper by contacting a slope 76 formed in the housing 46. 78.
[0027]
The first diaphragm 64 is formed of, for example, a rubber material, and has a function of protecting the sliding plate 68. The second diaphragm 66 maintains the liquid tightness of the pressure fluid and removes the liquid pool. For this purpose, for example, it may be formed of a resin material such as polytetrafluoroethylene (PTFE).
[0028]
The inner wall of the fluid passage 36 near the first port 28 is provided with a plurality of wave-breaking projections (projections) 77 a to 77 f protruding from the inner wall surface toward the inner center of the fluid passage 36 by a predetermined length. As shown in FIGS. 3 and 4, the plurality of wave-breaking projections 77 a to 77 f have a substantially trapezoidal shape that gradually widens from the inner wall of the fluid passage 36 toward the center of the fluid passage 36. It has a curved portion 79 with a chamfered portion and a concave portion 81 slightly recessed. Further, the plurality of wave-breaking projections 77a to 77f are spirally arranged at predetermined intervals along the clockwise direction on the inner peripheral wall surface of the fluid passage 36.
[0029]
In this case, as shown in FIG. 4, the first wave breaking protrusion 77a closest to the first port 28 is inclined at a predetermined angle in the direction of arrow A, and the second wave breaking protrusion 77b is moved in the direction of arrow B. The third wave-dissipating protrusion 77c is inclined by a predetermined angle in the direction of arrow C, the fourth wave-dissipating protrusion 77d is inclined by a predetermined angle in the direction of arrow D, and the fifth wave-dissipating protrusion 77e is inclined by a predetermined angle. The sixth wave-breaking projection 77f is inclined at a predetermined angle in the direction of arrow E, and the sixth wave-breaking projection 77f is formed at a predetermined angle in the direction of arrow F. The number of the wave-breaking projections 77a to 77f is not limited to six, but may be set to a desired number corresponding to the diameter of the fluid passage 36, the flow path length, and the like.
[0030]
When pulsation occurs in the pressure fluid flowing along the fluid passage 36, the pulsating pressure fluid collides with the plurality of wave-breaking projections 77a to 77f, and the pulsating pressure fluid enters the pressure fluid by the plurality of wave-breaking projections 77a to 77f. The contained pulsating energy can be dispersed and dissipated.
[0031]
Therefore, even if there is pressure fluctuation such as pulsation in the pressure fluid flowing through the fluid passage 36, the pressure fluid collides with the plurality of wave-breaking projections 77a to 77f projecting from the inner wall of the fluid passage 36 to pulsate. The energy is attenuated, and the pulsating energy of the pressure fluid flowing through the fluid passage 36 is attenuated by the pressure of the air supplied to the pressure chamber 60, so that the pressure fluid maintained at a substantially constant pressure can flow. .
[0032]
The flow rate adjusting mechanism 26 includes a housing 80 integrally connected to the second joint body 34, a first piston 82 that is displaced along a chamber formed inside the housing 80 along the arrow X <b> 1 or X <b> 2 direction, and And a second piston 84.
[0033]
As shown in FIG. 5, the first piston 82 is formed with a large-diameter first projection 86a on the lower side and a small-diameter second projection 86b on the upper side. The portion 86a is slidably inserted into the housing 80. A piston packing 88a is mounted on the outer peripheral surface of the first piston 82 via an annular groove.
[0034]
The second piston 84 is formed to have a substantially U-shaped cross section. The second protrusion 84b of the first piston 82 is engaged with a recess formed below, and is slidably inserted into the housing 80. A pair of piston packings 88b and 88c are mounted on the outer peripheral surface through an annular groove.
[0035]
A spring member 90 is interposed between the inside of the second piston 84 and the second projecting portion 86b, and the first piston 82 and the second piston 84 are separated from each other by the spring force of the spring member 90. Being energized.
[0036]
Further, a through screw hole 96 is formed in a substantially central portion of the second piston 84 to be screwed with a shaft portion of a drive shaft 92 described later.
[0037]
A pin member 98 is mounted on the side surface of the second piston 84 so as to protrude by a predetermined length through a groove, and the pin member 98 is provided so as to engage with an engagement groove 100 formed on the side surface of the housing 80. ing. That is, when the second piston 84 is displaced in the axial direction, the pin member 98 has a function of preventing rotation of the second piston 84 in the circumferential direction.
[0038]
A valve body 102 formed of a flexible material such as a resin material or a rubber material is connected to a lower end of the first piston 82, and the valve body 102 is integrated with the first piston 82. It is provided to be displaced. The valve body 102 includes a thick portion 104a formed substantially at the center and a thin portion 104b formed integrally with the thick portion 104a, and is formed to be freely bendable.
[0039]
In this case, the valve body 102 is separated from the seating portion 106 formed on the second joint body 34 or is seated on the seating portion 106 to open and close the fluid passage 36 and to open and close the valve of the valve body 102. The function of controlling the flow rate of the pressurized fluid flowing through the fluid passage 36 with high accuracy based on the lift amount (displacement amount of the valve body 102 along the axial direction).
[0040]
A ring-shaped buffer member 108 for protecting the thin portion 104b of the valve body 102 is provided on the upper surface of the valve body 102, and the buffer member 108 is formed of, for example, an elastic member such as rubber. 80 is held by the lower surface.
[0041]
As shown in FIG. 1, on the upper side of the flow rate adjusting mechanism 26, there is provided a bonnet 110 integrated with an upper portion of a housing 80, and a power source (not shown) is energized in the bonnet 110. A linear actuator 112 for driving the valve element 102 by the actuator and a rotation detecting unit 114 for detecting the amount of displacement of the valve element 102 based on the amount of displacement of the linear actuator 112 are provided.
[0042]
Note that a connector 120 for guiding a detection signal to the controller 118 via the lead wire 116 is disposed close to the rotation detection unit 114.
[0043]
The linear actuator 112 is composed of a linear stepping motor that is energized and deactivated by a rotation drive control signal (pulse signal) derived from a controller 118, and includes a stator and a rotor (not shown) provided in a casing, and a power supply (not shown). A rotor (not shown) is provided so as to rotate in a predetermined direction under the action of an exciting current supplied from the motor.
[0044]
The drive shaft 92 of the linear actuator 112 is provided so as to be displaceable along the axial direction (the direction of the arrow X1 or X2) under its rotation.
[0045]
On the other hand, the drive shaft 92 of the linear actuator 112 is provided with a first shaft portion 122 and a second shaft portion 124 in which screw portions having a predetermined pitch are engraved, respectively. Is set to be larger than the diameter of the lower second shaft portion 124.
[0046]
The rotation detecting unit 114 is provided with a light emitting unit and a light receiving unit (not shown) arranged at positions facing each other with a predetermined space therebetween, and is connected to a drive shaft 92 of a linear actuator 112 and integrally rotates. No rotor is provided. In this case, by receiving the light emitted from the light emitting element passing through the inside of the rotor by the light receiving element, the rotation angle and the number of rotations of the drive shaft 92 of the linear actuator 112 are detected, and the detection signal is derived to the controller 118 as a detection signal. You.
[0047]
In the controller 118, a displacement amount along the axial direction of the drive shaft 92 is calculated based on the pitch data of the drive shaft 92 of the linear actuator 112 and the detection signal such as the number of revolutions, and based on the calculation result, The separation distance between the valve element 102 and the seat 106, that is, the valve lift of the valve element 102 is calculated.
[0048]
Accordingly, the controller 118 obtains a deviation from a preset lift amount of the valve body 102, and adjusts the lift amount of the valve body 102 so that the deviation becomes zero, thereby controlling the pressure fluid flowing through the fluid passage 36. Can be controlled with high precision.
[0049]
The flow control device 20 according to the embodiment of the present invention is basically configured as described above. Next, the operation and the operation and effect will be described.
[0050]
As shown in FIG. 6, the pressure fluid stored in the tank 132 under the suction action of the pump 130 is supplied to the joint portion 22 of the flow control device 20, and is transmitted through the first port 28 of the joint portion 22. Pressure fluid is introduced into the pulsation balance 58. In this case, in the pressure adjusting section 54, the air supplied from the pressure fluid supply port 50 is introduced into a diaphragm chamber (not shown), and is introduced into the diaphragm chamber and the spring force of the spring member under the bending action of the diaphragm (not shown). By balancing the pressure of the air, the pressure of the air is adjusted to a desired pressure.
[0051]
Accordingly, the air adjusted to a desired pressure by the pressure adjusting unit 54 is introduced into the pressure chamber 60 of the pulsation equilibrium unit 58 through the passage 52, and the primary pressure of the pressure fluid flowing through the fluid passage 36 and the pressure The pressure of the air introduced into the chamber 60 is balanced.
[0052]
When the pressure fluid flowing through the fluid passage 36 has pressure fluctuation such as pulsation, the pressure fluctuation of the pressure fluid is transmitted to the sliding plate 68 via the second diaphragm 66, and the sliding plate 68 is slightly moved up and down. Operate. At this time, the pressure fluctuation of the pressure fluid is attenuated by being buffered by the air in the pressure chamber 60 provided on the opposite side of the fluid passage 36 with the sliding plate 68 therebetween.
[0053]
Further, in the present embodiment, when the pressure fluid flowing through the fluid passage 36 has pressure fluctuation such as pulsation, the pulsating pressure fluid collides with the inclined surfaces of the plurality of wave-breaking projections 77a to 77f, respectively, By dispersing the pulsating energy contained in the pressure fluid by the wave-dissipating protrusions 77a to 77f, the pulsating energy can be smoothly eliminated.
[0054]
As described above, in the present embodiment, even if the pressure fluid flowing through the fluid passage 36 has a pressure fluctuation such as pulsation, the plurality of wave-dissipating protrusions 77a to 77f formed to protrude from the inner wall of the fluid passage 36. The pulsation energy is attenuated by the collision of the pressure fluid, and the pulsation energy of the pressure fluid flowing through the fluid passage 36 is attenuated by the pressure of the air supplied to the pressure chamber 60, so that the pressure is maintained at a substantially constant pressure. A fluid can be circulated.
[0055]
The pressure fluid led out of the pulsation balance part 58 flows along the fluid passage 36 and is introduced into the flow rate adjusting mechanism 26. The flow rate adjusting mechanism 26 adjusts the distance between the valve body 102 and the seat 106 by biasing and deactivating the linear actuator 112 based on a rotational drive control signal derived from the controller 118. Is set. The valve opening of the valve body 102 is adjusted, and the pressure fluid flowing through the fluid passage 36 is controlled to a flow rate corresponding to the valve opening of the valve body 102.
[0056]
In this case, the controller 118 derives an urging signal to the linear actuator 112 and displaces the first and second shaft portions 122 and 124 that are the drive shaft 92 of the linear actuator 112 in the direction of the arrow X1. Accordingly, the second piston 84 and the first piston 82 screwed to the second shaft portion 124 through the through screw holes 96 under the rotation of the drive shaft 92 are displaced upward, whereby the valve body 102 is moved. It rises integrally and separates from the seat 106.
[0057]
The amount of displacement of the valve body 102 along the axial direction is detected by a rotation detector 114 via the amount of rotation of a linear actuator 112, and based on a detection signal (pulse signal) derived from the rotation detector 114, The controller 118 controls the linear actuator 112 so that the valve body 102 stops at a preset position.
[0058]
That is, the controller 118 counts the pulse signal derived from the rotation detecting unit 114 and, when the pulse signal reaches a predetermined number of pulses set in advance, derives a deenergization signal to the linear actuator 112 and drives the linear actuator 112 in a driving state. To stop. The controller 118 calculates the amount of displacement of the drive shaft 92 from the amount of rotation such as the number of rotations and the angle of rotation of the drive shaft 92 and the thread pitch of the second shaft portion 124 screwed to the second piston 84. Can be calculated. As a result, the lift amount of the valve body 102 can be controlled with high accuracy, and the flow rate of the pressure fluid corresponding to the lift amount of the valve body 102 can be controlled with high accuracy.
[0059]
In the present embodiment, a plurality of wave-breaking projections 77a to 77f protruding from the inner wall of the fluid passage 36 are provided as the pulsation damping mechanism 24, and a simple structure can smoothly attenuate pressure fluctuations such as pulsation of the pressure fluid. it can. Therefore, it is possible to prevent an increase in manufacturing cost without increasing the size of the entire apparatus.
[0060]
As shown in FIG. 7, a flow sensor 140 is provided in a fluid passage downstream of the flow control device 20, and a sensor detection signal from the flow sensor 140 is introduced into the controller 118 to perform feedback control. Thus, the flow rate flowing through the fluid passage 36 may be monitored in real time.
[0061]
In this case, the controller 118 compares the preset flow rate data with the sensor detection signal derived from the flow rate sensor 140, and adjusts the valve lift amount of the valve body 102 so that the deviation becomes zero. The flow rate actually flowing through the fluid passage 36 can be controlled with high accuracy.
[0062]
【The invention's effect】
According to the present invention, the following effects can be obtained.
[0063]
In other words, when the pressure fluid collides with the plurality of projections protruding from the inner wall of the fluid passage, pressure fluctuation such as pulsation is attenuated, and the flow rate of the pressure fluid can be stably controlled.
[Brief description of the drawings]
FIG. 1 is a partially omitted longitudinal sectional view of a flow control device according to an embodiment of the present invention.
FIG. 2 is a partially enlarged longitudinal sectional view of a pulsation equilibrium section constituting the flow control device of FIG.
FIG. 3 is a transparent perspective view of a plurality of wave breaking protrusions provided on an inner wall in a fluid passage.
FIG. 4 is a longitudinal sectional view taken along the line IV-IV in FIG. 1;
FIG. 5 is a partially enlarged longitudinal sectional view of a flow rate adjusting mechanism constituting the flow rate control device of FIG. 1;
FIG. 6 is a block diagram of a flow control system incorporating the flow control device shown in FIG. 1;
FIG. 7 is a block diagram showing a modification of the flow control system of FIG. 6;
FIG. 8 is a block diagram of a flow control system according to the related art.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 20 ... Flow control device 22 ... Coupling part 24 ... Pulsation damping mechanism 26 ... Flow rate adjusting mechanism 28, 32 ... Port 36 ... Fluid passage 54 ... Pressure regulating part 56,102 ... Valve 58 ... Pulse balancing part 60 ... Pressure chamber 64 66, diaphragm 68, sliding plates 72, 106, seating portions 77a to 77f, wave-dissipating protrusions 79, curved portions 81, concave portions 82, 84, pistons 92, drive shafts 96, through screw holes 112, linear actuators 114, Rotation detector 118 ... Controllers 122 and 124 ... Shaft 140 ... Flow sensor

Claims (2)

In a device that controls the flow rate of the pressure fluid flowing through the fluid passage by a valve body that opens and closes the fluid passage,
A pulsation damping mechanism for damping pressure fluctuations due to pulsation of the pressure fluid flowing through the fluid passage, wherein the pulsation damping mechanism includes a plurality of protrusions provided to protrude from an inner wall of the fluid passage. Flow control device. The device of claim 1,
The flow control device according to claim 1, wherein the plurality of protrusions are spirally arranged along an axial direction of the fluid passage.

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