KR101932484B1 - Quantitative auto control valve - Google Patents

Abstract

The present invention relates to an automatic fixed amount control valve and, more specifically, to an automatic fixed amount control valve which automatically detects and calculates the flow rate, temperature, and pressure of flowing fluid in real-time to discharge a fixed amount of fluid in different environmental conditions, and quickly control outflow of the fluid upon an abnormal change occurring in the flowing fluid, so as to stably discharge the fluid. According to the present invention, the automatic fixed amount control valve comprises: a main body (100) having a flow path part (110) formed therein to supply fluid; a flowmeter (200) installed in the main body (100) to measure the flow rate of fluid; a sensing unit (300) to detect the temperature of the fluid flowing in the flow path part (110); an outflow control part (500) installed in the main body (100) to open/close one longitudinal side of the flow path part (110); and a mini-computer to operate the outflow control unit (500) in accordance with a measurement value measured in the flowmeter (200) and the sensing part (300).

Description

{QUANTITATIVE AUTO CONTROL VALVE}

The present invention relates to a quantitative automatic control valve, and more particularly, to a quantitative automatic control valve capable of automatically detecting flow rate, temperature, pressure and the like of a flowing fluid in real time to discharge a predetermined amount of fluid under different environmental conditions, And more particularly, to a quantitative automatic control valve capable of rapidly discharging a fluid when a sudden change in the fluid occurs.

Generally, the volume of oil changes depending on the temperature and specific gravity of gasoline, diesel oil and kerosene. The volume change of these fluids is 0.11% per 1 ° C for gasoline, 0.10% per kcal for kerosene, And 0.09% rate change per 1 ℃ for light oil.

Therefore, when the fluid is injected and filled, when the temperature rises as high as in a hot summer season, the rate of volume change increases. Therefore, when the temperature rises as in a hot summer during the fluid injection process, There is a problem that a difference between the injection amount measured in the meter and the injection amount actually injected occurs.

As a background of the present invention, there is disclosed an electronic automatic temperature compensating apparatus and an adjusting control method thereof of the Korean Patent Registration No. 0125878.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a control valve for an internal combustion engine that senses a turning radius of an adjusting ball valve installed at one side of a flow path through an opening / And the communication area can be adjusted, and the flow rate and the temperature of the fluid flowing through the mini-com can be automatically detected and calculated in real time, so that a fixed amount of fluid to which the density correction according to the temperature is applied can be controlled by controlling the communication area between the communication hole and the flow path portion And a control valve for controlling the flow of the fluid when the pressure of the fluid is suddenly changed, thereby allowing a stable fluid to flow out.

In order to accomplish the above object, the present invention provides a metering automatic control valve comprising: a main body (100) having a flow path portion (110) for fluid flow therein; A flow meter (200) installed in the main body (100) and measuring a flow rate of the fluid; A sensing unit 300 sensing a temperature of a fluid flowing in the flow path unit 110; A flow control unit 500 installed in the main body 100 to open and close one side of the flow path unit 110 in the longitudinal direction thereof; And a microcomputer for driving the flow control unit 500 according to measured values measured by the flowmeter 200 and the sensing unit 300.

The outflow control unit 500 includes a driving actuator 510 and a driving actuator 510. The driving actuator 520 extends in the direction of the flow path 110 of the main body 100 in a state in which the flow control unit 500 is installed outside the main body 100 A control ball valve (not shown) which is rotatably installed on one side of a longitudinal direction of the flow path unit 110 while being connected to a drive shaft 520 of the drive actuator 510, and a communication hole for fluid flow from one side to the other side (530).

In addition, when the flow control unit 500 is driven, the open / close sensing unit 600 senses the open / close area and the open / close state of one side of the flow channel unit 110 in the longitudinal direction, 600 includes a rotation contact hole 610 provided on the main body 100 so as to be rotatable in a state of being connected to the outflow control part 500 and having a contact round hole 620 on one side in the longitudinal direction, And a tapered portion 630 provided on the main body 100 and sensing the operation of the outflow control portion 500 by contact of the contact round hole 620 when the outflow control portion 500 is driven, do.

The sensing region 630 may include a sensing body 631 electrically connected to the MiniCom 700 and a sensing body 631 disposed at one side of the sensing body 631 to allow the contact round 610, And a sensing unit 632 for sensing the contact of the sphere 620.

According to the present invention, it is possible to confirm the state of communication between the communication hole and the flow path portion of the control ball valve by the opening / closing sensing unit for sensing the rotation of the control ball valve, so that the outflow state of the fluid can be accurately grasped, The flow rate and the temperature of the fluid are automatically sensed in real time and a certain amount of fluid to which the density correction according to the temperature is applied flows out through the control of the communication hole and the flow path portion to allow a predetermined amount of fluid to flow out, It is possible to quickly control the outflow of the fluid at the time of change to secure the stability in the outflow of the fluid.

FIG. 1 is a state diagram showing a state of a quantitative automatic control valve according to the present invention,
2 is a state diagram schematically showing a cross-sectional state of the main body according to the present invention,
3 is a state diagram showing the state of the flow control unit according to the present invention,
4 is an enlarged view of a state of the opening / closing detector according to the present invention,
5 is a state diagram showing a state of a flow meter according to the present invention;
6 is a block diagram illustrating a state in which a sensing unit, a driving actuator, and an opening / closing sensing unit are connected to a central processing unit of the MiniCOM according to the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In addition, the thickness of the lines and the size of the constituent elements shown in the drawings may be exaggerated for clarity and convenience of explanation.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention, and may vary depending on the intent or practice of the manufacturer or manufacturer producing the article. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises", "having", and the like are intended to specify that there are stated features, numbers, steps, operations, elements, parts or combinations thereof, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Hereinafter, a quantitative automatic control valve according to the present invention will be described in detail. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a state view showing a state of a quantitative automatic control valve according to the present invention, FIG. 2 is a schematic diagram of a sectional state of a main body according to the present invention, and FIG. 3 is a view FIG. 5 is a state diagram showing a state of a flow meter according to the present invention, and FIG. 6 is a flow chart illustrating the operation of the microcomputer according to the present invention, A driving actuator, and an opening / closing sensing unit.

As shown in FIGS. 1 to 6, the automatic quantitative control valve according to the present invention includes a main body 100 having a flow path portion 110, a flow meter 200 for measuring a flow rate of a fluid, A flow control unit 500 for opening and closing one side of the flow path unit 110 in the longitudinal direction thereof, and a MiniCom 700.

That is, the quantitative automatic control valve according to the present invention calculates the temperature and the flow rate of the flowing fluid and selectively adjusts the open / close area of the flow path portion 110 by the flow control portion 500, So that a precise amount of fluid can be discharged.

The main body 100 is formed with a channel portion 110 for flowing fluid therein. The channel portion 110 has an inlet port 111 through which the fluid flows and an outlet port through which the fluid flows And a main flow path 113 formed between the inflow path 111 and the outflow path 112. A flow meter 200 to be described later is installed in the inflow channel 111 to measure the flow rate of the fluid flowing through the flow channel unit 110. The outflow channel 112 is connected to the outflow control unit 500 And controls the flow rate of the fluid through the open / close area of the outflow path (112).

Here, flange portions 120 are provided on both sides of the main body 100 in the longitudinal direction so as to be removably installed in a pipe through which the fluid flows. That is, the automatic quantitative control valve according to the present invention can be installed in a detachable manner in a piping so as to be selectively installed at a required position, and maintenance and repair can be easily performed.

The flow meter 200 is installed in the main body 100 and measures a flow rate of the fluid flowing through the inflow path 111.

At this time, the flow meter 200 is installed in the mounting space 130 on the side of the inflow path 111 provided in the main body 100, with the pair of rotors 210 interdigitated and rotated. The pair of rotors 210 are driven to be engaged with each other in the mounting space 130.

The rotor 210 is a non-circular gear. In particular, an oval gear, which is a kind of elliptical gear, is used, which does not greatly change the angle of engagement due to rotation. Oval Gear is widely used as a rotor of a flow meter because it has a large discharge amount per one revolution and can maintain high precision for a long period of time.

The sensing unit 300 senses the temperature of the fluid flowing in the flow path unit 110 and the sensing unit 300 is disposed at a position outside the upper part of the main body 100 in the direction of the flow path unit 110 And is installed in the main flow path 113 of the flow path portion 110 through the through hole 140.

A pressure sensor 400 for measuring the pressure of the fluid flowing through the flow path portion 110 separately from the sensing portion 300 and a pressure sensor 400 for measuring the specific gravity of the fluid are provided on the main body 100, The sensing unit 300, the pressure sensor 400, and the hydrometer may be electrically connected to the MiniCom 700. In addition,

The outflow control part 500 is installed in the main body 100 and opens and closes the outflow path 112 which is one side of the flow path part 110 in the longitudinal direction. A drive actuator 510 in which the drive shaft 520 extends in the direction of the flow path 110 of the main body 100 in a state of being installed outside the main body 100 and a drive shaft 510 of the drive actuator 510 And a control ball valve 530 rotatably installed on one side of the channel portion 110 in a state of being connected to the flow channel portion 520 and having a communication hole 531 for fluid flow from one side to the other side.

The driving shaft portion 520 includes a driving gear 521 connected to the driving actuator 510 and a connecting gear 522 gear-coupled to the driving gear 521. And a drive shaft 523 extending in the direction of the valve 530 and coupled.

It is to be noted that the drive shaft 520 may have a structure in which the drive shaft 523 extending from the drive actuator 510 is directly connected to the control ball valve 530.

The MiniCom 700 drives the flow controller 500 according to the measured values measured by the flow meter 200 and the sensing unit 300.

That is, when the driving actuator 510 is driven under the control of the MiniCOM 700 when the fluid flowing through the flow path unit 110 flows out, the control ball valve 530 connected to the driving shaft 520 The communication hole 531 is aligned with the flow path portion 110 so that the fluid flowing through the flow path portion 110 can flow out.

When the driving actuator 510 is driven under the control of the MiniCOM 700, the control ball valve 530 is rotated by a predetermined radius, so that the communication hole 531 is closed, It is possible to prevent the outflow of the fluid by not communicating with the flow path portion 110.

The flow rate of the fluid can be controlled by controlling the communication area between the communication hole 531 of the control ball valve 530 and the flow path portion 110. This is because when the flow control portion 500 is driven, And an open / close sensing unit 600 for sensing the open / close area of the channel unit 110 in the longitudinal direction and whether the open / close unit is open or closed.

Here, the opening / closing sensing unit 600 is rotatably installed on the upper side of the main body 100 in a state of being connected to the outflow control unit 500, and has a contact round hole 620 And a control unit 500 installed at the upper side of the main body 100 to sense the driving of the outflow control unit 500 due to the interference of the contact round hole 620 when the outflow control unit 500 is driven, (630).

That is, the rotary contact hole 610 is installed so as to surround the drive shaft 523 installed in the connecting gear 522, and the tapered portion 630 is formed to be adjacent to the rotary contact hole 610, One pair is mounted on the upper side of the body 100 at mutually opposite positions.

At this time, the communication hole 531 of the control ball valve 530 and the flow path portion 110 are perpendicular to each other so that the communication hole 531 communicates with the flow path portion 110, the rotation radius at which the control ball valve 530 rotates by 1/4 is equal to the length of the arc-shaped contact round hole 620, and the driving actuator 510, The rotation of the driving shaft portion 520 by the driving of the driving shaft 520 may have a constant rotation speed.

The sensing region 630 may include a sensing body 631 electrically connected to the MiniCom 700 and a sensing body 631 disposed on one side of the sensing body 631. When the sensing contact body 610 rotates, And a sensing unit 632 for sensing the contact of the sensor 620.

In order to control the opening / closing area and the opening / closing area of one side of the flow path unit 110 by the opening / closing sensing unit 600 configured as described above, the outflow path 112 The rotary contact 610 is rotated counterclockwise after the contact round hole 620 is interfered with the tear strip by the rotation of the rotary contact hole 610 so that the contact round hole 620 The communication between the communication hole 531 and the flow path portion 110 of the control ball valve 530 is stopped by sensing the movement of the driving actuator 510 by the MiniCom 700, So that it can be positioned in line.

When the outflow path 112 is closed at one side of the flow path 110 to prevent the fluid from flowing out, the contact round hole 620 is formed by the rotation of the rotation contact hole 610, The MiniCOM 700 senses the rotation of the rotary contact 610 when the rotary contact 610 is rotated counterclockwise and the contact round hole 620 and the touched area 630 are not in contact with each other, The actuator 510 is stopped to close one side of the flow path portion 110 by the control ball valve 530.

The time at which the contact round hole 620 of the rotary contact hole 610 interferes with the touched area 630 and the time at which the contact round hole 620 does not contact the touched area 630 The change value of the open / close area of the communication hole 531 of the control ball valve 530 and the flow path portion 110 according to the increase of the determination time value is stored in advance in the MiniCOM 700, By controlling the drive of the driving actuator 510 according to the determination time value and the change value in the MiniCOM 700 when the amount of the fluid flowing out from the channel unit 110 is adjusted, And the flow path area of the flow path portion 110 to control the flow rate of the fluid.

The MiniCOM 700 is provided with a central processing unit 710 for calculating the measured values of the sensing unit 300, the flow meter 200 and the pressure sensor 400 and controlling the driving of the driving actuator 510 The central processing unit 710 may check the open / close state of one side of the flow path unit 110 through a signal of the sensing region 630, The actuator 510 can be driven to quickly close one side of the flow path portion 110. [

The MiniCOM 700 is also provided with a display device (not shown) that allows the user to check the flow rate, temperature, pressure, density, etc. of the flowing fluid in real time and input the amount of fluid flowing through the flow path 110 It may be desirable to provide the second antenna 720.

In operation of the automatic control valve according to the present invention configured as described above, the initial specific gravity of fluid and a reference value of a predetermined amount are input to the MiniCom 700, The driving actuator 510 of the outflow control part 500 is driven.

When the communication hole 531 of the control ball valve 530 is communicated with the flow path portion 110 through the rotation contact hole 610 and the tapered portion 630 in a lined manner, The driving of the driving actuator 510 is stopped.

At this time, the flow meter 200, the sensing unit 300, and the pressure sensor 400 sense the flow rate, temperature, and pressure of the fluid flowing out through the flow path unit 110 in real time, To the central processing unit 710 of the computer 700.

In the central processing unit 710 of the MiniCOM 700, the fluid temperature per hour and the fixed amount flowing through the valve are measured through the transmitted value, and the driving actuator 510 is operated for a predetermined amount of fluid flow, The communication area between the communication hole 531 of the control ball valve 530 and the flow path portion 110 is adjusted.

When the pressure signal sensed by the pressure sensor 400 is rapidly changed, the central processing unit 710 of the MiniCom 700 senses this as a danger signal and drives the actuating actuator 510, The communicating hole 531 of the valve 530 and the flow path portion 110 are not communicated with each other, thereby preventing the fluid from flowing out.

When the flow rate of the initially inputted fluid is completed, the MiniCom 700 drives the driving actuator 510 so that the communication hole 531 of the control ball valve 530 and the flow path portion 110 are communicated with each other The flow of the fluid is blocked.

As described above, the quantitative automatic control valve according to the present invention senses the temperature, flow rate, and pressure of the flowing fluid in real time and selectively controls the open / close area of the flow path by the flow control unit, So that it can be discharged.

Although the present invention has been described in detail, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope of the present invention. Therefore, the scope of the present invention is not limited to the above-described embodiments, but should be determined by equivalents to the claims, as well as the following claims.

100: main body 110:
111: Inflow path 112: Outflow path
113: main flow path 120: flange portion
130: mounting space 140: through hole
200: flow meter 210: rotor
300: sensing part 400: pressure sensor
500: flow control section 510: drive actuator
520: drive shaft portion 521: drive gear
522: connecting gear 523: drive shaft
530: Adjustable ball valve 531:
600: opening / closing detection unit 610: rotating contact hole
620: Contact Round Sphere 630: Sense Earth
631: Detection body 632: Detection unit
700: Minicom 710: Central processing unit
720: Display device

Claims (5)

A flow path 110 formed of a main flow path 113 formed between the inflow path 111 and the outflow path 112 and an outflow path 112 through which the fluid flows, A main body 100 formed in a longitudinal direction inside;
A flow meter 200 for measuring a flow rate of a fluid flowing through the inflow path 111 by being rotatably engaged with a pair of rotors 210 in a mounting space 130 provided in the inflow path 111;
The temperature of the fluid flowing through the through hole 140 passing from the upper part of the main body 100 toward the flow path part 110 to the main flow path 113 of the flow path part 110, A sensing unit 300 for sensing the signal;
A pressure sensor (400) installed on the main body (100) for measuring a pressure of fluid flowing through the flow path portion (110);
A drive actuator 510 in which the drive shaft 520 extends in the direction of the flow path 110 of the main body 100 in a state where the drive shaft 510 is installed outside the main body 100, And an adjusting ball valve (530) rotatably installed on one side of the channel portion (110) in a state of being connected to the flow channel (520) and having a communication hole (531) for fluid flow from one side to the other side The driving shaft portion 520 includes a driving gear 521 connected to the driving actuator 510, a connecting gear 522 gear-coupled to the driving gear 521, A flow control unit 500 comprising a drive shaft 523 extending in the direction of the valve 530 and opening / closing one side of the flow path unit 110 in the longitudinal direction thereof;
A rotary contact hole 610 having a contact round hole 620 formed on one side of the main body 100 so as to be rotatable with the drive shaft 523 of the outflow control part 500 being wrapped around the main body 100, And a control unit 500 installed at an upper side of the main body 100 in a state of being adjacent to the rotation contact hole 610 to control the flow control unit 500 by interference of the contact round hole 620 when the flow control unit 500 is driven, And an opening / closing sensor (600) for detecting the opening / closing area and the opening / closing of the one side of the flow path unit (110) in the longitudinal direction.
A central processing unit 710 for calculating the measured values measured by the flow meter 200, the sensing unit 300 and the pressure sensor 400 and controlling the driving of the driving actuator 510 of the outflow control unit 500 And a mini-com (700)
The sensing region 630 may include a sensing body 631 electrically connected to the MiniCom 700 and a sensing body 631 disposed on one side of the sensing body 631 to receive the contact round hole 620 And a sensing unit (632) for sensing the contact of the valve body.
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