KR101695455B1 - Apparatus for regulating flow late - Google Patents

Abstract

The present invention relates to a device for controlling a flow rate of a fluid, which is capable of administering a predetermined flow rate into the body for a predetermined time without being influenced by an amount of fluid gradually decreasing with time of administration.
The apparatus for controlling the flow rate of a fluid according to the present invention comprises a fluid inlet 110 having a fluid inlet 111 for receiving a fluid from a fluid bottle and a vertical central axis 112 at a center thereof, And a liquid discharge port 120 formed at one side of the liquid discharge port 121 and connected to the liquid discharge port 121. The liquid discharge port 120 is connected to the liquid discharge port 120 through a vertical center shaft, A circular flow passage 140 formed around the vertical center axis formed on the upper surface of the flow rate adjusting dial 130 and having a radius different from that of the circular flow passage about the vertical center axis, A flow control valve 150 formed on the bottom surface of the inflow portion and configured to be in close contact with the upper portion of the flow rate adjusting dial, A lower gasket 170 provided on the upper surface of the liquid discharge portion and closely attached to a lower portion of the flow rate adjusting dial, a first gasket 170 formed to penetrate the upper gasket and to communicate with the fluid inlet and the circular flow path, A second chamber 190 formed through the flow rate adjusting dial so as to communicate with the flow rate adjusting flow passage; a connection passage 200 formed on the upper surface of the upper gasket to connect the second chamber and the circular flow passage; And a third chamber 210 formed to penetrate through the lower gasket to communicate the flow rate control passage and the fluid discharge port and to generate a negative pressure that varies according to the degree of rotation of the flow rate control dial on the flow rate control channel side .

Description

Apparatus for regulating flow rate

The present invention relates to a device for controlling a flow rate of a fluid, which is capable of administering a predetermined flow rate into the body for a predetermined time without being influenced by an amount of the fluid gradually decreasing with time.

In general, the sap may cause a hazardous situation to the patient if the necessary amount is not administered into the body for a predetermined time depending on the condition of the patient. Therefore, a fluid flow control device capable of freely controlling the discharge flow rate of the fluid is essentially provided in the fluid fluid set.

As shown in FIG. 1, the conventional liquid flow rate regulating apparatus 10 includes a check valve 3 connected to the lower end of the liquid bottle 1 so as to visually check the flow amount of the liquid, The hose 2 is provided in the middle of the hose 2 connecting the injector 4 injected to the patient so as to change the cross-sectional area of the hose 2 so as to control the flow rate of the liquid.

2, the fluid flow rate regulating device 10 includes a fixing member 11 having a fluid inlet 11a and a fluid outlet 11b connected to the hose 2, A first circular flow path 12a and a second circular flow path 12b are formed on the front side of the first circular flow path 12a so as to be vertically rotatable in a vertical direction and rotatably connected to the liquid inflow port 11a, A second circular flow passage 12b connected to the fluid discharge port 11b with a smaller diameter and a connection flow passage 12b communicating with the first circular flow passage 12a and the second circular flow passage 12b while communicating with the liquid inlet 11a 12c are formed.

Therefore, depending on the degree of rotation of the regulating member 12, the flow path of the fluid from the fluid inlet 11a to the fluid outlet 11b is changed, and the fluid outlet 11b The amount of the liquid exuded is controlled.

However, the above-described conventional fluid flow controller 10 has the following problems.

First, the conventional liquid flow rate regulating device 10 is constituted only by the fixing member 11 and the adjusting member 12, so that the user can rotate the adjusting member 12 only by using both hands. Therefore, the inconvenience of use is very large.

Secondly, in the conventional fluid flow control device 10, since the adjustment member 12 is vertically installed on the front surface of the fixing member 11, if the adjustment member 12 is rotated to the left or right, Since the hose 2 is transferred to the hose 2 and the hose 2 is bent to the left or right side, there is a problem that it is difficult to discharge the fluid smoothly during operation.

Thirdly, since the conventional liquid flow controller 10 is configured to control the amount of liquid discharged according to the change of the depth and width of the channel, the liquid flow controller 10 discharges the liquid to the liquid outlet 11b according to the amount of liquid contained in the liquid bottle. There is a change in the amount of the liquid. That is, if the amount of the liquid inside the sap is gradually decreased with time, the pressure of the sap flowing through the sap inlet 11a becomes small, and as a result, the sap flowing through the sap inlet 11a As the speed decreases, the amount of the liquid discharged into the liquid discharge port 11b gradually decreases.

In this way, if the amount of the discharged liquid is changed, if a certain amount of liquid can not be administered to the patient for a predetermined time, the normal drug efficacy may not be expressed or it may cause a dangerous situation. Therefore, It is inconvenient to rotate the adjusting member 12 so that the liquid is discharged.

In addition, if the amount of liquid discharge is increased by resetting the control member 12 in order to compensate for the decreased amount of the liquid discharge due to the above-mentioned reason, the liquid is injected into the patient at a speed higher than the normal speed, Lt; / RTI >

KR10-0468222B1

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a fluid flow rate regulating device capable of discharging a certain amount of fluid at a constant rate for a predetermined time without being affected by the amount of fluid gradually decreasing with time The purpose is to provide.

In order to achieve the above object, the present invention provides a fluid flow rate regulating apparatus comprising: a fluid inflow section formed with a fluid inflow port for inflowing a fluid from a fluid infusion bottle and having a vertical central axis at the center; A flow rate adjusting dial coupled between the fluid inflow section and the fluid inflow section such that the fluid inflow section and the fluid inflow section are rotatably fitted horizontally through a vertical center shaft; A circular flow passage formed on the upper surface of the flow rate adjusting dial and having a radius different from that of the circular flow passage on the bottom surface of the flow rate adjusting dial about the vertical center axis, A flow rate adjusting flow path, a flow rate adjusting dial provided on the bottom surface of the fluid inflow portion, A first chamber formed on the upper surface of the liquid discharge portion and closely contacting the lower portion of the flow rate adjusting dial, a first chamber formed to penetrate the upper gasket to communicate the fluid inlet and the circular flow passage, A second chamber formed through the flow rate adjusting dial so as to communicate with the flow path, a connection channel formed on the upper surface of the upper gasket to connect the second chamber and the circular flow path, And a third chamber formed through the gasket to generate a negative pressure that varies with the degree of rotation of the flow rate adjusting dial on the flow rate adjusting flow path side.

The second chamber may have a larger cross-sectional area than the circular flow path and the flow rate control flow path, and the third chamber may have a cross-sectional area larger than the flow rate control flow path.

It is also preferable that a grip portion extending from the lower end of the liquid discharge portion is further provided.

On the upper surface of the flow rate adjusting dial, circular first adhered protrusions formed on the inner side and outer side of the circular flow passage about the vertical center axis, and circular second adhered protrusions formed on the outer side of the second chamber about the vertical center axis are formed And a circular fourth adhered projection formed on an inner side and an outer side of the flow rate control channel around the vertical center axis and a circular fourth adhered projection formed on the bottom of the flow rate adjusting dial and formed on the inner side of the third chamber about the vertical center axis, Can be formed.

Preferably, the flow rate control channel and the fluid discharge port are spaced apart from each other so as not to lie on the same vertical line, and the third chamber is formed as a long hole directed toward the vertical center axis.

In the present invention having the above-described structure, since the plurality of chambers for generating negative pressure are provided on the discharge path of the liquid, the speed and amount of the discharged liquid are determined according to the change in the sound pressure generated in each chamber. Regardless of the amount, there is an effect that the liquid is discharged at a constant speed and amount at all times.

In addition, the present invention is characterized in that the flow rate adjusting dial is configured to be rotatable in a horizontal state, and the handgrip portion formed from the lower end is provided at the fluid-discharging port assembled at the lower portion of the flow rate adjusting dial. Therefore, when the user grasps the handle portion by hand, It is possible to rotate the flow rate adjusting dial very easily and easily, and also, since the external force is not transmitted to the hose, it is possible to ensure a smooth fluid discharge even when the flow rate adjusting dial is operated.

1 is a perspective view showing a state in which a general fluid-flow regulator is used.
2 is an exploded perspective view of the apparatus for controlling the flow rate of the fluid in Fig.
3 is a perspective view of the apparatus for controlling the flow of a fluid according to the present invention.
4 is an exploded perspective view of the apparatus for controlling a flow rate of a fluid according to the present invention.
5 is an exploded bottom perspective view of the apparatus for controlling the flow of a fluid according to the present invention.
6 is a cross-sectional perspective view of the apparatus for controlling the flow of a fluid according to the present invention.
7 is a plan view showing a state in which the liquid inflow part constituting the present invention is removed.
FIGS. 8 to 10 are bottom views of a state in which the liquid discharge portion constituting the present invention is removed, respectively, in which a discharge flow rate is adjusted according to the rotation state of the flow rate adjusting dial.

The features and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It must be interpreted in terms of meaning and concept.

Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings. The same reference numerals are used for the same components, and only the different portions are described for the sake of clarity.

3 to 6, the present invention is a medical device including a fluid inflow section 110 connected to an end of a hose 2a connected to a lower end of a fluid infusion bottle and through which a fluid flows from a fluid infusion bottle, A fluid outlet 120 connected to the connected hose 2b to discharge the fluid into the hose 2b and a flow rate adjusting dial 130 installed between the fluid inlet 110 and the fluid outlet 120 .

One side of the fluid inflow section 110 is formed with a fluid inflow port 111 through which the inflow fluid flows vertically. The fluid inflow port 111 is preferably formed to protrude upward from the upper surface of the inflow fluid inflow section 110 so that the inflow port 111 can be easily coupled with the hose 2a connected to the lower end of the infusion bottle. A vertical center axis 112 protruding downward is provided at the center of the bottom of the fluid inlet 111.

At one side of the liquid discharge unit 120, a liquid discharge port 121 through which liquid is discharged is vertically formed. The fluid outlet 121 is preferably formed to protrude downward from the bottom surface of the fluid-discharging portion 120 so that the fluid-discharging port 121 can be easily engaged with a hose 2b connected to a syringe injected to a patient.

A through hole 122 through which the vertical center axis 112 is inserted is formed at the center of the fluid outlet 120 and is inserted into the vertical center axis 112 of the fluid inlet 110 through the through hole 122. And is coupled to the lower portion of the fluid inflow portion 110 in a state of being in the state shown in Fig. In this case, the vertical center axis 112 includes a pair of elastic pieces 112a facing each other so as to be elastically fitted to the through holes 122 of the liquid discharge port 121, and a pair of elastic pieces 112a And an inclined protrusion 112b protruding upward from the lower end toward the outside. In addition, an insertion hole 125 having an outer diameter larger than the diameter of the elastic pieces 112a is coupled between the elastic pieces 112a. The insertion port 125 is extended from the vertical center axis 112 in the insertion process so as to be in close contact with the through hole 122 of the liquid discharge unit 120 to thereby connect the liquid discharge unit 110 and the liquid discharge unit 120 Thereby increasing the bonding force.

According to the present invention, the liquid receiving part 120 may further include a grip part 123. The handle 123 is formed to extend downward from the lower end of the liquid discharge unit 120. When the user grasps the handle 123, the handle 123 is rotated in the left-right direction using the thumb and index finger Rotating operation is possible. The handle portion 123 is formed so as to extend downward from the lower edge of the sap outlet 120 so as to minimize the interference between the handle portion 123 and the hoses 2a and 2b connected to the sap outlet 121 and the sap outlet 121 It is preferable that they are formed of a pair facing each other.

The flow rate adjusting dial 130 has a through hole 131 formed at the center thereof and a clearance 131 is formed in the vertical center axis 112 between the fluid inlet 110 and the fluid outlet 120 through the through hole 131. [ And is coupled in a rotatable state.

A circular flow passage 140 having a vertical center axis 112 as a center is formed on the upper surface of the flow rate adjusting dial 130. The radius of the circular passage 140 is equal to the distance between the liquid inlet 111 and the vertical center axis 112. Therefore, the circular flow path 140 communicates with the liquid inflow port 111 located at the upper side.

The arc-shaped flow rate regulating passage 150 is formed on the bottom surface of the flow rate regulating dial 130. The flow rate regulating passage 150 has a radius different from that of the circular flow passage 140 about the vertical center axis 112 and gradually increases or decreases in cross-sectional area. In this embodiment, the depth of the flow rate control valve 150 gradually changes.

On the other hand, on the outer surface of the flow rate adjusting dial 130, a plurality of anti-slip protrusions formed in the vertical direction may be formed to prevent sliding during the rotation operation.

An upper gasket 160 is installed on the bottom surface of the fluid inflow portion 110. The upper gasket 160 is made of a plate material having a predetermined thickness, such as silicon, which is harmless to the human body but has self-elasticity to exhibit excellent watertightness. A through hole 161 through which the vertical center shaft 112 passes is formed at the center of the upper gasket 160 and is coupled to the vertical center shaft 112 in a state of being fitted to the vertical center shaft 112. The top surface of the upper gasket 160 closely contacts the bottom surface of the fluid inflow portion 110 and the bottom surface closely contacts the top surface of the flow rate control dial 130. A fixing protrusion 162 is formed on the outer side of the upper gasket 160 to prevent the upper gasket 160 from flowing right and left between the fluid inlet 110 and the flow rate adjusting dial 130, A fixing groove 113 corresponding to the fixing protrusion 162 is formed.

A lower gasket 170 is installed on the upper surface of the liquid discharge unit 120. The lower gasket 170 is formed of a plate-like material having a predetermined thickness and is made of a material such as silicon which is harmless to the human body and has self-elasticity to exhibit excellent watertightness. A through hole 171 through which the vertical center shaft 112 passes is formed at the center of the lower gasket 170 and is coupled to the vertical center shaft 112 in a state where it is fitted. The upper surface of the lower gasket 170 is brought into close contact with the bottom surface of the flow rate adjusting dial 130 and the bottom surface is brought into close contact with the upper surface of the liquid- A fixing protrusion 172 is formed on the outer side of the lower gasket 170 so that the lower gasket 170 does not flow left and right between the flow rate adjusting dial 130 and the liquid discharge unit 120, A fixing groove 124 corresponding to the fixing protrusion 172 is formed.

As shown in FIG. 7, the upper gasket 160 is provided with a first chamber 180. The first chamber 180 is formed to vertically penetrate the upper gasket 160 vertically to communicate the fluid inflow port 111 and the circular flow path 140. The cross-sectional area of the first chamber 180 is larger than the cross-sectional area of the circular passage 140. Therefore, the flow rate of the liquid flowing into the first chamber 180 is greatly reduced through the bent channel in the process of being discharged to the circular flow path 140 side.

The flow rate adjusting dial 130 is provided with a second chamber 190. The second chamber 190 vertically penetrates the flow rate adjusting dial 130 and communicates with the flow rate adjusting flow channel 150. Sectional area of the second chamber 190 is larger than the cross-sectional area of the flow rate regulating passage 150.

The second chamber 190 is formed to be in communication with the flow rate control flow path 150 having a different radius from the circular flow path 140, and thus is spaced apart from the circular flow path 140. A connection flow path 200 connecting the second chamber 190 and the circular flow path 140 is formed on the upper surface of the flow rate adjusting dial 130. Sectional area of the connection passage 200 is smaller than the cross-sectional area of the second chamber 190. As a result, the flow rate of the liquid flowing into the second chamber 190 through the first chamber 180 is significantly reduced in the course of flowing into the second chamber 190 having a relatively large cross-sectional area through the bent channel.

In addition, a third chamber 210 is provided in the lower gasket 170. The third chamber 210 is formed so as to vertically penetrate the flow rate control dial 130 so as to communicate the flow rate control flow path 150 and the fluid discharge port 121 vertically. The third chamber 210 has a larger sectional area than that of the second chamber 190 and generates a negative pressure that varies according to the degree of rotation of the flow rate control dial 130 on the flow rate control channel 150 side.

On the upper surface of the flow rate adjusting dial 130 is formed a circular first contact protrusion 132 and a vertical center axis 112 formed on the inner side and the outer side of the circular flow passage 140 about the vertical center axis 112, Shaped second contact protrusions 133 formed on the outer side of the second chamber 190 are formed.

Since the first gasket 160 and the second gasket protrusion 133 are made of a material having a self-elasticity, the first and second contact protrusions 132, So that the bottom surface of the upper gasket 160 is buried under the elastic deformation. Accordingly, the first contact protrusion 132 and the second contact protrusion 133 do not generate a step with respect to the upper gasket 160, and at the same time, the upper gasket 160 is formed with a bent portion in the bottom of the upper gasket 160, The airtightness between the flow control dial 160 and the flow rate adjusting dial 130 is greatly improved. As a result, the outflow of the liquid flowing along the circular flow path 140 and the connection flow path 200 is completely blocked.

In addition, a circular third contact protrusion 134 formed on the inner side and the outer side of the flow rate control flow path 150 is formed on the bottom surface of the flow rate control dial 130, around the vertical center axis 112 .

Since the lower gasket 170 is made of a self-elastic material, the third contact protrusion 134 elastically deforms the upper surface of the lower gasket 170 while closely adhering to the lower gasket 170, 170). Accordingly, the third contact protrusion 134 does not generate a step with the lower gasket 170, and the lower gasket 170 and the flow rate adjusting dial 130 of the flow control flow path 150 is greatly improved, and the outflow of the liquid flowing along the flow control flow path 150 to the outside is completely blocked.

In addition, a circular fourth contact protrusion 135 formed on the bottom of the flow rate adjusting dial 130 and formed in the third chamber 210 around the vertical center axis 112 may be formed.

Since the lower gasket 170 is made of a material having a self-elasticity, the fourth contact protrusion 135 can elastically deform the upper surface of the lower gasket 170 while closely adhering to the lower gasket 170, 170). Therefore, the fourth contact protrusion 135 does not generate a step with the lower gasket 170 and forms a bent portion at the bottom of the lower gasket 170 so that the lower gasket 170 and the flow rate adjusting dial 130 of the third chamber 210, and thus the outflow of the liquid flowing along the third chamber 210 to the outside is completely blocked.

Meanwhile, the flow rate control flow path 150 and the fluid discharge port 121 may be spaced apart from each other so as not to be positioned on the same vertical line. In this case, the third chamber 210, which communicates the flow rate control flow path 150 and the fluid discharge port 121, is formed in the shape of a slot facing the vertical center axis 112. Therefore, the liquid discharged from the flow rate control channel 150 passes through the bent channel having a large cross-sectional area in the process of passing through the third chamber 210, so that the flow rate is greatly reduced and discharged to the liquid discharge port 121 in a very stable state .

A reference line 136 is formed on the outer circumferential surface of the flow rate adjusting dial 130. The amount of the liquid discharged into the outer circumferential surface of the liquid inflow portion 110 is sequentially discharged in correspondence with the reference line 136 Is displayed.

The operation of the thus structured fluid flow controller of the present invention will be described.

First, a reference line 136 formed on the outer circumferential surface of the flow rate control dial 130 is connected to the outer circumferential surface of the fluid inflow section 110 so as to maximize the amount of the fluid discharged to remove the air inside the fluid flow controller of the present invention. The second chamber 190 and the third chamber 210 are positioned on the same vertical line as shown in FIG. 8, and the flow rate adjusting dial 130 is rotated to be positioned at the indicated discharge flow rate "OPEN" The stored fluid flows along the hose 2a connected to the lower end of the infusion bottle through the fluid inlet 111, the first chamber 180, the circular passage 140, the connection passage 200, the second chamber 190, A large amount of fluid passes through the hose 2b connected to the syringe injected to the patient through the flow control flow path 150, the third chamber 210, and the fluid discharge port 121 in that order.

At this time, the user can easily and conveniently rotate the flow rate control dial 130 in the left and right direction by using the thumb and index finger while grasping the handgrip 123 provided on the liquid discharge unit 120 by hand. In this process, No external force is transmitted to the hoses 2a and 2b, so that even when the flow rate adjusting dial 130 is operated, the discharge of fluid is ensured.

When the reference line 136 formed on the outer circumferential surface of the flow rate adjusting dial 130 is positioned at the discharge flow rate CLOSE indicated on the outer circumferential surface of the fluid receiving inlet 110 so that the fluid is not discharged by rotating the flow rate adjusting dial 130, 9, the flow path between the flow rate regulating passage 150 and the third chamber 210 is closed, and the liquid is no longer discharged through the liquid outlet 121. In this state, the inside of the liquid flow rate regulating device is filled with the liquid and becomes a vacuum state. As a result, negative pressure acts on the third chamber 210 due to the liquid filled in the hose 2b connected to the syringe injected to the patient do.

In this state, when the flow rate adjusting dial 130 is rotated to one side, as shown in FIG. 10, the flow rate regulating passage 150 is communicated with the third chamber 210, and the liquid in the flow rate regulating passage 150 flows into the third And is discharged to the liquid discharge port 121 through the third chamber 210 at a constant speed by the negative pressure acting on the chamber 210. The cross-sectional area of the flow rate regulating passage 150 gradually increases or decreases in proportion to the amount of rotation of the flow rate regulating dial 130, so that the negative pressure acting on the third chamber 210 also gradually decreases or increases in inverse proportion to the cross-sectional area . As a result, the velocity of the liquid discharged through the third chamber 210 to the liquid discharge port 121 gradually increases or decreases in inverse proportion to the negative pressure which varies depending on the cross-sectional area. That is, when the cross-sectional area of the flow control valve 150 increases, the negative pressure acting on the third chamber 210 decreases, and the velocity of the liquid discharged from the flow control valve 150 to the third chamber 210 increases.

Therefore, even if the amount of the sap in the sap bottle is reduced, the sap is discharged from the flow rate control channel 150 to the third chamber 210 at a constant speed due to the negative pressure regardless of the amount of sap in the sap bottle. Is always kept constant.

If the flow rate adjusting dial 130 is rotated to place the reference line 136 formed on the outer peripheral surface of the flow rate adjusting dial 130 at the discharge flow rate "OPEN" indicated on the outer peripheral surface of the liquid receiving inlet 110, As the second chamber 190 and the third chamber 210 are positioned on the same vertical line and the negative pressure acting on the third chamber 210 is minimized, The speed and amount are maximum.

Meanwhile, when the liquid is discharged from the flow rate control passage 150, the negative pressure is increased in the second chamber 190, and the liquid is automatically replenished into the second chamber 190 through the circular passage 140 and the coupling passage 200 The negative pressure is increased in the first chamber 180 and the same amount of the liquid replenished into the second chamber 190 is automatically introduced into the first chamber 180 from the liquid inlet 111 side.

As described above, since the plurality of chambers 180, 190 and 210 for generating negative pressure are provided on the discharge path of the fluid, the speed and amount of the discharged fluid are determined according to the change in the sound pressure generated in the chambers 180, 190 and 210. Therefore, the fluid is discharged at a constant rate and amount without being influenced by the amount of the fluid in the fluid bottle.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be takeners of ordinary skill in the art, And such variations are within the scope of the present invention.

110 ... liquid inflow portion 111 ... liquid inflow port
112 ... vertical center axis 120 ... liquid discharge part
121 ... fluid outlet port 123 ... handle portion
130 ... flow rate adjusting dial 132 ... first contact projection
133 ... second contact projection 134 ... third contact projection
135 ... fourth contact projection 140 ... circular flow path
150 ... flow rate regulating passage 160 ... upper gasket
170 ... lower gasket 180 ... first chamber
190 ... second chamber 200 ... connection channel
210 ... third chamber

Claims (5)

A fluid inflow part formed with a fluid inflow port through which the inflow fluid flows from the infusion bottle and having a vertical central axis at the center;
And a liquid discharge port which is fitted to the lower part of the liquid inflow part through the vertical central axis and has a liquid discharge port through which the liquid is discharged at one side;
A flow rate adjusting dial coupled between the fluid inflow section and the fluid discharge section so as to be rotatably fitted horizontally through a vertical center axis;
A circular flow passage centered on the vertical center axis formed on the upper surface of the flow rate adjusting dial;
A flow rate regulating passage formed on the bottom surface of the flow rate adjusting dial and having an arc shape having a radius different from that of the circular flow passage with the vertical center axis as a center and gradually increasing or decreasing in cross sectional area;
An upper gasket provided on a bottom surface of the fluid inflow portion and closely attached to an upper portion of a flow rate adjusting dial;
A lower gasket provided on the upper surface of the liquid discharge portion and closely attached to a lower portion of the flow rate adjusting dial;
A first chamber formed to penetrate the upper gasket to communicate the fluid inlet and the circular flow path;
A second chamber formed through the flow rate adjusting dial to communicate with the flow rate adjusting passage;
A connecting channel formed on the upper surface of the flow rate adjusting dial to connect the second chamber and the circular flow channel; And
And a third chamber formed to penetrate through the lower gasket to communicate the flow rate control passage and the fluid discharge port and to generate a negative pressure that varies according to the degree of rotation of the flow rate control dial on the flow rate control channel side, Fluid flow control device. The method according to claim 1,
Wherein the second chamber has a larger cross-sectional area than the circular flow path and the flow rate control flow path,
Wherein the third chamber is formed to have a larger cross-sectional area than the flow rate control flow path. The method according to claim 1,
Further comprising a grip portion extending from a lower end of the liquid discharge portion. The method according to claim 1,
A circular first adhered protrusion formed on the inner side and the outer side of the circular flow passage about the vertical center axis and a circular second adhered protrusion formed on the outer side of the second chamber about the vertical center axis are formed on the upper surface of the flow rate adjusting dial,
A circular third contact protrusion formed on the inner side and the outer side of the flow rate control flow path around the vertical center axis and a circular fourth contact projection formed on the inner side of the third chamber about the vertical center axis are formed on the bottom surface of the flow rate adjusting dial And the flow rate of the fluid. The method according to claim 1,
The flow rate control channel and the fluid discharge port are spaced apart from each other so as not to be positioned on the same vertical line,
Wherein the third chamber is formed in the shape of a long hole facing the vertical central axis.

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