KR101601850B1 - Dual ball valve assembly - Google Patents

Abstract

The present invention relates to a dual ball valve for controlling flow of fluid, comprising: a valve body having a passage in a front and rear direction; an outer valve ball which is provided with a chamber in which an ball port is formed to penetrate in a front and rear direction and installed to be rotatable around one axis in the valve body; an inner valve ball which is installed to be rotated coaxially with the outer valve ball in the chamber of the outer valve ball, wherein an inner ball port is formed to penetrate in a front and rear direction to connect and block the passage of the valve body in the rotation direction; and a valve ball rotating means which rotates the outer and the inner valve ball to be rotated in opposite directions to each other. Accordingly, as a flow path of the dual ball valve is opened from the center thereof, the dual ball valve can minimize an eddy current from the valve ball when opening the flow path, thereby reducing loss of fluid energy.

Description

DUAL BALL VALVE ASSEMBLY

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double ball valve for controlling the flow of a fluid, and more particularly, to a double ball valve in which a valve ball is formed in the inside and outside of the double ball,

A valve is a mechanical element used in various piping to control the flow rate or pressure of a fluid in a pipe, or to control the flow of a fluid, and various kinds of valves are selected and used according to piping conditions and required functions in the piping.

A ball valve, which is one kind of such a valve, is a ball having a circular through hole as an element for controlling the flow rate, and the ball is a ball which is a flow path of the fluid And is rotated in accordance with the rotation of a stem provided in a direction perpendicular to the through hole.

Here, the stem may include a drive mechanism such as a manual lever, a manual gear, a manual gear with chain wheel, a pneumatic actuator, an electric actuator, And the rotation of the ball is induced according to the operation of the driving mechanism, and the ball provided inside the ball valve is also referred to as a valve ball.

Such techniques related to the ball valve are disclosed in Korean Patent Laid-Open Publication No. 10-2001-0009678 entitled " Double Blocking and Opening Device of Ball Valve ", Registered Utility Model Registration No. 20-0418253 "Flow Control Ball Valve" And so on.

The above-mentioned "double shut-off and opening device of a ball valve" includes a pair of valve balls rotatably installed inside a ball operating space of the valve body and formed so as to be symmetrically symmetrical from the center, A seat ring inserted and being in contact with an outer circumferential surface of a pair of valve balls; a seat ring which is lifted and lowered to open and close the pair of valve balls as the manual operation handle is rotated; An elastic means provided between the pair of valve balls to provide an elastic restoring force when the valve ball is operated; and an elastic means provided between the pair of valve balls, And a bleed valve for preventing the gas from leaking into the pipe and removing the residual pressure therein, The number of ball valves installed to perform the opening function can be reduced, so that the manufacturing cost of the apparatus can be reduced, and the assembly time at the time of installation can be shortened. The "flow rate control ball valve" is provided at the center of the flow path on both sides of the valve body, and includes a ball having a through hole, a stem fitted above the ball and vertically installed in the flow path, And a seat ring provided on the contact surface of the ball and the flow path for airtightness between the ball and the valve body, the flow rate of the ball is proportional to the flow angle of the ball overlaid on the flow angle of the ball relative to the rotation angle of the ball. So that it can be finely adjusted.

When the through hole of the valve ball and the flow path of the fluid coincide with each other, the conventional ball valve as described above allows the maximum allowable flow amount to flow in a fully opened state, Is 90 °, so that the fluid does not flow when the ball valve is in a fully closed state.

When it is necessary to adjust the flow rate of the fluid flowing through the ball valve, the valve ball is rotated at a predetermined angle so that the through hole of the ball and the flow path of the fluid are in a partially open state at an angle of 90 ° or less.

However, the conventional ball valve has a structure in which the flow rate is controlled by adjusting the rotation angle of the valve ball, so that the valve ball rotates at a predetermined angle so that the flow path of the fluid and the through- The valve ball is subjected to a high pressure due to the fluid resistance, thereby failing to maintain the proper position and sealing state, thereby failing to control the flow rate properly.

Accordingly, the present invention has been made in view of the above-mentioned circumstances, and it is an object of the present invention to provide a valve apparatus, in which a valve ball is composed of an outer valve ball and an inner valve ball, The present invention aims to provide a double ball valve which can be easily and easily operated by adjusting the flow rate to a predetermined numerical value by controlling the flow rate by driving the valve balls interlocked with each other.

In order to achieve the above object, a double ball valve according to a technical aspect of the present invention includes: a valve body having a through-passage formed in a front-back direction; An outer valve ball provided in the valve body so as to be rotatable about a single axis in the front and rear of the valve body, And the inner ball port is formed in the chamber of the outer valve ball so as to rotate coaxially with the outer valve ball, and an inner ball port is formed in the front and rear direction so as to penetrate therethrough so that the through- A valve ball; And a valve ball rotating means for rotating the outer valve ball and the inner valve ball in opposite directions to each other.

The valve-ball rotating means may include a first bevel gear rotatably mounted on the valve body by a drive shaft; A first driven gear meshed with the first bevel gear and coupled with the outer valve ball; A second bevel gear spaced apart from the first bevel gear and disposed on the drive shaft; And a second longitudinal synchronous gear which is coupled to the inner valve ball through the center of the first driven gear and is perpendicularly engaged with the second bevel gear.

The gear ratio of the first bevel gear and the first driven gear and the gear ratio of the second bevel gear and the second driven gear may be the same.

When the first bevel gear is engaged with any one side of the first driven gear, the second driven gear and the second bevel gear are positioned symmetrically with respect to the position where the first driven gear and the first bevel ear are engaged with each other, And the engaging portions are engaged with each other.

The gear ratio of the first bevel gear, the first driven gear, the second bevel gear, and the second driven gear is 1: 2, and the rotational angle of the rotary shaft of the first bevel gear and the second bevel gear is And is limited to be between 0 DEG and 180 DEG.

Further, the first driven gear is formed with a polygonal first protrusion extending in the direction of the rotational axis, and the outer valve ball is formed with an outer ball coupling groove penetrating at a position perpendicular to the direction in which the outer ball entry / exit port is formed, And a second protrusion having a polygonal shape is formed at a position passing through the rotation axis of the first driven gear at a rotation axis of the second driven gear, and the inner valve ball is connected to the protrusion at a position perpendicular to the direction in which the inner ball exit / And an inner ball coupling groove formed as a through hole or a concave groove is formed and coupled with the second projection.

The outer valve ball is a pair of divided bodies each having an outer circumferential surface and an inner circumferential surface formed in a hemispherical shape, and the pair of divided bodies are formed with fitting protrusions and fitting grooves having a concavo-convex relationship with each other, . ≪ / RTI >

According to the double ball valve as described above,

First, since the flow path is opened from the center by the outer valve ball and the inner valve ball which are rotated in mutually opposite directions, the vortex generated in the valve ball can be minimized, thereby reducing the loss of fluid energy.

Second, as the oil passage is opened from the center by the double valve ball, the uneven load generated on the side of the oil passage when the single ball valve is opened does not occur, so that damage due to the fatigue load can be prevented.

Third, since the biased load does not occur when the valve is opened, the operation of adjusting the flow rate to a predetermined numerical value is stably performed.

1 is a perspective view showing the outline of a double ball valve according to an embodiment of the present invention;
2 is a front view of a valve ball and a gear portion constructed in a valve body in a double ball valve according to an embodiment of the present invention.
FIG. 3A and FIG. 3B are cross-sectional views illustrating a structure and operation of a valve ball in a double ball valve according to an embodiment of the present invention;
FIGS. 4A and 4B are front views illustrating a valve body for explaining an open / closed state of a double ball valve according to an embodiment of the present invention; FIGS.
5 is an assembled view for explaining a state of engagement between an outer valve ball and an inner valve ball in a double ball valve according to an embodiment of the present invention.
6 is an assembled view for explaining a state of engagement of a gear portion in a double ball valve according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the outline of a double ball valve according to an embodiment of the present invention.

The double ball valve according to the embodiment of the present invention is installed in a pipe to control the flow rate of the fluid flowing through the pipe.

In order to apply the embodiment of the present invention to a pipe, a pipe is coupled to a through passage 108 formed in the valve body 101, and a drive shaft 130 (not shown), which can be projected to one side of the valve body 101 The through hole 108 is opened and closed while the outer valve ball 140 and the inner valve ball 150 built in the valve body 101 are rotated in mutually opposite directions.

2 and 3A, a double ball valve according to an embodiment of the present invention includes a valve body 101 having a through-passage 108 formed in the forward and backward directions, a chamber 101 formed to penetrate the outer ball entrance / An outer valve ball 140 installed in the valve body 101 so as to be rotatable about one axis and an outer valve ball 140 in the chamber 146 of the outer valve ball 140, And an inner valve hole 150 is formed in the front and rear direction so as to penetrate through the inner ball entrance and exit port 158. The inner valve ball 150 communicates and blocks the passage 108 of the valve body 101 according to the rotated direction, And valve ball rotating means for rotating the outer valve ball 140 and the inner valve ball 150 in opposite directions to each other.

Particularly, the valve ball rotating means includes a first bevel gear 131 rotatably installed in the valve body 101 by a drive shaft 130, a first bevel gear 131 perpendicularly engaged with the first bevel gear 131, A second bevel gear 132 disposed on the driving shaft 130 and spaced apart from the first bevel gear 131 and a second bevel gear 132 separated from the first bevel gear 131, And a second driven gear 120 coupled to the inner valve ball 150 through the center of the first bevel gear 110 and meshed with the second bevel gear 132 at right angles.

According to the above feature, unlike the conventional ball valve that regulates the flow rate through the adjustment of the rotation angle of the valve ball, the fluid resistance added to the valve ball is minimized to maintain the correct position of the valve ball, As the sealing remains stable, the flow rate can be precisely controlled. In addition, damage to the valve body or valve ball caused by repetitive addition of excessive pressure is minimized.

The outer valve ball 140 and the inner valve ball 140 are mechanically engaged by the first bevel gear 131 and the first driven gear 110, the second bevel gear 132 and the second driven gear 120, 150 rotate at the same time in opposite directions. Specifically, when the respective gears having the same gear ratio have the same gear ratio, the two valve balls 140, 150 rotate at the same speed. Therefore, the opening and closing of the valve are made from the center of the through passage 108, so that the vortex generated in the valve ball is reduced when the valve ball is partially opened, thereby reducing the loss of fluid energy.

The double ball valve according to the embodiment of the present invention includes a valve body 101, an outer valve ball 140 and an inner valve ball 150 as shown in FIGS. 1 and 2, And a valve ball rotating means connected to provide a rotational force to the ball 150.

The valve body 101 constitutes the body of the ball valve so that the outer valve ball 140 and the inner valve ball 150 are disposed on the through passage 108 formed in the forward and backward direction do.

The valve body 101 is provided with a valve ball rotating means coupled to the valve ball for rotating the valve ball. The valve ball rotating means includes a drive shaft 130 for inputting a rotational force transmitted from an operating portion (not shown), a first bevel gear 131 and a second bevel gear 132 formed to be spaced apart from the drive shaft 130 by a predetermined distance, The first driven gear 110 and the second driven gear 110 are coupled to the first bevel gear 131 and the second bevel gear 132 respectively and connected to the upper portions of the outer valve ball 140 and the inner valve ball 150, And a second driven gear 120. The driving shaft 130 to which the rotational force is input may be coupled with an operation unit (not shown) such as a manual lever, a gear box, a chain wheel attachment type gear box, a pneumatic actuator, and an electric driver.

The outer valve ball 140 is connected to the driven gear and the valve ball through the outer valve ball 140. For example, at the upper end of the outer valve ball 140, a polygonal recessed groove or an outer ball joint groove 142 penetrating to the chamber is formed, A first protrusion 112 having a shape corresponding to the ball coupling groove 142 is connected by being coupled to the outer ball coupling groove 142 by extending in the rotational axis direction of the first driven gear 110. [

Continuously explains the relationship between the valve balls and the gears in more detail.

FIGS. 3A and 3B are cross-sectional views illustrating a structure and operation of a valve ball in a double ball valve according to an embodiment of the present invention; FIG.

The outer valve ball 140 is disposed on the through passage 108 of the valve body 101. The outer valve ball 140 is formed such that an outer diameter of the outer ball exit / A chamber 146 capable of accommodating the wafer W is formed.

An outer ball coupling groove 142 (corresponding to the first projection 112 formed in a polygonal shape) for coupling with the first projection 112 formed on the first driven gear 110 is formed at an outer upper end of the outer valve ball 140 Is formed.

The inner valve ball 150 is disposed in the chamber 146 formed in the outer valve ball 140 and has an inner ball inlet and outlet 158 penetrating in the forward and backward direction as well as the outer valve ball 140. The inner valve ball 150 and the outer valve ball 140 are rotated in opposite directions to each other so that the through hole 108 formed in the valve body 101 is communicated with the outer ball entrance and exit port 148 and the inner ball entrance and exit port 158 The through holes 108 are communicated with each other.

The inner valve ball 150 has an upper end formed with a second protrusion 122 formed in a polygonal shape so as to engage with the second protrusion 122 formed on the rotary shaft 121 of the second driven gear 120, An engaging groove 152 is formed. The upper end of the inner valve ball 150 is at the same position as the outer ball coupling groove 142 of the outer valve ball 140 is formed.

That is, the outer ball coupling groove 142 for coupling the outer valve ball 140 to the first projection 112 is formed at a position perpendicular to the direction in which the outer ball entrance / exit 148 is formed, An inner ball engaging groove 152 for engaging with the second projection 122 is formed at a position perpendicular to the direction in which the inner ball exit 158 is formed.

The outer valve ball 140 and the inner valve ball 150 are shown as being spaced considerably apart from each other, but this is only intended to help explain and understand the configuration, and in actual ball valves, It is preferable that the outer valve ball 140 and the inner valve ball 150 are constructed so as to have almost no clearance therebetween or the outer valve ball 140 and the inner valve ball 150 are sealed.

The second driven gear 120 is installed so that the rotating shaft 121 passes through the center of the first driven gear 110 to be connected to the inner valve ball 150. Accordingly, the first driven gear 110 and the second driven gear 120 rotate about the same axis. That is, the first driven gear 110 is rotated with respect to the rotation shaft 121 of the second driven gear 120, and the second driven gear 120 is rotated with respect to the first driven gear 110. The diameter of the second driven gear 120 is preferably smaller than that of the first driven gear 110 as shown for engagement with the second bevel gear 132.

The first bevel gear 131 and the second bevel gear 132 are fixed to the drive shaft 130 and rotate together with the drive shaft 130. In this case, The first bevel gear 131 and the second bevel gear 132 are coupled to the first driven gear 110 and the second driven gear 120, respectively, so that the gear teeth can be formed at an angle .

The first bevel gear 131 is meshed with the first driven gear 110 at right angles and the second bevel gear 132 is meshed with the second driven gear 120 at right angles with the drive shaft 130 rotated in one direction The first driven gear 110 and the second driven gear 120 must be rotated in opposite directions by the rotational force of the first driven gear 110 and the second driven gear 120. Accordingly, The second driven gear 120 and the second bevel gear 132 are meshed with the first driven gear 110 and the first bevel gear 131 at symmetrical positions with each other. That is, if the first bevel gear 131 is engaged with a gear in the direction in which the drive shaft 130 extends from the outer peripheral surface of the first driven gear 110, the second bevel gear 132 is coupled to the drive shaft 130, Of the second driven gear 120 located in the opposite direction of the extended direction.

The first protrusion 112 extending in the rotational axis direction from the first driven gear 110 and the second protrusion 122 extending from the second driven gear 120 in the direction of the rotational axis 121 by the above- The outer valve ball 140 coupled to the first projection 112 and the inner valve ball 150 coupled to the second projection 122 rotate in opposite directions when the drive shaft 130 rotates in one direction, Are also rotated in opposite directions.

3A and 3B are cross-sectional views of the valve body and the gear portion in a state in which the valve body and the gear portion are viewed from the front without the valve body 101 in the configuration. When the valve shown in FIG. 1 is viewed from the same direction, And the ball valve position in Fig. 3B is a state when the valve is in an open state.

Since the gear ratios of the first bevel gear 131 and the first driven gear 110 are the same as the gear ratios of the second bevel gear 132 and the second driven gear 120, And the inner port of the inner valve ball 150 are parallel to each other at every 90 ° rotation.

The gear ratio between the first bevel gear 131 and the first driven gear 110, the second bevel gear 132 and the second driven gear 120 is 1: 2, The rotation angle of the bevel gear 131 and the second bevel gear 132, that is, the rotation angle of the drive shaft 130, is limited to between 0 and 180 degrees.

4A and 4B are front views showing a valve body for explaining an open / close state of a double ball valve according to an embodiment of the present invention.

4A shows a state in which the outer valve ball 140 and the inner valve ball 150 are rotated and closed as shown in FIG. 3A. When the valve is viewed in the direction in which the valve is closed, the outer circumferential surface of the outer valve ball 140 is visible in the through passage 108 of the valve body 101.

4B shows a state in which the outer valve ball 140 and the inner valve ball 150 are opened as shown in FIG. 3B. Since the passageway 108 of the valve body 101 and the outer ball entrance and exit 148 of the outer valve ball 140 and the inner ball entrance and exit 158 of the inner valve ball 150 are positioned side by side, It is in a communicative state where it can flow.

4B is formed so that the outer ball entrance and exit port 148 is formed smaller than the diameter of the through passage 108 and the inner ball entrance and exit port 158 is formed smaller and the outer valve ball 140 is formed on the through passage 108. [ The inner ball inlet / outlet port 148 and the inner ball inlet / outlet port 158 may have diameters different from each other in order to minimize the pressure of the fluid applied to the valve ball. It is preferable that the diameter of the through-hole 108 is equal to or larger than the diameter of the through-

5 is an assembled view for explaining a state of engagement between an outer valve ball and an inner valve ball in a double ball valve according to an embodiment of the present invention.

The outer valve ball 140 is formed by assembling a plurality of divided bodies to one another so that the inner valve ball 150 can be installed inside the outer valve ball 140.

To this end, the outer valve ball 140 according to the embodiment of the present invention is constituted by a pair of divided bodies which are coupled with hemispherical outer peripheral surfaces and inner peripheral surfaces, and the pair of divided bodies have a concavo- And the fitting protrusions 144 and the fitting grooves 145 are formed and fitted to each other.

When each of the divided bodies constituting the outer valve ball 140 is a predetermined thickness or more, a bolt hole penetrating through the surfaces where the divided bodies are coupled to each other is formed, so that the divided bodies can be coupled to each other by the bolts inserted into the bolt holes. have.

The inner valve ball 150 is made of a hollow spherical body having a predetermined thickness, the outer circumferential surface and the inner circumferential surface forming a spherical image.

The inner valve ball 150 is positioned inside the outer valve ball 140 and the outer valve ball 140 and the inner valve ball 150 are coupled to each other, ). ≪ / RTI >

A sealing hole is formed between the inner circumferential surface of the outer valve ball 140 and the outer circumferential surface of the inner valve ball 150 so that the leakage of the fluid between the outer valve ball 140 and the inner valve ball 150 Can be prevented.

6 is an assembled view for explaining a state of engagement of a gear portion in a double ball valve according to an embodiment of the present invention.

A through hole is formed in the center of the first driven gear 110 so that the rotational shaft 121 of the second driven gear 120 passes through the center of the first driven gear 110 and is engaged with the inner valve ball 150 , And the rotation axis 121 of the second driven gear 120 extends to a diameter corresponding to the through hole of the first driven gear 110. [ The second projection 122 is engaged with the rotation shaft 121 of the second driven gear 120 coupled to the through hole of the first driven gear 110. The protrusion may be formed on the rotating shaft 121 for assembling the second driven gear 120 and the second protrusion 122 as shown in FIG.

The rotation shaft 121 is extended from the second projection 122 and is coupled to the second driven gear 120 such that the second driven gear 120 and the second projection 122 are coupled to each other. The coupling structure may be implemented in any conventional coupling structure.

The first protrusion 112 and the second protrusion 122 are formed in a polygonal shape as shown in the figure and the outer ball coupling groove 142 of the outer valve ball 140 assembled with the inner protrusion 112 and the inner protrusion 122 of the inner valve ball 150 It is preferable that the ball defect groove is formed in a shape corresponding to the first projection 112 and the second projection 122.

In this case, the opening and closing of the valve is regulated according to the diameter of the outer ball entrance / exit port 148 and the diameter of the inner ball entrance / exit 158. In this case, the outer valve ball 140 and the inner valve ball 150, As the valve body 101 rotates in mutually opposite directions and is opened and closed at the center of the through passage 108 of the valve body 101, the fluid resistance added to the valve ball is minimized to maintain the correct position of the valve ball, 101 and the valve ball is not only stably maintained, but also the flow rate is accurately controlled.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

100: Ball valve 101: Valve body
108: penetrating passage 110: first driven gear
112: first projection 120: second driven gear
121: second driven gear rotating shaft 122: second projection
130: drive shaft 131: first bevel gear
132: second bevel gear 140: outer valve ball
142: outer ball coupling groove 144: fitting projection
145: fitting groove 146: chamber
148: Outer ball inlet / outlet 150: Inner valve ball
152: Inner ball coupling groove 158: Inner ball entrance /

Claims (8)

A valve body having a through-passage formed in the front-rear direction;
An outer valve ball provided in the valve body so as to be rotatable about a single axis in the front and rear of the valve body,
And the inner ball port is formed in the chamber of the outer valve ball so as to rotate coaxially with the outer valve ball, and an inner ball port is formed in the front and rear direction so as to penetrate therethrough so that the through- A valve ball;
And valve ball rotating means for rotating the outer valve ball and the inner valve ball in opposite directions to each other,
Wherein the valve ball rotating means comprises: a first bevel gear rotatably mounted on the valve body by a drive shaft; A first driven gear meshed with the first bevel gear and coupled with the outer valve ball; A second bevel gear spaced apart from the first bevel gear and disposed on the drive shaft; And a second longitudinal synchronous gear whose rotation axis passes through the center of the first driven gear to engage with the inner valve ball and to be orthogonally engaged with the second bevel gear. delete The method according to claim 1,
Wherein the gear ratio of the first bevel gear and the first driven gear and the gear ratio of the second bevel gear and the second driven gear are the same. The method of claim 3,
When the first bevel gear is engaged with any one side of the first driven gear, the second driven gear and the second bevel gear are positioned symmetrically with respect to the position where the first driven gear and the first bevel gear are meshed with each other And the second ball valve is engaged with the second ball valve. 5. The method of claim 4,
Wherein the gear ratio of the first bevel gear, the first driven gear, the second bevel gear, and the second driven gear is 1: 2, and the rotation angle of the drive shaft is limited between 0 ° and 180 °. Ball valve. The method according to claim 1,
The outer valve ball is formed with an outer ball coupling groove penetrating through the outer valve ball at a position perpendicular to a direction in which the outer ball entry / exit port is formed, and the first protrusion is formed in the outer valve ball, Coupled,
A second protrusion of a polygonal shape is formed at a position passing through a rotation axis of the first driven gear and a second protrusion of a polygonal shape is formed at the rotation shaft of the second driven gear, Wherein the inner ball coupling groove is formed to be coupled with the second projection. The method according to claim 1,
The outer valve ball is a pair of divided bodies having an outer circumferential surface and an inner circumferential surface formed in a hemispherical shape, and the pair of divided bodies are fitted to each other with fitting protrusions and fitting grooves formed in a concave- Double ball valve. A valve body having a through-passage formed in the front-
An outer valve ball provided in the valve body so as to be rotatable about a single axis,
And the inner ball port is formed in the chamber of the outer valve ball so as to rotate coaxially with the outer valve ball, and an inner ball port is formed in the front and rear direction so as to penetrate therethrough so that the through- A valve ball,
A first bevel gear rotatably mounted on the valve body by a drive shaft,
A first driven gear meshed with the first bevel gear and coupled with the outer valve ball,
A second bevel gear spaced apart from the first bevel gear and formed on the same drive shaft,
And a second driven gear provided so that a rotational axis passes through the center of the first driven gear and meshed with the second bevel gear and engaged with the inner valve ball,
When the first bevel gear is engaged with any one side of the first driven gear, the second driven gear and the second bevel gear are positioned symmetrically with respect to the position where the first driven gear and the first bevel gear are meshed with each other And the gear ratio of the first bevel gear, the first driven gear, the second bevel gear, and the second driven gear is 1: 2, and the rotation of the rotary shaft of the first bevel gear and the second bevel gear Wherein the first valve has a first protrusion formed in a polygonal shape extending in a direction of a rotational axis of the first driven gear and a second protrusion formed in the valve hole at a position perpendicular to a direction in which the outer ball exit / A second protrusion is formed at a position passing through a rotation axis of the first driven gear and a second protrusion of a polygonal shape is formed in the rotation shaft of the second driven gear, Entrance formation And the outer valve ball is formed as a pair of divided bodies coupled with the outer circumferential surface and the inner circumferential surface of a hemispherical shape, Wherein the split bodies of the pair are formed with fitting protrusions and fitting grooves having a concavo-convex relationship with the surfaces to be coupled with each other and are fitted to each other.

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