KR20180034020A - Dual cylinder valve assembly - Google Patents

Abstract

The present invention relates to a dual cylinder valve composed of an interior disc and an exterior disc rotating in different directions such that the discs are opened and closed from the center of a valve flow path, comprising: a valve body formed with a flow path penetrated in forward and backward directions; the exterior disc formed with a flow path penetrated in forward and backward directions and a chamber therein, and installed to be rotatable about a single shaft within the valve body; the interior disc formed with a flow path penetrated in forward and backward directions, and installed to rotate with the exterior disc about the single shaft within the chamber of the exterior chamber; and a driving gear set rotating the exterior disc and the interior disc in opposite directions such that opened portions of the flow path of the exterior disc and the flow path of the interior disc are faced at the front center of the flow path of the valve body.

Description

DUAL CYLINDER VALVE ASSEMBLY

The present invention relates to a double cylinder valve, more particularly to a dual cylinder valve in which the disc of the ball valve is constituted by inner and outer discs rotating in mutually different directions and the disc is opened and closed from the center of the valve channel .

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 type of valve, is a ball disk having a circular through hole as an element for controlling the flow rate, and the ball disk is a through- And is rotated according to the rotation of a stem installed in a direction perpendicular to the hole.

In the conventional ball valve, when the through hole of the ball disk coincides with the flow path of the fluid, the maximum allowable flow rate is fully opened and the flow path of the fluid and the through hole of the ball disk are 90 이루어 When the ball valve is fully closed, the fluid is prevented from flowing. When it is necessary to adjust the flow rate of the fluid flowing through the ball valve, the ball disk is rotated at a predetermined angle so that the through hole and the fluid flow path are in a partially opened state at an angle of 90 degrees or less.

However, the conventional ball valve is opened and closed from the side edge of the flow path formed in the ball valve through the adjustment of the rotation angle of the single ball disk. In the process of opening and closing the flow path, Cavitation occurred. When cavitation occurs, there is a strong vibration in the ball valve and the ball disk, and the life of the ball valve is shortened if the ball disk is damaged by such vibration.

Patent Document 10-1275056: Ball Valve and Manufacturing Method Thereof

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide an air conditioner in which a disc of a ball valve is composed of inner and outer discs rotated in different directions, It is an object of the present invention to provide a double cylinder valve.

According to an aspect of the present invention, there is provided a dual cylinder valve comprising: a valve body having a flow passage penetrating in a front-rear direction; a flow passage penetrating in a front-back direction; An inner disk provided in the body so as to be rotatable about a first axis and a flow path penetrating in the forward and backward direction and being coaxially rotated with the outer disk in the chamber of the outer disk; And a drive gear set that rotates the outer disc and the inner disc in opposite directions so that an open portion of the flow path of the inner disc faces the front center of the flow path of the valve body.

The driving gear set includes a ring gear having a lower portion coupled to an upper portion of the outer disc and rotating together with the outer disc with the same rotation axis, a lower portion coupled to an upper portion of the inner disc through a center of the ring gear, A sun gear rotating together with the inner disk, and a planetary gear meshed with the sun gear and the ring gear to transmit the rotational force of the sun gear to the ring gear in a reverse direction.

The rotation shaft of the inner disk may be coupled with a stem that provides a rotational power.

Also, the inner disk rotates at a speed three times faster than the outer disk, and the diameter of the flow path of the valve body is less than 1/5 of the diameter of the outer disk.

In addition, the radius of rotation of the outer disk is limited to 90 degrees.

The flow path of the valve body, the flow path of the outer disk, and the flow path of the inner disk may have the same diameter.

According to the double cylinder valve as described above,

First, since the flow path is opened from the center by the outer disk and the inner disk rotated in mutually opposite directions, cavitation occurring in the disk can be minimized, thereby preventing damage to the valve.

Second, the outer disc and the inner disc are engaged with each other by the planetary gear, so that the rotational power provided to the inner disc can be stably provided to the outer disc.

Third, since the diameter of the flow path of the valve body is less than 1/5 of the diameter of the outer disk when the inner disk rotates three times faster than the outer disk, the disk is prevented from opening on the flow path side of the valve body.

1 is a front view showing a cross section of a dual cylinder valve according to an embodiment of the present invention;
2 is a perspective view illustrating a driving gear set of a dual cylinder valve according to an embodiment of the present invention;
FIGS. 3A to 3D are plan views illustrating a double cylinder valve according to an embodiment of the present invention, which is driven from a closed state to an open state. FIG.

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

A double cylinder valve according to an embodiment of the present invention is a device installed in a piping to control the flow and flow of a fluid flowing through a pipe.

1, the double cylinder valve according to the embodiment of the present invention includes a valve body 102 formed with a flow path 104 penetrating in the front-rear direction, a flow path 114 penetrating in the front- An outer disc 110 formed in the valve body 102 so as to be rotatable about a single axis and a flow passage 124 penetrating in the front and rear direction are formed in the chamber of the outer disc 110, The inner disk 120 installed to rotate coaxially with the outer disk 110 and the opened portions of the outer disk 114 and the inner disk 124 in the front center of the valve body 104, And a driving gear set for rotating the outer disc 110 and the inner disc 120 in opposite directions to each other.

The valve body 102 is mounted on a pipe through which the fluid flows, and internally accommodates structures for controlling the flow and flow of the fluid. The flow path 104 formed through the valve body 102 is preferably formed vertically.

The outer disc 110 and the inner disc 120 are installed in the valve body 102 so as to have the same rotational axis. It is preferable that the flow path 104 of the valve body, the flow path 114 of the outer disk, and the flow path 124 of the inner disk have the same diameter for smooth fluid distribution.

In this embodiment, the outer disk 110 and the inner disk 120 are formed in a cylindrical shape, but they may also be formed in a spherical shape.

Next, the drive gear set will be described in more detail with reference to the drawings.

1 and 2, the driving gear set of this embodiment includes a ring gear 136 which is coupled to the upper portion of the outer disc 110 and rotates together with the same rotation axis as the outer disc 110, A sun gear 132 coupled to the upper portion of the inner disk 120 through the center of the gear 136 and rotating together with the inner disk 120 and a sun gear 132 coupled to the sun gear 132 and the ring gear 136, And a planetary gear 134 for converting the rotational force of the ring gear 136 into a reverse direction and transmitting it to the ring gear 136.

As shown, the ring gear 136 is a gear having teeth formed in the inner direction of the ring. The sun gear 132 and the planetary gear 134 are both provided with teeth on the outer circumferential surface. Particularly, the planetary gear 134 is engaged with the sun gear 132 and the ring gear 136, (136). The planetary gear 134 is rotatably coupled to the valve body 102. The rotational force of the sun gear 132 is more effectively transmitted to the ring gear 136 when the plurality of planetary gears 134 are disposed around the sun gear 132 .

In this embodiment in which the drive gear set is constituted by the planetary gear 134, the inner disk 120 may be rotated by three times faster than the outer disk 110. The sun gear 132 and the ring gear 136 have a gear ratio of 1: 3 so that the inner disk 120 can rotate at a speed three times faster than the outer disk 110. [ When the inner disk 120 rotates three times faster than the outer disk 110, when the outer disk 110 rotates 90 degrees, the inner disk 120 rotates 270 degrees. The flow path 124 of the inner disk 120 is vertically penetratingly formed (180 degrees) so that the flow path 124 of the inner disk is rotated twice while the outer disk 110 is rotated by 90 degrees, (104). Also, the flow path 124 of the inner disk becomes parallel to the flow path 114 of the outer disk when the outer disk 110 is at 0 degree, 45 degrees, and 90 degrees. The inner disks 120 are arranged such that the flow paths 114 and 124 of the inner disk 120 are parallel to each other even when the outer disk 110 is rotated at an angle of 45 degrees, When the size of the passage 114 of the disk is formed larger than a certain ratio, when the outer disk 110 is rotated by 45 degrees, the passage 114 of the outer disk is exposed on the passage 104 of the valve body, The opening of the valve at the edge of the valve 104 may occur. In order to prevent this phenomenon, in this embodiment in which the inner disk 120 rotates three times faster than the outer disk 110, the flow path 104 of the valve body, the flow path 114 of the outer disk, It is preferable that the diameter of the outer disk 110 is 1/5 or less of the diameter of the outer disk 110.

The stem 140, which provides rotational power for opening and closing the valve, may be coupled to one of the upper and lower portions of the rotating shaft of the inner disk 120.

Next, a driving process of the double cylinder valve according to one embodiment of the present invention will be described.

The embodiment shown in FIGS. 3A and 3D assumes that the outer disk 110 and the inner disk 120 rotate at the same speed.

FIG. 3A is a cross-sectional view of a plane showing a state in which the valve of this embodiment is closed. FIG. When the outer disk 110 and the inner disk 124 are rotated so as to be perpendicular to the flow path 104 of the valve body, the fluid can not flow in the valve body 102, Closed state.

3B is a cross-sectional view showing a state in which the outer disk 110 and the inner disk 120 of this embodiment are rotated at a predetermined angle. When the handle 150 (see FIG. 1) connected to the upper portion of the stem 140 is rotated, the outer disk 110 and the inner disk 120 are rotated in opposite directions by the driving gear set. Even if the outer disk 110 and the inner disk 120 rotate to some extent, the fluid in the valve body 102 is not circulated in a state in which the flow paths 114 and 124 of the two disks are not in contact with each other.

3C is a sectional view of a plane showing a state in which the outer disk 110 and the inner disk 120 of this embodiment are further rotated to partially open the valve. When the outer disk 110 and the inner disk 120 further rotate and the edges of the flow paths 114 and 124 of the two disks face each other, a fine inflow path is formed through the flow paths 114 and 124 of the two disks, As the disc 110 and the inner disc 120 rotate in the same direction, the size of the inflow path gradually expands until the flow paths 114 and 124 of the two discs are completely parallel. The flow rate of the fluid is also increased or decreased in proportion to the size of the inflow path formed by the flow paths 114 and 124 of the two disks facing each other.

Fig. 3D is a cross-sectional view of a plane showing a state in which the valve of this embodiment is fully opened. As shown in the figure, when the flow path 124 of the outer disk 110 and the inner disk is aligned with the flow path 104 of the valve body, the fluid can freely flow in the valve body 102.

It is preferable that the turning radius of the outer disk 110 is limited to 90 degrees so that the user can grasp the closed state and the opened state of the valve by the degree of rotation of the handle 150. [ The turning radius of the outer disk 110 is from 0 degrees in a state in which the valve is opened parallel to the oil passage 104 in the valve body to 90 degrees in a state in which the valve is closed perpendicularly to each other. Limiting the radius of rotation of the outer disc 110 may be accomplished by forming a blocking protrusion that physically restricts rotation of the outer circumferential surface of the stem 140 or the outer circumferential surface of the outer disc 110 and the valve body 102 beyond a predetermined angle .

In addition to the handle 150, a member that is automatically controlled by an electrical device, such as a motor, may be used for the member that provides the rotational force to the stem 140.

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.

102: valve body 104: flow path of valve body
110: outer disc 114: outer disc
120: inner disk 124:
132: sun gear 134: planetary gear
136: ring gear 140: stem
150: Handle

Claims (7)

A valve body having a flow passage penetrating in the front-rear direction;
An outer disk formed in the valve body and rotatable about a single axis, the flow path passing through in the forward and backward directions and the chamber being formed therein;
An inner disk provided in the chamber of the outer disk and configured to rotate coaxially with the outer disk;
And a drive gear set that rotates the outer disc and the inner disc in opposite directions so that the outer disc and the inner disc are opened at the front center of the flow path of the valve body Double cylinder valve. The drive gear set according to claim 1, wherein the drive gear set
A ring gear coupled to an upper portion of the outer disc and rotated together with the outer disc,
A sun gear coupled to an upper portion of the inner disk through a center of the ring gear and rotated together with the inner disk,
And a planetary gear engaged with the sun gear and the ring gear to transmit the rotation force of the sun gear to the ring gear in a reverse direction. 3. The method of claim 2,
Further comprising a stem coupled to a rotational axis of said inner disk to provide rotational power. The method of claim 3,
Wherein the inner disk rotates at a speed three times faster than the outer disk, and the diameter of the flow path of the valve body is 1/5 or less the diameter of the outer disk. The method of claim 3,
Wherein the turning radius of the outer disc is limited to 90 degrees. The method according to claim 1,
Wherein the flow path of the valve body, the flow path of the outer disk, and the flow path of the inner disk have the same diameter. A valve body having a flow passage penetrating in the front-rear direction;
An outer disk formed in the valve body and rotatable about a single axis, the flow path passing through in the forward and backward directions and the chamber being formed therein;
An inner disk provided in the chamber of the outer disk and configured to rotate coaxially with the outer disk;
A stem coupled to the rotational axis of the inner disc to provide rotational power;
And a drive gear set that rotates the outer disc and the inner disc in opposite directions so that the outer disc and the inner disc are opened at the front center of the flow path of the valve body,
Wherein the drive gear set includes a ring gear having a lower portion coupled to an upper portion of the outer disk and rotating together with the outer disk with the same rotation axis, a lower portion coupled to an upper portion of the inner disk through a center of the ring gear, And a planetary gear engaged with the sun gear and the ring gear to transmit the rotational force of the sun gear to the ring gear in a reverse direction,
Wherein the diameter of the flow path of the valve body is 1/5 or less of the diameter of the outer disk,
The turning radius of the outer disc is limited to 90 degrees,
Wherein the flow path of the valve body, the flow path of the outer disk, and the flow path of the inner disk have the same diameter.

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