JP2010014280A - Low noise rotary valve - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a low noise rotary valve capable of reducing noise and cavitation throughout all openings. <P>SOLUTION: Mutually orthogonal and communicating penetration passage 61 and communication path 31 are formed on a ball plug 60. A noise reducing member 65 having a plurality of slits 66 extending long in the rotating direction of the ball plug 60 and arranged side by side in the direction orthogonal to the rotating direction is provided on a seat ring 63 of the secondary side, and the slits 66 are made communicate with a secondary side circulation passage 10 of a valve body 3 to allow liquid 7 having passed the slits 66 flow into the secondary side circulation passage 10 when the ball plug 60 is rotated to an opening direction. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a low noise rotary valve.

  When a rotary valve such as a ball valve is used in a state where the cross-sectional area of both end openings of the through-flow passage formed in the ball plug is reduced, a large pressure drop occurs in the restricted opening and the flow velocity is very high. Therefore, noise is generated at the openings at both ends of the through flow path, and cavitation occurs at the downstream side of the flow path.

  As a result of investigating the noise reduction technology for such a rotary valve, Patent Literatures 1 to 4 were found.

  The ball valve described in Patent Document 1 includes a ball portion of a top portion located above the through hole in the height direction and a portion of the bottom portion located below the through hole in the height direction of the ball. A spherical portion and a side wall that is in the same height range as the through hole and that forms both sides in the axial direction of the through hole, leaving the other side wall facing the top portion. The spherical part and the bottom partial spherical part are cut out so as not to communicate with each other. In other words, this ball valve has a C-shaped cross section perpendicular to the axis of the through hole of the ball, thereby cutting one side wall of the through hole and closing the valve with the other side wall that is not cut when fully closed. It is what you do.

  In such a ball valve, when the ball is rotated in the closing direction, a side wall that is not cut out of the side walls forming both sides of the through hole in the axial direction and one seat ring located on the side of the side wall The cross-sectional area of one opening formed is reduced in the same manner as in the conventional ball valve, but the cross-sectional area of the other opening formed by the other seat ring is reduced so much on the cut side wall side. Therefore, the flow velocity does not increase as much as one of the openings, and the entire running noise can be reduced.

  In the ball valve described in Patent Document 2, a flow path opening including a through hole is formed in a ball, an arc-shaped protrusion is provided at a secondary side end of the flow path opening, and a circumferential direction is provided at a primary side end. A cut-out portion is provided so that the primary side is always open. In such a ball valve, since the flow area of the fluid can be increased by the notch, it is possible to prevent generation of noise due to running water noise and to rectify the fluid flow.

  In order to reduce noise generated by fluid flow, the ball valve assembly described in Patent Document 3 includes a plurality of small flow paths and an insert that defines at least one large flow path on the inner wall of the valve body downstream of the ball. It is arranged on the side. The insert has an airfoil surface that prevents the fluid from flaking off as the fluid passes through a relatively large flow path, and allows a two-stage pressure drop between the inner wall of the valve body. A cavity is formed.

The throttle valve described in Patent Document 4 divides a passage formed of a through hole formed in a spherical valve plug into a plurality of narrow passages by a plurality of partition plates orthogonal to the rotation axis of the valve plug. The front edge of the plate is formed in a streamlined manner to generate a laminar flow. In such a throttle valve, the pressure head across the valve is converted into frictional energy loss, so that noise and cavitation can be prevented.

Japanese Utility Model Publication No. 4-56981 JP 2000-46209 A JP-A-10-281339 JP 59-231822

  However, since the ball valve described in Patent Document 1 simply has a C-shaped ball cross-sectional shape and opens one side of the through hole, the opening portion is narrowed when the valve is at an intermediate opening degree. However, since the pressure drop still occurs and the flow velocity becomes very high, the generation of noise and cavitation cannot be prevented, and the noise reduction effect is low.

  The ball valve described in Patent Document 2 has a problem that a flow rate characteristic is a quick opening characteristic because the secondary side of the flow path opening is always open, and it cannot be used as a proportional control valve. In addition, since the secondary side of the channel opening is narrowed by the protruding portion, there is a problem that the noise reduction effect is low.

  In the ball valve assembly described in Patent Document 3, since the cross-sectional area of the opening on the downstream side of the ball of the valve body is restricted by the insert, the effect of reducing noise at high opening is low, and the passage of the insert There is a problem that the noise reduction function deteriorates when foreign matter is clogged in the cavity.

The throttle valve described in Patent Document 4 has a problem in that when the valve is throttled, the fluid that has entered the passage in the valve plug is largely bent by the partition plate, so that turbulent flow occurs and the noise reduction effect is low.
Further, since it is necessary to incorporate a sleeve integrally provided with a partition plate into the valve plug, there is a problem that the manufacturing and assembling work is troublesome and the valve plug is enlarged.

  The present invention has been made to solve the above-described conventional problems, and an object of the present invention is to provide a low-noise rotary valve capable of reducing the generation of noise and cavitation over the entire opening. .

  In order to achieve the above object, a first invention is a straight valve body having a flow passage opening on both sides, and an inflow side opening and an outflow side opening opposed to both end openings of the valve body when fully opened. A ball incorporated in the flow passage of the valve body having a through flow passage and a communication passage that opens at a position 90 ° apart from the inflow side opening and the outflow side opening of the through flow passage. A plug, a seat ring that rotatably holds an outer peripheral wall on the outflow side opening side of the ball plug, and a rotating means that rotates the ball plug, and the flow path is rotated by the rotation of the ball plug. In the rotary valve that opens and closes, the seat ring is provided with a noise reduction member having a plurality of slits extending in the rotation direction of the ball plug and arranged in parallel in a direction orthogonal to the rotation direction, ball When the lug is rotated in the opening direction, the slit is communicated with the secondary flow path of the flow passage is a fluid having passed through the slit which is introduced into the secondary side flow path.

  According to a second aspect of the present invention, there is provided a valve body having flow passages opened on both sides, a straight through passage having an inflow side opening and an outflow side opening opposed to both end openings of the valve body when fully opened, and the penetration A ball plug incorporated in the flow passage of the valve body, and a communication passage that opens at a position 90 ° apart from the inflow side opening of the flow path and the outflow side opening. In a rotary valve that includes a seat ring that rotatably holds an outer peripheral wall on the inflow side opening portion side, and a rotation unit that rotates the ball plug, and opens and closes the flow passage by rotation of the ball plug. The seat ring is provided with a noise reduction member having a plurality of slits extending in the rotation direction of the ball plug and arranged in parallel to the direction orthogonal to the rotation direction, and the ball plug rotates in the opening direction. Moved Occasionally, the slit communicates with the through passage of the ball plug is a fluid having passed through the slit which is flowing into the through channel.

  According to a third invention, in the first invention, the plurality of slits are formed such that the slit width gradually increases from the low opening side end to the high opening side end, and the ball plug is fully opened. Sometimes, the low opening side end of the slit is formed to be located on the communication path side of the ball plug.

  In a fourth aspect based on the second aspect, the plurality of slits are formed such that the slit width gradually increases from the low opening side end to the high opening side end, and the ball plug is fully opened. Sometimes, the slit is formed so that the end portion on the high opening side is located on the communication path side of the ball plug.

  According to a fifth aspect of the present invention, in any one of the first to fourth aspects of the present invention, at least one of the plurality of slits is orthogonal to the rotation direction of the ball plug at least on one low opening side end. A slit-shaped low noise reduction portion extending in the direction is formed.

  In the first and second inventions, the slit of the noise reduction member suppresses the flow velocity of the fluid and rapidly recovers the pressure drop of the fluid after the passage, so it is fully opened from the low opening when the fluid starts to flow. The generation of noise and cavitation can be suppressed over the entire opening, and noise can be reduced. Further, since the rotary valve itself only needs to form a communication path in the ball plug and provide the noise reduction member on the seat ring, the structure can be simplified and manufactured at low cost.

  In the third and fourth inventions, the flow rate characteristic of the valve can be an equal percentage characteristic and can be used as a proportional control valve.

  In the fifth aspect of the present invention, noise generated particularly when transitioning from the fully closed state to the low opening can be effectively reduced by the low opening noise reduction unit.

It is sectional drawing at the time of a full open which shows one Embodiment of the low noise rotary valve which concerns on this invention. It is sectional drawing in the time of full closure of the rotary valve. It is an external appearance perspective view of a ball plug. (A)-(c) is a figure which shows the fully open state of a rotary valve, the figure which shows an intermediate opening state, and the figure which shows a fully closed state. (A)-(d) is a figure which shows the modification of a slit, respectively. It is a figure which shows the relationship between a noise level and a noise characteristic. It is a figure which shows the relationship between a flow volume and a flow volume characteristic. It is sectional drawing of the low noise rotary valve which shows other embodiment of this invention. It is the side view seen from the primary side of the rotary valve. It is an external appearance perspective view of a ball plug, a secondary side seat ring, and a noise reduction member. It is the side view which looked at the secondary side seat ring and the noise reduction member from the secondary side. It is an external appearance perspective view of the ball plug which shows other embodiment of this invention.

Hereinafter, the present invention will be described in detail based on embodiments shown in the drawings.
1 is a cross-sectional view of a low-noise rotary valve according to an embodiment of the present invention when fully open, FIG. 2 is a cross-sectional view of the rotary valve when fully closed, FIG. 3 is an external perspective view of a ball plug, and FIG. (A)-(c) is a figure which shows the fully open state of a rotary valve, the figure which shows an intermediate opening state, and the figure which shows a fully closed state. In these drawings, a low-noise rotary valve generally indicated by reference numeral 1 includes a valve body 3 connected in the middle of a pipe 2 (2A, 2B), and a ball rotatably incorporated in the center of the valve body 3. A plug 4 and a valve shaft 5 as a rotating means for rotating the ball plug 4 in the horizontal direction within an angle range of about 90 ° are formed.

  The valve main body 3 is formed by two members, an upstream valve main body 3A and a downstream valve main body 3B, so that the overall shape constitutes an inverted T-shaped tube, and the three directions on both sides and above It is open to. The upstream valve body 3A includes a pipe body 30A and a cylindrical valve shaft mounting portion 30B integrally projecting upward toward the downstream side of the upper wall of the pipe body 30A. The internal space of the pipe body 30A includes a primary side (upstream side) flow passage 8 into which the fluid 7 flows, a ball cavity 9 in which the ball plug 4 is incorporated, and a part 10a of the secondary side (downstream side) flow passage 10. Is forming. A tapered female thread 12 that is screwed into a tapered male thread of the upstream pipe 2A is formed on the inner peripheral surface of the upstream opening 11 of the pipe body 30A. A female screw 14 for connecting the side valve main body 3B is formed. The valve shaft attachment portion 30B is located above the ball cavity 9, the valve shaft 5 is rotatably inserted through an O-ring 15, and the upper end opening is covered with a lid member 16.

  The downstream side valve body 3B is composed of a tube body whose both ends are open, and the internal space forms the remaining portion 10b of the secondary side flow passage 10. A male screw 19 is formed at the upstream opening end 18 on the outer peripheral surface of the downstream valve body 3B. On the other hand, a tapered female thread 22 that is screwed into the tapered male thread 21 of the downstream pipe 2B is formed in the downstream opening 20 on the inner peripheral surface of the downstream valve body 3B. The upstream side valve body 3 </ b> A and the downstream side valve body 3 </ b> B are integrally coupled by screwing of the female screw 14 and the male screw 19, and the coupling portion is sealed by the seal member 23.

  The ball plug 4 is formed in a substantially spherical shape from stainless steel, plated brass, or the like, and is rotatably inserted into the ball cavity 9 via a pair of seat rings 25 and 26. The portion of the outer peripheral wall of the ball plug 4 that is in sliding contact with the seat rings 25 and 26 forms a seating portion 27 that is a spherical surface centered on the spherical center of the ball plug 4.

  Inside the ball plug 4, a through flow path 30 and a communication path 31 for flowing the fluid 7 are formed. The through passage 30 is formed of a through hole that passes through the ball center of the ball plug 4 and is orthogonal to the axis of the valve shaft 5, thereby opening two openings 30 a and 30 b that open to the outer peripheral walls on both sides of the ball plug 4. have. Further, the through channel 30 has a circular cross section and is formed in a hole having the same inner diameter over substantially the entire length. The hole diameter of the through channel 30 is set slightly smaller than the inner diameter of the pair of seat rings 25 and 26. The two openings 30a and 30b are separated from each other by 180 ° in the rotation direction of the ball plug 4, and one opening 30a forms an inflow side opening and the other opening 30b forms an outflow side opening. Yes.

A portion of the outer peripheral wall of the ball plug 4 where the inflow side opening 30 a of the through flow path 30 is opened is cut out on a flat surface orthogonal to the axis of the through flow path 30. On the other hand, the portion of the outer peripheral wall of the ball plug 4 where the outflow side opening 30b of the through-flow passage 30 is open is not cut, and the surface thereof is the same spherical surface as the spherical seating portion 27, and the seat ring A spherical seating portion is formed with respect to 26. The outflow side opening 30b of the through-flow passage 30 extends in the rotation direction (horizontal direction) of the ball plug 4 and extends in parallel to four slits 33 (33a to 33a) arranged in a direction orthogonal to the rotation direction. 33d). The partition wall 28 that partitions the adjacent slits 33 is a portion in which the outflow side opening 30 b of the through-flow passage 30 is formed on the outer peripheral wall of the ball plug 4. Each slit 33a~33d are slit width are formed so as to gradually become wider toward the lower opening end Q ₁ to a high degree of opening end Q _2. The low opening side end portion Q ₁ of the slit 33 is a rotation side when the ball plug 4 is rotated in the opening direction as shown in FIG. 4B from the fully closed state shown in FIG. The high opening side end Q ₂ is an end opposite to the rotation direction side of the ball plug 4. The reason why the slit width of the slit 33 is changed is to change the flow rate characteristic of the rotary valve 1 and is formed so as to gradually increase from the low opening side end Q ₁ toward the high opening side end Q _2. In this case, the flow rate characteristic can be an equal percentage characteristic.

The communication path 31 is a hole with a circular cross section having the same hole diameter as the through flow path 30, and is perpendicular to the axis of the valve shaft 5 and the through flow path 30. It is formed in the radial direction of the ball plug 4 at the same height, and communicates with the inside center of the through flow path 30. The opening 31 a of the communication path 31 is open to one of the side walls 32 a and 32 b that form both sides of the communication path 31 in the axial direction on the outer peripheral wall of the ball plug 4. The one side wall portion 32 a is a side wall portion opposite to the valve opening direction of the ball plug 4, in other words, a side wall portion between the inflow side opening portion 30 a and the high opening side end portion Q _{2 of the} slit 33. In addition, the opening 31a of the communication passage 31 is opened at a position 90 ° away from the inflow side opening 30a and the outflow side opening 30b of the through-flow channel 30. A portion of the outer peripheral wall of the ball plug 4 where the opening 31 a of the communication path 31 is opened is cut out to a flat surface perpendicular to the axis of the communication path 31.

  A fitting recess 35 into which the inner end of the valve shaft 5 is fitted is formed in the upper peripheral wall portion of the ball plug 4. The outer end of the valve shaft 5 protrudes above the lid member 16 and is connected to an electric actuator (not shown) or attached with a handle for manual operation.

  The pair of seat rings 25 and 26 are pressed against the outer peripheral surface of the ball plug 4 by coupling the upstream side valve body 3A and the downstream side valve body 3B, thereby sealing the gap between the valve body 3 and the ball plug 4. is doing. A seat ring groove 36 into which the primary seat ring 25 is fitted is formed at the boundary between the primary side flow passage 8 and the ball cavity 9 on the inner wall surface of the pipe body 30A of the upstream valve body 3A. . On the other hand, a seat ring groove 37 into which the secondary seat ring 26 is fitted is formed on the inner peripheral surface of the upstream opening end 18 of the downstream valve body 3B.

  In the low noise rotary valve 1 having such a structure, FIG. 4 (a) shows a fully opened state. In this fully open state, the inflow side opening 30a and the outflow side opening 30b of the through-flow passage 30 are located in the seat rings 25 and 26, respectively, and the fluid 7 flows from the primary side flow passage 8 of the valve body 3 to the secondary side. It flows on the road 10. The outer end opening 31 a of the communication path 31 is located in the ball cavity 9. In this state, since the cross-sectional area of the inflow side opening 30a is not restricted by the seat ring 25, the pressure drop of the fluid 7 on the upstream side and the rapid change of the flow velocity do not occur. Therefore, no upstream noise is generated.

  On the other hand, in the downstream opening 30b, the slit 33 functions as a throttle for the fluid 7 because the opening cross-sectional area of the downstream opening 30b is reduced. In addition, the slit 33 has a rectifying function for performing rectification while minimizing changes in the flow line of the fluid 7 as much as possible. For this reason, the flow velocity of the fluid 7 passing through the slit 33 is suppressed by friction at the boundary in the slit 33, and after passing, when the fluid 7 flows into the secondary side flow passage 10, the passage cross-sectional area rapidly expands so that the fluid pressure Recovers rapidly. Therefore, even when the fluid 7 passes through the slit 33 on the secondary side, the flow disturbance is increased and no noise or cavitation occurs.

  Next, when the ball plug 4 is rotated clockwise in FIG. 4A to switch the rotary valve 1 from the fully open state to the intermediate opening state shown in FIG. 4B, the inflow side opening 30a rotates. Since the end portion on the direction side retreats to the outside of the seat ring 25 and moves into the ball cavity 9, the cross-sectional area of the opening communicating with the primary side flow passage 8 is reduced. On the other hand, when the intermediate opening is set, the rotation direction end of the opening 31a of the communication path 31 moves into the seat ring 25 and communicates with the primary side flow path 8, so that the primary side flow path 8 enters the ball plug 4. The flow rate of the inflowing fluid 7 is not greatly reduced even if the flow is reduced by switching from the fully open state to the intermediate opening degree. Therefore, even when switching to the intermediate opening degree, the pressure of the fluid 7 does not drop abruptly or the flow velocity does not change abruptly on the primary side, and the generation of noise on the primary side can be reduced.

Switching the rotary valve 1 in the intermediate opening, outlet aperture 30b moves into the ball cavity 9 high opening degree end Q ₂ of the slit 33 is moved to the outside of the seat ring 26, low opening The side end Q ₁ moves into the seat ring 26. For this reason, the outflow side opening 30b is narrowed, and the cross-sectional area of the opening portion communicating with the secondary side flow passage 10 is reduced. Accordingly, the pressure of the fluid 7 passing through the outflow side opening 30b is lowered and the flow velocity is rapidly increased. However, even at this intermediate opening, the fluid 7 passing through the outflow side opening 30b does not become turbulent because the change of streamlines is suppressed by the action of the slit 33, and also passes by friction at the boundary in the slit 33. After the passage of the slit 33, the flow velocity is suppressed and when the fluid flows into the secondary side flow passage 10, the passage cross-sectional area rapidly expands so that the fluid pressure is quickly recovered. Therefore, the noise on the secondary side as well as the primary side is reduced. And cavitation can be suppressed.

  When the intermediate opening is switched, the inflow side opening 30a is separated from the seat ring 25, but the surface of the outer peripheral wall of the ball plug 4 where the outflow side opening 30b is open is the same as the spherical seating portion 27. 4 (b), a gap may be generated between the outer peripheral wall of the outflow side opening 30b (partition wall 28 partitioning the slit 33) and the seat ring 26, as shown in FIG. Therefore, there is no possibility that the fluid 7 will hit the seat ring 26 when the fluid 7 passes through the slit 33 and the flow disturbance will increase, and the generation of noise and cavitation on the downstream side can be further reduced.

  When the rotary valve 1 is switched to the fully closed state as shown in FIG. 4C, the through flow path 30 is orthogonal to the primary side flow path 8 and the secondary side flow path 10, and the inflow side opening 30a and the outflow side opening The portion 30 b completely retracts to the outside of the seat rings 25 and 26, and the other side wall portion 32 b of the through channel 30 closes the seat ring 26. Therefore, the primary side flow passage 8 and the secondary side flow passage 10 are blocked.

As described above, in the low-noise rotary valve 1 according to the present invention, the outflow side opening 30b of the through passage 30 of the ball plug 4 is configured by the plurality of slits 33, and the communication passage 31 orthogonal to the through passage 30 is provided. Since the ball plug 4 is formed, the generation of noise and cavitation can be reduced over the entire opening from the fully open state to the low opening state where the flow starts, and noise reduction can be realized.
Also, the ball plug 4 can be manufactured relatively easily, and it is not necessary to incorporate another part, and the number of parts does not increase.

  FIGS. 5A to 5D show modifications of the slit formed in the ball plug. That is, in FIG. 5A, similarly to the slit 33 shown in FIG. 1, the first to fourth slits 41a to 41d that are long in the rotation direction of the ball plug 4 are arranged in parallel to the direction orthogonal to the rotation direction. Among them, a low-opening noise reduction part 42 that is bent in a direction orthogonal to the rotation direction is formed at the low opening side end of the second slit 41b. According to such a slit 41, the noise generated when the low opening noise reduction unit 42 provided in the second slit 41b makes a transition from the fully closed state to the low opening is shown in FIG. As compared with the above, it can be more effectively reduced.

  FIG. 5B shows a configuration in which first and second slits 43a and 43b that are long in the rotation direction of the ball plug 4 are arranged in parallel in a direction orthogonal to the rotation direction. The slit widths of the first and second slits 43a and 43b are the same over the entire length. With such a slit 43, the flow rate characteristic of the rotary valve can be made linear.

  FIG. 5C shows that the first and second slits 45 a and 45 b that are long in the rotation direction of the ball plug 4 are arranged in parallel to each other in the direction orthogonal to the rotation direction, and the low opening side end portions are connected to each other by the connecting groove 46. The slit 45 is connected.

  In FIG. 5D, first and second slits 47 a and 47 b that are also long in the rotation direction of the ball plug 4 are arranged in parallel to the direction orthogonal to the rotation direction, and the end portion on the high opening side is connected by the connecting groove 48. The slits 47 are connected to each other. The connecting groove 48 is formed wider than the slit width of the first and second slits 47a and 47b.

  FIG. 6 is a diagram showing the relationship between the noise level and the noise characteristics. In the figure, the curve A is the noise characteristic of the rotary valve 1 shown in FIG. 1, and the curve B is the same as the inflow side opening 30a without forming the outflow side opening 30b of the rotary valve 1 shown in FIG. It is the noise characteristic in the rotary valve made into the circular opening. As is apparent from this figure, according to the rotary valve 1 of the present invention, the noise level can be reduced by about 6 to 8 dBA by the slit 33 as compared with the rotary valve not provided with the slit of the curve B.

  FIG. 7 is a diagram showing the relationship between the flow rate and the flow rate characteristics. In the figure, a straight line C is a flow characteristic (equal percentage characteristic) of the rotary valve 1 shown in FIG. 1, and a curve D is a flow characteristic (linear characteristic) when the slit 43 shown in FIG. 5B is formed in a ball plug. FIG. As described above, in the present invention, the flow rate characteristic can be changed by changing the shape of the slit.

8 is a cross-sectional view of a low noise rotary valve showing another embodiment of the present invention, FIG. 9 is a side view of the rotary valve seen from the primary side, and FIG. 10 is a ball plug, a secondary seat ring, and noise reduction. FIG. 11 is a side view of the secondary side seat ring and the noise reduction member as seen from the secondary side.
In these drawings, the ball plug 60 is rotatably incorporated in the valve body 3 via a pair of seat rings 25 and 63 and is configured to be rotated by the valve shaft 5 within an angle range of 90 °. ing. Inside the ball plug 60, a through flow path 61 and a communication path 31 that are orthogonally connected to each other are formed. The through-flow channel 61 has a circular cross-sectional shape and the same hole diameter over the entire length. The portions of the outer peripheral wall of the ball plug 60 where the both end openings 62 a and 62 b of the through flow passage 61 are opened are cut out on a flat surface perpendicular to the axis of the through flow passage 61. Therefore, both end openings 62a and 62b form circular opening end faces, and are different from the ball plug 4 shown in FIG. 1 in that no slit is formed in any opening. The communication path 31 is the same as the communication path 31 of the ball plug 4 shown in FIG. 1, and is formed in the radial direction of the ball plug 60 so that the inner end communicates with the center of the through-flow channel 61 and the outer end is Of the two side walls forming both sides of the through-flow channel 61 in the axial direction, an opening is made in the side wall portion opposite to the rotation direction of the ball plug 60 when the valve is opened.

  The seat ring 25 on the primary side of the pair of seat rings 25 and 63 is the same as the seat ring 25 shown in FIG. 1 and has an inner diameter substantially equal to or larger than the hole diameters of the through flow path 61 and the communication path 31. ing.

  The seat ring 63 on the secondary side is formed in a cup shape by a cylindrical main body 63A and a disk portion 63B that covers an end surface of the main body 63A opposite to the ball plug 60 side. The main body 63A is substantially the same size as the primary side seat ring 25 and has an inner diameter equal to the inner diameter of the primary side seat ring 25. A noise reduction member 65 is integrally projected at the center of the surface of the disc portion 63B. The inner surface of the disc portion 63B is formed into a spherical surface having the same radius of curvature as the spherical surface of the outer peripheral wall of the ball plug 60.

  The noise reducing member 65 is composed of five slit forming plates 65a to 65e arranged in parallel in the vertical direction with a predetermined interval, and the gap between these plates defines the secondary side seat ring 63. Each slit 66 is formed to allow the fluid 7 that has passed therethrough to pass therethrough. The five slit forming plates 65a to 65e are formed with different lengths so that the entire contour shape is a circle smaller than the outer diameter of the disc portion 63B. The width of each slit 66 formed between adjacent slit forming plates 65a to 65e is formed so as to gradually widen from the low opening side end to the high opening side end. Further, these slits 66 are formed so as to penetrate through the disk portion 63B, thereby communicating with the inside of the secondary side seat ring 63.

  In the low-noise rotary valve 67 having such a structure, the outlet side opening 62b of the through flow passage 61 is throttled by the secondary side seat ring 63 at an intermediate opening, so that the sectional area of the opening is reduced. For this reason, the pressure of the fluid 7 passing through the outflow side opening 62b is lowered and the flow velocity is rapidly increased. Then, the fluid 7 that has passed through the outflow side opening 62 b passes through the slit 66 and flows into the secondary side flow passage 10. At this time, the flow velocity of the fluid 7 is suppressed by friction at the boundary in the slit 66, and after passing, the fluid pressure rapidly recovers when the fluid 7 flows into the secondary side flow passage 10 and the cross-sectional area rapidly expands. Therefore, also in such a rotary valve 67, the noise and cavitation which generate | occur | produce in intermediate | middle full open like the rotary valve 1 shown in FIG. 1 can be reduced. Similarly, noise and cavitation can be reduced by the action of the slit 66 even when fully open. Furthermore, since the secondary side seat ring 63 and the noise reduction member 65 are integrally formed, the number of parts does not increase.

FIG. 12 is an external perspective view of a ball plug showing still another embodiment of the present invention.
In this embodiment, a partition wall (part indicated by reference numeral 80 in FIG. 4A) that partitions the inflow side opening 30a of the through-flow passage 30 of the ball plug 4 and the opening 31a of the communication path 31 is cut out. By doing so, both openings are made to communicate. The ball plug 4 having such a structure is advantageous in that the weight can be reduced and the cost can be reduced. Moreover, since the partition wall is excised, the flow area on the upstream side is increased, and the generation of noise can be further suppressed.

The present invention is not limited to the above-described embodiments, and various modifications and changes can be made without departing from the gist of the invention. For example, in the embodiment shown in FIG. 1, the slit 33 is formed in the outflow side opening 30b of the through flow path 30, but the same effect can be obtained even if it is formed in the inflow side opening 30a.
Similarly, in the embodiment shown in FIGS. 8 to 11, the noise reduction member 66 is provided integrally with the secondary side seat ring 63, but the primary side flow passage with the secondary side seat ring 63 as the primary side. 8 and the primary side seat ring 25 may be incorporated in the secondary side flow passage 10 as the secondary side.
Further, the seat ring is not limited to a pair and may be one. Further, the noise reduction member 66 is not limited to being formed integrally with the seat ring, but may be formed separately.
Furthermore, the present invention can also be applied to an eccentric rotary valve.

  DESCRIPTION OF SYMBOLS 1 ... Low noise rotary valve, 2 ... Piping, 3 ... Valve body, 4 ... Ball plug, 5 ... Valve shaft, 7 ... Fluid, 8 ... Primary side flow path, 10 ... Secondary side flow path, 25, 26 ... Seat Ring 30, through-flow channel, 30 a, inflow side opening, 30 b, outflow side opening, 31, communication path, 31 a, opening, 33, slit, 41, slit, 42, low opening noise reduction unit, 43 45, 47 ... slit, 60 ... ball plug, 61 ... through channel, 63 ... secondary side ring, 65 ... noise reducing member, 66 ... slit, 80 ... partition wall.

Claims (5)

A valve body having flow passages opened on both sides, a straight through passage having an inflow side opening and an outflow side opening opposed to both end openings of the valve body when fully opened, and an inflow side opening of the through passage And a communication passage that opens at a position 90 ° apart from the outflow side opening, and a ball plug that is incorporated in the flow passage of the valve body, on the outflow side opening side of the ball plug In a rotary valve that includes a seat ring that rotatably holds an outer peripheral wall and a rotating means that rotates the ball plug, and opens and closes the flow passage by the rotation of the ball plug.
The seat ring is provided with a noise reduction member having a plurality of slits extending in the rotation direction of the ball plug and arranged in parallel in a direction perpendicular to the rotation direction,
When the ball plug is rotated in the opening direction, the slit is communicated with the secondary side flow path of the flow path, and the fluid that has passed through the slit is caused to flow into the secondary side flow path. Low noise rotary valve. A valve body having flow passages opened on both sides, a straight through passage having an inflow side opening and an outflow side opening opposed to both end openings of the valve body when fully opened, and an inflow side opening of the through passage And a communication path that opens at a position 90 ° apart from the outflow side opening, and a ball plug incorporated in the flow path of the valve body, and an inflow side opening side of the ball plug In a rotary valve that includes a seat ring that rotatably holds an outer peripheral wall and a rotating means that rotates the ball plug, and opens and closes the flow passage by the rotation of the ball plug.
The seat ring is provided with a noise reduction member having a plurality of slits extending in the rotation direction of the ball plug and arranged in parallel in a direction perpendicular to the rotation direction,
When the ball plug is rotated in the opening direction, the slit communicates with the through channel of the ball plug, and the fluid that has passed through the slit flows into the through channel. Rotary valve.   The plurality of slits gradually widen from the low opening side end to the high opening side end, and the low opening side end of the slit is the ball when the ball plug is fully opened. 2. The low noise rotary valve according to claim 1, wherein the low noise rotary valve is formed so as to be positioned on the communication path side of the plug.   The plurality of slits gradually widen from the low opening side end toward the high opening side end, and the high opening side end of the slit is the ball when the ball plug is fully opened. 3. The low noise rotary valve according to claim 2, wherein the rotary valve is formed so as to be positioned on the side of the communication path of the plug.   The slit-like low opening noise reduction portion extending in a direction orthogonal to the rotation direction of the ball plug is formed at at least one of the plurality of slits on the low opening side end. Item 5. The low-noise rotary valve according to any one of Items 1 to 4.

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