JP5847680B2 - Rotary valve - Google Patents

Description

  The present invention relates to a rotary valve that controls the flow of a fluid by rotation of a rotor in a case.

  In the rotary valve, the axial center of the cylindrical case is arranged in the left-right direction, and the rotor is concentrically fitted to the case. The case has end plates fixed to the left and right open ends. The left and right end plates open a central hole and penetrate the central hole through the left and right end portions of the rotation shaft of the rotor. The rotating shaft of the rotor has the left and right end portions supported by the left and right end plates. The case has an inlet opening at an upper portion of the peripheral wall, and a supply pipe is connected to the inlet. An outlet is opened in the lower part of the peripheral wall, and a discharge pipe is connected to the outlet.

  In the rotor, several blades are attached radially around the outer periphery of the central portion of the rotating shaft. The rotating shaft has concentric disk-shaped side plates attached to the left and right positions of the blades. The left and right side plates, two adjacent blades, and the rotation shaft form a recess. The recess is a pocket for the fluid. Several pockets are arranged at equal intervals around the outer periphery of the rotating shaft. The number of pockets is 4 or 8. The rotary shaft is configured such that one end is connected to a rotary drive device such as an electric motor.

  When the rotor is rotated by the rotary drive device and the fluid is supplied to the supply pipe, the fluid in the supply pipe enters the inlet of the case and flows into the pocket reaching the upper position of the rotating rotor. As the rotor rotates further, the fluid in the pocket reaches the lower position of the rotor, enters the outlet of the case and flows out into the discharge pipe. The fluid enters from the inlet, passes through the rotating rotor and exits to the outlet.

  Increasing or decreasing the rotational speed of the rotor increases or decreases the amount of fluid passing through the rotor. Increase or decrease the flow rate from the inlet to the outlet at the rotational speed of the rotor. When the rotation of the rotor is stopped, the inlet and the outlet are closed by the stopped rotor. Fluid does not pass through the rotor. The passage from the inlet to the outlet is opened and closed by rotating and stopping the rotor. That is, the flow of the fluid is controlled by the rotation of the rotor.

JP 2009-263051 A

[Task]
In the rotary valve as described above, when the fluid is odorous or contains gas or liquid, the odor, gas or liquid may leak to the outside. Examples of odorous fluids include waste liquid sludge, sewage, and roasted beans. Examples of the fluid containing gas include powder particles during pneumatic transportation. Examples of the fluid containing liquid include solid-liquid mixtures such as sludge and sewage.

  In the rotary valve, the inner peripheral surface of the case and the outer peripheral surface of the rotor are in contact with or close to each other in order to obtain hermeticity. The inner peripheral surface of the case, the fixed surface and the outer peripheral surface of the rotor, and the portion of the moving surface that face each other constitute a sealing surface that achieves hermeticity. The wider the sealing surface, the higher the sealing performance.

However, the outer peripheral surface of the rotor is the opening edge of the pocket, that is, the outer peripheral surface of the left and right side plates and the outer end surfaces of several blades, and has a small area. The sealing surface does not widen. It is hard to say that the sealing performance is high.
If the fixed surface of the case and the moving surface of the rotor are in contact with each other, the sealing performance is enhanced, but heat generation and wear are generated by friction. If the fixed surface of the case and the moving surface of the rotor are close to each other without being in contact with each other, heat generation and wear due to friction do not occur, but the sealing performance is difficult to increase.
In a rotary valve, it is desired that the sealing performance is likely to be high. In addition, it is desired that heat generation and wear due to friction do not easily occur.

[Idea]
1. Configuration of Rotor and Case A pocket-shaped rotor is provided with a large-diameter pocket component on a small-diameter rotating shaft. The pocket constituting part is not constituted by a blade or a side plate, but a round shaft-shaped body. The pocket constituting part of the round shaft-shaped body is divided into a central part and left and right end parts, and a recess and a pocket are opened on the outer peripheral surface of the central part. The number of pockets is one, two or three.
The cylindrical case is divided into three parts, a central part and left and right end parts, and an inlet and an outlet are provided in the upper part and the lower part of the central part.
As for the pocket forming part of the rotor, the central part with the pocket is fitted into the central part with the entrance and the outlet of the case, and the left and right end parts are fitted into the left and right end parts of the case.

Then, a pocket structure part and a case will face all the peripheral surfaces of an outer peripheral surface and an internal peripheral surface by the edge part on either side. The longer the left and right ends, the wider the sealing surface. Moreover, an outer peripheral surface other than a pocket portion and an inner peripheral surface other than an inlet / outlet portion face each other at the central portion of the pocket constituting portion and the case. When the number of pockets is one, two or three, the outer peripheral surface other than the pocket portion is widened. The sealing surface becomes wider.
The sealing surface tends to be wide, and the sealing performance tends to be high.

2. Lubricating groove and lubricant The pocket configuration portion and the case of the rotor are always opposed to each other at the left and right end portions, regardless of the rotational position of the rotor.

  The case is configured such that lubricating grooves are provided along the circumferential direction on the inner peripheral surfaces of the left and right end portions, and a lubricant is placed in the lubricating grooves. Or a pocket structure part is provided with the lubricating groove in the outer peripheral surface of a right-and-left end part along the circumferential direction, and makes it the structure which puts a lubricating material in a lubricating groove. The lubrication groove has an endless circular shape or a circular arc shape with ends. Also, lubrication grooves that communicate the left and right lubrication grooves are provided.

  The lubricant placed in the lubrication groove flows out into the gap between the inner peripheral surface of the case and the outer peripheral surface of the pocket constituting portion. The gap will be filled with lubricant and closed. Increases sealing performance. In addition, even if the inner peripheral surface of the case and the outer peripheral surface of the pocket forming portion come into contact with each other and are rubbed, the lubricant acts and hardly generates heat or wear.

3. Flocculant as lubricant The lubricant that has flowed out of the lubrication groove into the gap between the case and the pocket component of the rotor may leak into the inlet, pocket, or outlet and enter the fluid.

  On the other hand, the flocculant used for the treatment of the waste liquid is added to the sludge and waste water of the waste liquid, and the fine particles in the sludge and the waste water are combined to form a floc and form floc. There are various such flocculants, and some of them also act as lubricants. For example, a fluid flocculant or a viscous flocculant also acts as a lubricant.

  When the fluid contains a flocculant such as sludge or sewage, or when a flocculant is added later, the lubricant to be put in the lubricating groove is a flocculant that also acts as a lubricant. Even if this flocculant leaks out from the gap between the case and the pocket constituting part and is mixed into the fluid, it is difficult for harmful effects to occur.

1. In the rotary valve that controls the flow of fluid by the rotation of the rotor in the case,
The case has a cylindrical shape and the axial center is arranged in the left-right direction. The inlet and outlet are opened in the upper part and the lower part,
The rotor is provided with a pocket component on the rotating shaft, and the pocket component is fitted to the case.
When the rotor is rotated and fluid is supplied to the inlet of the case, the fluid flows into the pocket reaching the upper position of the rotor, and when the rotor further rotates, the fluid in the pocket flows out to the outlet of the case. A rotary valve configured,
The case is divided into three parts, a central part and left and right end parts, and an inlet and an outlet are arranged in the central part.
The pocket component is a round shaft-shaped body, divided into three parts, a central part and left and right end parts, and a pocket is opened on the outer peripheral surface of the central part.
This pocket component fits the central part with the pocket into the central part with the case entrance and the outlet, and the left and right end parts with the left and right end parts of the case,
The pocket component and the case face the outer peripheral surface and the entire inner peripheral surface at the left and right ends, and face the outer peripheral surface other than the pocket portion and the inner peripheral surface other than the inlet / outlet portion at the central portion. And
Lubricating grooves are provided along the circumferential direction on the inner peripheral surface of the left and right ends of the case or the outer peripheral surfaces of the left and right ends of the pocket component, and the lubricant is put in the lubricating grooves. Provide a lubrication groove to communicate,
The gap between the inner peripheral surface of the case and the outer peripheral surface of the pocket forming portion is configured to be filled with a lubricant and closed.
2. In the rotary valve of 1 above,
The number of pockets is one, two, or three.
3 . In the rotary valve of 1 or 2 above,
The lubrication groove has an endless annular shape or a circular arc shape with ends.
4 . In the above 1 , 2 or 3 rotary valve,
The lubricant is characterized by a coagulant that also acts as a lubricant.
5 . In the rotary valve of any one of the above 1-4 ,
The fluid is characterized by containing a flocculant or a flocculant added later.
6 . In any one of the rotary valves 1 to 5 above,
The fluid is characterized by sludge or sewage.

  The airtightness tends to be high between the case and the pocket component of the rotor. Less likely to generate heat and wear due to friction.

The longitudinal section front view of the rotary valve in the 1st example of the embodiment of the present invention. AA sectional view taken on the line AA of FIG. FIG. 3 is an enlarged cross-sectional view taken along line BB in FIG. 1. It is a figure which shows the state which supplied the fluid to the same rotary valve with a thick arrow, Comprising: Sectional drawing similar to FIG. FIG. 3 is a view showing a state where the rotor of the rotary valve is rotated by a quarter, and is a cross-sectional view similar to FIG. 2. FIG. 3 is a view showing a state where the rotor is half-rotated, and is a sectional view similar to FIG. It is a figure which shows the state which the same rotor rotated 3/4, Comprising: Sectional drawing similar to FIG. The longitudinal section front view of the rotary valve in the 2nd example of an embodiment. The CC sectional view taken on the line of FIG. FIG. 9 is an enlarged sectional view taken along the line D-D in FIG. 8. The longitudinal section front view of the rotary valve in the 3rd example. The EE sectional view enlarged view of FIG.

[First example (see FIGS. 1 to 7)]
<Constitution>
In the rotary valve of this example, as shown in FIGS. 1 to 3, the case 1 has a cylindrical shape and the axis is disposed in the left-right direction. The rotor 11 is provided with a pocket forming portion 13 concentrically at the center of the rotating shaft 12.

  The case 1 is divided into three parts, a central part 1a and left and right end parts 1b. The central portion 1a has an inlet 2 and an outlet 3 opened in the vertical direction at the upper and lower portions of the peripheral wall, respectively. The inlet 2 and the outlet 3 have the same shape and size. A short supply pipe 4 is connected to the inlet 2 on the upper side thereof. A short discharge pipe 5 is connected to the outlet 3 below. The upper end of the supply pipe 4 and the lower end of the discharge pipe 5 are respectively connectable to the pipe.

  In the rotor 11, the pocket constituting portion 13 is formed in a round shaft shape body having a diameter larger than that of the rotation shaft 12. The round shaft-shaped body 13 is formed in a thick cylindrical shape by forming a center hole at the axial center position, and the center portion of the rotating shaft 12 is fitted in the center hole. The round shaft-shaped body 13 and the rotating shaft 12 are prevented from rotating with a key 14 interposed. The rotating shaft 12 and the pocket component 13 are configured to rotate integrally.

The pocket forming part 13 is divided into three parts: a central part 13a and left and right end parts 13b. The central portion 13a has a recess and a pocket 15 opened on the outer peripheral surface. The pocket 15 has the same opening and dimension as the inlet 2 and outlet 3 of the case 1. The number of pockets 15 is one.
The case 1, the supply pipe 4 and the discharge pipe 5 are made of metal or synthetic resin. The rotating shaft 12 is made of metal. The round shaft-shaped body 13 of the pocket constituting part is made of synthetic resin, wood or metal.

  The pocket forming part 13 is concentrically fitted with a central part 13 a having a pocket 15 and a central part 1 a having an inlet 2 and an outlet 3 of the case 1. Further, the pocket constituting portion 13 has the left and right end portions 13b fitted concentrically with the left and right end portions 1b of the case 1, respectively. The pocket forming part 13 and the case 1 are close to the outer peripheral surface and the inner peripheral surface at the central portions 13a and 1a and the left and right end portions 13b and 1a, respectively. The pocket forming portion 13 is rotatable in the case 1 with the axis as the central axis.

  When the pocket component 13 in the case 1 rotates, the pocket 15 revolves around the axis of the pocket component 13. When the pocket 15 reaches the upper position, the pocket 15 assumes an upward posture and communicates with the inlet 2 of the case 1. When the pocket 15 reaches the lower position, the pocket 15 assumes a downward posture and communicates with the outlet 3 of the case 1. The pocket 15 faces the peripheral wall of the case 1 and closes when the front side position and the rear side position are in the horizontal posture. The entrance 2 of the case 1 is closed so as to face the outer peripheral surface of the pocket constituting portion 13 when the pocket 15 is in the lateral position of the front position and the rear position and the downward position of the lower position. The outlet 3 of the case 1 is closed so as to face the outer peripheral surface of the pocket constituting portion 13 when the pocket 15 is in the lateral position of the front position and the rear position and the upward position of the upper position.

  The rotary shaft 12 protrudes outward from the left and right openings of the case 1 at the left and right ends, respectively. The left and right open ends of the case 1 are closed by fixing disc-shaped end plates 21 concentrically. Each of the left and right end plates 21 has a center hole in the left-right direction, and penetrates the left and right ends of the rotating shaft 12 through the center hole. The outer surfaces of the left and right end plates 21 are each provided with a cylindrical mounting portion 22 concentrically. The left and right attachment portions 22 respectively penetrate the left and right end portions of the rotating shaft 12. A shaft seal device 23 is fitted between the left and right attachment portions 22 and the left and right ends of the rotating shaft 12. Ball bearings 24 are concentrically attached to the outer end surfaces of the left and right attachment portions 22, respectively. The rotating shaft 12 penetrates the left and right ball bearings 24 through left and right end portions protruding outward from the left and right shaft seal devices 23, respectively. The rotating shaft 12 is supported by ball bearings 24 on left and right end plates 21 with attachment portions 22 at the left and right ends.

  One end 25 of the rotating shaft 12 protrudes outward from the ball bearing 24. The projecting end portion 25 is a connecting portion that is connected to a rotary drive device such as a variable speed electric motor. When the rotary drive device is connected to the connecting portion 25 and the rotary drive device is driven, the rotor 11 rotates and the pocket forming portion 13 in the case 1 rotates. The rotary drive device is configured to be connected to the connecting portion 25 via a transmission mechanism. Or it is set as the structure connected directly, without going through a transmission mechanism.

  The case 1 and the pocket forming portion 13 are configured so that the left and right end portions 1b and 13a always face each other, regardless of the rotational position of the rotor 11, with the entire inner peripheral surface and outer peripheral surface. Each of the left and right end portions 1b of the case 1 has a lubricating groove 31 formed along the circumferential direction on the inner peripheral surface of the peripheral wall. The left and right lubrication grooves 31 each go around the inner peripheral surface of the peripheral wall of the case 1 in the circumferential direction. Endless ring shape. The left and right end portions of the case 1 are each provided with an injection portion 32 for putting a lubricant into the lubricating groove 31 in the upper portion of the peripheral wall. The left and right injection portions 32 each form an injection passage from the outer peripheral surface of the peripheral wall of the case 1 to the bottom surface of the lubricating groove 31, and are always provided with a closing valve at the outer end of the injection passage. When the injection device is injected by pressing the inlet of a lubricant injection device such as a grease gun against the normally closed valve, the normally closed valve opens and the lubricant is injected into the injection passage from the injection device. The lubricant enters the lubrication groove 31.

<Usage and action>
When using the rotary valve of this example, the left and right lubricating grooves 31 are filled with a lubricant, the rotor 11 is rotated in one direction, and the fluid is supplied to the supply pipe 4. Then, the fluid in the supply pipe 4 enters the case inlet 2 as shown by a thick arrow in FIG. 4, and the rotor pocket 15 of the rotating rotor reaches the upper position and assumes an upward posture to communicate with the inlet 2. Then, it falls and flows into the pocket 15 in the upward posture. When the rotor 11 further rotates halfway, the fluid-filled pocket 15 passes through the lateral orientation shown in FIG. 5, reaches the downward orientation of the rotor lower position shown in FIG. 6, and communicates with the outlet 3. The fluid in the pocket 15 reaches the lower position of the rotor, falls and flows out from the pocket 15 in the downward position as shown by a thick arrow in FIG. 6, enters the outlet 3 of the case, and flows out to the discharge pipe 5 To do. The pocket 15 at the lower position of the rotor is emptied by the outflow of the fluid, and returns to the upward attitude at the upper position shown in FIG. 4 through the lateral attitude shown in FIG.

  When the rotational speed of the rotor 11 is increased or decreased, the amount of fluid passing through the rotor 11 is increased or decreased. The flow rate from the inlet 2 to the outlet 3 is increased or decreased at the rotational speed of the rotor 11. When the rotation of the rotor 11 is stopped, the inlet 2 and the outlet 3 are closed by the stopped rotor 11. The fluid does not pass through the rotor 11. The passage from the inlet 2 to the outlet 3 is opened and closed by the rotation and stop of the rotor 11.

<Lubricant>
The lubricant put in the lubrication groove 31 flows out over the entire circumference into the gap between the inner peripheral surface of the case 1 and the outer peripheral surface of the pocket constituting portion 13. The gap will be filled with lubricant and closed. Increases sealing performance. Further, even if the inner peripheral surface of the case 1 and the outer peripheral surface of the pocket forming portion 13 come into contact with each other and are rubbed, the lubricant acts and hardly generates heat or wear.

Lubricant that flows between the case 1 and the pocket component 13 from the lubricating groove 31 may leak into the inlet 2, the pocket 15, or the outlet 3. The lubricant between the case 1 and the pocket component 13 flows between the end surface of the pocket component 13 and the inner surface of the end plate 21, and the inner peripheral surface of the center hole of the end plate 21 and the outer periphery of the rotary shaft 12. May flow between surfaces.
As the lubricant, various lubricants such as grease, petroleum-based lubricant, animal oil, vegetable oil and synthetic lubricant can be used. Further, a flocculant can be used as a lubricant.

<Flocculant as lubricant>
When the fluid contains a flocculant such as sludge or sewage, or when the flocculant is added later, the same or different type of flocculant as the flocculant is used as a lubricant. The flocculant used as the lubricant is injected into the lubricating groove 31. The flocculant put in the lubricating groove 31 flows out into the gap between the case 1 and the pocket constituting portion 13. And it may leak out to the inlet 2, the pocket 15, or the outlet 3 from the clearance, and may mix with a fluid. Even if the flocculant is mixed into a fluid containing the flocculant or a fluid to which the flocculant is added later, it is difficult to cause harmful effects.
When the fluid is sewage or sewage sludge or sewage, a polymer flocculant is preferred as the flocculant that also acts as a lubricant. Emulsion type polymer flocculants are suitable.

[Second Example (see FIGS. 8 to 10)]
In the rotary valve of this example, a lubrication groove 33 communicating the left and right lubrication grooves 31 is added to that in the first example.
As shown in FIGS. 8 to 10, linear lubricating grooves 33 are provided along the left-right direction on the inner peripheral surface of the peripheral wall of the case 1 so as to span the left and right annular-shaped lubricating grooves 31.

When a lubricant is injected from one of the left and right injection parts 32 into one annular lubrication groove 31 communicating with the injection part 32, the lubricant passes through the straight lubrication groove 33 and the other annular ring. It flows into the lubricating groove 31 having a shape. By the injection operation at one injection portion 32, the lubricant is filled into the left and right annular lubrication grooves 31 and the central linear lubrication groove 33.
When the lubricant is inserted into the left and right lubrication grooves 31 and the center lubrication groove 33, the lubricant is easily distributed over the entire gap between the case 1 and the pocket constituting portion 13.
Other points are the same as in the first example. Parts similar to those in the first example are denoted by the same reference numerals as those in the first example.

[Third example (see FIGS. 11 and 12)]
In the rotary valve of this example, the member provided with the lubrication groove is replaced with the case 1 in the first example, and the pocket constituting portion 13 is used.

  As shown in FIGS. 11 and 12, the pocket forming portion 13 has lubricating grooves 41 formed in the circumferential direction on the outer peripheral surfaces of the left and right end portions 13a. The left and right lubrication grooves 41 each go around the outer peripheral surface of the pocket forming portion 13 in the circumferential direction. Endless ring shape.

The left and right end portions 1b of the case 1 are each provided with an injection portion 42 for putting a lubricant into the lubricating groove 41 in the upper portion of the peripheral wall. The left and right injection parts 42 each form an injection passage from the outer peripheral surface of the peripheral wall of the case 1 to the inner peripheral surface of the peripheral wall. A normally closed valve similar to that in the first example is provided at the outer end of the injection passage. The inner end of the injection passage faces the lubricating groove 41 opened on the outer peripheral surface of the pocket constituting portion 13. When the injection device is injected by pressing the inlet of a lubricant injection device such as a grease gun against the normally closed valve, the normally closed valve opens and the lubricant is injected into the injection passage from the injection device. The lubricant is configured to enter the lubrication groove 41.
Other points are the same as in the first example. Parts similar to those in the first example are denoted by the same reference numerals as those in the first example.

[Modification]
The present invention is not limited to the above embodiment. The following modifications are exemplified.
1. In the above embodiment, the lubricating grooves 31, 33, and 41 are provided on one side of the case 1 and the pocket constituting portion 13, but are provided on both.
2. In the above embodiment, the left and right lubrication grooves 31 and 41 have an endless circular shape, but have a circular arc shape with ends.
3. In the above embodiment, the number of pockets 15 is one, but it is two or three. The two pockets are arranged at symmetrical positions with the axis of the pocket forming portion 13 in between. The three pockets are arranged at equal intervals around the axis of the pocket forming portion 13.

  The present invention can be used for controlling the flow of fluids such as sludge, sewage, roasted beans, powders and solid-liquid mixtures.

DESCRIPTION OF SYMBOLS 1 Case 1a Case central part 1b Case right and left edge part 2 Case entrance 3 Case exit 4 Supply pipe 5 Discharge pipe 11 Rotor 12 Rotor rotating shaft 13 Rotor pocket component, round shaft shaped body 13a Pocket component Central portion 13b Left and right end portions 14 of the pocket constituting portion Key 15 Pocket 21 End plate 22 Mounting portion 23 Shaft seal device 24 Ball bearing 25 End portion of the rotating shaft, projecting end portion, connecting portion 31, 33, 41 Lubricating groove 31 41 Left and right lubrication grooves 33 Central lubrication grooves 32, 42 Injection section

Claims (6)

In the rotary valve that controls the flow of fluid by the rotation of the rotor in the case,
The case has a cylindrical shape and the axial center is arranged in the left-right direction. The inlet and outlet are opened in the upper part and the lower part,
The rotor is provided with a pocket component on the rotating shaft, and the pocket component is fitted to the case.
When the rotor is rotated and fluid is supplied to the inlet of the case, the fluid flows into the pocket reaching the upper position of the rotor, and when the rotor further rotates, the fluid in the pocket flows out to the outlet of the case. A rotary valve configured,
The case is divided into three parts, a central part and left and right end parts, and an inlet and an outlet are arranged in the central part.
The pocket component is a round shaft-shaped body, divided into three parts, a central part and left and right end parts, and a pocket is opened on the outer peripheral surface of the central part.
This pocket component fits the central part with the pocket into the central part with the case entrance and the outlet, and the left and right end parts with the left and right end parts of the case,
The pocket component and the case face the outer peripheral surface and the entire inner peripheral surface at the left and right ends, and face the outer peripheral surface other than the pocket portion and the inner peripheral surface other than the inlet / outlet portion at the central portion. And
Lubricating grooves are provided along the circumferential direction on the inner peripheral surface of the left and right ends of the case or the outer peripheral surfaces of the left and right ends of the pocket component, and the lubricant is put in the lubricating grooves. Provide a lubrication groove to communicate,
A rotary valve characterized in that the gap between the inner peripheral surface of the case and the outer peripheral surface of the pocket component is filled with a lubricant and closed.   The rotary valve according to claim 1, wherein the number of pockets is one, two, or three. 3. The rotary valve according to claim 1, wherein the lubricating groove has an endless annular shape or a closed arc shape. 4. The lubricant, a rotary valve according to claim 1, 2 or 3, characterized in that in the flocculant to act as a lubricant. The rotary valve according to any one of claims 1 to 4 , wherein the fluid includes a flocculant or a flocculant added later. Fluid is rotary valve according to any one of claims 1 to 5, characterized in that in the sludge or sewage.

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