JP6974802B2 - Venturi scrubber device and its operation method - Google Patents

Description

The present invention relates to a Venturi scrubber device and its operating method, and more particularly to a Venturi scrubber device used to remove soot and dust contained in gas and its operating method.

A rod type scrubber rod that allows the processing gas containing soot dust and liquid particles to pass through the gaps between a plurality of round bar-shaped scrubber rods arranged at regular intervals, and removes the soot and dust contained in the processing gas due to the collision between the soot dust and the liquid particles. A Venturi scrubber device is known (see Patent Document 1).

In such a Venturi rubber device, the number of scrubber rods is increased or decreased according to the processing gas flow rate per unit time, so that the processing gas passes through the gap between the scrubber rods even under different conditions of the processing gas flow rate. The passing speed is kept constant so that a constant dust removal efficiency can be maintained.

Japanese Unexamined Patent Publication No. 49-81968

However, in the above-mentioned Venturi rubber device, in order to change the number of scrubber rods, it is necessary to temporarily stop the operation of the Venturi rubber device. Therefore, if the flow rate of the processing gas fluctuates while the Venturi rubber device is in operation, it is necessary to temporarily stop the device and increase or decrease the number of scrubber rods. As a result, the Venturi scrubber device has a problem that it cannot be continuously operated under working conditions in which the amount of processing gas fluctuates.

The present invention has been made in view of such a point, and keeps the speed of the processing gas passing between the scrubber rods constant even under working conditions in which the amount of the processing gas fluctuates without stopping the operation. It is an object of the present invention to provide a Venturi scrubber device capable of being capable of and a method of operating the same.

According to the present invention
Multiple columnar scrubber rods arranged approximately parallel at intervals,
Each of the scrubber rods is provided with a rotation mechanism for rotating each of the scrubber rods synchronously with respect to the central axis in the longitudinal direction.
The scrubber rod has an oval cross-sectional shape.
A Venturi scrubber device characterized by this is provided.

According to such a configuration, since the cross section of the scrubber rods arranged substantially parallel to each other at intervals has an oval shape, the scrubber rod rotates about the central axis in the longitudinal direction, so that the scrubber rods and the adjacent scrubber rods are formed. It is possible to change the interval of. Since the rotation of the scrubber rod is possible even during the operation of the Venturi scrubber device, the above configuration is a process of changing the gap with the scrubber rod and passing between the scrubber rods even during the operation of the Venturi scrubber device. It is possible to change the gas flow rate.

According to another preferred embodiment of the invention.
The rotation mechanism includes a link mechanism to which a tip end side portion of each scrubber rod is connected, and an actuator for operating the link mechanism.

According to such a configuration, since each scrubber rod is connected to the link mechanism operated by the actuator, each scrubber rod can be moved at the same time by the operation of the actuator.

According to another preferred embodiment of the invention.
The link mechanism includes an elongated rotary shaft bracket in which a central portion in the longitudinal direction is fixed to the tip end side of each scrubber rod, a first connecting rod for connecting one end side portion of each rotary shaft bracket, and each rotary shaft bracket. With a second connecting rod, which connects the other end side portion,
The first and second connecting rods swingably connect one end side portion and the other end side portion of the respective rotary shaft brackets.

According to such a configuration, each scrubber rod can be rotated synchronously with a simple configuration of a rotary shaft bracket and first and second connecting rods.

According to another preferred embodiment of the invention.
The actuator has an output shaft
The output shaft is fixed to the longitudinally central portion of the elongated actuator bracket.
One end side portion and the other end side portion of the actuator bracket are swingably connected to the first and second connecting rods.

With such a configuration, it is possible to transmit the movement of the actuator to the first and second connecting rods via the elongated actuator bracket.

According to another preferred embodiment of the invention.
The scrubber rod has a round bar-shaped rotating shaft and a scrubber collar having an oval contour shape detachably attached to the outer periphery of the rotating shaft.

With such a configuration, the scrubber collar that comes into contact with the processing gas can be replaced. Therefore, if it is necessary to change the material of the scrubber rod in order to process the treatment gas with different characteristics, only the scrubber collar, which is the outer part, can be replaced with one that corresponds to the characteristics of the scrubber. The cost required to change the rod is reduced.

According to another preferred embodiment of the invention.
Further, a differential pressure gauge for detecting the differential pressure between the upstream side and the downstream side of the scrubber rod is provided.

According to such a configuration, the Venturi rubber device can be operated so that the differential pressure between the upstream side and the downstream side of the scrubber rod becomes constant.

According to another preferred embodiment of the invention.
Further equipped with a control unit for controlling the operation of the Venturi scrubber device,
The control unit controls the operation of the actuator based on the detection result of the differential pressure gauge, and rotates each scrubber rod about the longitudinal axis through the link mechanism.

According to another aspect of the invention.
A method of operating a Venturi rubber device equipped with multiple scrubber rods.
The step of measuring the differential pressure between the upstream side and the downstream side of the scrubber rod,
The control unit comprises a step of rotating a step rod having an oval cross-sectional shape about a longitudinal axis so that the measured differential pressure becomes a preset control value.
Provided is a method of operating a Venturi scrubber device, characterized in that.

According to such a configuration, the scrubber rod is rotated around the center point of the cross section of the scrubber rod so that the differential pressure value between the upstream side and the downstream side of the scrubber rod becomes a preset control value. While operating the Venturi scrubber device, the scrubber rod spacing can be changed to control the flow rate of the processing gas.

According to another aspect of the invention.
The control unit rotates the scrubber rod by operating the actuator.

According to the present invention, a Venturi rubber device capable of maintaining a constant speed of processing gas passing between scrubber rods without stopping operation even under working conditions in which the amount of processing gas fluctuates, and its operation. The method is provided.

It is a vertical sectional view schematically showing the structure of the Venturi scrubber apparatus of the preferable aspect of this invention. It is a schematic plan view of the dust removal mechanism of a Venturi scrubber device. It is a side view from the right direction of FIG. It is a drawing which shows the scrubber collar constituting the scrubber rod of FIG. 1, (a) is a side view, (b) is a plan view, (c) is a front view. (A) to (e) are diagrams schematically showing the state of the gap between the scrubber rods when the scrubber rods are rotated by 90 ° by the actuator. As shown in FIG. 5, it is a figure which showed the relationship between the plane angle (the angle which a long axis forms with the vertical direction) of a scrubber rod when the scrubber rod is rotated, and the space (gap) of a scrubber rod. It is a schematic drawing which shows the flow of water in a Venturi scrubber device and wastewater treatment. It is a drawing which shows the detailed structure used in the wastewater treatment part of the Venturi scrubber apparatus of embodiment of this invention. It is a vertical sectional view similar to FIG. 1 which schematically shows the structure of the Venturi scrubber of another preferable embodiment.

Hereinafter, the configuration of the Venturi scrubber device 1 according to the preferred embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a vertical sectional view schematically showing the configuration of the Venturi scrubber device 1.

The Venturi scrubber device of the present embodiment is a device that removes soot and dust from the processing gas. The treatment gas treated by the Venturi scrubber device of the present embodiment may be of any type, but the Venturi scrubber of the present embodiment is particularly suitable when it is flammable or toxic. Specifically, it is suitable for treating gas generated in a gasification facility using biomass as a raw material.

As shown in FIG. 1, the venturi scrubber device 1 includes a prismatic housing 2. A processing gas introduction port 4 is provided on one side surface of the upper part of the housing 2, and a processing gas discharge port 6 is provided on the other side surface.

The internal space 10 of the housing 2 is divided into an introduction port side processing chamber 12 and a discharge side processing chamber 14 by a partition wall 8 extending downward from the center position in the width direction of the top plate 2a of the housing 2. The introduction port 4 is formed in the upper part of the introduction port side processing chamber 12, and the discharge port 6 is arranged in the upper part of the discharge side treatment chamber 14.

As shown in FIG. 1, the partition wall 8 is terminated without reaching the lower end of the internal space of the housing 2. As a result, the inlet-side processing chamber 12 and the discharge-side processing chamber 14 communicate with each other through the communication region 16 at the lower end of the internal space 10 of the housing 2.

With such a configuration, the processing gas introduced from the introduction port 4 as shown by the arrow A flows downward in the discharge side processing chamber 14 and passes through the communication region 16 from the lower part of the discharge side treatment chamber 14. It flows into the lower part of the discharge side treatment chamber 14, further flows upward through the discharge side treatment chamber 14, and is discharged to the outside from the discharge port 6 at the upper part of the discharge side treatment chamber 14 as shown by an arrow B. ..

Spray nozzles 18 are provided at the upper positions inside the introduction port side treatment chamber 12 and the discharge side treatment chamber 14, respectively, from the upper part of the introduction port side treatment chamber 12 and the discharge side treatment chamber 14 to the introduction port side. The structure is such that water is sprayed toward the treatment gas flowing in the treatment chamber 12 and the discharge side treatment chamber 14.

A drainage port 20 for draining water from the internal space 10 (introduction port side treatment chamber 12 and discharge side treatment chamber 14) is provided in the lower part of the housing 2, and the drainage port 20 is a water storage tank 22 for storing waste water. Communicate with.

A plurality of scrubber rods 24 for removing soot and dust from the processing gas are arranged at an intermediate position in the height direction of the introduction port side processing chamber 12. The plurality of scrubber rods 24 are installed in a state of blocking the flow of the processing gas flowing downward in the treatment chamber 12 on the introduction port side. The scrubber rod 24 constitutes a soot dust removing mechanism 26 that removes soot dust from the processing gas.

The scrubber rod 24 is connected to a motor 28, which is an actuator for rotating the scrubber rod 24. Further, a control unit 30 for controlling the operation of the motor (servo motor) 28 is connected to the control unit 30, and the difference in detecting the pressure difference between the introduction port side processing chamber 12 and the discharge side processing chamber 14 is connected to the control unit 30. The pressure gauge 31 is connected.

Next, the configuration of the soot dust removing mechanism 26 that removes soot dust from the processing gas by the scrubber rod 24 will be described in detail with reference to FIGS. 2 to 4. FIG. 2 is a schematic plan view of the soot removal mechanism 26, and FIG. 3 is a side view from the right direction of FIG. 4A and 4B are drawings showing scrubber collars constituting the scrubber rod 24, where FIG. 4A is a side view, FIG. 4B is a plan view, and FIG. 4C is a front view.

The scrubber rod 24 has an elongated cylindrical rotating shaft 32 and a scrubber collar 34 detachably attached to the outer peripheral portion on the tip side of the rotating shaft 32. In this embodiment, two scrubber collars 34 are attached in series to one rotating shaft 32. In the present invention, the scrubber collar attached to the rotating shaft 32 is not limited to two.

As shown in FIG. 2, in the soot removal mechanism 26, seven scrubber rods 24 are arranged substantially in parallel in the same plane at regular intervals. The tip of each scrubber rod 24 is rotatably attached to the scrubber rod plate 37 via a bearing 36. The scrubber rod plate 37 is a frame-shaped support plate attached so as to cross the introduction port side processing chamber 12 at the center position in the height direction of the introduction port side processing chamber 12.

The number of scrubber rods 24 included in the soot removal mechanism 26 can be appropriately changed depending on the size of the venturi rubber device 1.

The dust removing mechanism 26 includes a rotation mechanism that rotates (rotates) each scrubber rod 24 synchronously with respect to the central axis in the longitudinal direction. Each scrubber rod 24 has a base end side connected to a rotation mechanism, and the rotation mechanism has a link mechanism to which a base end side portion of each scrubber rod is connected.

Specifically, each scrubber rod 24 is supported by a bearing 40 whose base end is attached to a bearing plate 38, and the base end is fixed to a longitudinal center portion of a rotary shaft bracket 42 having an elongated shape. Further, as shown in FIG. 3, a first connecting rod 44 for connecting one end side portion of each rotating shaft bracket 42 and a second connecting rod connecting the other end side portion of each rotating shaft bracket 42. 46 is provided.

The rotary shaft brackets 42 are arranged in parallel with each other, and both ends thereof are rotatably (swingable) connected to the first and second connecting rods 44 and 46 about the connecting portion 42a. As a result, each rotation shaft bracket 42 is rotated (swinged) about the center position in the longitudinal direction as the first or second connecting rods 44, 46 move in the longitudinal direction.

One ends of the first and second connecting rods 44 and 46 are connected to an actuator bracket 48 having the same dimensions and shape as the rotary shaft bracket 42. Both ends of the actuator bracket 48 are rotatably (swingable) connected to the first and second connecting rods 44 and 46 about the connecting portion 48a, similarly to both ends of the rotary shaft bracket 42. ..

The actuator bracket 48 has an output shaft 52 of a motor 28, which is an actuator, fixed to the center in the longitudinal direction, and is configured to be rotatable around a central portion in the longitudinal direction by the motor 28.

In such a configuration, when the output shaft 52 of the motor 28 rotates in the direction indicated by the arrow C due to the rotation of the motor 28, the actuator bracket 48 in which the output shaft 52 is fixed at the center position in the longitudinal direction also Rotate in the direction indicated by the arrow C. Along with this rotation, the first connecting rod 44 translates in the direction indicated by the arrow D, and the second connecting rod 46 translates in the direction indicated by the arrow E. Then, each rotation shaft bracket 42 whose both ends are relatively rotatably connected to the first connection rod 44 and the second connection rod 46 rotates in synchronization with the direction indicated by the arrow F, and each rotation shaft. All scrubber rods 24 (rotating shafts 32) whose tips are fixed at the center of the bracket 42 in the longitudinal direction also rotate (rotate).

Such a mechanism that enables all the scrubber rods 24 to rotate in the same direction in synchronization is referred to as a link mechanism, and in the present embodiment, the rotary shaft bracket 42, the first and second connecting rods 44 , 46, the actuator bracket 48, and the like constitute a link mechanism. However, the present invention is not limited to this, and another form can be adopted as long as the scrubber rod 24 moves synchronously.

The scrubber collar 34 has an elliptical (oval) column shape as shown in FIG. 4A, and has an opening 34a extending along the central axis in the longitudinal direction. The opening 34a has a dimensional shape that allows the rotating shaft 32 to be fitted and inserted. The scrubber collar 34 further has a screw hole 34b in the side wall portion for communicating the opening 34a to the outside. With such a configuration, the scrubber collar 34 can be detachably fixed to the rotary shaft 32 by screwing a bolt from the outside into the screw hole 34b with the rotary shaft 32 inserted through the opening 34a. ..

As the material of the material constituting the scrubber collar 34, a different material can be selected according to the characteristics of the processing gas and the like. When the effect of preventing wear due to soot and dust in the processing gas is required, a rigid body such as metal is used, and when the effect of preventing corrosion due to corrosive gas is required, a corrosion resistant member such as stainless steel is used. Used. Further, when the effect of preventing the adhesion of soot and dust in the treated gas is required, a fluororesin is used.

Next, the arrangement of the scrubber rod 24 when the scrubber rod 24 is rotated in the Venturi rubber device of the present embodiment will be described. FIGS. 5A to 5E are diagrams schematically showing the state of the gap between the scrubber rods 24 when the scrubber rods are rotated by 90 ° by the motor 28.

As described above, the link mechanism is operated by the motor 28 to rotate (rotate) each scrubber rod in synchronization, and the scrubber rods can be arbitrarily arranged at the rotation position. FIG. 5A shows a state in which the scrubber rod is arranged at a rotational position (angle position) in which the long axis M of the ellipse constituting the cross section is oriented in the vertical direction by the operation of the motor. In this state, the gap between adjacent scrubber rods is widest.

From the arrangement of FIG. 5A, when the scrubber rod 24 is rotated (rotated) in the clockwise direction by the motor 28 as shown by the arrow G, the flat cross-sectional shape of the scrubber rod 24 (scrubber collar 34) is formed. As shown in FIGS. 5 (b) to 5 (d), the distance between the scrubber rods gradually decreases. The distance between the scrubber rods 24 is the narrowest at the rotation position (angle position) of FIG. 5 (e) in which the long axis M of the ellipse constituting the cross section of the scrubber rod 24 is oriented in the horizontal direction. As described above, in the present embodiment, by rotating the scrubber rod 24, the width of the gap between the scrubber rods 24 can be changed, and the flow rate of the processing gas passing through the gap can be adjusted.

FIG. 6 is a diagram showing the relationship between the plane angle of the scrubber rod (the angle formed by the major axis in the vertical direction) and the scrubber rod spacing (gap) when the scrubber rod is rotated as shown in FIG. Yes, it continuously represents the distance between adjacent scrubber rods when the plane angle of the scrubber rods changes from 0 ° to 90 °. By changing the cross-sectional shape of the scrubber collar used for the scrubber rod, it is possible to change the numerical value in the gap between the scrubber rods and the profile of the change with respect to the rotation.

Next, a method for treating the treated gas in the Venturi scrubber device 1 of the present embodiment will be described with reference to FIG.

As described above, the processing gas introduced from the introduction port 4 as shown by the arrow A flows downward in the discharge side processing chamber 14.

Water is sprayed from the spray nozzle 18 to the processing gas flowing downward in the discharge side processing chamber 14, and the processing gas in a high temperature state is cooled. Next, the processing gas is passed through the gap between the adjacent scrubber rods 24 of the dust removing mechanism 26 provided in the central portion of the housing 2. During the passage, the soot dust contained in the processing gas and the water particles sprayed from the spray nozzle 18 collide with each other, and the soot dust in the gas is taken into the water particles. Then, the water particles that have taken in the soot and dust become water droplets, fall into the water tank 22, and are collected. By passing through the soot dust removing mechanism 26 in this way, the processing gas is purified.

The processing gas purified by the soot removal mechanism 26 provided with the scrubber rod 24 flows from the lower part of the discharge side treatment chamber 14 through the communication region 16 to the lower part of the discharge side treatment chamber 14, and further flows into the lower part of the discharge side treatment chamber 14. Is discharged upward from the discharge port 6 at the upper part of the discharge side treatment chamber 14 as indicated by an arrow B.
The processing gas is also cooled by the water from the spray nozzle 18 when flowing upward through the discharge side processing chamber 14.

The gap between the scrubber rods 24 of the soot dust removing mechanism 26 can be changed by rotating (rotating) the scrubber rods 24 according to the fluctuation of the processing gas amount. The angular position of the scrubber rod 24 is controlled by the control unit 30 so that the numerical value of the differential pressure gauge 31 that detects the differential pressure between the upstream side and the downstream side of the scrubber rod 24 becomes a preset control value.

The differential pressure gauge 31 and the motor 28 that drives the scrubber rod 24 by the link mechanism are connected to the control unit 30 that stores the control values set in advance. This preset control value is a numerical value set by the administrator as an optimum value for the differential pressure between the upstream side and the downstream side of the scrubber rod 24.

The control unit 30 compares the control value with the actually measured value of the differential pressure value, and when the actually measured value is high, the scrubber rod 24 is set by the motor 28 and the link mechanism so as to widen the gap between the scrubber rod 24. Rotate. Further, when the measured value is small, the control unit 30 rotates the scrubber rod 24 by the motor 28 and the link mechanism so as to narrow the gap between the scrubber rods 24.

Next, the wastewater containing soot and dust contained in the treated gas in the venturi scrubber device 1 will be described with reference to FIGS. 7 and 8.

FIG. 7 is a schematic drawing showing a Venturi scrubber device and water flow in wastewater treatment. The Venturi scrubber device 100 of FIG. 7 has a configuration in which two Venturi scrubber devices 1 of the above embodiment are connected in series. Therefore, two soot and dust removing mechanisms 26 are provided.

In the configuration of FIG. 7, the elements corresponding to the configuration of the above embodiment are designated by the same reference numerals as those of the above embodiment.

The water sprayed from the spray nozzle 18 of the Venturi scrubber device 100 is stored in the water tank 22 through the drain port 20. The wastewater collected in the water storage tank 22 is separated into a supernatant liquid and a sedimentation portion liquid by natural sedimentation in the water storage tank 22.

A part of the supernatant liquid of the wastewater is sent to the cooling tower 104 by the liquid feed pump 102, cooled in the cooling tower 104, and then returned to the water storage tank 22. The other portion of the supernatant liquid is supplied to the spray nozzle 18 by another liquid feeding pump 106 and reused as water for spraying.

The sedimentation liquid in the lower part of the water storage tank 22 is supplied to the wastewater treatment unit 110 by a dedicated liquid feed pump 108, treated by the wastewater treatment unit 110, and then discharged to the outside. Further, the water storage tank 22 is configured so that clean water 112 is added so that the water storage level becomes constant.

FIG. 8 is a drawing showing a detailed configuration of the wastewater treatment unit 110. For the wastewater treatment unit 110, a precoat type vacuum filtration device 114, which is most suitable for treating wastewater from exhaust gas treatment, is used.

In the precoat type vacuum filtration device 114, in order to form a precoat layer acting as a filter on the filter drum 116 in advance, a liquid in which a precoat material (for example, diatomaceous earth) is dispersed in water in a precoat tank 118 is precoated. It is supplied to the processing tank 120 of the vacuum filtration device by a pump, and the inside of the filter drum 116 is evacuated by the vacuum pump 122 to form a precoat layer on the filter drum 116.

The waste liquid is supplied from the water storage tank 22 to the waste liquid storage tank 124, is made into a state in which flocs are easily formed by the chemical liquid treatment, and then is supplied to the treatment tank 120 of the precoat type vacuum filtration device by a pump. After that, the inside of the filter drum 116 is depressurized by the vacuum pump 122, and the precoat layer formed on the filter drum 116 captures the fine particles in the waste liquid. The fine particles in the captured effluent form a cake layer.

At the same time, the scraper 126 is moved toward the cake layer at a predetermined speed to scrape off the cake layer. At this time, since the surface layer of the precoat layer is also scraped off together with the cake layer, a new surface of the precoat layer is exposed, and the solid-liquid separation operation can be continuously performed.

Next, the Venturi scrubber device 200 of another preferred embodiment of the present invention will be described. FIG. 9 is a vertical cross-sectional view similar to FIG. 1, which schematically shows the configuration of the Venturi scrubber device 200 of another preferred embodiment.

The Venturi scrubber device 200 of another preferred embodiment is characterized in that it includes a pre-dust removal mechanism 202. The pre-dust removal mechanism 202 is effective when the processing gas is highly contaminated. This is because when a highly contaminated processing gas is treated with a normal rod scrubber, the gap between the rod scrubbers may be blocked.

As the pre-dust removal mechanism 202, an S-shaped impeller as shown in FIG. 9 is used. In the Venturi scrubber device 200, water is stored up to a certain level in the lower part of the device. An S-shaped impeller is provided between the height position of the water surface and the vertical partition wall of the Venturi scrubber device (FIG. 9).

The S-shaped impeller comprises two semi-cylindrical members. The two semi-cylindrical members are arranged so that the openings extending in the radial direction face each other and are offset from each other in the radial direction. As a result, in the S-shaped impeller, the space between the two semi-cylindrical members becomes an S-shaped flow path.

The dust removal principle of the S-shaped impeller is that the processing gas flows from the top to the bottom inside the housing of the Venturi scrubber device, reverses on the water surface at the bottom of the Venturi scrubber device, and passes through the inside of the S-shaped impeller. Bubbles are generated in the lower part where the water and the S-shaped impeller are in contact. This bubble exhibits the action of removing coarse soot and dust in the processing gas. Then, by using this S-shaped impeller, the possibility that the gap of the rod scrubber is closed is reduced.

Not limited to the above-described embodiment of the present invention, various modifications and modifications can be made within the scope of the technical idea described in the claims.

In the Venturi rubber device of the above embodiment, the radial cross-sectional shape of the scrubber rod is elliptical, but it may be another oval shape or a flat eccentric shape.

In the above embodiment, the motor is used as the actuator, but other actuators such as a hydraulic cylinder, a pneumatic cylinder, an electric cylinder and the like may be used. Since the electric cylinder and the servomotor do not require piping or a hydraulic pump, they have an advantage that the structure of the actuator is simplified.

1: Venturi scrubber device 2: Housing 4: introduction port 6: discharge port 8: partition wall 12: introduction port side treatment room 14: discharge side treatment room 16: communication area 18: spray nozzle 20: drain port 22: water storage tank 24 : Scrubber rod 26: Dust removal mechanism 28: Motor (actuator)
30: Control unit 32: Differential pressure gauge 34: Scrubber collar 36: Bearing 38: Bearing plate 40: Bearing 42: Rotating shaft bracket 44: First connecting rod 46: Second connecting rod 48: Actuator bracket 50: Output shaft

Claims (9)

Multiple columnar scrubber rods arranged approximately parallel at intervals,
Each of the scrubber rods is provided with a rotation mechanism for rotating each of the scrubber rods synchronously with respect to the central axis in the longitudinal direction.
The scrubber rod has an oval cross-sectional shape and has an oval cross-sectional shape.
The rotation mechanism includes a link mechanism to which a base end side portion of each scrubber rod is connected, and an actuator for operating the link mechanism.
The link mechanism includes an elongated rotary shaft bracket in which a central portion in the longitudinal direction is fixed to the base end side of each scrubber rod, a first connecting rod for connecting one end side portion of each rotary shaft bracket, and each rotary shaft bracket. With a second connecting rod, which connects the other end of the
The first and second connecting rods swingably connect one end side portion and the other end side portion of each rotation shaft bracket.
Venturi scrubber device featuring that. Multiple columnar scrubber rods arranged approximately parallel at intervals,
Each of the scrubber rods is provided with a rotation mechanism for rotating each of the scrubber rods synchronously with respect to the central axis in the longitudinal direction.
The scrubber rod has an oval cross-sectional shape and has an oval cross-sectional shape.
The scrubber rod has a round bar-shaped rotating shaft and a scrubber collar having an oval contour shape detachably attached to the outer periphery of the rotating shaft.
Venturi scrubber device featuring that. The rotation mechanism includes a link mechanism to which a base end side portion of each scrubber rod is connected, and an actuator for operating the link mechanism.
The Venturi scrubber device according to claim 2. The link mechanism includes an elongated rotary shaft bracket in which a central portion in the longitudinal direction is fixed to the base end side of each scrubber rod, a first connecting rod for connecting one end side portion of each rotary shaft bracket, and each rotary shaft bracket. With a second connecting rod, which connects the other end of the
The first and second connecting rods swingably connect one end side portion and the other end side portion of each rotation shaft bracket.
The Venturi scrubber device according to claim 3. The actuator has an output shaft
The output shaft is fixed to the longitudinally central portion of the elongated actuator bracket.
In the actuator bracket, one end side portion and the other end side portion are swingably connected to the first and second connecting rods.
The Venturi scrubber device according to claim 1 or 4. Further, a differential pressure gauge for detecting the differential pressure between the upstream side and the downstream side of the scrubber rod is provided.
The Venturi scrubber device according to any one of claims 1 to 4. Further equipped with a control unit for controlling the operation of the Venturi scrubber device,
The control unit controls the operation of the actuator based on the detection result of the differential pressure gauge, and rotates each scrubber rod about the longitudinal axis through the link mechanism.
The Venturi scrubber device according to claim 6. Venturi scrubber device
Multiple columnar scrubber rods arranged approximately parallel at intervals,
A rotation mechanism that rotates each of the scrubber rods synchronously with respect to the central axis in the longitudinal direction,
A control unit that controls the operation of the Venturi scrubber device is provided.
The scrubber rod has an oval cross-sectional shape and has an oval cross-sectional shape.
The rotation mechanism includes a link mechanism to which a base end side portion of each scrubber rod is connected, and an actuator for operating the link mechanism.
The link mechanism includes an elongated rotary shaft bracket in which a central portion in the longitudinal direction is fixed to the base end side of each scrubber rod, a first connecting rod for connecting one end side portion of each rotary shaft bracket, and each rotary shaft bracket. With a second connecting rod, which connects the other end of the
A method of operating a Venturi scrubber device in which the first and second connecting rods swingably connect one end side portion and the other end side portion of the respective rotary shaft brackets.
The step of measuring the differential pressure between the upstream side and the downstream side of the scrubber rod,
It is provided with a step of rotating each of the scrubber rods synchronously about the longitudinal axis under the control of the control unit so that the measured differential pressure becomes a preset control value. ,
A method of operating a Venturi scrubber device, which is characterized by that. Venturi scrubber device,
Multiple columnar scrubber rods arranged approximately parallel at intervals,
A rotation mechanism that rotates each of the scrubber rods synchronously with respect to the central axis in the longitudinal direction,
A control unit that controls the operation of the Venturi scrubber device is provided.
The scrubber rod has an oval cross-sectional shape and has an oval cross-sectional shape.
The scrubber rod is a method of operating a Venturi rubber device having a round bar-shaped rotating shaft and a scrubber collar having an oval contour shape detachably attached to the outer periphery of the rotating shaft.
The step of measuring the differential pressure between the upstream side and the downstream side of the scrubber rod,
It is provided with a step of rotating each of the scrubber rods synchronously about the longitudinal axis under the control of the control unit so that the measured differential pressure becomes a preset control value. ,
A method of operating a Venturi scrubber device, which is characterized by that.

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