JP2006297186A - Garbage treatment apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a garbage treatment apparatus capable of effectively pulverizing even fibrous garbage and garbage which easily floats on a water surface. <P>SOLUTION: The garbage treatment apparatus (1) for pulverizing the garbage together with washing water comprises: a garbage treating chamber (2) where a garbage feeding port (2a) is formed at an upper part; a rotary plate (4) arranged in it; a driving means (6) for rotationally driving it; upper side pulverizing means (8, 10) arranged on the upper side of the rotary plate for pulverizing the garbage fed onto the rotary plate; a discharge part (18) provided with a discharge port formed on the lower side of the rotary plate so as to discharge the garbage and the washing water; water level control means (16, 22, 24) for controlling a water level inside the garbage treating chamber so that the prescribed amount of the garbage and the washing water stay inside the garbage treating chamber; an agitation means (12) for agitating the garbage and the washing water staying on the lower side of the rotary plate inside the garbage treating chamber; and a lower side pulverizing means (14) for pulverizing the garbage staying inside the garbage treating chamber. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a soot processing apparatus, and more particularly, to a soot processing apparatus that pulverizes and discharges the input soot.

  Japanese Unexamined Patent Publication No. 2000-84430 (Patent Document 1) describes a pulverizing apparatus. This pulverization apparatus is configured to pulverize a crushed material from a pulverized material inflow chamber, a pulverized chamber that pulverizes the processed material using a fixed blade and a rotary blade, a crushed material and a crushed material inflow chamber into which water flows. A drainage channel for discharging, and a circulation channel for communicating the pulverization chamber and the pulverized material inflow chamber are provided. The soot and water pulverized in the pulverizing chamber flow into the pulverized material inflow chamber, and return to the pulverizing chamber through the circulation path from the pulverized material inflow chamber. The soot returned to the pulverization chamber is pulverized again by the fixed blade and the rotary blade and flows into the pulverized material inflow chamber. Accordingly, the soot is pulverized many times by the fixed blade and the rotary blade while circulating through the pulverization chamber and the pulverized material inflow chamber, so that the soot is pulverized more finely.

JP 2000-84430 A

  However, in the pulverization processing apparatus described in Japanese Patent Application Laid-Open No. 2000-84430, only the pulverization with the fixed blade and the rotary blade is repeated in the pulverization chamber. There is a problem that it is difficult. Further, in the pulverizing apparatus described in JP-A-2000-84430, soot that has been pulverized in the pulverizing chamber and falls into the pulverized material inflow chamber circulates between these chambers, and therefore floats on the water surface in the pulverizing chamber. However, there is a problem that the ridges that do not pass through the fixed blade and the rotary blade cannot be crushed. In particular, fibrous soot is difficult to finely pulverize by pulverization by grinding, and also has a problem that it remains easily without being pulverized because it tends to float on the water surface. Furthermore, when the soot that could not be finely pulverized is discharged from the pulverization apparatus, there is a problem that the drainage pipe is clogged.

  Accordingly, an object of the present invention is to provide a cocoon treatment apparatus that can effectively pulverize fibrous cocoons and cocoons that easily float on the water surface.

  In order to solve the above-described problems, the present invention is a soot processing device that pulverizes soot together with cleaning water, a soot processing chamber in which a soot inlet for pouring the soot is formed upward, and the soot processing chamber A rotating plate disposed therein, a driving means for rotationally driving the rotating plate, and an upper crushing means disposed above the lower surface of the rotating plate and crushing the soot put on the rotating plate from the soot slot. A discharge portion having a discharge port formed below the rotating plate of the dredging device, and the dredging and washing water, The water level control means for controlling the water level in the soot treatment chamber and a lower plate than the rotating plate of the soot treatment chamber so as to stay in a predetermined amount in the soot treatment chamber and stay in the soot treatment chamber by being rotated. Stirring hand that stirs the candy and washing water When disposed below the rotating plate of the garbage processing chamber is characterized by having a lower pulverizing means for pulverizing the garbage that staying below the rotary plate of the garbage processing chamber, the.

  In the present invention configured as described above, the soot introduced into the soot processing chamber via the soot entry port falls on the rotating plate. When the rotary plate is driven to rotate by the driving means, the soot on the rotary plate is crushed by the upper crushing means, and falls below the rotary plate together with the supplied cleaning water. A predetermined amount of the soot and washing water that have fallen under the rotating plate are retained in the soot treatment chamber by the water level control means. The soot and washing water staying in the soot processing chamber are stirred by the stirring means, and the lower grinding means further grinds the staying soot. The crushed soot and washing water stay in the soot processing chamber and are then discharged through the discharge port.

  According to the present invention configured as above, the soot and washing water are pulverized while staying in the soot processing chamber, so that the soot can be pulverized more finely. Further, according to the present invention configured as described above, the soot and washing water staying in the soot treatment chamber are pulverized while being stirred by the stirring means, so that the soot that tends to float on the water surface can be submerged in the washing water. This can be crushed effectively. Thereby, it is possible to sufficiently finely pulverize the soot that is difficult to pulverize, such as a fibrous soot, and prevent clogging of the drain pipe and the like. Furthermore, according to the present invention configured as described above, the lower crushing means crushes the soot in the washing water staying in the soot processing chamber, so that noise generated during the crushing can be reduced.

In the present invention, preferably, the stirring means is attached so as to extend downward from the lower surface of the rotating plate.
According to the present invention configured as described above, since the stirring means is rotated together with the rotating plate, soot and washing water staying in the soot treatment chamber can be removed without providing any special means for driving the stirring means. Can be stirred.

  In the present invention, preferably, the lower crushing means is constituted by a plurality of fixing protrusions arranged in a comb-teeth shape extending upward from the bottom surface of the soot processing chamber, and the stirring means is in a direction substantially orthogonal to the rotating plate. And a plurality of moving protrusions arranged so as to pass between the fixed protrusions.

  According to the present invention configured as described above, since the stirring means is rotated together with the rotating plate, soot and washing water staying in the soot treatment chamber can be removed without providing any special means for driving the stirring means. Can be stirred. Further, according to the present invention configured as described above, the cocoon in the cocoon treatment chamber is crushed so as to be sheared between the fixed protrusion and the moving protrusion, and thus particularly the fibrous cocoon is crushed effectively. be able to.

In the present invention, preferably, the driving means includes an output shaft attached to the rotating plate and extending upward from the bottom surface of the soot processing chamber, and the lower crushing means is attached to extend radially from the output shaft. .
According to the present invention configured as described above, the lower crushing means is rotated together with the output shaft that drives the rotating plate, so that it rotates without providing any special means for driving the lower crushing means. Soot remaining in the soot processing chamber can be crushed by the lower crushing means.

In the present invention, preferably, the driving means includes an output shaft attached to the rotating plate and extending upward from the bottom surface of the soot processing chamber, and the stirring means and the lower crushing means are attached so as to extend radially from the output shaft. It has been.
According to the present invention configured as described above, since the stirring means and the lower crushing means are rotated together with the output shaft that drives the rotating plate, the stirring means is rotated without providing a special driving means, The soot staying in the processing chamber can be pulverized by the rotating lower pulverizing means.

In the present invention, it is preferable that the water level control means rotate the stirring means in a direction that prevents the flow to the discharge port of the soot and the washing water in the soot treatment chamber or in a direction that promotes the flow, or The water level is controlled by stopping the rotation of the means.
According to the present invention configured as described above, since the water level is controlled by the rotation direction of the stirring means, etc., the soot and the washing water can be supplied to the soot treatment chamber without providing a special means for opening and closing the discharge port. The water level in the soot treatment chamber can be controlled.

In the present invention, preferably, the water level control means includes an on-off valve that opens and closes the discharge port, and a water supply amount control means that controls the amount of cleaning water supplied into the soot processing chamber by the water supply means.
According to the present invention configured as described above, the water level in the soot processing chamber is controlled by the on-off valve that opens and closes the discharge port and the water supply amount control means that controls the supply amount of the cleaning water, so that the rotation of the stirring means The water level can be controlled independently of the flow rate.

In the present invention, preferably, the water level control means has a water level sensor for detecting the water level in the dredging treatment chamber, and controls the water level based on the detection result of the water level sensor.
According to the present invention configured as described above, the water level in the soot processing chamber is detected by the water level sensor, and the water level is controlled based on the detected water level, so that the water level in the soot processing chamber can be accurately set.

  According to the soot treating apparatus of the present invention, fibrous soot and soot that tends to float on the water surface can be effectively pulverized.

Next, preferred embodiments of the present invention will be described with reference to the accompanying drawings.
First, with reference to FIG. 1 thru | or FIG. 5, the wrinkle processing apparatus by 1st Embodiment of this invention is demonstrated. FIG. 1 is a cross-sectional view showing the entire wrinkle processing apparatus according to the first embodiment of the present invention. FIG. 2 is a perspective view showing the upper surface side of the rotating plate used in the wrinkle processing apparatus of this embodiment, and FIG. 3 is a perspective view showing the lower surface side. FIG. 4 is a cross-sectional perspective view showing the lower part of the soot treating chamber of the soot treating apparatus along the line IV-IV in FIG. FIG. 5 is a cross-sectional view showing the action of the flapper valve provided at the discharge port of the soot processing chamber.

  As shown in FIG. 1, the slag processing apparatus 1 according to the first embodiment of the present invention includes a slag processing chamber 2 disposed in the lower part of the kitchen sink S, and an intermediate part of the slag processing chamber 2 in a horizontal direction. It has a disc-shaped rotating plate 4 and a motor 6 which is arranged below the soot processing chamber 2 and is a driving means for driving the rotating plate 4 to rotate. In addition, two swing hammers 8 are attached to the upper surface of the rotating plate 4, and two blades 12 that are stirring means are attached to the lower surface of the rotating plate 4. A fixed blade 10 is attached to a portion of the inner wall of the soot processing chamber 2 that faces the swing hammer 8. In the present embodiment, the swing hammer 8 and the fixed blade 10 constitute upper crushing means.

  Further, a cutting blade 14 as a lower crushing means is attached to an intermediate portion of the output shaft 6 a of the motor 6. In addition, four circumferential projections 15 are formed on the lower inner wall of the soot treatment chamber 2 to effectively agitate the cleaning water in the soot treatment chamber 2. Further, at the lower part of the soot treatment chamber 2, there is provided a discharge part 18 in which a discharge port 18 a through which the washing water in the soot treatment chamber 2 flows out is formed. Moreover, the dredging device 1 according to the present embodiment includes a water supply device 16 that is a water supply amount control means for supplying a predetermined amount of cleaning water into the dredging treatment chamber 2, and a flapper that is an on-off valve that opens and closes the discharge port 18a. It has the valve 20 and the pressure gauge 22 which is a water level sensor which detects the water level in the soot processing chamber 2. FIG. Furthermore, the soot treating apparatus 1 has a controller 24 that controls the water level in the soot treating chamber 2 based on the detection result of the pressure gauge 22. In the present embodiment, the water supply device 16, the flapper valve 20, the pressure gauge 22, and the controller 24 constitute a water level control means.

  The dredging treatment chamber 2 includes an input port 2a that opens upward, and the input port 2a is disposed so as to communicate with a drain port S1 provided on the bottom surface of the sink S. Moreover, the soot processing chamber 2 is substantially cylindrical, and is formed so that the inner diameter is small at the top inlet 2a and the inner diameter is increased downward from the vicinity of the intermediate portion where the rotating plate 4 is disposed. Further, a spout 2b is formed at a position above the rotating plate 4 in the dredging chamber 2, and the wash water supplied from the water supply device 16 is discharged from the spout 2b. Further, the output shaft 6a of the motor 6 extends vertically upward from the center of the bottom surface of the soot processing chamber 2, and the rotating plate 4 is attached to the upper end thereof.

  As shown in FIGS. 2 and 3, the rotating plate 4 is a circular metal plate, the center of which is attached to the output shaft 6 a of the motor 6, and is driven to rotate inside the soot processing chamber 2. In addition, twelve circular holes 4 a for allowing washing water to flow mainly under the rotating plate 4 are opened at the peripheral edge of the rotating plate 4.

  Further, as shown in FIG. 2, two swing hammers 8 are rotatably attached to the upper surface of the rotating plate 4. Each swing hammer 8 is attached to a position symmetrical with respect to the center of the rotating plate 4 so as to be rotatable about the rotating shaft 8a. The swing hammer 8 has a generally rectangular shape, and is formed so that the proximal end portion supported by the rotating shaft 8a is thin and the distal end portion is thick. Further, the swing hammer 8 is formed in an arc shape so that a tip end portion thereof follows the peripheral edge of the rotating plate 4. The swing hammer 8 is positioned so that the tip of the swing hammer 8 is positioned slightly inside the peripheral edge of the rotating plate 4 when it is directed in the radial direction of the rotating plate 4.

  Further, as shown in FIG. 1, a fixed blade 10 is attached to a position of the inner peripheral wall of the scissor treatment chamber 2 facing the swing hammer 8. The fixed blade 10 is formed by arranging a plurality of rectangular metal blades at equal intervals along the circumference of the inner wall of the scissor treatment chamber 2. The soot introduced into the soot processing chamber 2 is sandwiched between the edges (not shown) of each metal blade of the fixed blade 10 and the swing hammer 8 and crushed so as to be ground.

  Further, as shown in FIG. 3, two blades 12 for stirring the cleaning water and the soot in the soot processing chamber 2 are attached to the lower surface of the rotating plate 4. Each blade 12 has a generally rectangular plate shape, and is attached to a position symmetrical to the center of the rotating plate 4 so as to extend vertically downward from the rotating plate 4. Further, each blade 12 is directed to be inclined at a predetermined angle with respect to the radial direction of the rotating plate 4. Further, the swing hammer 8 on the upper surface of the rotating plate 4 and the blades 12 on the lower surface of the rotating plate 4 are alternately arranged on the circumference of the rotating plate 4 with an interval of 90 °.

  Next, as shown in FIG. 4, the cutting blade 14 as the lower crushing means is attached to an intermediate portion of the output shaft 6 a of the motor 6 that extends upward from the bottom surface of the soot processing chamber 2. The two cutting blades 14 are arranged at positions symmetrical with respect to the output shaft 6a, that is, so as to extend in a straight line on both sides of the output shaft 6a. Each cutting blade 14 has an elongated thin plate shape with a sharp tip, and is formed so that the peripheral edge portion is thin. Further, each cutting blade 14 is bent so that the tip thereof faces obliquely upward.

  Further, four circumferential protrusions 15 are formed at the lower inner periphery of the soot treatment chamber 2. The circumferential protrusions 15 have a semi-cylindrical shape, and are arranged on the inner peripheral wall of the soot processing chamber 2 at intervals of 90 °. Each circumferential protrusion 15 extends from the bottom surface of the soot processing chamber 2 to a position slightly below the lower end of the blade 12 on the lower surface of the rotating plate 4.

  In addition, a discharge part 18 is formed in the lower part of the soot treatment chamber 2. The discharge portion 18 is a cylindrical pipe extending in the radial direction of the soot treatment chamber 2 and communicates with a discharge port 18 a formed on the inner wall of the lower side surface of the soot treatment chamber 2. When the flapper valve 20 is opened, the crushed soot and washing water in the soot treatment chamber 2 are discharged downstream through the discharge unit 18. Further, a pressure gauge 22 is attached to the lower inner wall surface of the discharge portion 18 so that the water level in the soot treatment chamber 2 can be detected.

  Next, as shown in FIG. 5, the flapper valve 20 is provided at the outlet end of the discharge portion 18. The flapper valve 20 is configured to be rotatable about a support shaft 20a, and when the flapper valve 20 is closed as shown in FIG. 5A, it prevents the washing water and soot from flowing out in the soot treatment chamber 2. However, when it is opened as shown in FIG. 5 (b), the washing water and the soot are allowed to flow downstream.

  In addition, as shown in FIG. 1, a water supply device 16 is provided so as to supply cleaning water into the soot treatment chamber 2. The water supply device 16 includes: a water supply valve 16a that switches between supply and stop of tap water into the dredging treatment chamber 2, a vacuum breaker 16b that prevents backflow of cleaning water in the dredge treatment chamber 2 to the water supply, and a vacuum breaker 16b. And a water supply line 16c for supplying cleaning water to the soot treatment chamber 2. The vacuum breaker 16b is provided on the downstream side of the water supply valve 16a, and is configured to prevent the sewage from flowing backward from the dredging chamber 2 to the water when the upstream side of the water becomes negative pressure. . The water supply pipe line 16c is connected so as to guide the washing water from the vacuum breaker 16b to the dredging treatment chamber 2, and the washing water supplied from the water supply pipe line 16c passes through the water discharge port 2b above the rotating plate 4. It is configured to flow into the processing chamber 2.

  Further, the controller 24 is configured to output control signals to the water supply valve 16a and the flapper valve 20 based on the detection signal from the pressure gauge 22, and to open and close them. The controller 24 is configured to send a control signal to the motor 6 to start and stop it. Specifically, the controller 24 includes a microprocessor, a memory, and a program (not shown above) that operates them.

  Next, the operation of the scissor processing device 1 according to the first embodiment of the present invention will be described. First, the user throws the soot to be crushed into the soot processing chamber 2 through the entrance 2a. The introduced soot falls on the rotating plate 4 disposed in the soot processing chamber 2. Next, the user closes the lid of the drain S1 of the sink S and operates an operation switch (not shown) of the soot treating apparatus 1. When the dredging device 1 is activated, the controller 24 closes the opened flapper valve 20, activates the motor 6, and opens the water supply valve 16a. When the water supply valve 16a is opened, tap water flows into the soot treatment chamber 2 through the water supply valve 16a, the vacuum breaker 16b, and the water supply pipe line 16c. When the motor 6 is actuated, the rotating plate 4 attached to the output shaft 6a is rotated, and the wrinkles on the rotating plate 4 are moved to the peripheral portion of the rotating plate 4 by centrifugal force. In the present embodiment, the rotating plate 4 is rotationally driven at a rotational speed of about 2000 revolutions per minute. Preferably, the rotational speed of the rotating plate 4 is 1500 to 3000 revolutions per minute.

  The scissors that have moved to the peripheral edge of the rotating plate 4 are sandwiched between the swing hammer 8 and the fixed blade 10 and crushed so as to be ground. Further, since the tip of the swing hammer 8 is formed to be large, the swing hammer 8 receives a force so as to be directed in the radial direction by the centrifugal force generated by the rotation of the rotating plate 4. This force acts to narrow the distance between the tip of the swing hammer 8 and the fixed blade 10, and the wrinkles between the swing hammer 8 and the fixed blade 10 are effectively crushed. The soot crushed by the swing hammer 8 and the fixed blade 10 passes between the peripheral edge of the rotating plate 4 and the inner wall of the soot treatment chamber 2, and together with the washing water flowing into the soot treatment chamber 2 from the water supply pipe 16 c, the rotating plate 4 drops below.

  Since the flapper valve 20 is closed, the soot and the washing water dropped below the rotating plate 4 stay in the lower part of the soot treatment chamber 2 and are stirred by the two blades 12. In addition, since the blade | wing 12 is orientated so that it may incline with respect to the radial direction of the rotating plate 4, the stirring effect becomes higher than the case where the blade | wing 12 is arrange | positioned in a radial direction. The soot stirred together with the washing water in the soot processing chamber 2 is further finely pulverized by the cutting blade 14 that is driven to rotate together with the rotating plate 4 under the rotating plate 4. Here, even when the water level in the soot treatment chamber becomes high due to the retention of the washing water, the backflow of the soot that has dropped below the rotating plate 4 to the upper side of the rotating plate 4 is prevented by the rotating plate 4. Therefore, the soot can be retained under the rotating plate 4 where the cutting blade 14 is disposed, and the soot can be finely pulverized. In addition, the circumferential protrusion 15 formed in the lower part of the soot treatment chamber 2 prevents the generation of a large vortex along the inner wall in the soot treatment chamber 2, and the soot and cleaning water in the soot treatment chamber 2. Is stirred more effectively. Since the soot and washing water staying in the soot treatment chamber 2 are sufficiently stirred, soot that tends to float on the water surface is submerged in the washing water and finely crushed by the rotating cutting blade 14. Furthermore, since pulverization is performed in a state where the soot and washing water are retained in the soot processing chamber 2, the soot frequently collides with the cutting blade 14, and the fibrous soot is also finely pulverized.

  The pressure gauge 22 attached to the discharge unit 18 measures the hydrostatic pressure on the bottom surface of the soot treatment chamber 2 to detect the water level in the soot treatment chamber 2 every moment, and sends the detection signal to the controller 24. When the water level in the soot processing chamber 2 reaches the vicinity of the rotating plate 4, the controller 24 sends a control signal to the flapper valve 20 to open the flapper valve 20. In the present embodiment, cleaning water is supplied into the soot treatment chamber 2 at a flow rate of about 2 liters per minute. Since the volume below the rotating plate 4 of the soot processing chamber 2 is about 1 liter, the water level in the soot processing chamber 2 reaches the height of the rotating plate 4 in about 30 seconds.

  The controller 24 opens the flapper valve 20 and sends a control signal to the water supply valve 16a to increase the water supply flow rate from the water supply pipe line 16c to about 8 liters per minute. For this reason, the soot that stays in the soot processing chamber 2 and is finely pulverized is quickly swept away by a large amount of washing water and discharged downstream through the discharge port 18a. Further, since the crushed soot is discharged together with a large amount of washing water, it does not stay in the sewer pipe, and the drain pipe is prevented from being clogged. The controller 24 supplies cleaning water for about 30 seconds after opening the flapper valve 20, and then sends a control signal to the water supply valve 16a to close the water supply valve 16a and stop the motor 6. Thereby, one crushing process is completed.

  According to the soot treating apparatus of the first embodiment of the present invention, soot and washing water are retained in the soot treating chamber and pulverized by the lower pulverizing means disposed below the rotating plate. It can be finely pulverized. Further, according to the soot treatment apparatus of this embodiment, soot and washing water staying in the soot treatment chamber are pulverized while stirring with blades, so that soot that tends to float on the water surface can be submerged in the washing water. Can be effectively pulverized. Thereby, it is possible to sufficiently finely pulverize the soot that is difficult to pulverize, such as a fibrous soot, and prevent clogging of the drain pipe and the like. Furthermore, according to the soot treating apparatus of the present embodiment, the cutting blade grinds the soot in the washing water staying in the soot treating chamber, so that noise generated during the grinding can be reduced.

  In addition, according to the soot treating apparatus of the first embodiment of the present invention, since the blades are rotated together with the rotating plate, soot and soot staying in the soot treating chamber without providing any special means for driving the blades. The washing water can be stirred. Furthermore, according to the scissor processing apparatus of the present embodiment, the cutting blade is rotated together with the output shaft that drives the rotating plate, so that the cutting blade can be rotated without providing a special means for driving the cutting blade. The soot staying in the soot processing chamber can be crushed.

  Further, according to the soot treatment device of the first embodiment of the present invention, the water level in the soot treatment chamber is controlled by the flapper valve that opens and closes the discharge port, the water supply valve that controls the supply amount of cleaning water, and the controller. The water level can be controlled independently of the blade rotation. Furthermore, according to the soot treatment apparatus of this embodiment, the water level in the soot treatment chamber is detected by the pressure gauge, and the water level is controlled based on this, so that the water level in the soot treatment chamber can be set accurately. .

  In the above-described embodiment, the water level in the soot processing chamber 2 is detected by the pressure gauge 22 and the flapper valve 20 and the like are controlled. However, the pressure gauge 22 can be omitted. In this case, after the driving of the rotating plate 4 is started, the flapper valve 20 is closed for a predetermined time, and then the flapper valve 20 is opened. Further, a constant flow valve or the like may be provided in the water supply device 16 in order to regulate the flow rate of the cleaning water flowing into the soot treatment chamber 2 within an appropriate range.

  Next, with reference to FIG. 6 thru | or FIG. 9, the wrinkle processing apparatus by 2nd Embodiment of this invention is demonstrated. Note that the soot treating apparatus according to the present embodiment is different from the first embodiment in the configuration of the stirring means, the lower crushing means, the water level control means and the like. Therefore, here, only the points of the second embodiment of the present invention that are different from the first embodiment will be described, and the same components are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 6 is a cross-sectional view showing the entire wrinkle processing apparatus according to the second embodiment of the present invention. FIG. 7 is a perspective view showing the upper surface side of the rotating plate used in the wrinkle processing apparatus of this embodiment, and FIG. 8 is a perspective view showing the lower surface side. FIG. 9 is a cross-sectional perspective view showing the lower part of the soot treating chamber of the soot treating apparatus along the line IX-IX in FIG. 6.

  As shown in FIG. 6, the soot processing apparatus 100 according to the second embodiment of the present invention is disposed horizontally in the soot processing chamber 102 disposed in the lower part of the sink S and in an intermediate portion of the soot processing chamber 102. And a motor 6 that rotationally drives the rotating plate 104. Two swing hammers 8 are attached to the upper surface of the rotating plate 104, and two sets of moving projections 112 as stirring means are attached to the lower surface of the rotating plate 104. A fixed blade 10 is attached to a portion of the inner wall of the soot processing chamber 102 facing the swing hammer 8. In the present embodiment, the swing hammer 8 and the fixed blade 10 constitute upper crushing means.

  Furthermore, four sets of fixing protrusions 114 as lower crushing means are provided on the bottom surface of the soot processing chamber 102. In addition, a discharge unit 118 in which a discharge port 118a is formed is provided at the bottom of the soot processing chamber 102. Furthermore, the soot processing apparatus 100 includes a controller 124 that controls the rotation of the motor 6.

  The soot processing chamber 102 includes an input port 102a, and the input port 102a is arranged to communicate with the drain port S1 of the sink S. The soot processing chamber 102 is generally cylindrical, and is formed so that the inner diameter is small at the top inlet 102a and the inner diameter is increased downward from the vicinity of the intermediate portion where the rotating plate 104 is disposed. An output shaft 6a of the motor 6 extends vertically upward from the bottom surface of the soot processing chamber 102, and a rotating plate 104 is attached to the upper end thereof.

  As shown in FIGS. 7 and 8, the rotating plate 104 is a circular metal plate, the center of which is attached to the output shaft 6 a of the motor 6 and is driven to rotate inside the soot processing chamber 102. In addition, twelve circular holes 104 a for allowing washing water to flow mainly under the rotating plate 104 are opened at the peripheral portion of the rotating plate 104.

  Further, as shown in FIG. 7, two swing hammers 8 are attached to the upper surface of the rotating plate 104. Further, as shown in FIG. 6, a fixed blade 10 is attached to a position of the inner peripheral wall of the cocoon processing chamber 102 facing the swing hammer 8.

  Further, as shown in FIG. 8, two sets of moving protrusions 112 for stirring the cleaning water and the soot in the soot processing chamber 102 are attached to the lower surface of the rotating plate 104. The set of moving protrusions 112 is composed of four protrusions having a substantially quadrangular prism shape extending vertically downward from the lower surface of the rotating plate 104. The four protrusions are arranged in a straight line in the radial direction of the rotating plate 104 in a comb shape. Each set of moving protrusions 112 composed of four protrusions is disposed at a symmetrical position with respect to the center of the rotating plate 104. Further, the swing hammer 8 on the upper surface of the rotating plate 104 and the moving projection 112 on the lower surface of the rotating plate 104 are alternately arranged on the circumference of the rotating plate 104 at intervals of 90 °.

  Next, as shown in FIG. 9, the four sets of fixed protrusions 114 serving as the lower crushing means are configured to extend vertically upward from the bottom surface of the soot processing chamber 102. The set of fixed protrusions 114 is composed of four substantially quadrangular prism-shaped protrusions. The four protrusions are arranged in a comb shape in a straight line in the radial direction of the cocoon treatment chamber 102. Each set of the fixed protrusions 114 including four protrusions is arranged on the circumference of the soot processing chamber 102 with an interval of 90 °. Further, each fixed protrusion 114 is arranged such that the moving protrusion 112 rotated together with the rotating plate 104 passes between the fixed protrusions 114.

  In addition, a discharge unit 118 is formed in the lower part of the soot treatment chamber 102. The discharge portion 118 is a cylindrical pipe extending in the tangential direction of the soot processing chamber 102, and communicates with a discharge port 118a formed eccentrically with respect to the center of the inner wall of the lower side surface of the soot processing chamber 102. Yes. With this configuration, the flow of the crushed soot and cleaning water in the soot processing chamber 102 to the discharge port 118a is prevented when the rotating plate 104 is rotated in the direction D1 in FIG. 9, and the rotating plate 104 is in the D2 direction. When it is rotated, it is promoted.

  The controller 124 is configured to output a control signal to the motor 6 so that the motor 6 is rotated forward, reversely, or stopped. Specifically, the controller 124 includes a microprocessor, a memory, and a program (not shown above) for operating them.

  Next, the operation of the scissor processing device 100 according to the second embodiment of the present invention will be described. First, the user puts the soot to be crushed into the soot processing chamber 102 through the introduction port 102a and discharges water from a faucet 116 provided adjacent to the sink S. The water discharged from the faucet 116 should have a flow rate of about 8 liters per minute. Next, the user closes the lid of the drain outlet S1 of the sink S and operates an operation switch (not shown) of the soot processing apparatus 100. When the scissor processing device 100 is activated, the motor 6 is activated by the controller 124, and the rotating plate 104 is rotated in the direction D1 in FIG. In the present embodiment, the rotating plate 104 is rotationally driven in the D1 direction at a rotational speed of about 2000 revolutions per minute. Preferably, the rotation speed of the rotating plate 104 is 1500 to 3000 rotations per minute.

  When the motor 6 is operated, the wrinkles on the rotating plate 104 are sandwiched between the swing hammer 8 and the fixed blade 10 and crushed so as to be crushed. The soot crushed by the swing hammer 8 and the fixed blade 10 passes between the peripheral edge of the rotating plate 104 and the inner wall of the soot treatment chamber 102 and is discharged from the faucet 116 and together with the cleaning water flowing into the soot treatment chamber 102. It falls below the rotating plate 104.

  Since the rotating plate 104 is rotated in the direction D1, the flow of the cleaning water and the soot that has fallen under the rotating plate 104 to the discharge port 118a is obstructed by the moving projection 112 that rotates together with the rotating plate 104, and the discharge unit The discharge flow rate from 118 decreases. That is, when the rotating plate 104 is rotated in the direction D1, the soot and the washing water near the discharge port 118a are moved away from the discharge port 118a by the moving projection 112. For this reason, the outflow of the soot and washing water from the discharge port 118a is prevented, and the discharge flow rate is reduced. As the discharge flow rate from the discharge unit 118 decreases, the cleaning water stays in the soot treatment chamber 102 and the water level in the soot treatment chamber 102 rises. In the present embodiment, the water level in the soot processing chamber 102 is in an equilibrium state at a position where it has risen to near the height of the rotating plate 104. Therefore, in the present embodiment, the discharge port 118a formed eccentrically, and the movement protrusion 112 and the motor 6 that move the soot and the washing water away from the discharge port 118a function as water level control means.

  Washing water and soot staying in the soot processing chamber 102 are agitated by the moving projection 112 rotated together with the rotating plate 104. In addition, the moving projection 112 rotates and moves the fan in the fan-shaped space to the fixed protrusion 114 while being rotationally moved in the fan-shaped space partitioned by the four sets of fixed protrusions 114 arranged radially in the rod processing chamber 102. Pull towards the person. When the moving protrusion 112 is further rotated and reaches the arrangement of the fixed protrusions 114, the wrinkles moved by the moving protrusion 112 are sheared between the moving protrusions 112 and the fixed protrusions 114 and pulverized. Since the washing water in the dredging chamber 102 is sufficiently agitated by the moving projection 112, the soot that tends to float on the water surface is also submerged in the washing water and easily crushed between the moving projection 112 and the fixed projection 114. Is done. In addition, since the fibrous soot that is difficult to pulverize in the conventional cocoon treatment apparatus is easily caught on the moving projection 112 that rotates, the fibrous soot is sandwiched between the moving projection 112 and the fixed projection 114 and easily pulverized. Furthermore, in the soot processing apparatus 100 of the present embodiment, soot and cleaning water crushed on the rotating plate 104 stay in the soot processing chamber 102 to some extent, so that the soot is moved several times by the moving protrusion 112 and the fixed protrusion 114. Is also sheared and pulverized.

  The controller 124 rotates the motor 6 in the direction D1 in FIG. 9 for a predetermined time, and then sends a control signal to the motor 6 to rotate the motor 6 in the direction D2 in FIG. In this embodiment, the controller 124 rotates the motor 6 in the D1 direction after rotating the motor 6 in the D1 direction for about 40 seconds. In this embodiment, the rotating plate 104 is rotationally driven in the D2 direction at a rotational speed of about 2000 revolutions per minute. Preferably, the rotation speed of the rotating plate 104 is 1500 to 3000 rotations per minute.

  When the motor 6 is rotated in the D2 direction, the flow of the cleaning water and the soot to the discharge port 118a is promoted by the moving projection 112 rotated together with the rotating plate 104, and the discharge flow rate from the discharge unit 118 increases. That is, when the rotating plate 104 is rotated in the direction D2, the soot and the washing water near the discharge port 118a are moved toward the discharge port 118a by the moving projection 112. For this reason, the outflow of the soot and washing water from the discharge port 118a is promoted, and the discharge flow rate increases. By increasing the discharge flow rate of the soot from the discharge port 118a and the washing water, soot in the soot processing chamber 102 is rapidly discharged downstream, and the drainage pipe is prevented from being clogged.

  The controller 124 rotates the motor 6 in the direction D2 in FIG. 9 for a predetermined time, and then sends a control signal to the motor 6 to stop the motor 6. In the present embodiment, the controller 124 rotates the motor 6 in the direction D2 for about 5 seconds and then stops it. After stopping the motor 6, the controller 124 sounds a notification sound to notify the user of the end of the pulverization process. The user who is informed of the end of the pulverization process closes the faucet 116 to end the water discharge, and one pulverization process is completed.

  According to the wrinkle treatment apparatus of the second embodiment of the present invention, the wrinkles in the wrinkle processing chamber are crushed so as to be sheared between the fixed protrusions and the moving protrusions. can do. In addition, according to the dredging device of the present embodiment, the water level is controlled by the rotation direction of the moving projection, etc., so that dredging of the dredging and washing water is performed without providing a special means for opening and closing the discharge port. The water level in the soot processing chamber can be controlled by staying in the chamber.

  In the embodiment described above, the controller 124 rotates the motor 6 in the direction D1 for a predetermined time and then reverses the rotation direction. However, as a modification, the controller 124 rotates the motor 6 according to the amount of processing of the soot. May be changed. For example, the motor current value proportional to the motor load may be detected, and when the current value falls below a predetermined value, it may be determined that the motor load has decreased, and the rotation direction may be reversed. According to this modified example configured as described above, for example, when the amount of wrinkle processing is small, the motor 6 is rotated in the D1 direction for about 10 seconds and then rotated in the D2 direction for about 5 seconds. When the amount of processing is large, the operation is to rotate about 50 seconds in the D1 direction and then about 5 seconds in the D2 direction.

  Next, with reference to FIG.10 and FIG.11, the wrinkle processing apparatus by 3rd Embodiment of this invention is demonstrated. Note that the soot treating apparatus according to the present embodiment is different from the second embodiment in the configuration of the stirring means, the lower crushing means, and the like. Accordingly, here, only the points of the third embodiment of the present invention that are different from the second embodiment will be described, and the same components are denoted by the same reference numerals, and description thereof will be omitted.

  FIG. 10 is a cross-sectional view showing the entire wrinkle processing apparatus according to the third embodiment of the present invention. FIG. 11 is a cross-sectional perspective view showing the lower part of the soot treating chamber of the soot treating apparatus along the line XI-XI in FIG.

As shown in FIG. 10, the soot processing apparatus 200 according to the third embodiment of the present invention is disposed horizontally in the soot processing chamber 202 disposed in the lower part of the sink S and in an intermediate portion of the soot processing chamber 202. And a motor 6 that rotationally drives the rotating plate 204. Two swing hammers 8 are attached to the upper surface of the rotating plate 204. Further, a fixed blade 10 is attached to a portion of the inner wall of the soot processing chamber 202 facing the swing hammer 8. In the present embodiment, the swing hammer 8 and the fixed blade 10 constitute upper crushing means.
Furthermore, a blade 212 as a stirring means and a cutting blade 214 as a lower crushing means attached to the tip thereof are attached to an intermediate portion of the output shaft 6a of the motor 6. In addition, four circumferential protrusions 215 that generate an appropriate flow of cleaning water in the soot treatment chamber 202 are formed on the lower inner wall of the soot treatment chamber 202. In addition, a discharge unit 218 having a discharge port 218a is provided in the lower portion of the soot processing chamber 202. Furthermore, the soot processing apparatus 200 includes a controller 224 that controls the rotation of the motor 6.

  The dredging chamber 202 includes an input port 202a, and the input port 202a is disposed so as to communicate with the drain port S1 of the sink S. The soot processing chamber 202 is generally cylindrical, and is formed so that the inner diameter is small at the top inlet 202a and the inner diameter is increased downward from the vicinity of the intermediate portion where the rotating plate 204 is disposed. Further, the output shaft 6a of the motor 6 extends vertically upward from the bottom surface of the soot processing chamber 202, and a rotating plate 204 is attached to the upper end thereof. The rotating plate 204 is a circular metal plate, the center of which is attached to the output shaft 6 a of the motor 6 and is driven to rotate inside the soot processing chamber 202. In addition, twelve circular holes are formed in the peripheral portion of the rotating plate 204 for mainly allowing the cleaning water to flow under the rotating plate 204.

  Furthermore, as shown in FIG. 10, two swing hammers 8 are attached to the upper surface of the rotating plate 204. A fixed blade 10 is attached to a position of the inner peripheral wall of the heel treatment chamber 202 facing the swing hammer 8.

  Next, as shown in FIGS. 10 and 11, the blade 212 that is a stirring means is attached to an intermediate portion of the output shaft 6 a of the motor 6 that extends upward from the bottom surface of the soot treatment chamber 202. The two blades 212 are arranged at positions symmetrical with respect to the output shaft 6a, that is, so as to extend in a straight line on both sides of the output shaft 6a. Each blade 212 is configured by a rectangular plate-shaped member oriented in the vertical direction. Further, a cutting blade 214 as a lower crushing means is attached to the tip of each blade 212. This cutting blade 214 has a shape of an elongated rectangular plate oriented in the horizontal direction, and has a peripheral portion. It is formed to be thin.

  Further, four circumferential protrusions 215 are formed at the lower inner periphery of the soot treating chamber 202. The circumferential protrusions 215 have a quadrangular prism shape, and are disposed on the inner peripheral wall of the soot processing chamber 202 at intervals of 90 °. Each circumferential protrusion 215 extends from the bottom surface of the soot processing chamber 202 to a position slightly below the rotating plate 204. In addition, a slit for passing the cutting blade 214 is formed in the middle portion of each circumferential protrusion 215, and when the rotating cutting blade 214 passes through this slit, the ridges are sheared between them. It is configured.

  In addition, a discharge unit 218 is formed in the lower part of the soot treatment chamber 202. The discharge part 218 is a cylindrical pipe extending in the tangential direction of the soot treatment chamber 202, and communicates with a discharge port 218a formed on the inner wall of the lower side surface of the soot treatment chamber 202 so as to be eccentric with respect to the center thereof. Yes. With this configuration, the flow of the crushed soot and cleaning water in the soot treatment chamber 202 to the discharge port 218a is prevented when the blade 212 is rotated in the direction D1 in FIG. 11, and the blade 212 is rotated in the direction D2. When it is done, it is promoted.

  The controller 224 is configured to output a control signal to the motor 6 so that the motor 6 is rotated forward, reverse, or stopped. Specifically, the controller 224 includes a microprocessor, a memory, and a program (not shown above) for operating them.

  Next, the operation of the scissor processing device 200 according to the third embodiment of the present invention will be described. First, the user throws in the soot processing chamber 202 the soot to be crushed into the soot processing chamber 202 through the introduction port 202a, and discharges water from a faucet 216 provided adjacent to the sink S. The water discharged from the faucet 216 should have a flow rate of about 8 liters per minute. Next, the user closes the lid of the drain outlet S1 of the sink S and operates an operation switch (not shown) of the soot processing device 200. When the scissor processing device 200 is operated, the motor 6 is activated by the controller 224, and the rotating plate 204 is rotated in the direction D1 in FIG. In this embodiment, the rotating plate 204 is rotationally driven in the D1 direction at a rotational speed of about 2000 revolutions per minute. Preferably, the rotational speed of the rotating plate 204 is 1500 to 3000 revolutions per minute.

  When the motor 6 is operated, the wrinkles on the rotating plate 204 are sandwiched between the swing hammer 8 and the fixed blade 10 and crushed so as to be crushed. The soot crushed by the swing hammer 8 and the fixed blade 10 is discharged from the faucet 216 and passes between the peripheral edge of the rotating plate 204 and the inner wall of the soot treatment chamber 202 together with the cleaning water flowing into the soot treatment chamber 202. It falls below the rotating plate 204.

  Since the rotating plate 204 is rotated in the direction D1, the flow of the cleaning water and the soot that has dropped below the rotating plate 204 to the discharge port 218a is blocked by the blades 212 that are rotated together with the rotating plate 104, and the discharge unit 218. The discharge flow from is reduced. That is, when the rotating plate 204 is rotated in the direction D1, soot and washing water in the vicinity of the discharge port 218a are moved away from the discharge port 218a by the blades 212. For this reason, the outflow of the soot and washing water from the discharge port 218a is prevented, and the discharge flow rate is reduced. As the discharge flow rate from the discharge unit 218 decreases, the cleaning water stays in the soot treatment chamber 202 and the water level in the soot treatment chamber 202 rises. In the present embodiment, the water level in the soot treatment chamber 202 is in an equilibrium state at a position where it has risen to the vicinity of the height of the rotating plate 204. Accordingly, in the present embodiment, the eccentric discharge port 218a, the blade 212 and the motor 6 that move the soot and the washing water away from the discharge port 218a function as water level control means.

  Washing water and soot remaining in the soot treatment chamber 202 are agitated by blades 212 that are rotated together with the rotating plate 204. When the cutting blade 214 is rotated and reaches the slit of the circumferential protrusion 215, the ridge is sheared between the circumferential protrusion 215 and the cutting blade 214 and is finely pulverized. Since the washing water in the dredging chamber 202 is sufficiently agitated by the blades 212, the dredging that tends to float on the water surface is also submerged in the washing water and easily crushed between the circumferential protrusion 215 and the cutting blade 214. Is done. Furthermore, in the soot processing apparatus 200 of the present embodiment, soot and washing water crushed on the rotating plate 204 stay in the soot processing chamber 202 to some extent, so that the soot is not removed by the circumferential protrusion 215 and the cutting blade 214. Times are also sheared and pulverized.

  The controller 224 rotates the motor 6 in the direction D1 in FIG. 11 for a predetermined time, and then sends a control signal to the motor 6 to rotate the motor 6 in the direction D2 in FIG. In the present embodiment, the controller 224 rotates the motor 6 in the D1 direction after rotating the motor 6 in the D1 direction for about 40 seconds. In this embodiment, the rotating plate 204 is rotationally driven in the D2 direction at a rotational speed of about 2000 revolutions per minute. Preferably, the rotational speed of the rotating plate 204 is 1500 to 3000 revolutions per minute.

  When the motor 6 is rotated in the D2 direction, the flow of the cleaning water and the soot to the discharge port 218a is promoted by the blades 212 rotated together with the rotating plate 204, and the discharge flow rate from the discharge unit 218 increases. That is, when the rotating plate 204 is rotated in the direction D2, soot and cleaning water near the discharge port 218a are moved toward the discharge port 218a by the blades 212. For this reason, the outflow of the soot and washing water from the discharge port 218a is promoted, and the discharge flow rate increases. By increasing the discharge flow rate of the soot from the discharge port 218a and the washing water, the soot in the soot treatment chamber 202 is rapidly discharged downstream, and the drain pipe is prevented from being clogged.

  The controller 224 rotates the motor 6 in the direction D2 in FIG. 11 for a predetermined time, and then sends a control signal to the motor 6 to stop the motor 6. In the present embodiment, the controller 224 rotates the motor 6 in the direction D2 for about 5 seconds and then stops it. After stopping the motor 6, the controller 224 sounds a notification sound to notify the user of the end of the pulverization process. The user who is informed of the end of the pulverization process closes the faucet 216 to end the water discharge and completes one pulverization process.

  According to the soot treating apparatus of the third embodiment of the present invention, since the blade and the cutting blade are rotated together with the output shaft that drives the rotating plate, the blade is rotated without providing a special driving means, and the soot treating chamber is provided. It is possible to pulverize the stagnation retained by the cutting blade rotating.

  In the above-described embodiment, the controller 224 rotates the motor 6 in the direction D1 for a predetermined time and then reverses the rotation direction. However, as in the above-described modification of the second embodiment, the amount of soot processing The time for rotating the motor 6 may be changed according to the above. Alternatively, a sensor for detecting the water level in the soot treatment chamber 202 is provided, and the number of rotations and the direction of rotation of the motor 6 are controlled according to the water level detected by this sensor to rotate the water level in the soot treatment chamber 202. It can also be configured to maintain near the height of the plate 204.

  In the above-described embodiment, there are only two cutting blades 214 provided on both sides of the output shaft 6a. However, two or more cutting blades 214 may be provided radially, or the cutting blades 214 may be provided radially. May be arranged in multiple stages in the vertical direction.

  As mentioned above, although preferable embodiment of this invention was described, a various change can be added to embodiment mentioned above. In particular, in the embodiment described above, the input port of the soot processing device is provided in communication with the drain port of the sink, but the soot processing device can be installed separately from the sink.

1 is a cross-sectional view showing the entire soot processing apparatus according to a first embodiment of the present invention. It is a perspective view which shows the upper surface side of the rotating plate currently used for the wrinkle processing apparatus by 1st Embodiment of this invention. It is a perspective view which shows the lower surface side of the rotating plate currently used for the scissor processing apparatus by 1st Embodiment of this invention. It is a cross-sectional perspective view which shows the lower part of the soot processing chamber which follows the IV-IV line of FIG. It is sectional drawing which shows the effect | action of the flapper valve provided in the discharge port of the soot processing chamber. It is sectional drawing which shows the whole wrinkle processing apparatus by 2nd Embodiment of this invention. It is a perspective view which shows the upper surface side of the rotating plate currently used for the wrinkle processing apparatus by 2nd Embodiment of this invention. It is a perspective view which shows the lower surface side of the rotating plate currently used for the wrinkle processing apparatus by 2nd Embodiment of this invention. It is a cross-sectional perspective view which shows the lower part of the soot processing chamber which follows the IX-IX line of FIG. It is sectional drawing which shows the whole wrinkle processing apparatus by 3rd Embodiment of this invention. It is a cross-sectional perspective view which shows the lower part of the soot processing chamber which follows the XI-XI line of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS S Sink S1 Drainage port 1 Soot processing apparatus 2 by 1st Embodiment of this invention 2 Soot processing chamber 2a Inlet 2b Water outlet 4 Rotating plate 4a Circular hole 6 Motor 6a Output shaft 8 Swing hammer 8a Rotating shaft 10 Fixed blade 12 Blade 14 Cutting blade 15 Circumferential protrusion 16 Water supply device 16a Water supply valve 16b Vacuum breaker 16c Water supply line 18 Discharge portion 18a Discharge port 20 Flapper valve 20a Spindle 22 Pressure gauge 24 Controller 100 Saddle treatment device 102 according to the second embodiment of the present invention Treatment chamber 104 Rotating plate 112 Moving projection 114 Fixed projection 116 Faucet 118 Discharge portion 118a Discharge port 124 Controller 200 Soot processing apparatus 202 according to the third embodiment of the present invention 202 Soot processing chamber 204 Rotating plate 212 Blade 214 Cutting blade 216 Faucet 218 Discharge section 18a discharge port 224 controller

Claims (8)

A cocoon treatment device for pulverizing cocoons with washing water,
A soot processing chamber in which a soot inlet for pouring the soot is formed above,
A rotating plate disposed in the soot treatment chamber;
Driving means for rotationally driving the rotating plate;
An upper crushing means disposed above the lower surface of the rotating plate, and crushing the pestle charged on the rotating plate from the slag inlet,
A discharge unit having a discharge port formed below the rotary plate of the soot treatment device in order to discharge the crushed and dropped soot and washing water under the rotary plate;
Water level control means for controlling the water level in the soot treatment chamber such that soot and washing water stay in a predetermined amount in the soot treatment chamber;
A stirring means that is disposed below the rotary plate of the soot treatment chamber and that is driven to rotate so as to stir the soot and washing water remaining in the soot treatment chamber;
A lower crushing means disposed below the rotary plate in the soot treatment chamber and crushing the soot remaining below the rotary plate in the soot treatment chamber;
A wrinkle treatment device characterized by comprising:   2. The soot treating apparatus according to claim 1, wherein the stirring means is attached so as to extend downward from the lower surface of the rotating plate.   The lower crushing means is constituted by a plurality of fixing protrusions arranged in a comb-teeth shape extending upward from the bottom surface of the cocoon treatment chamber, and the stirring means extends in a direction substantially orthogonal to the rotating plate, The scissor treatment apparatus according to claim 2, comprising a plurality of moving protrusions arranged so as to pass between the fixed protrusions.   The said drive means is provided with the output shaft to which the said rotating plate was attached extended upwards from the bottom face of the said soot processing chamber, The said lower side grinding | pulverization means is attached so that it may extend radially from the said output shaft. The wrinkle processing apparatus according to 1 or 2.   The drive means includes an output shaft to which the rotating plate is attached and extends upward from the bottom surface of the soot processing chamber, and the stirring means and the lower crushing means are attached so as to extend radially from the output shaft. The soot processing apparatus according to claim 1.   The water level control means may rotate the stirring means in a direction that hinders the flow of the soot and washing water to the discharge port of the soot treatment chamber or in a direction that promotes the flow, or of the stirring means. The dredge processing apparatus according to any one of claims 1 to 5, wherein the water level is controlled by stopping rotation.   The said water level control means has an on-off valve which opens and closes the said discharge port, and the water supply amount control means which controls the quantity of the washing water supplied in the said soot processing chamber by the said water supply means. The soot processing apparatus of Claim 1.   The dredge treatment apparatus according to any one of claims 1 to 7, wherein the water level control means includes a water level sensor that detects a water level in the dredge treatment chamber, and controls the water level based on a detection result of the water level sensor. .

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