JP2007130552A - Water-sealing unit for garbage treatment apparatus and garbage treatment apparatus provided with it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a garbage treatment apparatus capable of easily cleaning the inside of a garbage treatment chamber and a drain trap conduit connected to this. <P>SOLUTION: The garbage treatment apparatus (1) for discharging the crushed garbage together with washing water to a drain pipe has the garbage treatment chamber (12) formed with a garbage throwing port (6) on an upper side; crushing means (20, 22) for crushing the thrown garbage; a garbage discharge part (18) for discharging the garbage crushed by the crushing means from the garbage treatment chamber; the drain trap conduit (24) provided with a descending pipe part downwardly directed from the garbage discharge part and an ascending pipe part upwardly directed from a lower end of the descending pipe part; a drain valve (26) closed in order to stay the washing water in the garbage treatment chamber and the drain trap conduit at cleaning; and an air staying prevention means (28) for preventing air from staying between the garbage discharge part and the drain valve when the drain valve is closed to clean the garbage treatment apparatus. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a water sealing device, and more particularly to a water sealing device for a soot processing device that causes soot and washing water crushed by a main body of a soot processing device to flow into a drain pipe, and a soot processing device including the same.

  Japanese Patent Application Laid-Open No. 2001-224976 (Patent Document 1) describes a soot processing device that discharges together with cleaning water while smashing the soot introduced into the soot processing chamber. In this soot treatment apparatus, soot is pulverized by a moving blade attached to a rotating plate disposed in the soot treatment chamber and a fixed blade attached to the inner wall of the soot treatment chamber, and a drain pipe together with cleaning water flowing into the treatment chamber To be discharged. In general, in this type of soot processing apparatus, crushed soot is unavoidably attached to the inner wall of the soot processing chamber, and the inner wall of the soot processing chamber and the blade for crushing the soot are regularly provided. Need to clean.

  On the other hand, Japanese Patent Application Laid-Open No. 62-262716 (Patent Document 2) describes a soot processor. In this dredging machine, the dredged straw is drained, the dredged water is collected in the dredging storage box, and the water that has flowed down from the dredging is discharged from the drainage port of the dredging chamber. In addition, this dredging machine is provided with a valve at the drainage port of the dredging chamber so that when cleaning the dredging chamber, washing water is stored in the dredging chamber so that the dredging chamber can be submerged and washed. It is configured.

JP 2001-224976 A Japanese Patent Laid-Open No. 62-262716

However, in the soot treating apparatus of the type described in Japanese Patent Application Laid-Open No. 2001-224976, the entrance of the soot treating chamber is narrow and the shapes of the fixed blade and the moving blade are complicated, so these are cleaned with a brush or the like. To do is a very time consuming task. In particular, it is very difficult to clean the back side of the rotating plate.
Furthermore, in such a soot processing device that discharges the smashed soot together with the washing water, there is a problem that dirt easily adheres to the pipe line through which the soot is discharged, in particular, the drain trap pipe formed in a U shape. is there. However, cleaning the drain trap line connected to the soot treating apparatus is more difficult than cleaning the soot treating chamber.

  Moreover, in the soot processing machine described in Japanese Patent Application Laid-Open No. 62-262716, the soot processing chamber can be immersed and washed, so that the soot processing chamber can be cleaned relatively easily. It is not possible to clean the drain trap line connected to. This contamination of the drain trap pipe is particularly problematic in the soot treatment apparatus of the type described in Japanese Patent Application Laid-Open No. 2001-224976 which discharges the crushed soot together with the washing water.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a sealing device for a soot processing device capable of easily cleaning a soot processing chamber and a drain trap pipe connected thereto, and a soot processing device including the same. Yes.

  In order to solve the above-described problems, the present invention is a soot processing device that smashes soot and discharges the ground soot together with cleaning water into a drain pipe, and a soot inlet for pouring soot is formed above. A soot treatment chamber, a grinding means for grinding the soot introduced into the soot treatment chamber, a soot discharge unit provided at a lower portion of the soot treatment chamber and discharging the soot that has been crushed by the grinding means from the soot treatment chamber, A drain trap pipe formed in communication with the soot discharge section and having a descending pipe section extending downward from the soot discharge section, and an ascending pipe section extending upward from the lower end of the descend pipe section, and the drain trap pipe When cleaning the soot treatment device by closing the drain valve and closing the drain valve in order to retain the wash water in the soot treatment chamber and in the drain trap pipe at the time of cleaning,厨 芥 Discharge section and discharge It is characterized by having an air retention preventing means for preventing the air from staying between the valve.

  In the present invention configured as described above, by closing the drain valve at the time of cleaning, the washing water is retained in the dredging device including the drain trap pipe, and soaking can be performed. Further, in the present invention configured as described above, the air staying prevention means prevents the staying of air between the soot discharge part and the drain valve, so that the entire inner wall surface of the drain trap pipe is effectively immersed. Can be placed and washed.

In the present invention, it is preferable that the air retention preventing means is a bypass pipe that communicates the upper part of the ascending pipe part with the downstream side of the drain valve.
In the present invention configured as described above, the air remaining in the drain trap pipe is exhausted through the bypass pipe when the washing water flows into the drain trap pipe.
According to the present invention configured as described above, the air in the drain trap pipe can be exhausted with a simple structure, and the upper limit of the water level in the soot treatment chamber can be regulated by the height of the bypass pipe. it can.

In the present invention, preferably, the air retention prevention means is an exhaust pump that exhausts the air remaining in the upper portion of the rising pipe portion.
According to the present invention configured as described above, the air staying at the upper portion of the rising pipe portion is discharged by the exhaust pump.

In this invention, Preferably, it further has a cleaning time determination means for determining when to clean the soot processing device, and a notification means for notifying the user that the cleaning time has come.
According to the present invention configured as described above, the user is notified by the notification means that the cleaning time has arrived, so that the scissor treatment device can be cleaned at an appropriate time.

In this invention, Preferably, a cleaning time determination means determines the time which should clean a soot processing apparatus based on the frequency | count of use of the soot processing apparatus after the most recent cleaning implementation.
According to the present invention configured as described above, the cleaning time can be determined by a simple processing algorithm.

In this invention, Preferably, a cleaning time determination means determines the time which should clean a wrinkle processing apparatus based on the elapsed time after the last cleaning implementation.
According to the present invention configured as described above, the cleaning time can be determined by a simple processing algorithm.

In the present invention, preferably, it further includes a dirt sensor for detecting dirt in the soot processing chamber, and the cleaning time determination means determines a time for cleaning the soot processing apparatus based on a detection result of the dirt sensor.
According to the present invention configured as described above, the cleaning time can be determined based on the actual level of dirt in the cocoon processing chamber.

In the present invention, preferably, it further includes a flow rate sensor for detecting a flow rate of the waste water flowing in the pipe line downstream of the soot discharge portion, and the cleaning timing determination means is configured to detect the soot treatment device based on the detection result of the flow rate sensor. Determine when to clean.
According to the present invention configured as described above, it is possible to determine the cleaning time based on the actual degree of dirt on the pipe line downstream of the soot discharge section.

  Further, the present invention is a water sealing device that causes the soot and washing water crushed by the soot treatment device main body to flow out to the drain pipe, and seals between the soot treatment device main body and the drain pipe. A drain trap pipe formed so as to communicate with the soot discharge part, and provided with a descending pipe part extending downward from the soot discharge part and an ascending pipe part extending upward from the lower end of the descending pipe part, and the drain trap pipe The drainage valve is provided downstream of the wastewater treatment device and is closed when the wastewater treatment device body is cleaned, and when the wastewater treatment device body is cleaned by closing the wastewater valve, air stays between the waste discharge portion and the wastewater valve. And an air retention preventing means for preventing the air retention.

  According to the water sealing device for a soot treating apparatus of the present invention and the soot treating apparatus provided with the same, the soot treating chamber and the drain trap pipe connected thereto can be easily cleaned.

Next, preferred embodiments of the present invention will be described with reference to the accompanying drawings.
First, with reference to FIG. 1 thru | or 7, the wrinkle processing apparatus by 1st Embodiment of this invention is demonstrated. FIG. 1 is a schematic cross-sectional view showing a state in which a soot treating apparatus according to a first embodiment of the present invention is installed in a sink of a sink. FIG. 2 is a perspective view of a lid body that is attached to the bag input port of the bag processing apparatus of the present embodiment. FIG. 3 is an enlarged perspective view showing the bag inlet for attaching the lid, and FIG. 4 is a cross-sectional view showing a state where the lid is attached to the bottle inlet.

  As shown in FIG. 1, the soot treating apparatus 1 according to the first embodiment of the present invention includes a soot treating apparatus main body 2 that discharges grinded soot together with washing water while grinding the soot, and the soot treating apparatus main body 2. And a sealing device 4 for a soot treatment device that causes the waste water to flow out into the drain pipe. The soot processing device main body 2 is installed such that the soot insertion port 6 opens on the bottom surface of the sink 8 of the sink (not shown). In addition, a faucet 8a is provided in the vicinity of the sink 8, and cleaning water is supplied from the faucet 8a when the slag processing apparatus 1 is operated and cleaned. Moreover, the soot processing device main body 2 is connected to the drain pipe 10 through the sealing device 4 for soot processing device that forms a trap, and is installed so that the crushed soot can be discharged. Furthermore, the drain pipe 10 is connected to a sewer (not shown) through a septic tank (not shown).

  The dredging device 1 according to the first embodiment of the present invention closes the drain valve 26 of the sealing device 4 for dredging device and retains washing water during cleaning, and the dredging treatment chamber 12 of the dredging device body 2. , And pipes connected thereto can be immersed and washed.

  Here, FIG. 7 is a cross-sectional view showing a state in which a drain valve 204 is simply provided in the drain pipe 202 of the conventional soot treating apparatus 200. First, in a state in which the drain valve 204 is opened and water discharge from the sink faucet 206 is stopped, drainage remains in the trap portion of the drain pipe 202 up to a water level L1 indicated by a broken line. As a result, the drain pipe 202 is sealed, and odors from the sewer connected to the drain pipe 202 are blocked. Next, the drain valve 204 is closed, and water is discharged from the faucet 206, whereby the water level in the dredging chamber is raised to a water level L2 indicated by a one-dot chain line. Here, even after the soot processing chamber is raised to the water level L2, the water level inside the drainage pipe 202 rises only to the water level L3 because air trapped in the drainage pipe 202 remains. In this state, even if the soot treatment device is immersed and washed, the portion where the air in the drain pipe 202 is retained is not cleaned. Further, the portion where the air in the drain pipe 202 stays is a portion where dirt easily adheres, so that it is necessary to perform sufficient cleaning. In the bag processing apparatus of this embodiment, this problem is solved by the configuration described later.

  On the other hand, in the soot treating apparatus 1 according to the first embodiment of the present invention, as shown in FIG. 1, the soot treating apparatus main body 2 includes a soot treating chamber 12 in which a soot filling port 6 for pouring soot is formed upward, A rotating plate 14 disposed in the soot processing chamber 12, a motor 16 that is a driving means for rotationally driving the rotating plate 14, and provided below the rotating plate 14 below the soot processing chamber 12 and pulverized. And a soot discharge portion 18 for discharging soot from the soot processing chamber 12. A fixed blade 20 is attached to the inner wall surface of the intermediate portion of the soot processing chamber 12. Further, two swing hammers 22 are attached to the upper surface of the rotating plate 14 so as to be rotatable about a shaft 22a. In the present embodiment, the fixed blade 20 and the swing hammer 22 constitute pulverizing means. Moreover, the soot processing device main body 2 has a controller 23 that operates the motor 16 and the drain valve 26 based on the detection signal of the magnetic detection element 37 (FIG. 3) provided in the soot insertion port 6.

  Further, the water sealing device 4 for the dredging device is formed in communication with the dredging discharge portion 18, and is formed by a downward pipe portion 24a that goes downward and an upward pipe portion 24b that goes upward from the lower end of the downward pipe portion 24a. It has a drain trap pipe 24 that is a discharge passage, and a drain valve 26 provided on the downstream side of the drain trap pipe 24. Further, the water-sealing device 4 for dredging device includes a water level setting pipe 28a branched from the upper part of the ascending pipe portion 24b and extending vertically upward, and an upper end of the water level setting pipe 28a and a pipe line downstream of the drain valve 26. It has a bypass line 28 formed from a return line 28b to be communicated. In the present embodiment, the bypass conduit 28 functions as an air retention preventing means and a water level regulating means.

  On the other hand, the soot processing chamber 12 is formed in a substantially truncated cone shape with a circular soot inlet 6 opened upward. The dredge inlet 6 also serves as a drain for the sink 8, and the water in the sink 8 enters the dredging chamber 12 through the dredger inlet 6, and the dredging outlet 18, drain trap line 24, drain valve 26. It is comprised so that it may drain into the drain pipe 10 via.

  The rotating plate 14 is a metal disk that is horizontally supported by the middle portion of the soot processing chamber 12. Further, the center of the rotating plate 14 is screwed to the rotating shaft 16 a of the motor 16 and is rotated by the motor 16. Two shafts 22a are attached to the rotating plate 14 so as to penetrate the rotating plate 14 at a right angle. The shaft 22a rotatably supports the metal swing hammer 22 on the upper surface side of the rotating plate 14. The swing hammer 22 has a substantially rectangular parallelepiped block shape, and a shaft 22a is passed through one end thereof. Further, the bottom surface of the swing hammer 22 is a flat surface and increases in thickness toward the tip, and the tip is formed in an arc shape having substantially the same curvature as the periphery of the rotating plate 14. The length of the swing hammer 22 is set so that the tip of the swing hammer 22 substantially coincides with the periphery of the rotary plate 14 when the swing hammer 22 is directed radially outward of the rotary plate 14.

  As shown in FIG. 1, a metal fixed blade 20 is attached to the inner wall of the intermediate portion of the cocoon treatment chamber 12 so as to surround the rotating plate 14. The fixed blade 20 is formed with a large number of cutout portions (not shown) at equal intervals in the circumferential direction. The soot is crushed in the soot processing chamber 12 by being pushed between the edge of each cutout portion (not shown) of the fixed blade 20 and the swing hammer 22.

  The soot discharge unit 18 is a discharge port for discharging the crushed soot, and is formed in the lower part of the soot processing chamber 12 below the rotating plate 14. The soot discharging part 18 is connected to the upstream end of the drain trap pipe 24, and causes soot and washing water that has been crushed and dropped to the lower side of the rotating plate 14 to flow into the drain trap pipe 24.

  The controller 23 controls the motor 16 and the drain valve 26 on the basis of the detection signal of the magnetic detection element 37 (FIG. 3) attached to the soot insertion port 6 so that the soot treatment device 1 is in the soot treatment mode and the cleaning mode. It is configured to operate. In addition, the controller 23 has a cleaning time determination unit 23a for determining a time when the soot treating apparatus 1 should be cleaned. This cleaning time determination means 23a determines the time to be cleaned based on the number of times the wrinkle processing device 1 is used after the cleaning mode of the wrinkle processing device 1 was previously executed. When the cleaning time determination unit 23a determines that it is time to clean the scissor processing device 1, the cleaning time determination unit 23a rings the buzzer 40, which is a notification unit provided on the wall surface of the kitchen, to notify the user of the arrival of the cleaning time. . In the present embodiment, the cleaning time determination unit 23a determines that the cleaning time has arrived when the operation in the soot processing mode is performed 10 times after the cleaning mode is executed. Specifically, the controller 23 includes a microprocessor, a memory, and a program (not shown above) stored therein.

  The drain trap pipe 24 is integrally formed so as to communicate with the descending pipe part 24a whose upper end is connected to the soot discharge part 18 and the descending pipe part 24a, and extends upward from the lower end of the descending pipe part 24a. It is comprised by the pipe part 24b. In the present embodiment, the drain trap pipe 24 is constituted by a pipe bent in a generally U shape. A pipe line extending substantially vertically downward is formed on the downstream side of the ascending pipe portion 24b, and a drain valve 26 that can be opened and closed is disposed at the lower end thereof.

  Further, the bypass pipe line 28 connects the water level setting pipe 28a branched from the upper part of the ascending pipe part 24b and extending substantially vertically upward, and the upper end of the water level setting pipe 28a and the pipe line on the downstream side of the drain valve 26. The return line 28b is formed. The water level setting pipe 28a communicates with the upper ceiling surface of the ascending pipe portion 24b, and its upper end is configured to be located slightly below the soot inlet 6. This water level setting pipe 28a acts as an overflow pipe, and regulates the upper limit of the water level in the soot treatment chamber 12 when the drain valve 26 is closed and the washing water is retained in the soot treatment chamber 12. As a result, the water level in the soot processing chamber 12 becomes higher than that of the soot inlet 6, and the cleaning water in the soot processing chamber 12 is prevented from flowing back to the sink 8. Further, the water level setting pipe 28 a also plays a role of letting the air staying in the drain trap pipe 24 escape to the drain pipe 10 through the drain valve 26. For this reason, when the drain valve 26 is closed and the water level in the soot processing chamber 12 is raised, air does not remain in the drain trap conduit 24 as shown in FIG.

Next, with reference to FIGS. 2 to 4, the lid 30 that is attached to the soot insertion port 6 of the soot processing apparatus main body 2 will be described.
As shown in FIGS. 2 and 4, the lid 30 includes a donut plate-like upper plate portion 32, a cylindrical lower tube portion 34 extending downward from the upper plate portion 32, and an inner side of the lower tube portion 34. Further, it is formed by an inner cylindrical portion 36 formed concentrically. A funnel-shaped conical surface 32a is formed at the center of the upper plate portion 32, and a first inflow port 32c is formed at the bottom of the conical surface 32a. Moreover, the holding part 32b extended in the radial direction of the conical surface 32a is formed so that both sides of the conical surface 32a may be bridged.

  Further, six second inflow ports 34a are formed at equal intervals on the circumference of the upper end of the lower cylindrical portion 34 (only three are shown in FIG. 2). Further, two inclined grooves 34b are formed at symmetrical positions so as to extend obliquely upward from the lower end of the lower cylindrical portion 34 (only one is shown in FIG. 2). The inclined grooves 34b include a vertical groove 34c that extends substantially vertically from the lower end of the lower cylindrical portion 34, an inclined groove 34d that extends obliquely upward from the upper end of the vertical groove 34c, and a substantially horizontal direction from the tip of the inclined groove 34d. It is formed from an extending horizontal groove 34e. Furthermore, magnets 35 for activating the scissor processing device 1 are embedded in two locations on the circumference of the lower cylinder portion 34.

  The inner cylinder part 36 is formed concentrically inside the lower cylinder part 34, and the lower end thereof is located inside the lower cylinder part 34 by an annular annular bottom surface 36 b extending radially outward from the inner cylinder part 36. It is connected to the side. In the space surrounded by the lower cylinder portion 34, the inner cylinder portion 36, and the annular bottom surface 36b, granular cleaning chemical 38 is placed when the heel treatment apparatus 1 is cleaned. Furthermore, a number of drug diffusion holes 36 a for diffusing the cleaning drug 38 dissolved in the cleaning water are formed in about ½ of the region below the inner cylindrical portion 36.

  Furthermore, as shown in FIG. 3, the soot insertion port 6 to which the lid 30 is attached includes a cylindrical portion 6a that communicates with the upper end of the soot processing chamber 12, and a flange that extends outward from the upper end of this cylindrical portion 6a. Part 6b. In a state where the main body 2 is attached to the sink 8, only the upper surface of the flange portion 6 b is exposed to the outside, and the other portion is disposed below the bottom surface of the sink 8. Also, two cylindrical projections 6c are provided on the inner surface of the cylindrical portion 6a (only one is shown). The protrusion 6 c is configured to be received in the inclined groove 34 b of the lid 30. Further, a magnetic detection element 37 for detecting the magnetism of the starting operation magnet 35 attached to the lower cylindrical portion 34 of the lid 30 is attached to the outer surface of the cylindrical portion 6a.

  Next, with reference to FIG. 1, FIG. 5 and FIG. 6, the operation of the scissor processing device 1 according to the first embodiment of the present invention will be described. FIG. 5 is a perspective view showing a state in which the lid body 30 is attached to the basket insertion slot 6, and FIG. 6 is a state in which the lid body 30 attached to the basket insertion slot 6 is rotated to operate the basket processing apparatus 1. FIG.

  First, the action at the time of crushing the soot by the soot treating apparatus 1 of the present embodiment will be described. When pulverizing the soot by the soot processing apparatus 1, first, the lid body 30 is removed from the soot loading port 6, and the soot to be processed is put into the soot processing chamber 12 from the soot loading port 6. The thrown straw is placed on the rotating plate 14. In addition, during normal use, the drain valve 26 is always open.

  Next, the faucet 8 a is made to discharge water, and washing water is caused to flow into the soot treatment chamber 12 from the soot inlet 6. In this state, the lid body 30 is attached to the basket inlet 6. First, as shown in FIG. 5, in the state where the lid body 30 is attached to the basket insertion slot 6 and the protrusion 6 c of the basket insertion slot 6 is received in the vertical groove 34 c of the lid body 30, 32 becomes the 1st position which becomes higher than the flange part 6b of the basket input port 6. FIG. Next, when the user grasps the grip portion 32b of the lid body 30 and rotates the lid body 30, the projection 6c slides along the inclined groove portion 34d, and the lid body 30 is lowered as shown in FIG. Thus, the upper plate portion 32 and the flange portion 6b become the second position located on the same plane. In this state, the wash water discharged from the faucet 8a flows into the soot processing chamber 12 through the first inlet 32c.

  When the lid 30 is rotated and the protrusion 6c reaches the end of the horizontal groove 34e, it is attached to one of the magnets 35 attached to the lower cylindrical portion 34 of the lid 30 and the cylindrical portion 6a of the basket insertion port 6. The position of the magnetic detection element 37 is matched, and the magnetism of the magnet 35 is detected by the magnetic detection element 37. Since the magnets 35 are attached to two locations of the lower cylindrical portion 34, any one of the magnets 35 is aligned with the magnetic detection element 37 regardless of the direction in which the lid 30 is attached to the basket inlet 6. The magnetic detection element 37 can detect magnetism. When the magnetic detection element 37 detects magnetism, the controller 23 activates the wrinkle processing device 1 in the wrinkle processing mode. That is, the controller 23 activates the motor 16 and the rotating plate 14 is rotated.

  Thus, in the cocoon treatment apparatus 1 of this embodiment, since the motor 16 is started by operation of the cover body 30, the motor 16 is rotated in a state where the user puts his hand in the cocoon treatment chamber 12. There is no. When the rotating plate 14 is rotated, the soot on the rotating plate 14 is crushed between the fixed blade 20 and the swing hammer 22, and the crushed soot falls to the lower side of the rotating plate 14 together with the cleaning water. The soot that has fallen under the rotating plate 14 flows out from the soot processing chamber 12 through the soot discharge section 18 together with the cleaning water, and is discharged to the drain pipe 10 through the drain trap pipe 24. When the motor 16 is rotated for a predetermined time and the soot in the soot processing chamber 12 is crushed, the controller 23 stops the motor 16. Next, the user stops water discharge from the faucet 8a, and one dredging process is completed.

  Moreover, the cleaning time determination means 23a built in the controller 23 increases the integrated value of the number of times of use of the soot processing apparatus 1 by one. If this integrated value exceeds 10, the cleaning time determination means 23a sends a signal to the buzzer 40 to sound it, and informs the user that the cleaning time of the heel treatment apparatus 1 has arrived.

  Next, an effect | action at the time of cleaning the wrinkle processing apparatus 1 of this embodiment is demonstrated. When cleaning the soot treating apparatus 1 of the present embodiment, first, the cleaning agent 38 of the soot treating apparatus 1 is put into the lid 30 from the second inflow port 34a (see FIG. 4). Next, the user puts the faucet 8 a into a water discharge state and attaches the lid 30 to the jar inlet 6. When the user rotates the lid 30 twice quickly in the manner of double-clicking with the lid 30 attached to the bag insertion slot 6 as shown in FIG. 6, the magnetic detection element 37 detects this. The controller 23 activates the soot treating apparatus 1 in the cleaning mode. In the cleaning mode, the controller 23 first closes the drain valve 26. If the wash water flows into the soot treatment chamber 12 with the drain valve 26 closed, the wash water stays upstream of the drain valve 26 and the drain trap pipe 24 becomes full. At this time, the air staying in the drain trap pipe 24 is exhausted downstream of the drain valve 26 through the bypass pipe 28.

  When the washing water further flows in the state where the drain trap pipe 24 is full, the water level in the dredging treatment chamber 12 and the water level setting pipe 28a rises. When this water level becomes higher than the height of the upper end of the water level setting pipe 28a, the wash water that has flowed into the soot processing chamber 12 overflows from the water level setting pipe 28a and is discharged from the drain pipe 10 through the return pipe 28b. The water level is regulated by the height of the water level setting pipe 28a. Since the height of the water level setting pipe 28a is substantially the same as that of the soot inlet 6, the washing water does not overflow from the soot inlet 6.

  After the water level of the washing water rises to a predetermined height in the vicinity of the trough inlet 6, the user sets the faucet 8a to a water stop state. In a state in which the water level of the cleaning water has risen to the vicinity of the jar inlet 6, the cleaning chemical 38 placed in the lid 30 is immersed in the cleaning water, and the cleaning chemical 38 dissolved in the cleaning water passes through the chemical diffusion hole 36a. It is gradually released and diffuses into the wash water. With the cleaning agent 38 dissolved in the washing water, the inside of the soot processing chamber 12 and the drain trap pipe 24 are immersed and washed. Further, since the air staying in the drain trap pipe 24 is exhausted and the drain trap pipe 24 is filled with water, the cleaning water and the cleaning agent act on the entire inner wall surface of the drain trap pipe 24, The drain trap line 24 is also cleaned to every corner.

  After a predetermined time has elapsed, the controller 23 operates the motor 16 to intermittently rotate the rotating plate 14 soaked in the cleaning water in which the cleaning chemical 38 is dissolved in the forward and reverse directions. This effectively removes dirt adhering to the rotating plate 14 and the swing hammer 22 and effectively adhering dirt adhering to the inner wall surface of the soot processing chamber 12 due to the water flow generated by the rotation of the rotating plate 14. Removed.

  The controller 23 immerses and cleans the soot processing chamber 12 and the drain trap pipe 24 for a predetermined time, and then opens the drain valve 26 and peels off from the inner wall surfaces of the soot processing chamber 12 and the drain trap pipe 24 by soaking and cleaning. The removed dirt is discharged together with the washing water. At this time, the controller 23 intermittently forwards and reversely rotates the rotating plate 14 to prevent the dirt that has been peeled off from reattaching. Preferably, the user discharges cleaning water from the faucet 8a, rinses the rotating plate 14 and the swing hammer 22, and prevents the dirt from reattaching to the uneven portions. Moreover, the cleaning time determination means 23a of the controller 23 resets the integrated value of the number of times of use of the soot processing apparatus 1 to zero. In the present embodiment, the controller 23 closes the drain valve 26 for about 3 hours and executes the soaking. As a modified example, the controller 23 may be configured so that the user can set the time for performing the soaking and cleaning by a timer or the like.

According to the dredging device of the first embodiment of the present invention, the cleaning water is retained in the dredging device including the drain trap pipe by cleaning the submerged valve by closing the drain valve during cleaning. it can. In addition, according to the soot treatment device of the present embodiment, since the retention of air between the soot discharge part and the drain valve is prevented by the bypass pipe, the entire inner wall surface of the drain trap pipe is effectively immersed and washed. can do. Furthermore, according to the soot treatment apparatus of the present embodiment, the water level in the soot treatment chamber is regulated by the height of the bypass conduit, so that it is possible to prevent the wash water from overflowing from the soot treatment chamber during washing. .
Further, according to the soot treating apparatus of this embodiment, the user is notified by the buzzer that the cleaning time of the soot treating apparatus has arrived, so that the soot treating apparatus can be cleaned at an appropriate time.

  In the first embodiment described above, the cleaning agent 38 is placed in the lid 30 when the soot treatment apparatus is operated in the cleaning mode. However, during normal use of the soot treating apparatus, the lid 30 Other drugs can be used inside. For example, a slime control agent for preventing germs from propagating in the cocoon treatment chamber 12 or the drain trap pipe 24 may be used in the lid 30. Here, when crushing by the dredging device 1 is not performed and the dredging device functions as a drain port for the sink 8, the lid 30 is placed at the first position shown in FIG. It is attached to. In this first position, the water that has flowed into the sink 8 mainly flows into the lid body 30 from the second inlet 34a, and the slime control agent put between the lower cylinder part 34 and the inner cylinder part 36. Is dissolved and flows into the soot processing chamber 12 from the drug diffusion hole 36a. Thereby, it is possible to suppress the propagation of various germs in the cocoon treatment chamber 12 or the like.

  Moreover, when performing the crushing process of the soot by the soot processing apparatus 1, the lid body 30 is attached to the soot inlet 6 at the second position shown in FIG. In this second position, the washing water discharged from the faucet 8a to discharge the crushed soot mainly flows into the soot treatment chamber 12 through the first inlet 32c of the lid 30. To do. For this reason, the slime control agent put in the cover body 30 is not dissolved, and the slime control agent that is not required at the time of pulverizing the soot is not wasted. In addition, the cleaning chemical | medical agent 38 used for the cleaning of the wrinkle processing apparatus 1 and a slime control agent can also be used.

  In the above-described embodiment, the return pipe 28b is connected to the drain pipe 10 on the downstream side of the drain valve 26, but the return pipe 28b is connected to another drain pipe of a system different from the drain valve 26. You may connect.

  Furthermore, in the above-described embodiment, the cleaning time determination unit 23a determines the cleaning time based on the number of times the heel processing apparatus 1 is used. However, the elapsed time after the cleaning time determination unit 23a performs the previous cleaning. It can also be configured to determine the cleaning time based on the above. Alternatively, a dirt sensor such as an odor sensor 42 for detecting dirt in the soot processing chamber 12 is provided in the soot processing chamber 12, and the cleaning time determination means 23a determines the cleaning time based on the detection result of the smell sensor 42. It can also be configured to. By configuring the soot processing device in this way, the cleaning time determination means 23a can determine the cleaning time based on the actual degree of dirt in the soot processing chamber.

  Further, since the flow velocity of the drainage flowing through the pipeline decreases when the inside of the pipeline becomes dirty, a flow velocity sensor 44 that detects the drainage flow velocity is provided in a pipeline such as the drain trap pipeline 24, and the flow velocity sensor 44 The cleaning time determination unit 23a may be configured to determine the cleaning time based on the detection result. By configuring the soot treatment device in this way, the cleaning time determination means 23a can determine the cleaning time based on the actual degree of dirt on the pipe line downstream of the soot discharge section.

Furthermore, in the above-described embodiment, the user has been informed by the buzzer that the cleaning time has come. However, as a modification, the LED, lamp, etc. are lit instead of or together with the buzzer. You may comprise as follows.
In the above-described embodiment, the crushing mode is activated by rotating the lid once, and the cleaning mode is activated by rotating the lid twice. The grinding mode can be activated when the body is rotated clockwise, and the cleaning mode can be activated when the body is rotated counterclockwise. In this case, three magnets are embedded in the lid, and when the lid is rotated clockwise, the magnetism of the two magnets is detected by the magnetic detection element, and the lid is counterclockwise. It is preferable to identify the operation of the lid by arranging each magnet and each magnetic detection element so that the magnetism of all the magnets is detected by the magnetic detection element when it is rotated around.

  Next, with reference to FIG. 8, a wrinkle processing apparatus according to a second embodiment of the present invention will be described. The soot treating apparatus according to the present embodiment is different from the first embodiment in that the air staying in the drain trap pipe is exhausted using an exhaust pump. Accordingly, 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 will be denoted by the same reference numerals and the description thereof will be omitted.

  As shown in FIG. 8, the soot processing device 100 according to the second embodiment of the present invention includes the soot processing device main body 2 and a sealing device 102 for the soot processing device. In addition, the sealing device 102 for the dredging device includes a drain trap pipe 24, a drain valve 26 provided downstream thereof, and an air retention that discharges air in the drain trap pipe 24 to the downstream side of the drain valve 26. And an exhaust pump 104 which is a prevention means.

  The exhaust pump 104 is connected to the upper part of the rising pipe portion 24 b of the drain trap pipe 24, sucks air staying in the drain trap pipe 24, and passes it to the drain pipe 10 on the downstream side of the drain valve 26. It is configured to exhaust.

  Next, the operation of the scissor processing device 100 according to the second embodiment of the present invention will be described. In addition, since the effect | action in the cocoon treatment mode of the cocoon treatment apparatus 100 is the same as that of 1st Embodiment of this invention, description is abbreviate | omitted.

  First, when the operation of the cleaning mode of the soot processing device 100 is started, a controller (not shown in FIG. 8) closes the drain valve 26. When the user puts the faucet 8a into a water discharge state, the water level in the drain trap pipe 24 gradually rises. After closing the drain valve 26, the controller operates the exhaust pump 104 to exhaust the air staying in the drain trap pipe 24 to the drain pipe 10 on the downstream side of the drain valve 26. By raising the water level in the drain trap pipe 24 while operating the exhaust pump 104, air does not stay in the drain trap pipe 24, and the drain trap pipe 24 becomes full as shown in FIG. Is done.

  The controller operates the exhaust pump 104 for a predetermined time, and stops the exhaust pump 104 after the drain trap pipe 24 is full. The user sets the faucet 8a to a water-stopping state after the water level in the soot treatment chamber 12 reaches a predetermined water level. Further, the controller immerses and cleans the soot treatment chamber 12 and the drain trap conduit 24 for a predetermined time, and then opens the drain valve 26, and soaks and cleans the soot treatment chamber 12 and the drain trap conduit 24 from the inner wall surface. The dirt that has been peeled off is discharged together with the washing water.

  According to the soot treating apparatus of the second embodiment of the present invention, it is possible to prevent air from staying in the drain trap pipe by the exhaust pump.

  Next, a wrinkle processing apparatus according to a third embodiment of the present invention will be described with reference to FIG. The soot treating apparatus according to the present embodiment is different from the first embodiment in that the air staying in the drain trap pipe is exhausted using two drain valves. Accordingly, here, only the points of the third embodiment of the present invention that are different from the first embodiment will be described, and the same components will be denoted by the same reference numerals and description thereof will be omitted.

  As shown in FIG. 9, the dredging device 110 according to the third embodiment of the present invention includes the dredging device body 2 and a sealing device 112 for the dredging device. Further, the sealing device 112 for the dredging device includes a drain trap pipe 24, an upstream drain valve 114 provided upstream thereof, a downstream drain valve 116 provided downstream of the drain trap pipe 24, Have In the present embodiment, the upstream drain valve 114 and the downstream drain valve 116 function as air retention prevention means.

  The upstream drain valve 114 and the downstream drain valve 116 are configured to be opened and closed at a predetermined timing by a controller (not shown in FIG. 9) so that the drain trap pipe 24 is filled with water.

  Next, the operation of the scissor processing device 110 according to the third embodiment of the present invention will be described. In addition, since the effect | action in the cocoon treatment mode of the cocoon treatment apparatus 110 is the same as that of 1st Embodiment of this invention, description is abbreviate | omitted.

  First, when the operation in the cleaning mode of the soot processing device 110 is started, a controller (not shown in FIG. 9) closes the upstream drain valve 114. When the user puts the faucet 8a into a water discharge state, the water level in the soot processing chamber 12 gradually rises. The controller opens the upstream drain valve 114 when a predetermined amount of cleaning water is stored in the soot processing chamber 12 after the upstream drain valve 114 is closed. As a result, the wash water that has flowed down from the dredging chamber 12 into the drain trap pipe 24 pushes the air staying in the drain trap pipe 24 into the drain pipe 10 to fill the drain trap pipe 24 with water. To do. The controller closes the downstream drain valve 116 at the moment when the drain trap pipe 24 is filled with water, and maintains the drain trap pipe 24 in a full state.

  The user sets the faucet 8a to a water-stopping state after the water level in the soot treatment chamber 12 reaches a predetermined water level. Further, the controller immerses and cleans the soot treatment chamber 12 and the drain trap conduit 24 for a predetermined time, and then opens the downstream drain valve 116 and immerses the soot treatment chamber 12 and the drain trap conduit 24 by soaking. The dirt peeled off from the wall surface is discharged together with cleaning water.

  According to the dredging device of the third embodiment of the present invention, the upstream drain valve and the downstream drain valve can prevent air from staying in the drain trap pipe.

  Next, with reference to FIG. 10, a wrinkle processing apparatus according to a fourth embodiment of the present invention will be described. The soot treating apparatus according to the present embodiment is different from the first embodiment in that the air staying in the drain trap pipe is exhausted using the cleaning water supply apparatus. Accordingly, only the points of the fourth embodiment of the present invention that are different from the first embodiment will be described here, and the same components will be denoted by the same reference numerals and the description thereof will be omitted.

  As shown in FIG. 10, the dredging device 120 according to the fourth embodiment of the present invention includes the dredging device body 2 and the sealing device 122 for the dredging device. Moreover, the sealing device 122 for dredging device includes a drain trap pipe 24, a cleaning water supply device 124 which is an air retention preventing means provided downstream thereof, and a drain valve 126.

  The cleaning water supply device 124 is controlled by a controller (not shown in FIG. 10), and is configured to instantaneously flow a large amount of cleaning water into the downstream side of the drain trap pipe 24 at a predetermined timing. .

  Next, the operation of the scissor processing device 120 according to the fourth embodiment of the present invention will be described. In addition, since the effect | action in the cocoon treatment mode of the cocoon treatment apparatus 120 is the same as that of 1st Embodiment of this invention, description is abbreviate | omitted.

  First, the user sets the faucet 8a to a water discharge state and activates the cleaning mode of the culm treatment device 120. When the operation of the cleaning device 120 in the cleaning mode is started, the controller (not shown in FIG. 10) operates the cleaning water supply device 124 to supply a large amount of cleaning water to the downstream side of the drain trap pipe 24. Let it flow. Thereby, the air staying in the drain trap pipe 24 is pushed out by the wash water and sucked out from the drain trap pipe 24 by the flow of the wash water, and the drain trap pipe 24 is washed. Filled with water. The controller closes the downstream drain valve 126 at the moment when the drain trap pipe 24 is filled with water, and maintains the drain trap pipe 24 in a full state.

  The user sets the faucet 8a to a water-stopping state after the water level in the soot treatment chamber 12 reaches a predetermined water level. Further, the controller immerses and cleans the soot treatment chamber 12 and the drain trap conduit 24 for a predetermined time, and then opens the downstream drain valve 116 and immerses the soot treatment chamber 12 and the drain trap conduit 24 by soaking. The dirt peeled off from the wall surface is discharged together with cleaning water.

  According to the soot treatment device of the fourth embodiment of the present invention, it is possible to prevent air from staying in the drain trap pipe by the cleaning water supply device.

  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 above-described embodiment, the cleaning water is supplied from the faucet provided in the vicinity of the sink, but it is also possible to provide a water supply means for supplying the cleaning water directly into the tub treatment chamber separately from the faucet. . In this case, it is good to comprise so that the water stop and water discharge of a water supply means may be controlled by a controller.

In the above-described embodiment, the soot processing device is operated by operating the lid, but a switch for operating the soot processing device may be provided at another position.
Furthermore, in the above-described embodiment, the cleaning chemical is put in the lid, but the user may directly put the cleaning chemical into the bag processing chamber.

It is a schematic sectional drawing which shows a mode that the soot processing apparatus by 1st Embodiment of this invention was installed in the sink of the sink. FIG. 3 is a perspective view of a lid body that is attached to the bag input port of the bag processing apparatus according to the first embodiment of the present invention. It is a perspective view which expands and shows the bag input port which mounts a cover body. It is sectional drawing which shows the state which mounted | wore the lid | cover with the lid | cover. It is a perspective view which shows the state with which the cover body was mounted | worn at the bag insertion opening. It is a perspective view which shows the state which rotated the lid | cover mounted | worn with the sputum slot and operated the spear processing apparatus. It is sectional drawing which shows the state which provided the drain valve simply in the drain pipe of the conventional soot processing apparatus. It is a schematic sectional drawing which shows a mode that the soot processing apparatus by 2nd Embodiment of this invention was installed in the sink of the sink. It is a schematic sectional drawing which shows a mode that the soot processing apparatus by 3rd Embodiment of this invention was installed in the sink of the sink. It is a schematic sectional drawing which shows a mode that the soot processing apparatus by 4th Embodiment of this invention was installed in the sink of the sink.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Soot processing apparatus by 1st Embodiment of this invention 2 Soot processing apparatus main body 4 Sealing apparatus for soot processing apparatus 6 Soot inlet 6a Tubular part 6b Flange part 6c Protrusion 8 Sink 8a Water tap 10 Drain pipe 12 Soot processing chamber DESCRIPTION OF SYMBOLS 14 Rotating plate 16 Motor 18 Reed discharge part 20 Fixed blade 22 Swing hammer 22a Shaft 23 Controller 23a Cleaning time determination means 24 Drain trap pipe 24a Down pipe part 24b Up pipe part 26 Drain valve 28 Bypass pipe 28a Water level setting pipe 28b Return Pipe line 30 Lid 32 Upper plate part 32a Conical surface 32b Gripping part 32c First inlet 34 Lower cylinder 34a Second inlet 34b Inclined groove 34c Vertical groove 34d Inclined groove 34e Horizontal groove 35 Magnet 36 Inner cylinder 36a Drug diffusion Hole 36b Annular bottom 37 Magnetic detection element 38 Cleaning agent 4 Buzzer 42 Odor sensor 44 Flow rate sensor 100 Soot processing apparatus according to the second embodiment of the present invention 102 Sealing apparatus for soot processing apparatus 104 Exhaust pump 110 Soot processing apparatus according to the third embodiment of the present invention 112 Sealing apparatus for soot processing apparatus 114 Upstream Drain Valve 116 Downstream Drain Valve 120 Dredging Device 122 according to Fourth Embodiment of the Present Invention 122 Sealing Device for Dredging Device 124 Washing Water Supply Device 126 Drain Valve 200 Dredging Device 202 Drain Pipe 204 Drain Valve 206 Water plug

Claims (9)

A slag treatment device that pulverizes slag and discharges the smashed slag together with washing water into a drain pipe,
A soot processing chamber in which a soot entry port for pouring soot is formed above,
Pulverizing means for pulverizing the soot introduced into the soot processing chamber;
A soot discharge portion provided at a lower portion of the soot treatment chamber and for discharging the soot crushed by the pulverization means from the soot treatment chamber;
A drain trap pipe formed in communication with the soot discharge part, and having a down pipe part that goes downward from the soot discharge part, and an up pipe part that goes up from the lower end of this down pipe part,
A drain valve provided downstream of the drain trap pipe and closed during cleaning to retain cleaning water in the soot treatment chamber and the drain trap pipe;
When the drainage valve is closed and the soot treatment device is cleaned, an air retention preventing means for preventing air from staying between the soot discharge part and the drainage valve;
A wrinkle treatment device characterized by comprising:   2. The soot treating apparatus according to claim 1, wherein the air retention preventing means is a bypass pipe that communicates the upper part of the rising pipe part with the downstream side of the drain valve.   2. The soot treating apparatus according to claim 1, wherein the air retention preventing means is an exhaust pump that exhausts air accumulated in an upper portion of the rising pipe portion.   4. The apparatus according to claim 1, further comprising: a cleaning time determination unit that determines when the heel treatment apparatus should be cleaned, and a notification unit that notifies the user that the cleaning time has arrived.厨 芥 treatment equipment.   5. The soot processing device according to claim 4, wherein the cleaning time determination means determines the time to clean the soot processing device based on the number of times the soot processing device is used after the most recent cleaning.   The wrinkle treatment device according to claim 4, wherein the cleaning time determination means determines the time when the wrinkle treatment device should be cleaned based on an elapsed time after the most recent cleaning.   5. The dirt sensor according to claim 4, further comprising a dirt sensor for detecting dirt in the soot processing chamber, wherein the cleaning time determination means determines the time for cleaning the soot processing apparatus based on a detection result of the dirt sensor.厨 芥 Treatment equipment.   Furthermore, it has a flow rate sensor for detecting the flow rate of the waste water flowing in the pipe line downstream of the soot discharge section, and the cleaning time determination means should clean the soot treatment device based on the detection result of the flow rate sensor. The soot processing apparatus of Claim 4 which determines time. A sealing device that causes the soot and washing water crushed by the soot treatment device main body to flow into the drain pipe, and seals between the soot treatment device main body and the drain pipe,
A drain trap pipe formed so as to communicate with the soot discharge portion of the soot treating apparatus body, and having a down pipe portion that goes downward from the soot discharge portion and an up pipe portion that goes upward from the lower end of this down pipe portion; ,
A drain valve provided downstream of the drain trap pipe and closed when cleaning the main body of the soot treatment device;
When the drainage valve is closed and the soot treatment device main body is cleaned, an air retention preventing means for preventing air from being retained between the soot discharge part and the drainage valve;
A water-sealing device for a cocoon treatment device, comprising:

Images