JP5054959B2 - Sludge concentrator and sludge concentrator equipped with the same - Google Patents

Description

  The present invention relates to a sludge concentrating device that concentrates and collects septic tank sludge, industrial waste sludge, and the like, and a sludge concentrating vehicle equipped with the same.

  Conventionally, septic tank sludge, industrial waste sludge, etc. (hereinafter simply referred to as “sludge”) are collected regularly (once a year) or as needed by sludge trucks and sent to designated disposal sites. Being transported. In the case of the above-mentioned septic tank sludge, sewerage is spreading nationwide in urban areas, but it is declining, but it is difficult to disseminate sewage equipment to mountain villages etc. away from urban areas, and septic tank sludge increases in such areas. Tend to. This is due to the widespread use of a combined septic tank that treats domestic wastewater from a conventional single septic tank only for human waste. However, in the case of the septic tank sludge, since a large amount of water is collected together with the sludge, the sludge collection vehicle having a limited tank capacity has few septic tanks that can collect sludge in one collection operation, and the operation efficiency is very poor. .

  Therefore, a sludge concentrating vehicle that collects only the solid content in the collected sludge and attempts to improve operational efficiency has been proposed. In the case of this sludge concentrating vehicle, a sludge separator provided with a screen is provided apart from the tank (see, for example, Patent Document 1).

In addition, as another conventional technique, there is a tank in which a stock solution tank and a sludge tank are integrated, and a flat elliptical trick-type small drum screen with a rotating shaft inclined above the sludge tank (for example, , See Patent Document 2).
Japanese Patent Laid-Open No. 2004-100221 (Page 7, FIGS. 2 and 3) Japanese Utility Model Publication No. 61-45920 (page 3-4, FIG. 4)

  However, since Patent Document 1 has a configuration in which a sludge separator provided with a screen is installed apart from a tank, each configuration is connected by a very large number of pipes, and many of them open and close those pipes. This valve is required. Therefore, in this patent document 1, a lot of time and labor are required for connection of pipes at the time of manufacture, and complicated opening / closing operations of these pipes are required at the time of operation. However, the number of skilled workers is greatly reduced, making it difficult to operate efficiently, and it is difficult to operate an efficient sludge concentrating vehicle.

  In the case of Patent Document 2 as well, a plurality of pipes connected to a drum screen provided above the tank extend to the upper part of the tank, and many valves for opening and closing the pipes need to be provided around the tank. Therefore, this Patent Document 2 also requires a lot of time and labor for connecting pipes at the time of manufacture, and complicated opening and closing operations of these pipes are necessary at the time of operation. However, the number of skilled workers is greatly reduced, making it difficult to operate efficiently, and it is difficult to operate an efficient sludge concentrating vehicle.

  This also applies to sludge concentrators other than sludge concentrators, and the number of skilled workers is greatly reduced, making it difficult to operate efficiently, and the efficient operation of sludge concentrators is difficult.

  On the other hand, as mentioned above, there are many mountain villages that leave the urban area where septic tanks remain, so by concentrating sludge, the number of septic tanks that can collect sludge in one collection operation is increased to increase operational efficiency. There is also a demand to collect only sludge quickly in a place where it is not installed and to collect it more efficiently.

  Furthermore, when collecting sludge with a sludge concentrating vehicle, the vehicle is usually stopped at the left end of the road on the left-handed road, and in that case, the space on the left side of the vehicle for the worker to collect the work. Will disappear.

  Then, an object of this invention is to provide the sludge concentration apparatus which can perform efficient sludge collection | recovery in a sludge tank easily from the back of a concentration apparatus, and a sludge concentration vehicle provided with the same.

In order to achieve the above object, a sludge concentrating apparatus of the present invention comprises a tank in which a sludge tank and a reaction tank are separated by a partition, a pump for depressurizing or pressurizing the inside of the tank, and a communication between the pump and the inside of the tank. Alternatively, a suction switching valve for shutting off is provided, and a pressure switching valve operating section for switching the suction switching valve is disposed at the rear of the tank. Thereby, the suction switching valve can be operated from the rear side of the tank by the pressure switching valve operating section to allow the pump and the reaction tank to communicate with each other. Further, the tank is provided with a tank switching valve for communicating the sludge suction pipe for sucking the raw sludge water and the sludge tank or the reaction tank, or the tank switching valve for communicating the sludge tank and the reaction tank. It is disposed to the rear of the tank vessel changeover valve operating section for performing. The “raw sludge water” in the specification and the claims is “sludge water” including “sludge”, and refers to “sludge” to be sucked. Thereby, the tank switching valve operation unit can be operated from the rear of the tank to connect the sludge suction pipe and the sludge tank, the sludge tank and the reaction tank, and the suction switching valve operated by the pressure switching valve operation unit. By switching these valves according to the operation of the pump and sucking the air in the reaction tank with a pump to reduce the pressure, the vacuum function of sucking the raw sludge water from the sludge suction pipe to the sludge tank is demonstrated and the sludge separation means It is possible to exert a concentration function of sucking and concentrating the sewage separated into the reaction tank.

  Moreover, if the operation part of the pressurization valve which opens and closes the sludge suction pipe is arranged at the rear part of the tank, the operation of opening and closing the sludge suction pipe side can be easily performed from the rear of the tank.

  Further, if an intake pipe and an intake valve for opening and closing the intake pipe are provided between the tank switching valve and the pressurizing valve, and an operation part of the intake valve is disposed at the rear part of the tank, the intake pipe is introduced into the reaction tank. When air is sucked from the tank, the intake valve can be easily opened and closed from the rear of the tank. Further, the intake pipe can be used to suck sludge water without going through the sludge suction pipe.

  In addition, a rotation speed operation unit for changing the rotation speed of the pump may be disposed at the rear of the tank. Thereby, the pressure in a sludge tank and the pressure in a reaction tank can be changed by operating a pump rotation speed, and an efficient sludge collection operation | work can be performed.

Furthermore, the pressure-switching valve operating section constituted by pressure-switching valve control lever, said tank selector valve operating section constituted by the bath switching valve operating lever, connecting the intake 引切 Kawaben and piezoelectric switching valve control lever The tank switching valve and the tank switching valve operating lever may be connected by a connecting member, and the pressure switching valve operating lever and the tank switching valve operating lever may be provided side by side on the tank. Thus, the operator can efficiently perform the sludge collection work by operating the operation levers arranged side by side at the rear side of the tank at the same position.

  On the other hand, the sludge concentration vehicle of the present invention includes any one of these sludge concentration apparatuses. By providing such a sludge concentrating device in the sludge concentrating vehicle, the vehicle can be stopped at the left end of the road and the sludge concentrating device can be operated from the rear of the vehicle to efficiently collect the sludge up to the maximum capacity of the tank. A good sludge concentrating vehicle can be constructed.

  According to the present invention, it is possible to provide a sludge concentrator capable of efficiently performing a sludge collecting operation by operating the sludge concentrator from the rear of the tank by means as described above.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. 1 is a side view showing a sludge concentrating vehicle according to an embodiment of the present invention, FIG. 2 is a plan view of the sludge concentrating vehicle shown in FIG. 1, and FIG. 3 is a plan view of the sludge concentrating vehicle shown in FIG. It is a rear view. The overall configuration of the sludge concentration vehicle 1 equipped with the sludge concentration device 20 will be described based on these drawings. In the following description, the front side, rear side, left side, and right side refer to the front side, rear side, port side, and starboard side of the vehicle. Further, “primary sewage” in the specification and claims refers to “sewage” obtained by separating “sludge” from the “original sludge water”, and “secondary sewage” refers to this “primary sewage”. This refers to “sewage” obtained by separating “sludge” that has been floculated by agglomeration reaction from “muddy water”.

  As shown in FIG. 1, a traveling engine E is provided below the driver seat 2 of the sludge concentrating vehicle 1, and the engine E is provided with a PTO 21 (Power Take Off) for taking out power. A vehicle body frame 3 is provided rearward from the driver's seat 2, a sub-frame 4 is provided above the vehicle body frame 3, and a sludge concentrating device 20 is mounted on the frames 3 and 4.

  The tank 5 of the sludge concentrating device 20 is provided on the subframe 4. The tank 5 includes two tanks, a reaction tank 7 and a sludge tank 8 which are formed so as to extend in the front-rear direction of the vehicle and separated by a partition wall 6 in the front-rear direction. A reaction tank 7 is provided on the front side of the vehicle, and a sludge tank 8 is provided on the rear side. A hose reel 9 for sucking raw sludge water into the tank 5 is provided at the upper part of the tank 5. The hose reel 9 stores, for example, several tens of meters of sludge suction pipe (resin hose, etc., “51” shown in FIG. 7).

As shown in FIGS. 1 and 2, on the left side of the rear portion of the tank 5 , there is provided a tank switching valve 45 of a four-way valve that switches when sucking raw sludge water or discharging sewage into the tank 5 . The tank switching valve 45 includes a fourth sludge pipe 47 connected to a sludge suction pipe 51 described later, a second sludge pipe 44 for sucking raw sludge water and the like into the sludge tank 8, and sewage from the sludge tank 8. The 3rd sludge pipe | tube 46 which discharges and the 1st sludge pipe | tube 43 connected to the inside of the reaction tank 7 are connected. The fourth sludge pipe 47 is provided with a pressurizing valve 49, an intake pipe 97 is provided at the vehicle rear position of the fourth sludge pipe 47, and an intake valve 98 is provided in the intake pipe 97. The intake valve 98 has an opening toward the rear of the vehicle.

In addition, the left front of the tank 5, the suction-pressure switching valve 25 (suction switching valve) of the four-way valve for switching when applying vacuum or pressure to the tank 5 is provided. An oil separator 13, an air separator 15, an air release pipe 26, and an overflow safety valve 14 are connected to the suction / pressurization switching valve 25. The overflow safety valve 14 is connected to the upper part of the reaction tank 7 via the float valve 10. Detailed piping of these configurations will be described later.

Further, a flocculant tank 12 is provided on the left side of the vehicle, and a flocculant tank 12 and a water tank 16 are provided on the right side of the vehicle as shown in FIG. Further, a drum screen 11 as a sludge separation means is provided in the upper part of the sludge tank 8. The details of this drum screen 1 1 will be described later. As shown in FIG. 1, a confirmation pipe 18 for confirming the amount of primary sewage in the reaction tank 7 is provided on the left side of the tank 5, and the amount of sludge stored in the sludge tank 8 is confirmed at the rear of the tank 5. A confirmation tube 19 is provided. The confirmation pipes 18 and 19 are formed of a transparent pipe at the center between the connecting fittings 17 provided on the upper and lower sides.

  As shown in FIGS. 1 and 3, on the left side of the rear part of the tank 5, a pressure switching valve operating lever 101 as a pressure switching valve operating unit for operating the suction / pressurization switching valve 25, and the tank switching A tank switching valve operation lever 102 serving as a tank switching valve operation unit for operating the valve 45 is provided. These operation levers 101 and 102 are provided on a lever mounting plate 103 projecting from the tank 5 toward the left side, and are arranged side by side. The pressure switching valve operating lever 101 is connected to the suction / pressurization switching valve 25 by a rod-shaped connecting member 104, and the tank switching valve operating lever 102 is connected to the tank switching valve 45 by a rod-shaped connecting member 105. . In addition, you may comprise this connection member 104,105 with a link, a wire cable, etc. The pressure switching valve operating lever 101 and the tank switching valve operating lever 102 are rotated in a plane orthogonal to the axial direction of the connecting members 104 and 105, so that the suction / pressurization switching valve 25 and the tank switching valve 45 are controlled. Switching operation can be performed. In this embodiment, by configuring the pressure switching valve operation section and the tank switching valve operation section with the operation levers 101 and 102, the configuration can be simplified and each valve can be switched with a simple operation. Yes. The pressure switching valve operation section and the tank switching valve operation section may be switches other than the operation levers 101 and 102, and the suction / pressure switching valve is driven by a motor by ON / OFF operation of the switch. 25, the tank switching valve 45 may be switched.

In this embodiment, the suction / pressurization switching valve 25 and the pressure switching valve operating lever 101 serving as the pressure switching valve operating section, and the tank switching valve 45 and the tank switching valve operating lever 102 serving as the tank switching valve operating section, are provided at separate positions, these suction-pressure switching valve 25 and the pressure-switching valve operating lever 101, and the tank selector valve 45 and the tank switching valve lever 102 of the tank 5 is formed integrally with each You may arrange | position in a rear part. In this embodiment, the pressurizing valve 49 and the intake valve 98 are arranged at the rear part of the tank 5. However, the pressurizing valve 49 and the intake valve 98 are arranged at a position away from the rear part of the tank 5. Only the operation part connected by the connecting members 104 and 105, the link, the wire cable, or the like may be disposed in the rear part of the tank 5 .

  Further, below these operation levers 101 and 102, an instrument mounting portion 106 projects from the subframe 4 toward the left side. The instrument mounting portion 106 includes a tank pressure gauge 107 that displays the pressure in the reaction tank 7, a tank pressure gauge 108 that displays the pressure in the sludge tank 8, and the rotational speed of the engine E manually. A throttle lever 109 is provided as a rotation speed operation unit for raising and lowering the rotation speed of the pump 22 (see FIG. 7). By providing these pressure gauges 107 and 108 and the throttle lever 109 in the vicinity of the operation levers 101 and 102, the pressure in the sludge tank 8 and the pressure in the reaction tank 7 that are preferable for the work during the sludge collection work described later. The valves 25 and 45 are operated while being adjusted to enable efficient sludge collection work.

  In this way, by providing the valves 25, 45, 49, and 98 in a concentrated manner on the left side of the rear portion of the sludge concentrating device 20, the worker can stop the sludge concentrating vehicle 1 at the left end of the road, The sludge collecting work can be efficiently performed by operating the valves 25, 45, 49, and 98 on the rear left side of 1.

  4 (a) is a rear view of a partial cross-section of the state in which the drum screen provided in the sludge concentrating vehicle in FIG. 1 is removed as seen from the rear of the vehicle, and FIG. FIG. 5 is a view showing a state in which the drum screen provided in the sludge concentrating vehicle of FIG. 1 is removed, and is a view taken along arrows VV shown in FIG.

  As shown in FIGS. 4 (a), 4 (b) and 5, a hollow rectangular mounting base 62 is fixed to the upper part of the sludge tank 8 and protrudes a predetermined amount upward from the outer surface of the sludge tank 8. A mounting flange 63 is provided at the upper end of the mounting base 62. The drum screen 11 provided in the sludge tank 8 from the attachment port 61 provided in the central portion of the attachment base 62 includes a rotary drum 67 supported by a lower portion of an upper plate 64 fixed to the tank 5, and the rotary drum. 67, and a scraper 79 that scrapes off the sludge adhering to the surface of the screen main body 69 on the sludge discharge side (the right side in FIG. 4A) of the screen main body 69. The drum screen 11 is integrally inserted into the sludge tank 8 from the mounting opening 61, and the upper plate 64 is fixed to the mounting flange 63 with bolts 65.

  The rotary drum 67 is provided between two drum mounting plates 66 provided so as to protrude downward from the lower surface of the upper plate 64 so as to be rotatable about a horizontal rotation shaft. The rotating drum 67 is driven by the hydraulic motor 40. Further, as shown in FIG. 4A, a support frame 76 is provided between the drum mounting plates 66, and a hinge 77 with a spring material as shown in FIG. A scraper frame 78 is provided. A scraper 79 is provided at the lower end of the scraper frame 78 and is pressed toward the screen main body 69 by the hinge 77 with a spring material.

  According to the drum screen 11 configured as described above, the configuration of the rotating drum 67, the screen main body 69, the scraper 79, etc. is integrated from the sludge tank 8 by removing the bolt 65 that fixes the upper plate 64 to the mounting flange 63. Can be removed. In addition, by providing the drum screen 11 as the sludge separation means inside the sludge tank 8, the configuration for sealing the drum screen 11, the piping for supplying / discharging sludge water to the drum screen 11, and the switching valve The configuration can be simplified by reducing the number. In addition, the switching valve can be reduced by simplifying the piping configuration.

  On the other hand, in the upper part of the sludge tank 8 where the drum screen 11 is provided, a water container 38 is provided between the two support frames 72 provided downward from the mounting base 62. The water container 38 is for storing the sewage (separated water) after the sludge is separated by the screen body 69, and is sized so that a predetermined amount of water can be stored in the lower part of the screen body 69. Is formed. The water container 38 is provided such that the screen surface passes through the water stored in the water container 38 when the screen main body 69 rotates. The water container 38 in this example is formed in a bowl shape extending between the support frames 72.

  Further, as shown in FIG. 4 (a), sludge water formed by a side wall 91 and a bottom wall 92 fixed to the peripheral wall of the sludge tank 8 is formed on the left side portion of the sludge tank 8 where the drum screen 11 is provided. A diffusion unit 90 is provided. A supply pipe 93 connected to the second sludge pipe 44 (see FIG. 2) of the tank switching valve 45 provided at the side of the sludge tank 8 is connected to the sludge water diffusion section 90. The supply pipe 93 extends laterally into the sludge tank 8 from the tank switching valve 45, bends upward below the sludge water diffusion part 90, and opens inside the sludge water diffusion part 90.

  Further, a drain pipe 95 extending in the horizontal direction is provided on the lower left side of the water container 38. The drain pipe 95 extends in the horizontal direction from the water container 38 and is provided with a pipe flange 96 at a portion protruding to the outside of the sludge tank 8. The third sludge pipe 46 is connected to the pipe flange 96 (see FIGS. 1 and 2). The configurations relating to the water container 38, the sludge water diffusion section 90, the supply pipe 93, and the drain pipe 95 are provided on the sludge tank 8 side. Further, a stop valve 80 is provided in a portion of the drain pipe 95 in the sludge tank 8.

  6 is a drawing of a stop valve provided on the downstream side of the drum screen shown in FIG. 4, wherein (a) is a sectional view in plan view, (b) is a side view, and (c) is a side view during operation. It is. As shown in the figure, the stop valve 80 is provided with a pipe body 81 having a predetermined length with flanges provided at both ends so that the stop valve 80 can be provided in the middle of the drain pipe 95. Inside the tubular body 81, partition walls 83 provided with circular openings 82 having a predetermined diameter are provided on the upstream side and the downstream side. A ball 84 having a predetermined diameter is placed between the partition walls 83 so as to be freely movable. The ball 84 is formed with a diameter larger than the diameter of the opening 82 provided in the partition wall 83. When the ball 84 is in contact with the circular opening 82 formed in the partition wall 83, the ball 84 comes into contact with the periphery of the opening 82 and closes the entire surface. Therefore, if the ball 84 closes the opening 82 of the partition wall 83 on the downstream side, the flow of sewage is stopped. If the ball 84 closes the opening 82 of the partition wall 83 on the upstream side, the backflow of sewage is stopped.

  On the other hand, on the downstream side of the partition wall 83 on the downstream side, a swing shaft 85 that penetrates in a direction orthogonal to the axial direction of the tube body 81 is provided. A float 86 that swings integrally with the swing shaft 85 is provided. In this embodiment, the float 86 is provided at both ends of the swing shaft 85 so that the float 86 moves up and down according to the amount of sludge stored on both sides of the tubular body 81. A support pin 88 is provided at the lower portion of the tube body 81 to prevent rocking at a predetermined position when the float 86 is lowered by its own weight.

  In addition, a stopper 87 that swings integrally with the swing shaft 85 is provided at the center of the swing shaft 85. The stopper 87 is provided so as to be positioned substantially at the center of the opening 82 provided in the partition wall 83 when the float 86 is supported by the support pin 88. When the float 86 rises and the swing shaft 85 rotates, the stopper 87 swings toward the downstream side from a position substantially at the center of the opening 82 and moves away from the partition wall 83 to the downstream side (see FIG. 6 (c)).

  Therefore, when the float 86 is lowered, the stopper 87 is positioned substantially at the center of the opening 82. Even if the ball 84 is pushed by the sewage and flows downstream, the stopper 87 abuts on the stopper 87 and the opening 82 is opened. Sewage flows because it does not block. On the other hand, when the float 86 is raised, the stopper 87 moves from the center of the opening 82 to the downstream side and leaves the opening 82, so that the ball 84 pushed by the sewage closes the entire surface of the opening 82 and the sewage flows. Stop. Note that a sealing material 89 is provided at a connection portion between the upstream pipe 81 and the drain pipe 95 where the pressure rises when the flow of sewage is stopped by the stop valve 80. The stop valve 80 can be incorporated in the middle of the pipe, and has a compact and simple configuration.

  As described above, when the amount of sludge collected in the sludge tank 8 exceeds a predetermined amount and the float 86 is pushed up, the stop valve 80 automatically closes the opening 82 and stops the flow of sewage. It is constituted by a float type stop valve 80 which eliminates the pressure change in the sludge tank 8 and prevents the sludge water from flowing into the sludge tank 8. Thereby, when the sludge in the sludge tank 8 reaches a full amount (for example, a predetermined amount of about 80 to 90%), it can be automatically stopped so as not to collect more sludge.

  FIG. 7 is a piping system diagram of the sludge concentrating device mounted on the sludge concentrating vehicle shown in FIGS. FIG. 7 illustrates a state when the raw sludge water in the septic tank is sucked. A piping system of the sludge concentrator 20 will be described below with reference to FIG. A pump 22 driven by the power extracted by the PTO 21 is provided, and air is sucked into the pump 22 via a check valve 23. An oil separator 13 is provided on the discharge side of the pump 22 to remove oil in the discharged air. On the downstream side of the oil separator 13, the inside of the reaction tank 7 and the sludge tank 8 of the tank 5 is decompressed (negative pressure) by discharging air from the pump 22 to the discharge pipe 24, or the inside of the reaction tank 7 and the sludge tank. The suction / pressurization switching valve 25 is provided for switching when pressurizing the inside. The atmosphere release pipe 26 connected to the suction / pressurization switching valve 25 is open to the atmosphere 27. The discharge pipe 24 is provided with a branch pipe 28, and the branch pipe 28 is provided with a relief valve 29 that opens at a predetermined set pressure. The relief valve 29 is set to a set pressure that allows the air discharged from the pump 22 to escape to the atmosphere 27 when the pressure on the suction / pressurization switching valve 25 side increases. On the upstream side of the check valve 23, there is provided an on-off valve 30 that is normally closed for use during maintenance inspections.

  The suction / pressurization switching valve 25 is connected to a first air pipe 31 that communicates with the check valve 23 and a second air pipe 32 that communicates with the tank 5 side. By switching the suction / pressurization switching valve 25, the first air pipe 31, the second air pipe 32, the discharge pipe 24, and the atmosphere release pipe 26 are switched. The first air pipe 31 is provided with an air separator 15. With such a pipe configuration, the pump 22 can perform pressure reduction for sucking air in the reaction tank 7 and the sludge tank 8 and pressure for discharging air into the reaction tank 7 and the sludge tank 8. It is like that.

  Further, the second air pipe 32 is connected to a third air pipe 33 communicating with the reaction tank 7 of the tank 5 and a fourth air pipe 34 communicating with the sludge tank 8. The third air pipe 33 has a float valve 10 that stops the flow of fluid to the pump 22 side when the reaction tank 7 is full, and does not flow to the pump 22 side even if sludge or water overflows from the float valve 10. An overflow safety valve 14 is provided. Further, the fourth air pipe 34 is provided with a check valve 35 for preventing reverse flow of air.

  According to these structures, it functions as follows. When the suction / pressurization switching valve 25 is switched to the left suction position a shown in the figure, the discharge pipe 24 of the pump 22 and the atmosphere release pipe 26 communicate with each other, and the first air pipe 31 and the second air pipe 32 communicate with each other. To do. If the pump 22 is driven in this state, the air in the reaction tank 7 is sucked into the second air pipe 32 and the first air pipe 31 via the third air pipe 33, and the air separator 15 and the oil separator 13 are connected. Through the discharge pipe 24 and released from the atmosphere open pipe 26 to the atmosphere 27. Further, when the suction / pressurization switching valve 25 is switched to the middle positive position b in the center, the atmosphere release pipe 26 and the second air pipe 32 communicate with each other, and the discharge pipe 24 of the pump 22 and the first air pipe 31 communicate with each other. . In this state, the reaction tank 7 and the sludge tank 8 are open to the atmosphere via the second air pipe 32 and the open air pipe 26. Further, when the suction / pressurization switching valve 25 is switched to the right pressurization position c shown in the figure, the discharge pipe 24 of the pump 22 and the second air pipe 32 communicate with each other, and the atmosphere release pipe 26 and the first air pipe 31 Communicate. When the pump 22 is driven in this state, the atmosphere is sucked into the pump 22 from the atmosphere opening pipe 26 via the first air pipe 31, and the pressurized air discharged from the pump 22 is discharged into the discharge pipe 24, suction / pressurization switching. Via the valve 25 and the second air pipe 32, the third air pipe 33 is supplied to the reaction tank 7 and the fourth air pipe 34 is supplied to the sludge tank 8.

  The hydraulic motor 40 that rotates the rotating drum 67 of the drum screen 11 provided in the sludge tank 8 is driven by oil supplied from the hydraulic pump 39 driven by the PTO 21. 41 shown is a relief valve set to a predetermined pressure, and 42 is an oil tank.

  On the other hand, between the reaction tank 7 and the sludge tank 8, a first sludge pipe 43 provided in the reaction tank 7 and a second sludge that supplies raw sludge water or primary sludge water to the drum screen 11 in the sludge tank 8. The tank switching valve 45 that communicates with or shuts off the pipe 44 is provided. The tank switching valve 45 is connected to a third sludge pipe 46 for discharging primary sewage or secondary sewage from the water container 38 of the drum screen 11 and a fourth sludge pipe 47 connected to the hose reel 9. Has been. In this figure, the stop valve 80 is provided in the third sludge pipe 46. The fourth sludge pipe 47 is provided with a pressurizing valve 49 that closes when the inside of the tank 5 is pressurized. Between the pressurizing valve 49 and the tank switching valve 45, an intake pipe 97 and the intake pipe are provided. An intake valve 98 that opens and closes 97 is provided. Further, an air suction valve 48 for sucking air into the sludge tank 8 is provided above the sludge tank 8, and a sludge suction pipe 51 extending to the septic tank 50 is provided on the hose reel 9. .

  Further, a flocculant supply pipe 55 is connected to the first sludge pipe 43, and the flocculant supply pipe 55 is connected to the flocculant tank 12 through a flocculant valve 56. When supplying the flocculant, a necessary amount of flocculant can be sucked from the flocculant tank 12 into the depressurized reaction tank 7 by opening or closing the flocculant valve 56 manually or automatically.

  According to these structures, it functions as follows. When the tank switching valve 45 is switched to the right sludge tank position d shown in the figure, the fourth sludge pipe 47 and the second sludge pipe 44 communicate with each other, and the third sludge pipe 46 and the first sludge pipe 43 communicate with each other. If the inside of the reaction tank 7 is depressurized in this state, the inside of the sludge tank 8 is depressurized via the first sludge pipe 43 and the third sludge pipe 46, and the second sludge pipe 44, the fourth sludge pipe 47, and the sludge suction pipe 51. The raw sludge water is sucked from the septic tank 50 to the drum screen 11 in the sludge tank 8 through The primary sewage from which the sludge has been separated by the drum screen 11 is sucked into the reaction tank 7 from the water container 38 through the third sludge pipe 46 and the first sludge pipe 43. Further, if the tank switching valve 45 is switched to the left reaction tank position f shown in the figure, the first sludge pipe 43 and the fourth sludge pipe 47 communicate with each other, and the second sludge pipe 44 and the third sludge pipe 46 communicate with each other. To do. In this state, the reaction tank 7 is opened to the atmosphere via the first sludge pipe 43 and the intake pipe 97. Further, when the tank switching valve 45 is switched to the intermediate two tank connection position e shown in the figure, the first sludge pipe 43 and the second sludge pipe 44 communicate, and the third sludge pipe 46 and the fourth sludge pipe 47 communicate. To do. If the inside of the reaction tank 7 and the sludge tank 8 is pressurized in this state, the inside of the sludge tank 8 communicates with the sludge suction pipe 51 via the third sludge pipe 46 and the fourth sludge pipe 47. 7 is pumped to the drum screen 11 in the sludge tank 8 through the first sludge pipe 43 and the second sludge pipe 44.

  Further, a discharge valve 53 is provided at the lower part of the sludge tank 8, and the sludge stored in the sludge tank 8 is sludge discharged from the sludge tank 8 by opening the discharge valve 53 and pressurizing the sludge tank 8. It is discharged to the disposal site 54 through 52.

  Further, the sludge concentrating device 20 of this embodiment is provided with a cleaning device 59 for injecting water in the water tank 16 from an injection nozzle 58 by a pump 57. With this cleaning device 59, the inside of the septic tank 50 can be cleaned or the hands of workers can be cleaned.

  The pump 22, the hydraulic motor 40 and the like are provided below the tank 5 in the rear part of the driver seat 2 shown in FIGS. 7 that appear in FIGS. 1 and 2 are denoted by the same reference numerals in FIGS.

  FIG. 8 is a work content diagram in the configuration of the piping system diagram shown in FIG. As shown in FIG. 8, main sludge collection work for sucking and concentrating septic tank sludge by the sludge concentrator 20 is as follows: raw sludge water suction, agglomeration reaction, release to the atmosphere, sludge concentration, discharge valve discharge. There is one. FIG. 8 summarizes these operations, the operation state of each valve at the time of each operation, the internal pressure of the sludge tank 8 and the reaction tank 7, and the presence or absence of sludge water in a list format. Hereinafter, details of the operations in each column will be described with reference to FIGS.

  FIG. 9 is a piping system diagram at the time of raw sludge water suction in the work content diagram shown in FIG. 8, FIG. 10 is a piping system diagram at the time of agglomeration reaction in the reaction tank in the work content diagram shown in FIG. 8 is a piping system diagram when the atmosphere is released in the work content diagram shown in FIG. 8, FIG. 12 is a piping system diagram when sludge is concentrated in the work content diagram shown in FIG. 8, and FIG. 13 is a discharge valve in the work content diagram shown in FIG. It is a piping system figure at the time of discharge from.

  As shown in FIG. 9, when the raw sludge water is sucked, the tip of the sludge suction pipe 51 is inserted into the septic tank 50, the pressurizing valve 49 is opened, the intake valve 98 is closed, and the tank switching valve 45 is connected to the sludge tank. The suction / pressure switching valve 25 is switched to the suction position a by switching to the position d. Then, by driving the pump 22, the air in the reaction tank 7 is sucked and the pressure in the reaction tank 7 is reduced. As a result, the inside of the sludge tank 8 is depressurized via the first sludge pipe 43 and the third sludge pipe 46, and the sludge tank 8 is passed through the fourth sludge pipe 47 and the second sludge pipe 44 from the sludge suction pipe 51. Raw sludge water is sucked into the drum screen 11 provided. The sucked raw sludge is separated by the screen body 69 of the drum screen 11, and the primary sludge from which the sludge has been separated passes from the water container 38 through the third sludge pipe 46 and the first sludge pipe 43. And sucked into the reaction vessel 7. This is a path for sucking raw sludge water from the sludge suction pipe 51 into the sludge tank 8 and separating the sludge with the drum screen 11, and the primary sludge separated with the drum screen 11 from the sludge tank 8. And a path for suctioning into the reaction tank 7. By this operation, sludge is stored in the sludge tank 8 and primary sludge is stored in the reaction tank 7.

  By this operation, primary sludge water sucked into the tank 5 is subjected to primary filtration, and scum, precipitated sludge, and the like in the septic tank 50 are stored in the sludge tank 8 from the drum screen 11 and filtered through the drum screen 11. Only the sewage is sucked into the reaction tank 7. The suction of raw sludge water by this operation is a vacuum function, and scum and precipitated sludge can be efficiently sucked into the sludge tank 8. Moreover, only one sludge can be efficiently stored in the sludge tank 8 through the drum screen 11 in the original sludge water having a large amount of sludge and the raw sludge having a small amount of sludge by one suction operation. Since only the sewage can be sucked, efficient raw sludge water suction and sludge separation can be performed continuously.

  Further, when the sludge content separated from the raw sludge water and stored in the sludge tank 8 by this work reaches a predetermined amount, the float 86 of the stop valve 80 is pushed up as shown in FIG. The moving shaft 85 rotates and the stopper 87 located at the position of the opening 82 of the partition wall 83 moves downstream and leaves the opening 82. As a result, the ball 84 provided in the tube 81 is pushed downstream by the primary sewage to block the entire surface of the opening 82 and the flow of the primary sewage in the third sludge pipe 46 is stopped. When the flow of primary sewage in the third sludge pipe 46 is stopped in this way, the pressure in the sludge tank 8 becomes the same normal pressure as the pressure on the septic tank 50 side, so that the sludge suction pipe 51 enters the sludge tank 8. The raw sludge water suction stops, and the sludge suction into the sludge tank 8 stops. When this stop valve 80 is operated, the sludge tank 8 is in a state where the maximum amount of sludge is stored, and efficient sludge collection using the capacity of the sludge tank 8 can be performed easily.

  In this operation, even if the operation of the suction / pressurization switching valve 25 is mistakenly pressurized in the reaction tank 7, the stop valve is caused by the sewage pumped from the first sludge pipe 43 to the third sludge pipe 46. 80 balls 84 close the opening 82 of the partition wall 83 on the upstream side to prevent the backflow of sewage.

  As shown in FIG. 10, at the time of agglomeration reaction of the primary sewage sucked into the reaction tank 7, the pressurization valve 49 of the fourth sludge pipe 47 is closed and the intake valve 98 of the intake pipe 97 is opened, and the tank switching valve 45 reacts. It is switched to the tank position f. The suction / pressurization switching valve 25 is at the suction position a, and the air in the reaction tank 7 is sucked by driving the pump 22. Thus, air is sucked into the reaction tank 7 from the intake pipe 97, and the primary sewage in the reaction tank 7 is agitated (aerated). This is a path for sucking air and stirring the primary sewage in the reaction tank 7. Further, the flocculant valve 56 is opened, and a predetermined amount of the flocculant is sucked into the reaction tank 7 from the flocculant tank 12. The amount of the flocculant is determined by the amount of primary sewage sucked into the reaction tank 7 or the like. In this way, the flocculant is supplied to the primary sewage in the reaction tank 7 and air agitation is performed to promote the flocculation reaction of the primary sewage, so that the sludge content in the primary sewage becomes floc. During this operation, there is sludge in the sludge tank 8 and primary sewage in the reaction tank 7.

  As shown in FIG. 11, when the atmosphere is released, the tank switching valve 45 is switched to the reaction tank position f, and the suction / pressurization switching valve 25 is switched to the neutral position b. Further, the air intake valve 48 of the sludge tank 8 is also opened. As a result, the third air pipe 33 of the reaction tank 7 communicates with the atmosphere release pipe 26 via the second air pipe 32 and is opened to the atmosphere. Further, the first sludge pipe 43 of the reaction tank 7 can be opened to the atmosphere via the intake valve 98 of the intake pipe 97. In this example, the reaction tank 7 is opened to the atmosphere on the intake pipe 97 side, but the pressure valve 49 of the fourth sludge pipe 47 may be opened to open the reaction tank 7 to the atmosphere on the fourth sludge pipe 47 side. Further, the sludge tank 8 is opened to the atmosphere via the air suction valve 48. These are paths that open the reaction tank 7 and the sludge tank 8 to the atmosphere. During this operation, there is sludge in the sludge tank 8 and primary sewage in the reaction tank 7.

  As shown in FIG. 12, at the time of sludge concentration, the tank switching valve 45 is switched to the two tank connection position e, and the suction / pressure switching valve 25 is switched to the pressure position c. The intake valve 98 of the intake pipe 97 and the air intake valve 48 of the sludge tank 8 are closed, and the pressurization valve 49 of the fourth sludge pipe 47 is opened. Accordingly, the water container 38 provided on the drum screen 11 of the sludge tank 8 is connected to the sludge suction pipe whose tip is inserted into the septic tank 50 via the third sludge pipe 46, the tank switching valve 45, and the fourth sludge pipe 47. 51 is communicated. Then, by driving the pump 22, the atmosphere is sucked into the pump 22 via the suction / pressurization switching valve 25 from the atmosphere opening pipe 26, and the reaction tank 7 is sucked from the pump 22 via the suction / pressurization switching valve 25. Pressurized air is supplied to the inside and the sludge tank 8. At this time, since the inside of the sludge tank 8 communicates with the septic tank 50 under atmospheric pressure as described above, the primary sewage in the pressurized reaction tank 7 becomes the first sludge pipe 43, the tank switching valve 45, the second It is pumped to the drum screen 11 in the sludge tank 8 having a low pressure through the sludge pipe 44. The primary sewage sent to the drum screen 11 is separated by the screen body 69 of the drum screen 11. By this operation, the primary sewage in the reaction tank 7 is pumped into the sludge tank 8 so that there is no primary sewage in the reaction tank 7.

  By this operation, the secondary filtration of the primary sewage is performed, and the floc sludge that has been coagulated in the reaction tank 7 is stored in the sludge tank 8 from the drum screen 11. This is a concentration function for concentrating the sludge from the primary sewage in the reaction tank 7 by the drum screen 11 as the sludge separation means. Moreover, since the secondary sewage filtered by the drum screen 11 is water from which the sludge is further removed from the primary sewage, the third sludge pipe 46, the tank switching valve 45, the fourth sludge pipe 47, Is discharged from the sludge suction pipe 51 as the tanning water of the septic tank 50. This is a path for discharging secondary sewage from the sludge suction pipe 51 to the outside.

  When the floc-like sludge separated from the primary sewage by this operation and stored in the sludge tank 8 reaches a predetermined amount, the float 86 of the stop valve 80 is pushed up as shown in FIG. 6 (c). Then, the swing shaft 85 rotates and the stopper 87 located at the position of the opening 82 of the partition wall 83 moves to the downstream side and moves away from the opening 82. Thereby, the ball 84 provided in the tube 81 is pushed downstream by the sewage to block the entire surface of the opening 82 and the flow of the secondary sewage in the third sludge pipe 46 is stopped. When the flow of secondary sewage in the third sludge pipe 46 is stopped in this way, the pressure in the sludge tank 8 becomes the same as the pressure in the reaction tank 7, and sludge pumping into the sludge tank 8 is stopped. When this stop valve 80 is operated, the sludge tank 8 is in a state where the maximum amount of sludge is stored, and efficient sludge collection using the capacity of the sludge tank 8 can be performed easily.

  In this operation, even if the operation of the suction / pressurization switching valve 25 is mistakenly depressurized in the reaction tank 7, the inside of the sludge tank 8 is connected via the first sludge pipe 43 and the second sludge pipe 44. Is reduced, and the ball 84 of the stop valve 80 closes the opening 82 of the upstream partition wall 83 to prevent the backflow of sewage.

  As shown in FIG. 13, when discharging from the discharge valve 53, at the disposal site 54, the tank switching valve 45 is switched to the reaction tank position f, and the suction / pressure switching valve 25 is switched to the pressure position c. The pressurization valve 49 of the fourth sludge pipe 47 and the intake valve 98 of the intake pipe 97 are closed, and the discharge valve 53 is opened. Then, by driving the pump 22, the atmosphere is sucked into the pump 22 from the atmosphere opening pipe 26 via the suction / pressurization switching valve 25, and the suction / pressurization switching valve 25 and the second air pipe 32 are pumped from the pump 22. Then, pressurized air is supplied from the third air pipe 33 into the reaction tank 7 and from the fourth air pipe 34 into the sludge tank 8. At this time, since the pressurizing valve 49 and the intake valve 98 are closed, the inside of the reaction tank 7 is closed, and the pressurized air is supplied only into the sludge tank 8 and stored in the sludge tank 8 by this pressurized air. The sludge thus discharged is discharged from the discharge valve 53 to the disposal site 54 through the sludge discharge pipe 52. By this operation, the sludge in the sludge tank 8 is surely discharged, and there is no sludge in the sludge tank 8.

  The details of the work contents shown in FIG. 8 are as described above, and a series of sludge collection work performed by such an operation is performed from the rear side of the sludge concentrating vehicle 1 shown in FIGS. , 53, 98 can be easily performed, and the sludge collection work can be efficiently performed in a state where the sludge concentrating vehicle 1 is stopped at the left end of the road.

  In the above-described embodiment, the example in which the sludge water in the septic tank 50 is sucked and concentrated has been described. For example, if the raw sludge water has a low solid content, the tank switching valve 45 is switched to the reaction tank position f. Each of the operations such as suction of sludge is not limited to the operations described above.

  Further, the above-described embodiment shows an example, and various modifications can be made without departing from the gist of the present invention, and the present invention is not limited to the above-described embodiment.

  The sludge concentrating apparatus according to the present invention can be used for collecting sludge for suctioning septic tank sludge, industrial waste sludge and the like by a vacuum function, or simply concentrating and dewatering to improve loading efficiency and transport.

It is a side view which shows the sludge concentration vehicle which concerns on one embodiment of this invention. It is a top view of the sludge concentration vehicle shown in FIG. It is a rear view of the sludge concentration vehicle shown in FIG. (a) is the rear view of the partial cross section which looked at the state which removed the drum screen provided in the sludge concentration vehicle of FIG. 1 from the vehicle rear, (b) is the IV section enlarged view. It is drawing which shows the state which removed the drum screen provided in the sludge concentration vehicle of FIG. 1, and is VV arrow line view shown in FIG. It is drawing of the stop valve provided in the downstream of the drum screen shown in FIG. 4 shown in FIG. 4, (a) is sectional drawing of planar view, (b) is a side view, (c) is a side view at the time of operation | movement. It is. It is a piping system diagram of the sludge concentration apparatus mounted in the sludge concentration vehicle shown in FIGS. FIG. 8 is a work content diagram in the configuration of the piping system diagram shown in FIG. 7. It is a piping system diagram at the time of sludge water suction in the work content diagram shown in FIG. It is a piping system figure at the time of the aggregation reaction in the reaction tank in the work content diagram shown in FIG. FIG. 9 is a piping system diagram when the atmosphere is released in the work content diagram shown in FIG. 8. It is a piping system diagram at the time of sludge concentration in the work content diagram shown in FIG. It is a piping system diagram at the time of discharge from the discharge valve in the work content diagram shown in FIG.

Explanation of symbols

1 ... Sludge concentration vehicle
5 ... Tank
6 ... Bulkhead
7 ... Reaction tank
8 ... Sludge tank
9 ... Hose reel
11 ... Drum screen (sludge separation means)
20 ... Sludge concentrator
22 ... Pump
25 ... Suction / pressurization switching valve
38 ... Water container
45 ... Tank switching valve
50 ... Septic tank
51 ... Sludge suction pipe
52. Sludge discharge pipe
67 ... Rotating drum
69 ... Screen body
79 ... Scraper
80 ... Stop valve
81 ... Tube
82 ... Opening
83 ... Partition wall
84 ... Ball
85 ... Oscillating shaft
86 ... Float
87 ... Stopper
95 ... Drain pipe 101 ... Pressure switching valve operating lever (pressure switching valve operating section)
102 ... Tank switching valve operating lever (tank switching valve operating section)
104, 105 ... connecting member 106 ... instrument mounting part

Claims (6)

A tank in which a sludge tank and a reaction tank are separated by a partition;
A pump for depressurizing or pressurizing the tank;
A suction switching valve for communicating or blocking between the pump and the tank;
A pressure switching valve operating section for switching the suction switching valve is disposed at the rear of the tank ;
The tank is connected to a sludge suction pipe for sucking raw sludge water and the sludge tank or the reaction tank, or a tank switching valve for communicating the sludge tank and the reaction tank is provided, and the tank switching valve is switched. A sludge concentrating device characterized in that a tank switching valve operation section is disposed at the rear of the tank . The sludge concentration apparatus according to claim 1, wherein an operation portion of a pressurizing valve that opens and closes the sludge suction pipe is disposed at a rear portion of the tank. The sludge concentration apparatus according to claim 2 , wherein an intake pipe and an intake valve for opening and closing the intake pipe are provided between the tank switching valve and the pressurizing valve, and an operation part of the intake valve is disposed at the rear part of the tank. The sludge concentration apparatus of any one of Claims 1-3 which arrange | positioned the rotation speed operation part which changes the rotation speed of the said pump in the said tank rear part. The pressure switching valve operating part is configured with a pressure switching valve operating lever, the tank switching valve operating part is configured with a tank switching valve operating lever,
The intake 引切 Kawaben and a piezoelectric switching valve operating lever linked by a linking member, said tank selector valve and the cistern switching valve operating lever linked by a linking member, piezoelectric switching valve operating lever and the tank switching valve The sludge concentration apparatus according to any one of claims 1 to 4 , wherein an operation lever is provided side by side on the tank side. The sludge concentration vehicle provided with the sludge concentration apparatus of any one of Claims 1-5 .

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