JP5419593B2 - Suction car - Google Patents

Description

  The present invention relates to a suction vehicle used for sludge collection work in sewers, manholes, road gutters, etc., and muddy sand collection work in a water purification plant.

  In the past, suction vehicles that collect and collect sludge and muddy water using negative pressure in sludge collection work such as in sewers, manholes, side ditches of roads, and sludge collection work in water purification plants are known. Yes. For example, Patent Document 1 discloses a suction hose inserted in a collection place for a collection target, a receiver tank connected to the suction hose and collecting the collection target, and a first cyclone dust collector connected to the receiver tank. And a suction wheel including a blower connected to the first cyclonic dust collector and a second cyclonic dust collector connected to the downstream side of the blower.

  In this suction wheel, a suction hose connected to the receiver tank is inserted into a collection place, and air in the receiver tank is sucked by a blower to reduce the pressure in the receiver tank. As a result, the collection object such as sludge is collected in the receiver tank. At this time, dust having a relatively low specific gravity and mass that has not been collected in the receiver tank is collected by the first and second cyclone dust collectors.

JP 2007-92481 A

  By the way, after collecting objects to be collected such as sludge and muddy water from sewers, manholes, road gutters and water treatment plants with such a suction vehicle, washing equipment such as sewers, manholes, road gutters and water treatment plants, etc. However, this cleaning requires a high-pressure cleaning device. For this reason, it is necessary to prepare a high-pressure washing device in addition to the suction wheel for the collection work of sludge and the like, and the equipment cost and the transportation cost are increased.

  Therefore, in the present invention, to provide a suction vehicle that can not only recover objects to be collected such as sludge and muddy water from sewers, manholes, side ditches of roads, water purification plants, etc., but also perform washing with high-pressure water. With the goal.

The suction wheel of the present invention includes a receiver tank that collects an object to be collected by suction negative pressure of a blower, a water tank that contains water, a high-pressure washing pump that sucks water in the water tank and discharges it as high-pressure water A power take-out device for taking out the power for driving the blower from the engine for driving the vehicle, and a pump drive mechanism for transmitting the power taken out by the power take-out device to the high-pressure washing pump through the clutch, wherein the pump drive mechanism is The pulley connected to the power take-off shaft of the power take-out device, the pulley connected to the input shaft of the clutch, and the rotation of the pulley connected to the power take-out shaft of the power take-out device to the input shaft of the clutch A belt that transmits to a connected pulley, and the high pressure washing pump is connected to an output shaft of the clutch .

According to the present invention, it is possible to drive the high pressure washing pump by the power take-off device with the clutch of the pump drive mechanism in the connected state, and to suck the water in the water tank and discharge it as high pressure water by this high pressure washing pump. It becomes. When the clutch is engaged, the high pressure washing pump has a driving force of the power take-off shaft of the power take-off device via a pulley connected to the power take-out shaft of the power take-off device, a belt, a pulley connected to the input shaft of the clutch, and the clutch. It operates by being transmitted.

  The suction wheel of the present invention transmits the first pulley connected to the power take-off shaft of the power take-off device, the second pulley connected to the drive shaft of the blower, and the rotation of the first pulley to the second pulley. It is desirable to have a blower drive mechanism having a belt. As a result, the power take-off shaft of the power take-off device and the blower are always connected by the first pulley, the second pulley and the belt, so that the high pressure washing pump is operated or stopped by switching the clutch while the blower is operating. Washing can be performed with high-pressure water.

  The suction wheel of the present invention is preferably provided with a switch for operating or stopping the high-pressure washing pump in the operation panel, and the clutch is an electromagnetic clutch that operates in conjunction with the switch. Thus, when cleaning with high-pressure water, the high-pressure cleaning pump can be activated or stopped by operating the switch on the operation panel.

(1) A receiver tank that collects an object to be collected by the suction negative pressure of a blower, a water tank that contains water, a high-pressure washing pump that sucks water in the water tank and discharges it as high-pressure water, and a vehicle traveling The receiver tank is provided with a power take-out device for taking out the power for driving the blower from the engine and a pump drive mechanism for transmitting the power taken out by the power take-out device to the high-pressure washing pump through the clutch. In addition, the clutch of the pump drive mechanism can be connected and the high-pressure washing pump can be driven by the power take-out device to wash the equipment with high-pressure water. Moreover, the waste after washing | cleaning can be collect | recovered to a receiver tank with the suction negative pressure of a blower.

(2) Since the power take-off shaft of the power take-off device and the blower are always connected, the high pressure washing pump is operated or stopped by switching the clutch while the blower is operating, and washing is performed with high pressure water. The blower can be washed with high-pressure water while collecting objects to be collected such as sludge and muddy water from sewers, manholes, side ditches of roads and water purification plants.

(3) A switch for operating or stopping the high-pressure washing pump is provided on the operation panel, and the clutch is an electromagnetic clutch that operates in conjunction with the switch. Thus, the high-pressure washing pump can be operated or stopped easily.

It is a side view of the suction wheel in the embodiment of the present invention. It is a top view of the suction wheel of FIG. It is a rear view of the suction wheel of FIG. It is sectional drawing which shows the drive mechanism of a Roots blower and a high-pressure washing pump. It is an AA arrow line view of FIG. It is a BB arrow line view of FIG. It is CC arrow line view of FIG. It is an air system diagram of a suction device with a high-pressure washing device. It is a water system figure of the suction device with a high pressure washing device.

  1 is a side view of a suction wheel according to an embodiment of the present invention, FIG. 2 is a plan view, and FIG. 3 is a rear view. 1 to 3, the suction wheel 1 according to the embodiment of the present invention includes a vehicle 10 and a suction device 20 with a high-pressure cleaning device mounted on the vehicle 10. The vehicle 10 includes a cab 11 and a chassis frame 12. The chassis frame 12 includes a vehicle running engine 2 (see FIG. 6), a propeller shaft 3 (see FIG. 6), a PTO (power take-off device) 4 (see FIG. 6), a subframe 13, wheels 14 and the like. Is attached.

  The sub frame 13 mounted on the chassis frame 12 extends in the front-rear direction of the vehicle 10. The suction device 20 with a high-pressure cleaning device includes the sub-frame 13 and includes the following devices mounted on the sub-frame 13.

  A receiver tank 21 as a primary catcher is installed in the rear portion of the subframe 13. The receiver tank 21 collects an object to be collected by suction negative pressure of a roots blower 25 described later. In this specification, the cab 11 side of the vehicle 10 will be referred to as the front side, the receiver tank 21 side as the rear side, the right side of the vehicle 10 from the receiver tank 21 side toward the cab side will be described as the right side, and the left side will be described as the left side.

  The front portion of the subframe 13 has a cyclone dust collector 23 as a tertiary catcher, a cyclone dust collector 24 as a fourth catcher, a roots blower 25 as a blower that generates a suction negative pressure, and water in which water is stored. A tank 26 and an operation panel 27 are arranged. Below the chassis frame 12, a high-pressure cleaning pump 28 that sucks water in the water tank 26 and discharges it as high-pressure water is attached. In addition, although the suction wheel 1 in this embodiment is not provided with the secondary catcher which collects dust from a suction collection thing, it can also be set as the structure provided with a secondary catcher.

  The cyclonic dust collectors 23 and 24 are provided on a common tank 29. In the tank 29, the cyclone dust collector 23 side and the cyclone dust collector 24 side are separated by a partition wall (not shown). Water is stored inside the tank 29. The roots blower 25 and the high pressure washing pump 28 are driven by the power of the engine 2 taken out through the PTO 4 described above.

  Here, the drive mechanism of the roots blower 25 and the high-pressure washing pump 28 will be described. 4 is a cross-sectional view showing a drive mechanism of the roots blower 25 and the high-pressure washing pump 28, FIG. 5 is a view taken along the line AA in FIG. 4, FIG. 6 is a view taken along the line BB in FIG. It is CC arrow line view.

  The drive mechanism of the roots blower 25 includes a first pulley 31 connected to the power take-off shaft 30 of the PTO 4 via a drive shaft 39a described later, a second pulley 32 connected to the drive shaft of the roots blower 25, and the first pulley 31. The belt 35 transmits the rotation of the belt 35 to the second pulley 32, the tensioner 36 adjusts the slackness of the belt 35, and the like. The drive mechanism of the high-pressure washing pump 28 is connected to the high-pressure washing pump 28 via the third pulley 33 connected to the power take-off shaft 30 of the PTO 4 via the drive shaft 39a and the output shaft 37a via the drive shaft 39c described later. The electromagnetic clutch 37, a fourth pulley 34 connected to the input shaft of the electromagnetic clutch 37, a belt 38 for transmitting the rotation of the third pulley 33 to the fourth pulley 34, and the like.

  Each of the first to fourth pulleys 31, 32, 33, and 34 is a V pulley having a plurality of V grooves. Each of the belts 35 and 38 includes a plurality of V belts. The power take-off shaft 30 of the PTO 4 and the third pulley 33 are connected by a drive shaft 39a. One end of the rotation shaft 31 a of the first pulley 31 is fixed to the third pulley 33. A hydraulic pump 50 is connected to the other end of the rotating shaft 31a via a drive shaft 39b. The hydraulic pump 50 is for generating hydraulic pressure used for the dumping operation of the receiver tank 21 and the opening / closing operation of the tailgate. The output shaft 37a of the electromagnetic clutch 37 and the high pressure washing pump 28 are connected by a drive shaft 39c. The electromagnetic clutch 37 operates in conjunction with a switch 27 a that operates or stops the high-pressure washing pump 28 provided on the operation panel 27.

  In this embodiment, the power take-off shaft 30 of the PTO 4 and the roots blower 25 are always connected. When the PTO 4 is operated, the power take-out shaft 30 of the PTO 4 rotates and the pulleys 31, 33 rotate through the drive shaft 39a. . The rotation of the pulley 31 is transmitted to the pulley 32 by the belt 35, and the drive shaft of the roots blower 25 is rotated. Thereby, the roots blower 25 operates.

  On the other hand, the rotation of the pulley 33 is transmitted to the pulley 34 by the belt 38, but when the stop of the high-pressure washing pump 28 is selected by the switch 27a provided in the operation panel 27, the electromagnetic clutch 37 is in a disconnected state. Therefore, the rotation of the pulley 34 is not transmitted to the output shaft 37a, and the high-pressure washing pump 28 does not operate. When the operation of the high pressure washing pump 28 is selected by the switch 27 a provided on the operation panel 27, the electromagnetic clutch 37 is connected, and the rotation of the pulley 34 operates the high pressure washing pump 28 through the electromagnetic clutch 37. .

  Next, the air system of the suction device 20 with a high-pressure cleaning device will be described with reference to FIG. FIG. 8 is an air system diagram of the suction device 20 with a high-pressure cleaning device.

  As shown in FIG. 8, the exhaust port 21 a of the receiver tank 21 and the intake port 23 a of the cyclone dust collector 23 are connected by a pipe 40. The middle of the pipe 40 is branched by a pipe 41. The pipe 41 is provided with a load release valve 42, and its tip is open to the atmosphere. A valve 44 a is provided in the middle of the pipe 40 and between the branch portion of the pipe 41 and the exhaust port 21 a of the receiver tank 21.

  A pipe 45 is connected to the exhaust port 23 b of the cyclone dust collector 23. The tip of the pipe 45 is connected to the intake port 25 a of the roots blower 25. A vacuum breaker 46 is connected in the middle of the pipe 45. The vacuum breaker 46 takes in air from the outside when the pressure inside the pipe 45 becomes a predetermined pressure or less.

  A pipe 47 is connected to the exhaust port 25 b of the roots blower 25. The tip of the pipe 47 is connected to the intake port 24 a of the cyclone type dust collector 24. A valve 44c is provided in the middle of the pipe 47 leading to the intake port 24a. Further, a pipe 48 connects between the valve 44 c and the exhaust port 25 b of the roots blower 25 in the middle of the pipe 47 and a pipe 44 connects between the valve 44 a and the exhaust port 21 a of the receiver tank 21. Has been. A valve 44 b is provided in the middle of the pipe 48.

  A relief valve 49 is provided in the middle of the pipe 48 that connects the valve 44 b and the pipe 47. The relief valve 49 is automatically opened when the inside of the pipe 48 becomes a predetermined pressure or more, and releases the pressure to the outside.

  With the above configuration, in the suction device 20 with a high-pressure cleaning device in the present embodiment, a suction hose (not shown) is connected to the suction port 21b provided below the tailgate of the receiver tank 21 when collecting the collection target. Then, the tip of this suction hose is inserted into a collection place such as a sewer, a manhole, a gutter on a road or a water purification plant. At this time, the valves 44a and 44c are opened, and the valve 44b and the load release valve 42 are closed. Then, the roots blower 25 is driven through the PTO 4 by the power of the engine 2.

  Thereby, the air in the receiver tank 21 is sucked by the Roots blower 25 from the exhaust port 21a through the pipe 40, the cyclone dust collector 23 and the pipe 45. As a result, the pressure in the receiver tank 21 decreases, and the collection target is collected in the receiver tank 21 through the suction hose. At this time, dust or the like that has not been collected in the receiver tank 21 is collected by the cyclone dust collector 23.

  On the other hand, the suction air in the receiver tank 21 sucked by the roots blower 25 is discharged to the cyclone type dust collector 24 through the pipe 47. In the cyclone type dust collector 24, water droplets mainly contained in the exhaust are collected and discharged to the outside from the exhaust port 24b of the cyclone type dust collector 24.

  Moreover, in this suction device 20 with a high-pressure washing device, it is possible to pressurize and discharge the collection target in the receiver tank 21. During pressurized discharge, a discharge hose (not shown) is connected to a discharge port 21c provided below the tailgate of the receiver tank 21, the valve 44b and the load release valve 42 are opened, and the valves 44a and 44c are closed. Then, the roots blower 25 is driven through the PTO 4 by the power of the engine 2.

  Thereby, the atmosphere is sucked by the roots blower 25 through the load release valve 42, the pipe 41, the cyclone dust collector 23 and the pipe 45. The air sucked by the roots blower 25 flows into the receiver tank 21 through the pipes 47, 48 and 40. Thereby, the inside of the receiver tank 21 is pressurized, and the collection object in the receiver tank 21 is discharged outside from the discharge hose connected to the discharge port 21c.

  In addition, the suction wheel 1 is provided with a water discharge port 21 d at the tailgate behind the receiver tank 21. From this water discharge port 21d, it is possible to discharge the supernatant water of the collection target in the receiver tank 21.

  Next, the water system of the suction device 20 with a high-pressure cleaning device will be described with reference to FIG. FIG. 9 is a water system diagram of the suction device 20 with a high-pressure washing device.

  As shown in FIG. 9, a valve 51, branch pipes 52 and 53, and a valve 54 are sequentially connected to the water inlet 26 a at the bottom of the water tank 26. A hose 55 is connected to the branch pipe 53, and a valve 56, a strainer 57, a branch pipe 58, and a valve 59 are sequentially connected to the tip of the hose 55. The valve 59 is for drain. One of the branch pipes 58 is connected to the water inlet 28 a of the high-pressure washing pump 28.

  On the other hand, a pressure hose 60 is connected to the drain outlet 28 b of the high-pressure washing pump 28. An unload valve 61 is connected to the tip of the pressure hose 60. The pressure hose 60 is connected to the inlet 61 a of the unload valve 61. A pressure-resistant hose 62, a branch pipe 63, a pressure-resistant hose 64, a valve 65, and a socket 66 are connected in order to the outlet 61b of the unload valve 61. A cleaning gun (not shown) is connected to the socket 66. A pressure gauge 67 is connected to one of the branch pipes 63.

  A branch pipe 68 and a valve 69 are sequentially connected to the drain port 61 c of the unload valve 61. The valve 69 is for drain. A hose 70 is connected to one of the branch pipes 68. The tip of the hose 70 is connected to the spillway 26 b at the top of the water tank 26.

  A hose 71 is connected to the valve 54, and a hose 72 is connected to the spillway 26 c at the top of the water tank 26. The ends of these hoses 71 and 72 are connected to a branch pipe 73 to constitute a drain port 74. A hose 75 is connected to the water injection port 26 d at the top of the water tank 26. A multi-suction pipe 76 is connected to the tip of the hose 75.

  A hose 77 is connected to one of the branch pipes 52. The tip of the hose 77 is connected to the lower part of the tank 29 on the cyclone dust collector 24 side through a valve 78. A hose 79 is connected to the lower part of the tank 29 on the cyclone type dust collector 24 side. A branch pipe 81 is connected to the tip of the hose 79 via a valve 80. A valve 82 is connected to one side of the branch pipe 81. The valve 82 is for drain.

  A hose 83 is connected to the other end of the branch pipe 81. The tip of the hose 83 is connected to the inlet 45a of the roots blower 25 of the pipe 45 via the gate valve 84 and is used for cooling the roots blower 25. A hose 85 is connected immediately after the exhaust port 23b of the cyclone dust collector 23 in the pipe 45. The tip of this hose 85 is connected to the exhaust port 24b side of the cyclone type dust collector 24 so as to supplement the shortage of intake of the roots blower 25.

  With the above configuration, in the suction device 20 with a high-pressure cleaning device in the present embodiment, the high-pressure cleaning pump 28 is driven by the PTO 4 with the electromagnetic clutch 37 in the connected state, and the valve 51, the branch pipe 52, 53, the hose 55, the valve 56, the strainer 57, and the branch pipe 58, the water in the water tank 26 is sucked, and the pressure from the washing gun is increased through the pressure hose 60, unload valve 61, pressure hose 62, branch pipe 63 and valve 65. It can be discharged as water.

  At this time, excess water is discharged from the drain port 61 c of the unload valve 61 in order to set the cleaning gun to a predetermined set pressure, and is returned to the water tank 26 through the branch pipe 68 and the hose 70. Further, in the suction device 20 with a high-pressure washing device in the present embodiment, the roots blower 25 is always driven, but water is supplied from the tank 29 through the hose 79, the valve 80, the branch pipe 81, the hose 83, and the gate valve 84, and the roots blower 25 is supplied. Is cooled. In the tank 29, water droplets contained in the exhaust of the roots blower 25 are collected by the cyclone dust collector 24, and water is supplied from the water tank 26 by a hose 77 as necessary.

  As described above, in the suction device 20 with the high-pressure cleaning device in the present embodiment, the recovery target can be recovered in the receiver tank 21 and the high-pressure cleaning pump 28 is operated by the PTO 4 with the electromagnetic clutch 37 in the connected state. It is possible to wash the equipment with high-pressure water. Although the water temperature rises when the high-pressure washing pump 28 is driven when it is not required, it can be stopped by disengaging the electromagnetic clutch 37, and an increase in the water temperature can be prevented. In addition, the waste after washing can be collected in the receiver tank 21.

  Moreover, in this suction device 20 with a high-pressure washing device, the power take-off shaft 30 of the PTO 4 and the roots blower 25 are always connected by the first pulley 31, the second pulley 32 and the belt 35, so that the roots blower 25 remains in operation. By switching the electromagnetic clutch 37, the high-pressure washing pump 28 can be operated or stopped to perform washing with high-pressure water, and objects to be collected such as sludge and muddy water can be removed from sewers, manholes, side ditches of roads and water purification plants. Washing with high-pressure water is possible while collecting.

  Further, in this suction device 20 with a high-pressure cleaning device, a switch 27a for operating or stopping the high-pressure cleaning pump 28 is provided in the operation panel 27, and the electromagnetic clutch 37 operates in conjunction with this switch. When performing this operation, it is possible to easily operate or stop the high-pressure washing pump 28 by operating this switch.

  The suction vehicle of the present invention is useful as a suction vehicle used for sludge collection work in sewers, manholes, road gutters, etc., and muddy sand collection work in water purification plants, etc. It is suitable as a suction wheel capable of not only recovering collection objects such as sludge and muddy water but also washing with high-pressure water.

1 Suction Wheel 2 Engine 3 Propeller Shaft 4 PTO (Power Extraction Device)
DESCRIPTION OF SYMBOLS 10 Vehicle 11 Cab 12 Chassis frame 13 Subframe 14 Wheel 20 Suction device with high-pressure washing device 21 Receiver tank 23, 24 Cyclone dust collector 25 Roots blower 26 Water tank 27 Operation panel 27a Switch 28 High-pressure washing pump 29 Tank 30 Power take-out shaft 31, 32, 33, 34 First to fourth pulleys 35, 38 Belt 36 Tensioner 37 Electromagnetic clutch 39a, 39b, 39c Drive shaft 40, 41, 45, 47, 48 Piping 42 Load release valve 44a, 44b, 44c Valve 46 Vacuum Breaker 49 Relief valve 50 Hydraulic pump 51, 54, 56, 59, 65, 69, 78, 80, 82 Valve 52, 53, 58, 63, 68, 81 Branch pipe 55, 70, 71, 72, 75, 77, 79, 83, 5 hose 57 strainer 60, 62, 64, pressure hose 61 unload valve 66 socket 67 pressure gauge 74 drain port 76 multi suction tube 84 gate valve

Claims (3)

A receiver tank that collects an object to be collected by the suction pressure of the blower;
A water tank in which water is stored;
A high-pressure washing pump that sucks water in the water tank and discharges it as high-pressure water;
A power take-off device for taking out the power for driving the blower from an engine for running the vehicle;
A pump drive mechanism that transmits power taken out by the power take-out device to the high-pressure washing pump via a clutch ;
The pump drive mechanism is configured to rotate a pulley connected to a power take-off shaft of the power take-out device, a pulley connected to an input shaft of the clutch, and a pulley connected to the power take-out shaft of the power take-out device. A belt that transmits to a pulley coupled to the input shaft of the clutch,
The suction wheel , wherein the high pressure washing pump is connected to the output shaft of the clutch . A first pulley connected to a power take-off shaft of the power take-out device;
A second pulley coupled to the drive shaft of the blower;
The suction wheel according to claim 1, further comprising a blower drive mechanism having a belt that transmits the rotation of the first pulley to the second pulley. A switch for operating or stopping the high-pressure washing pump is provided on the operation panel,
The clutch, suction vehicle according to claim 1 or 2, an electromagnetic clutch which operates in conjunction with said switch.

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