KR100975290B1 - Agitating-type Sludge Pump Apparatus for Wet-type Dust Collector - Google Patents

Abstract

The present invention relates to a stirred sludge pump apparatus of a wet dust collector,

A circular swivel 85 installed at the upper center portion of the pond 50 and having a gear gear 85b formed therein; A sludge suction pipe 84c is formed in a central portion, and a spiral rotating suction pipe 84b is formed along the periphery thereof so that the water suctioned through the filter 84a is discharged to the upper side of the sludge suction pipe 84c. A rotary suction pipe (84) having a support arm (84d) for maintaining an inclined state at a predetermined angle with respect to the vertical axis, and configured to generate magnetic force upon inflow of sludge; A crank tube 88 having a pinion gear 85c formed outside the pipe so as to be engaged with the rack gear 85b, and provided with rotary link portions 83 at upper and lower ends of the pipe so as to be rotatable; A discharge pump (81a) connected to the rotary suction pipe (84) via the crank tube (88) and providing suction force for suction of sludge; The lower end is fixed to the bottom side of the pond 50 through the intermediate member 82b, the drive shaft is installed upward is fixedly connected to the one side of the crank-type tube 88 through the connecting member 82c, the crank tube 88 A rotation motor 82 providing a rotational force to the; And a turbidity measurement system 86 installed in the pond 50 to measure the turbidity of the sludge and transmitting a signal to start the rotary motor 82 when the measured value exceeds a predetermined set value. ,

Since the sludge in the pond is discharged while stirring, the sludge does not stagnate or accumulate, and smooth discharge is achieved to achieve stable operation.

Wet Dust Collector, Stirring, Sludge Pump

Description

Agitating-type Sludge Pump Apparatus for Wet-type Dust Collector}

1 is a configuration diagram showing an example of a conventional wet dust collector process,

2 is a configuration diagram of a sludge treatment unit of a conventional wet dust collector process,

Figure 3 is a perspective view of the stirred sludge pump apparatus according to an embodiment of the present invention,

Figure 4 is a detailed configuration diagram of the rotary link unit of the stirred sludge pump apparatus according to an embodiment of the present invention,

5 is a cutaway view of a rotary suction pipe of the stirred sludge pump apparatus according to an embodiment of the present invention,

Figure 6 is an exploded perspective view of the main portion of the stirred sludge pump apparatus according to an embodiment of the present invention,

7a and 7b is an operating state diagram of the stirred sludge pump apparatus according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

50: pond 81a: discharge pump

82: rotary motor 82b: intermediate member

82c: connecting member 83: rotary link portion                 

84: rotary suction pipe 84a: filter

84b: rotary suction pipe 84c: sludge suction pipe

84d: support arm 85: circular swivel

85b: Rec Gear 85c: Pinion Gear

86: turbidity meter 88: crank tube

The present invention relates to an agitated sludge pump apparatus of a wet dust collector, and more particularly, to a pump apparatus for treating sludge of a wet dust collector for collecting dust and treating it by flushing.

Particularly, the present invention applies a stirring pump structure in the process of collecting and collecting the dust using water after collecting the dust, so that the sludge accumulated in the pond is effectively treated. It relates to an agitated sludge pump apparatus.

1 is a configuration diagram showing an example of a conventional wet dust collector process, Figure 2 is a configuration diagram of a sludge treatment unit of a conventional wet dust collector process.

There are various kinds of dust collectors for collecting dust, and a bag filter type dust collector using a bag filter and a wet dust collector which collects dust and washes it with water is used. (See Fig. 1)                         

An example of the structure of the conventional wet dust collector is demonstrated.

The fan blower 40 is operated to suck in dust from the dust generating source, that is, the hood 30.

The dust is sucked into the hood 30 by the suction force of the fan blower 40 and enters the venturi screw burr 10 through the inpinjet screw burr 20.

At this time, since the water pump 60 is in operation, water 51 stored in the pond 50 is injected downward through the nozzle 11 inside the venturi screw server 10.

Since the water 51 is sprayed when the dust passes through the inside of the venturi screw server 10, the dust is precipitated and discharged to the bottom, and the clean air is discharged to the top and dispersed into the atmosphere through the stack 41.

The sediment discharged to the bottom together with the water 51, that is, the sludge 52 is temporarily stored in the pond 50.

The water 51 and the sludge 52 flowing into the pond 50 are separated from each other, so that the sludge 52 sinks below the pond 50 and the water 51 is located at the top.

Therefore, the water 51 stored in the pond 50 by the operation of the water pump 60 enables continuous circulation use for spraying the nozzle 11.

Meanwhile, the sludge 52 formed in the pond 50 is sucked by the sludge pump 70 and then stored in the sludge tank 71 and reused as a by-product.

However, such a wet dust collector had some process problems.

That is, in the process of processing the sludge 52, there is a problem that the sludge 52 in the pond 50 is not smoothly processed and gradually accumulates in the pond due to the following causes.

First, the bottom of the pond 50 is formed to be inclined so that the sludge 52 flows naturally to the sludge pump 70 side, but due to the solidification of the sludge 52, it does not flow down naturally. Due to this, the sludge 52 may not be discharged smoothly.

Second, the amount of sludge 52 is generated is proportional to the discharge of dust, if the dust is generated and accumulated at a large amount irregularly at a time, the sludge pump 70 is not normally discharged is accumulated in the pond 50 Occurred.

Third, the sludge pump 70 should be operated in a state in which continuous operation is always performed, but if a temporary stop or blockage, suction failure, etc. occurs for a moment due to various causes, the sludge 52 may be stagnated and sludge 52 may occur. There was a case that the piled up on the bottom of the pond (50).

The present invention is to solve the problems as described above, so that the produced sludge does not stagnate or accumulate on the bottom of the pond and can be discharged smoothly by the sludge pump, the stirring of the wet dust collector to promote a good operating state of the wet dust collector It is an object to provide a type sludge pump apparatus.

The present invention for achieving the above object is, a circular swivel (85) is installed on the upper center portion of the pond 50, the rack gear (85b) formed inward; A sludge suction pipe 84c is formed in a central portion, and a spiral rotating suction pipe 84b is formed along the periphery thereof so that the water suctioned through the filter 84a is discharged to the upper side of the sludge suction pipe 84c. A rotary suction pipe (84) having a support arm (84d) for maintaining an inclined state at a predetermined angle with respect to the vertical axis, and configured to generate magnetic force upon inflow of sludge; A crank tube 88 having a pinion gear 85c formed outside the pipe so as to be engaged with the rack gear 85b, and provided with rotary link portions 83 at upper and lower ends of the pipe so as to be rotatable; A discharge pump (81a) connected to the rotary suction pipe (84) via the crank tube (88) and providing suction force for suction of sludge; The lower end is fixed to the bottom side of the pond 50 through the intermediate member 82b, the drive shaft is installed upward is fixedly connected to the one side of the crank-type tube 88 through the connecting member 82c, the crank tube 88 A rotation motor 82 providing a rotational force to the; A turbidity measuring system 86 installed in the pond 50 to measure the turbidity of the sludge, and transmitting a signal to start the rotary motor 82 when the measured value exceeds a predetermined set value. .

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

Figure 3 is a perspective view of a stirred sludge pump apparatus according to an embodiment of the present invention, Figure 4 is a detailed configuration of the rotary link unit of the stirred sludge pump apparatus according to an embodiment of the present invention, Figure 5 is one of the present invention Sectional view of the rotary suction pipe of the stirring sludge pump apparatus by an Example, FIG. 6: is an exploded perspective view of the principal part of the stirring sludge pump apparatus which concerns on one Example of this invention.

In the upper center portion of the pond 50, a circular swivel 85 having a rack gear 85b is provided inward.

Inside the pond 50, a rotary suction pipe 84 is provided which generates self-power by the flow of water sucked in (water suctioned from the sludge) and agitates in the pond 50 at the same time as the inflow.

Sludge suction pipe 84c through which sludge flows is formed in the substantially center part of the rotary suction pipe 84.

A spiral rotating suction tube 84b is formed along the circumference of the sludge suction tube 84c to allow the water suctioned through the filter 84a to be discharged to the upper side of the sludge suction tube 84c.

The rotary suction pipe 84b formed in two rows is formed only outside thereof as illustrated so as not to penetrate the sludge suction pipe 84c formed in the center portion.

The rotary suction pipe 84b is configured to have two rows of spirals in order to allow the rotary suction pipe 84 to rotate at the same time as the suction using the inclined flow generated inside the water.

The illustrated filter 84a is a separate filter. In the middle of the circular filter 84a, an opening having the same diameter as the sludge suction pipe 84c is formed, and a filter part for filtering foreign matter is formed in the remaining part.

On the upper side of the rotary suction pipe 84, a support arm 84d is installed to allow the rotary suction pipe 84 to be rotatable while maintaining a tilted angle at a predetermined angle.

The lower part of the support arm 84d is fixedly attached to the rotary suction tube 84, and the upper part is attached to the crank tube 88, but is attached via the rotary bearing 84e so that rotation is freely made.

On the other hand, the crank-type tube 88 in which the pinion gear 85c was formed in the outer side of a pipe so that it may engage with the rack gear 85b of the circular turntable 85 is provided.

Rotating link portions 83 are provided at upper and lower ends of the crank-type tube 88 so as to allow smooth rotation during operation.

The rotary link portion 83 is a bearing for enabling a 360 degree rotation when the rotary suction tube 84 rotates at the end of the crank tube 88 or rotates along the circular swivel 85 by the rotary motor 82. Play a role.

One such rotary link portion 83 is provided at each of the upper and lower ends of the crank-type tube 88, the lower rotary link portion 83 is connected to the rotary suction tube 84, the upper rotary link portion 83 Is connected to the suction part of the discharge pump 81a.

The rotary link portion 83 has a ball bearing portion 83a (see FIG. 4C) inserted therein and an outer bearing housing portion 83b (see FIG. 4B), so that they can rotate smoothly. It consists of several inserted balls 83c (see Fig. 4A). Fig. 4A shows the cross-sectional structure of the rotary link portion.

On the other hand, the discharge pump 81a is connected to the rotary suction pipe 84 via the crank-type pipe 88 and provides a suction force for suctioning the sludge.

The sludge 52 is sucked through the rotary suction pipe 84 by the start of the discharge motor 81, and then discharged through the discharge pipe 81 b via the crank-type pipe 88.

On the other hand, the crank-type tube 88 is provided with a rotary motor 82 for providing a rotational force.

A drive shaft installed upward of the rotary motor 82 is fixedly connected to one side of the crank-type tube 88 through a connecting member 82c. In addition, the rotary motor 82 is fixed by the lower motor cover 82a, and is fixed to the bottom of the pond 50 through the intermediate member 82b.

Pond 50 has a turbidity measuring system 86 is installed to measure the turbidity of the sludge, the turbidity (SS) measuring system 86 is the sludge 52 of the measuring rod (86a) inserted into the pond 50 Turbidity is measured by detecting specific gravity.

Starting conditions of the discharge motor 81 and the rotary motor 82 are determined according to the specific gravity of the sludge 52 detected by the turbidity measuring system 86.

That is, the turbidity measuring system 86 transmits a signal to start the rotary motor 82 when the measured value exceeds a predetermined set value.

The turbidity measuring system 86 can arbitrarily change the set value for specific gravity by operating the indicator hand. For example, the turbidity (SS) can be set to a value of about 200 ml / g based on a design reference value to operate the device. have.

Hereinafter, an operating state of the present embodiment will be described with reference to the accompanying drawings.

7a and 7b is an operating state diagram of the stirred sludge pump apparatus according to an embodiment of the present invention.

In this embodiment, the reference value for turbidity of the sludge 52 contained in the pond 50 is set to 200 ml / g.

The case where the turbidity of the sludge 52 does not exceed this set value will be described first (see FIG. 7A).

When the continuous operation of the wet dust collector is achieved by the overall operating conditions, the water 51 is circulated by the discharge pump 81a to collect the dust.

Since the turbidity of the sludge 52 is relatively clean water of 200 ml / g or less, only the discharge motor 81 is operated in response to the transmission signal of the turbidity measuring system 86.

Accordingly, the discharge pump 81a sucks the sludge inside the pond 50 through the sludge suction pipe 84c with a strong suction force and sends it to the sludge tank side.

Simultaneously with this action, a strong suction action occurs toward the rotary suction pipe 84b formed in the rotary suction pipe 84, so that the water is sucked and the rotary suction pipe 84 rotates (rotates) in one direction. rotation)

The rotational action of the rotary suction pipe 84 is achieved because two rotary suction pipes 84b are formed in a spiral shape, and a rotary link portion 83 is formed on the upper portion thereof.

When the rotary suction pipe 84 rotates, a predetermined inclination angle (15 degrees in this embodiment) is maintained by the support arm 84d.

In this way, when the turbidity of the sludge 52 is measured below the reference value, only the discharge motor 81 is operated to suck the rotary suction pipe 84 while rotating, so that the sludge 52 formed around the suction is processed without being stagnant.

On the other hand, when such operation is performed for a long time, the amount of sludge 52 is gradually increased so that turbidity may exceed the reference value. (See FIG. 7B).

In this case, the discharge motor 81 and the rotary motor 82 operate simultaneously by receiving the transmission signal from the turbidity measuring system 86. That is, the state in which only the discharge motor 81 is in operation is operated to the rotation motor 82.

When the rotary motor 82 is operated, the pinion gear 85c is rotated while being engaged with the rack gear 85b, and at this time, the crank-type tube 88 is rotated.

Rotating link portion 83 is formed at the upper end of the crank-type tube 88, and the driving shaft of the rotary motor 82 is fixedly connected to one side thereof, so that continuous rotation is achieved. Accordingly, the rotary suction tube 84 rotates (FIG. At the same time as the rotation in the A direction of 7b, the vehicle rotates 360 degrees along the circular swivel 85 (the rotation in the B direction of FIG. 7b).

Therefore, by the action of the discharge motor 81 and the action of the rotary motor 82, the agitated sludge pump device performs a rotation and pumping action while drawing a circular trajectory with respect to the entire inside of the pond 50. 52 is discharged smoothly without stagnation or accumulation.

During this process, the discharge motor 81 is continuously operated, and the rotary motor 82 is repeatedly operated and stopped by the transmission signal of the turbidity measurement system 86.

The present invention described above can be embodied in many different forms without departing from the spirit or main features thereof. Therefore, the above embodiments are merely examples in all respects and should not be interpreted limitedly.

Therefore, according to the present invention, it is discharged while stirring the sludge inside the pond by the operation of the stirred sludge pump device, the sludge is not stagnant or accumulated can be smoothly discharged to achieve a stable operation.

Claims (1)

A circular swivel 85 installed at the upper center portion of the pond 50 and having a gear gear 85b formed therein; A sludge suction pipe 84c is formed in the center portion, and a spiral rotating suction pipe 84b is formed to discharge water filtered and sucked through the filter 84a to the upper side of the sludge suction pipe 84c along the periphery thereof. A rotary suction pipe (84) having a support arm (84d) for maintaining an inclined state at a predetermined angle with respect to the vertical axis, and configured to generate magnetic force upon inflow of sludge; A crank tube 88 having a pinion gear 85c formed outside the pipe so as to be engaged with the rack gear 85b, and provided with rotary link portions 83 at upper and lower ends of the pipe so as to be rotatable; A discharge pump (81a) connected to the rotary suction pipe (84) via the crank tube (88) and providing suction force for suction of sludge; The lower end is fixed to the bottom side of the pond 50 through the intermediate member 82b, the drive shaft is installed upward is fixedly connected to the one side of the crank-type tube 88 through the connecting member 82c, the crank tube 88 A rotation motor 82 providing a rotational force to the; A turbidity measuring system (86) installed inside the pond (50) to measure the turbidity of the sludge and transmitting a signal to start the rotary motor (82) when the measured value exceeds a predetermined set value. Agitated sludge pump device of dust collector.

Images