KR101026492B1 - Flocculator for water & wastewater treatment - Google Patents

Abstract

PURPOSE: A water processing condenser is provided to reduce the generation of vibrations and noises by minimizing a power transferring distance and improving power transferring linearity between a driving motor and an outputting shaft. CONSTITUTION: A water processing condenser includes a reducing unit(10), a hollow shaft(16), a rotary shaft, an impeller, a driving motor, an oil receiving unit(15), a supporting unit, an eccentric installing unit, a level difference supporting unit, a reducer clutching unit, and a motor clutching unit. The reducing unit includes a gear part and a cycloid reducer. The hollow shaft is installed in the gear part and is in connection with the cycloid reducer. The upper side of the rotary shaft is inserted into the hollow shaft. The impeller is installed at the lower side of a condenser rotary shaft. The driving motor is in connection with the cycloid reducer using the clutching unit.

Description

Flocculator for Water & Wastewater treatment

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to aggregators for water treatment, and more particularly, to aggregators for water treatment which allow growth of flocs formed in agglomerates into gradually larger flocs that are easy to sink.

Hereinafter, a background art and a problem thereof will be described with reference to the accompanying drawings.

In general, during the treatment process of water purification plant, the raw water supplied through the raw water pipe in the intake station is mixed with the chemicals by the chemical injector and the chemical injector in the chemical chamber and the mixed paper, and then mixed with the fine flocs in the agglomerated paper. It is a very important process to make it possible.

For example, in a water treatment plant, chemicals are introduced into the raw water, and the chemical treatment unit is operated by stirring the raw water to agitate the raw water. Then, the chemicals are added to the raw water. The raw water introduced into the water purification plant is purified through the process.

Operation of agglomerators in water treatment plants such as water purification plants, sewage plants or wastewater treatment plants is an essential process in the water treatment process. Such agglomerators maintain a rich continuity (speed at which foreign substances do not settle) when stirred in process water. Therefore, it should be operated to prevent sedimentation at the bottom of the coagulation tank.

Next, with reference to FIGS. 1A-1C, the structure of the general water treatment flocculator is demonstrated.

1A is a view for explaining the configuration of a general water treatment flocculator, FIG. 1B is a cross-sectional view for explaining the configuration of a general water treatment flocculator, and FIG. 1C is a view for explaining an input shaft of a general flocculator.

1A to 1C, a general water treatment flocculator includes a deceleration means 10 installed on an upper surface of an agglomeration tank 20, and a drive motor 14 is installed on an upper surface of the deceleration means 10. The agglomerator rotating shaft 11 extending into the agglomeration tank 20 is connected to the deceleration means 10, and an impeller 12 is installed at a lower end of the agglomerator rotating shaft 11.

The impeller 12 is provided with a stirring blade 122 radially on the outer periphery of the agglomerator rotating shaft 11, the stirring blade 122 is installed to be inclined at a predetermined angle (about 30 degrees to 45 degrees). .

Such a conventional water treatment stirrer does not properly transmit the turbulent kinetic energy formed in the flocculation tank 20 to the blind spot in the flocculation tank 20, so that there is a problem that the coagulation efficiency is lowered and power loss occurs. In order to solve this problem, the agglomerator rotating shaft 11 of the agglomerator for water treatment is further extended to be close to the bottom surface of the agglomeration tank 20, or the length of the stirring blade 122 of the impeller 12 is increased. A longer extension method was used.

However, in the case of extending the agglomerator rotating shaft 11 or extending the length of the stirring blades 122 of the impeller 12 as described above, the agglomerator rotating shaft 11 or As the shaking angle of the stirring blade 122 becomes larger than that of the general water treatment flocculator, the fatigue life of the agitator rotating shaft 11 or the stirring blade 122 of the impeller 12 is greatly reduced, thereby increasing the overall life of the water treatment flocculator. There was a problem that drastically reduced.

The agglomerator is agglomerated by rotating the agglomerator rotating shaft 11 by rotating the agglomerator rotating shaft 11 at a constant rate by the reduction means 10. Stirring the liquid in the tank 20 is continuously operated 24 hours a day without rest, the operation time is relatively long compared to other rotary devices, the lubricating oil inside the deceleration means 10 flows down the agglomerator rotating shaft 11 There was a problem of contaminating the liquid in the flocculation tank 20.

That is, the general agglomerator is provided with an oil seal (Oil Seal) to prevent leakage of the lubricating oil at the site where the agglomerator rotating shaft 11 and the deceleration means 10 is in contact, the oil seal formed of the rubber material is agitator The lip portion of the seal of rubber material is formed by heat generated by friction with the agglomerator rotating shaft 11 and an oil film formed between the oil seal and the agglomerator rotating shaft 11 as it is used for a long time. As it loses its elasticity when cured, oil leakage occurs between the oil seal and the agglomerator rotating shaft 11, and the oil for lubrication flows down the agglomerator rotating shaft 11 to contaminate the liquid in the agglomeration tank 20.

1B and 1C, a conventional agglomerator has a deceleration means 10 installed on an upper surface of the agglomeration tank 20, and an agglomerator rotating shaft 11 positioned inside the deceleration means 10. Cycloidal reducer 101 is installed on one side of the upper surface of the reduction means 10 so that the upper end and the output shaft 101a of the gear 161 is connected, the drive shaft 14 of the rotary shaft 140 of the cycloidal reducer 101 The driving motor 14 is installed on the upper surface of the cycloid reducer 101 to be connected to the input shaft 131.

The input shaft 131 of the general agglomerator configured as described above is the first support portion 131a inserted into and supported by the bearing 101c inserted into the expansion connection portion 101b of the output shaft 101a of the cycloid reducer 101. And a key groove 1310b formed on one side of the first support portion 131a to have a larger diameter than the support portion, and a key groove (not shown) of the eccentric 101d is inserted into the outer circumferential surface thereof. An eccentric mounting portion 131b, a stepped support portion 131c extending to have a diameter larger than the eccentric mounting portion 131b on one side of the eccentric mounting portion 131b, and one side of the stepped supporting portion 131c. The second support portion 131d is formed to extend to have a diameter smaller than the stepped support portion 131c and is supported by a bearing inserted into the center portion of the adapter 130, and the first support portion 131d on one side of the second support portion 131d. 2 Hollow to have an outer diameter smaller than the support portion 131d It is formed to protrude in a shape, it is composed of a coupling installation portion 131e is formed with a key groove (not shown) on one side.

In order to connect the input shaft 131 of the general agglomerator which is configured as described above to the drive shaft 14 and the rotation shaft 140, a flexible coupling 3 for the reduction gear is installed in the coupling installation part 131e. In order to be connected to one side of the reducer flexible coupling 3, the motor shaft 14 and the input shaft may be installed on the drive shaft 14 of the drive shaft 14 by installing the motor flexible coupling 4. 131) are connected to each other.

As described above, in order to connect the input shaft 131 of the conventional general agglomerator with the drive shaft 14 rotating shaft 140, the drive motor together with the separate flexible coupling 3 for the reducer installed on the input shaft 131. 14) The conventional agglomeration in which the general input shaft 131 is installed as described above should be provided with a separate motor flexible coupling 4 installed on the rotating shaft 140 and connected to the flexible coupling 3 for the reduction gear. In order to accommodate the inside of the flexible coupling 3 for the reducer and the flexible coupling 4 for the motor connected to each other in a straight line should be provided with an adapter 130 secured a space of a sufficient height.

Agglomerator having a conventional general input shaft 131 connected to the rotation shaft 140 of the drive motor 14 by using the flexible coupling 3 for the reducer and the flexible coupling 4 for the motor as described above. 20, the height from the upper surface of the coagulation tank 20 to the upper end of the driving motor 14 is not only high, but also from one end of the rotation shaft 140 of the driving motor 14 to the height of the input shaft 131. As the length to the other end is long, the straightness of the power transmission is reduced, thereby providing a cause of vibration and noise to the agglomerator, and the rotational resistance is increased as the power transmission distance is increased, thereby providing a large capacity drive motor ( There is a problem that the maintenance cost of the agglomerator is increased by using 14).

In addition, the stirring efficiency due to the phenomenon that the input shaft 131 is eccentrically rotated as the connection between the rotary shaft 140 and the input shaft 131 of the drive motor 14, which is rotated at a high speed in addition to the vibration generated in the flocculator In addition to this deterioration, there is a problem in that parts such as bearings installed inside the deceleration means 10 are frequently broken and the life of the agglomerator is greatly shortened.

In addition, the conventional agglomerator is a fixing member 164 to the end plate 163 provided at the upper end of the hollow shaft 16 after the agglomerator rotating shaft 11 is simply inserted into the hollow shaft 16 having a straight hollow portion. Screwed by a), the agglomerator rotating shaft 11 is fastened to the hollow shaft 16 in a loose fitting manner so that there is a gap between the inner circumferential surface of the hollow shaft 16 and the agglomerator rotating shaft 11. Is generated so that the agglomerator rotating shaft 11 is shaken or eccentric to bend, causing the oil seal 17 installed to maintain airtightness between the gear part 100 and the hollow shaft 16 to be separated or shaped. Deformation or breakage occurs frequently and the service life of the agglomerator is greatly reduced, and oil leakage inside the deceleration means 10 occurs between the gear part 100 and the hollow shaft 16. 20) Contaminate the liquid filled in There is a problem in that, the tolerance between the inner diameter of the hollow shaft 16 and the diameter of the agglomerator rotating shaft 11 is very small, so that the operation of inserting and tightening the agglomerator rotating shaft 11 into the hollow shaft 16 There is a problem that it is not easy to be assembling property is lowered, the conventional water treatment flocculator as described above has a problem that mainly used foreign products.

Therefore, the object of the present invention is that the agglomerator rotary shaft is not shaken or eccentric to rotate even after long use, which greatly extends the service life and at the same time the gap between the hollow shaft and the gear portion is filled with lubricating oil. It is to prevent leakage into the inside of the coagulation tank, and by using a cycloid reducer with excellent durability, it is to provide a high quality water treatment flocculator with pure domestic technology corresponding to imported goods.

Another object of the present invention is to improve the power transmission straightness and at the same time to minimize the power transmission distance to reduce the vibration and noise, and to significantly extend the service life, as well as to improve the cohesive efficiency and low power operation. It is to provide a flocculator for water treatment.

Still another object of the present invention is to minimize the shaking width of the stirring blades caused by the vortex generated at the tip of the stirring blades, so that the radius of the stirring blade can be formed longer than the impeller of the conventional water treatment flocculator. To provide a flag.

It is still another object of the present invention to provide an agglomerator for water treatment in which deposits do not occur not only at the lower end of the wall of the branch but also at the center of the bottom of the branch where the hub of the impeller is located.

It is still another object of the present invention to provide agitation blades for water treatment that can not only produce a thinner iron plate than conventional water agglomerator impellers, but also need not install a separate water storage device.

In order to achieve the above object, the present invention, the gear unit is provided on the upper surface of the coagulation tank and a deceleration means consisting of a cycloid reducer is installed on the upper end of the gear portion; A hollow shaft rotatably installed in the gear unit, connected to the cycloid reducer, and having a tapered portion having a predetermined height at the lower end of the inner circumferential surface thereof, the diameter of which gradually decreases in an upward direction; The upper end is inserted into the hollow shaft, and the upper end is screwed to the end plate provided on the upper surface of the hollow shaft by a fixing member, and the upper end is formed with a taper part inserted into a taper formed on the hollow shaft, and screwed by the fixing member. An agglomerator rotating shaft inserted into the hollow shaft in an interference fit manner as it is fastened and lifted; An impeller installed at the lower end of the agglomerator rotating shaft; A drive motor connected by the cycloid reducer and clutch means; And an oil receiving part surrounding the outside of the hollow shaft to prevent leakage of lubricating oil filled in the gear part between the gear part and the hollow shaft.

Here, the oil receiving portion, a ring-shaped groove formed on the bottom surface of the gear provided on the hollow shaft; A guard portion fixedly installed in the gear portion and having a center portion penetrated by the hollow shaft; And a blocking wall inserted into the ring-shaped recess and fixed to an upper surface of the guard part so as to surround the outside of the hollow shaft.

The clutch means includes: a support part inserted into and supported by a bearing inserted into an expansion connection part of an output shaft of a cycloidal reducer; An eccentric installation portion formed on one side of the support portion to have a larger diameter than the support portion, and an outer circumferential surface formed with a key groove into which an eccentric key is inserted; A stepped support part extended to have a larger diameter than the eccentric mounting part on one side of the eccentric mounting part; A reducer clutch portion formed to extend in a hollow shape to have an outer diameter smaller than a diameter of the step support portion on one side of the step support portion, and a plurality of clutch protrusions protrude at a predetermined interval on one side; And a hollow shaft formed in the hollow shape so as to be arranged on the driving motor rotation shaft. A key groove into which a key of the motor rotation shaft is inserted is formed on an inner circumferential surface thereof, and a plurality of clutch projections inserted and coupled between neighboring clutch projections of the reducer clutch portion on the other side thereof. It may be configured to include an input shaft consisting of; a motor clutch portion protruding at a predetermined interval.

Here, the clutch projection of the motor clutch portion is preferably inserted between the adjacent clutch projection of the reducer clutch portion so that both sides are spaced apart from the side of the clutch projection adjacent to each other by a predetermined distance.

In addition, an impact preventing member may be further interposed between both side surfaces of the clutch protrusion of the motor clutch portion and side surfaces of the clutch protrusion adjacent to each other.

On the other hand, the impact preventing member, the ring-shaped body portion which is interposed between the other side surface of the reducer clutch portion and the other side of the motor clutch portion; And a plurality of impact preventing protrusions protruding at a predetermined interval on the outer circumferential surface of the body portion so as to be interposed between both side surfaces of the clutch protrusion of the motor clutch portion and side surfaces of the clutch protrusion adjacent to each other.

Here, in the direction of the outer circumferential surface of the motor clutch portion, it is preferable that a plurality of fixing holes having a thread formed therein for screwing the fixing member for fixing the motor clutch portion to the driving motor rotating shaft are further formed at regular intervals.

In addition, the impeller, the hub is arranged in the lower end of the agglomerator rotating shaft; A hub plate radially attached to the outer circumferential surface of the hub to be inclined in one direction; An inner wing portion having a root portion attached to the lower surface of the hub plate, and an end portion of the inner wing portion extending to be narrower in an outer direction toward the outer side of the hub plate so as to be bent toward the lower direction of the inner wing portion; From the bent portion formed at the boundary with the wing portion, the angle of bending gradually increases toward the tip direction, and the outer wing portion bent in multiple stages inclined downward in both directions from the center portion to the pitch angle gradually decreases toward the tip direction from the bending portion. Agitated vanes; And a winglet portion extending from the tip of the outer wing portion and bent upwardly inclined to face an upper direction of the outer wing portion.

Here, it is preferable that the outer wing is bent to face downward of the inner wing so that the bent portion, which is a boundary between the inner wing and the outer wing, is formed in a diagonal shape.

In addition, an auxiliary stirring blade may be further attached to the hub plate.

The auxiliary stirring blade may include a fixing part attached to the hub plate to be in close contact with the inner wing part, and a wing part extending from the end of the fixing part to be bent toward the lower direction of the fixing part. Can be.

Here, it is preferable that the wing portion of the auxiliary stirring blade is bent downwardly diagonally in a diagonal shape to face downward direction of the fixing portion.

Agglomerator for water treatment according to the present invention as described above, the taper portion is provided on the hollow shaft and the agglomerator rotating shaft to fasten the agglomerator rotating shaft to the end plate so that the agglomerator rotating shaft is raised along the hollow shaft to the agglomerator rotating shaft. It has the effect of assembling by inserting and tightening by force fitting method, and the straightness of the agglomerator rotating shaft is automatically formed, which prevents the agglomeration of the agglomerator rotating shaft from bending or eccentricity and also prevents bending. It is possible to insert and fasten the rotating shaft very quickly and easily, thereby greatly improving the assembly convenience, and at the same time, the reducer clutch unit is integrally provided on the input shaft, and the motor clutch unit which is flexiblely connected to the reducer clutch unit also has the input shaft itself. The drive motor rotary shaft is inserted into the input shaft By significantly reducing the length of the adapter, which is the part to be connected, it improves the power transmission straightness from the drive motor to the output shaft of the cycloid reducer, and minimizes the power transmission distance, greatly reducing vibration and noise, improving service life and maintenance costs. This greatly reduces the power transmission distance, and as the power transmission distance is minimized, as well as improving the cohesive efficiency, the low power operation is possible due to the reduction of the rolling resistance, thereby reducing the operating cost.

In addition, the agglomerator for water treatment according to the present invention is formed such that the angle at which the outer wing portion of the stirring blade is bent toward the end portion is gradually increased so that the pitch angle is gradually reduced toward the end portion at the bent portion. The outer wing portion is formed to extend toward the outer end portion of the inner wing portion to be narrower toward the outer direction, and at the same time bent to the lower direction of the inner wing portion, the length of the stirrer blade can be made longer under the same resistance conditions, By minimizing the occurrence of blind spots, the stirring intensity of the water stream is made uniform and at the same time, the flow of water flows toward the hub to increase the output power, which improves the stirring efficiency. From the center to gradually decrease the pitch angle toward The auxiliary stirring blades having wings formed bent diagonally downward in multiple stages in the direction of the side edges are further attached to the hub plate so that the stirring energy is uniform throughout the stirring blades and the auxiliary stirring blades. There is an effect to evenly distribute the fluid energy of iii) to improve the water treatment efficiency.

In addition, the flocculator for water treatment according to the present invention further includes auxiliary stirring blades in addition to the stirring blades, so that sediment deposition does not occur not only at the bottom of the wall portion of the paper but also at the center of the bottom surface of the paper where the hub of the impeller is located. By preventing the coagulation efficiency can be further improved, there is an effect to further improve the water treatment efficiency.

In addition, the flocculator for water treatment according to the present invention is further formed by the winglet portion to prevent the generation of vortex at the end of the stirring blade to minimize the phenomenon that the stirring blade shakes up and down more than the conventional flocculator for water treatment Since it can be formed long, it is more effective to prevent sediment deposition from occurring at the lower end of the wall part of the paper than the conventional agglomerator for water treatment, so that the coagulation efficiency can be further improved. At the same time, by minimizing the shaking of the stirring blade up and down, the fatigue life of the stirring blade is improved, as well as the power loss can be significantly reduced, so that the maintenance cost can be reduced, and the operation noise can also be greatly reduced.

In addition, the aggregator for water treatment according to the present invention does not need to install a separate water storage device because the winglet portion functions as a stabilizer, and as the outer wing portion is bent in multiple stages, a plurality of force beams are formed at regular intervals on the outer wing portion. By reinforcing the strength of the wing portion, even if the stirring blade is made of a thinner iron plate than the conventional agglomerator for water treatment, the stirring blade is not inverted, there is an effect that can significantly reduce the manufacturing cost.

1A is a view for explaining the configuration of a general water treatment flocculator
1B is a cross-sectional view for explaining the configuration of a general water treatment flocculator;
1C is a diagram for explaining an input shaft of a general agglomerator.
2 is an exemplary view showing an installation state of the stirrer for water treatment according to the present invention.
3 is a detailed view of 'a' of FIG.
Figure 4 is a perspective view of the input shaft applied to the clutch means of the stirrer for water treatment according to the present invention
5 is an exploded perspective view of FIG.
6 is a perspective view of an impeller according to the present invention;
7 is a plan view of the impeller according to the present invention;
8 is a view for explaining the change in the length of the outer wing of the impeller according to the present invention

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In describing an embodiment of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. For the convenience of description, the same reference numerals are given to the same parts as those of the conventional water treatment flocculator.

2 is an exemplary view showing an installation state of the water treatment stirrer according to the present invention, Figure 3 is a detailed view of the 'ga' of FIG.

2 to 3, the aggregator for water treatment according to the present invention, the deceleration means 10, hollow shaft 16, agglomerator rotating shaft 11, impeller 12, clutch means 13, drive motor ( 14), the oil containing portion 15 is configured.

The deceleration means 10 of the aggregator for water treatment according to the present invention configured as described above is a gear unit 100 is installed on the upper surface of the coagulation tank 20, and the cycloid is installed on the upper end of the gear unit 100 It consists of a reducer 101.

The hollow shaft 16 is supported by the plurality of self-aligning roller bearings 160 to be rotatable inside the gear unit 100, and is connected to the cycloid reducer 101 by a gear 161. At the lower end of the inner circumferential surface of the hollow shaft 16, a tapered portion 162 having a predetermined height is formed to gradually decrease in diameter toward the upper direction.

Here, the gear connecting the hollow shaft 16 and the cycloid reducer 101 is a helical gear 161a and a helical gear 161a installed on the outer circumferential surface of the hollow shaft 16 and the helical gear 161a to be connected to the gear. It is preferable that the pinion gear 161b provided on the output shaft 101a of 101 be used.

The agglomerator rotating shaft 11 has an upper end inserted into the hollow shaft 16, and the upper end is screwed to the end plate 163 provided on the upper surface of the hollow shaft 16 by the fixing member 164. The upper end portion is provided with a tapered portion 110 inserted into the tapered portion 162 formed on the hollow shaft 16, and screwed by the fixing member 164, the agglomerator rotating shaft 11 is a hollow shaft ( As it rises in the upper direction of the 16, it is possible to obtain the effect of assembling the agglomerator rotary shaft 11 to the hollow shaft 16 in an interference fit manner.

The impeller is installed at the lower end of the agglomerator rotating shaft 11, the drive motor 14 is connected by the cycloid reducer 101 and the clutch means (13).

In addition, the oil accommodating part 15 may surround the outside of the hollow shaft 16 to prevent leakage of lubricating oil filled in the gear part 100 between the gear part 100 and the hollow shaft 16. To help.

Here, the oil receiving portion 15 as described above is composed of a ring-shaped groove 150, the guard portion 151, the blocking wall 152, the ring-shaped groove 150 of the oil receiving portion 15 as described above It is formed on the bottom surface of the helical gear (161a) provided on the outer circumferential surface of the hollow shaft 16, the guard portion 151 is fixed to the interior of the gear portion 100 and the central portion by the hollow shaft 16 The penetrating wall 152 is inserted into an upper end of the ring-shaped groove 150 and fixedly installed on an upper surface of the guard part 151 to surround the outside of the hollow shaft 16.

Next, the configuration of the clutch means of the aggregator for water treatment according to the present invention will be described in detail with reference to FIGS. 3 to 5.

Figure 4 is a perspective view of the input shaft applied to the clutch means of the agglomerator for water treatment according to the present invention, Figure 5 is an exploded perspective view of FIG.

3 to 5, the clutch means 13 of the aggregator for water treatment according to the present invention, the lower end is connected to the cycloid reducer 101 and the upper end is connected to the adapter 130 and the drive motor 14, It is installed in the adapter 130 is composed of an input shaft 131 connecting the drive motor 14 and the cycloid reducer 101.

Here, the input shaft 131 is composed of a support portion 131a, an eccentric mounting portion 131b, a stepped support portion 131c, a reducer clutch portion 131d, and a motor clutch portion 131e.

The support portion 131a of the input shaft 131 configured as described above is inserted into and supported by a bearing 101c inserted into the expansion connection portion 101b of the output shaft 101a of the cycloid reducer 101, and the eccentric mounting portion 131b is formed to extend to have a diameter larger than the support portion 131a at one side of the support portion 131a, and a key groove 1310b into which the key of the eccentric unit 101d is inserted is formed on the outer circumferential surface thereof, and the step support portion 131 131c is formed to have a diameter larger than the eccentric mounting portion 131b on one side of the eccentric mounting portion 131b, and the reducer clutch portion 131d is provided on one side of the step supporting portion 131c. It is formed to extend in a hollow shape so as to have an outer diameter smaller than the diameter of one side and a plurality of clutch projections 1310d protruding at a predetermined interval on one side, the motor clutch portion 131e is the rotational axis of the drive motor 14 ( Hollow type to be built up at 140) Key groove 1310e is formed in the inner peripheral surface is inserted into the key of the drive shaft 14, the rotary shaft 140, and the other side is inserted and coupled between the neighboring clutch projection (1310d) of the reducer clutch portion (131d) A plurality of clutch protrusions 1311e are formed to protrude at regular intervals.

Here, the clutch protrusion 1311e of the motor clutch unit 131e is adjacent to each other of the reducer clutch unit 131d such that both sides thereof are spaced apart from the side surfaces of the clutch protrusion 1310d adjacent to each other by the reducer clutch unit 131d. It is preferable to be inserted and coupled between the clutch protrusion 1310d.

In addition, an impact preventing member 131f may be further interposed between both side surfaces of the clutch protrusion 1311e of the motor clutch unit 131e and side surfaces of the clutch protrusion 1310d adjacent to each other of the reducer clutch unit 131d.

Here, the impact preventing member 131f is composed of a body portion 1310f and a plurality of impact preventing projections 1311f, and the body portion 1310f of the impact preventing member 131f configured as described above is the clutch of the reducer. It is formed in a ring shape so as to be interposed between the other side surface of the portion 131d and the other side surface of the motor clutch portion 131e, and the plurality of impact preventing members 131f are clutch protrusions of the motor clutch portion 131e. 1311e is protruded and formed on the outer circumferential surface of the body portion 1310f so as to be interposed between both side surfaces of the 1311e and side surfaces of the clutch projection 1310d adjacent to each other of the reducer clutch portion 131d.

In addition, in the direction of the inner circumferential surface from the outer circumferential surface of the motor clutch unit 131e, a screw thread capable of screwing a fixing member (not shown) to fix the motor clutch unit 131e to the rotation shaft 140 of the driving motor 14 is provided. A plurality of fixing holes 1312e formed may be further penetrated at a predetermined interval.

6 to 8, the impeller structure of the aggregator for water treatment according to the present invention will be described in detail as follows.

Figure 6 is a perspective view of the impeller according to the present invention, Figure 7 is a plan view of the impeller according to the present invention, Figure 8 is a view for explaining the change in the length of the outer wing of the impeller according to the present invention.

6 to 8, the impeller 12 of the aggregator for water treatment according to the present invention includes a hub 120, a hub plate 121, a stirring blade 122, and a winglet 123. .

The hub 120 of the impeller 12 according to the present invention configured as described above is arranged at the end of the agglomerator rotating shaft 11, and the hub plate 121 has a plurality of one side on the outer circumferential surface of the hub 120. Radially attached so as to be inclined in a direction, the stirring vane 122 may include an inner wing 122a having a root portion 1220a attached to a lower surface of the hub plate 121, and an inner wing 122a of the inner wing 122a. The end portion is formed so as to extend toward the outside toward the outer width is bent toward the lower direction of the inner blade portion (122a), the end portion in the bent portion (1220c) formed in the boundary portion with the inner blade portion (122a) The bent angle gradually increases toward the direction 1221b, so that the pitch angle gradually decreases toward the end portion 1221b from the bend portion 1220c. It is composed of a side wing portion (122b), the winglet portion 123 is formed extending to the end portion (1221b) of the outer wing portion 122b is bent upwardly inclined to face the upper direction of the outer wing portion (122b). .

Here, the outer wing portion 122b is bent to face the lower direction of the inner wing portion 122a such that the bent portion 1220c, which is a boundary between the inner wing portion 122a and the outer wing portion 122b, is formed in a diagonal shape. It is preferably formed.

In addition, the hub plate 121 may be further attached to the auxiliary stirring blade 124, the auxiliary stirring blade 124 as described above is attached to the hub plate 121 to be in close contact with the inner blade portion (122a). It is composed of a fixed portion 124a and a wing portion 124b extending to the end of the fixed portion 124a and bent to face the downward direction of the fixed portion 124a.

Here, it is preferable that the wing portion 124b of the auxiliary stirring blade 124 is bent to be inclined downward in a diagonal form in the downward direction of the fixing portion 124a.

Again, with reference to Figures 2 to 8 will be described in detail with respect to the effect of the flocculator for water treatment according to the present invention.

First, referring to FIGS. 2 to 8, the aggregator for water treatment according to the present invention is provided with a tapered portion 162 at the lower end of the inner circumferential surface of the hollow shaft 16, and is inserted into and coupled to the hollow shaft 16. The upper end of the outer peripheral surface of the rotary shaft 11 is formed with a taper 110 inserted into the tapered portion 162, so that the upper end of the agglomerator rotating shaft 11 is screwed to the end plate 163 using the fixing member 164. When combined, the agglomerator rotating shaft 11 is raised along the inner circumferential surface of the hollow shaft 16, and as the agglomerator rotating shaft 11 is raised along the hollow shaft 16, the agglomerator rotating shaft ( 11) the tapered portion 110 formed on the outer circumferential surface of the hollow shaft 16 has the effect of assembling the tapered portion 162 formed on the inner circumferential surface of the hollow shaft 16, so that the straightness of the agglomerator rotating shaft 11 is automatically Is formed and the inner peripheral surface of the hollow shaft 16 and the agglomerator rotating shaft 11 Since there is no gap between the outer circumferential surface, vibration and noise can be greatly reduced by preventing the phenomenon that the agglomerator rotating shaft 11 is rotated or eccentrically bent, and the components such as bearings installed inside the agglomerator are prevented. Not only does it significantly reduce wear and breakage, it can reduce maintenance costs and prolong the service life of the agglomerator, and also makes the agglomerator rotating shaft 11 very quickly and easily inside the hollow shaft 16. By inserting and tightening, there is an advantage that the assembly convenience can be greatly improved.

As described above, since the agglomerator rotating shaft 11 is not shaken or eccentric, bending does not occur, an oil seal interposed to maintain airtightness between the gear part 100 and the lower end of the outer circumferential surface of the hollow shaft 16 ( The separation phenomenon and the form of the deformation or wear of the 17) can be prevented from occurring because the oil inside the gear unit 100 can be prevented from leaking, and thus, there is an advantage that the liquid inside the coagulation tank 20 is not contaminated.

In addition, the agglomerator for water treatment according to the present invention is provided with an oil receiving part 15 formed of a ring-shaped groove 150, a guard part 151, and a blocking wall 152 in the gear part 100. The lubricating oil filled in the 100 is leaked into the gap between the stirrer rotating shaft 11 and the gear unit 100 and flows into the coagulation tank 20 to more reliably prevent the phenomenon of flowing into the coagulation tank 20. By doing so, it is possible to prevent a phenomenon in which the liquid filled in the flocculation tank 20 is contaminated by the leaked oil.

That is, the lubricating oil filled in the gear part 100 by the blocking wall 152 is primarily prevented from directly contacting the hollow shaft 16, and the lubricating oil is hollowed over the blocking wall 152. Although the oil flows between the shaft 16 and the blocking wall 152, the lubricating oil introduced between the hollow shaft 16 and the blocking wall 152 is in the oil receiving portion 15 formed of the guard part 151 and the blocking wall 152. By storing and preventing leakage, the lubricant is prevented from leaking into the gap between the hollow shaft 16 and the gear unit 100.

Next, referring to FIGS. 4 and 5, in order to connect the drive motor 14 and the cycloid reducer 101 using the clutch means 13 of the water treatment flocculator according to the present invention, first, the input shaft 131. The impact preventing member 131f is coupled to the reduction gear clutch portion 131d of the.

That is, the impact preventing protrusion 1311f of the impact preventing member 131f is inserted between the neighboring clutch protrusions 1310d protruding from the reducer clutch portion 131d, and one side surface of the reducer clutch portion 131d is provided. The impact preventing member 131f is coupled to the reducer clutch portion 131d so that the other side surface of the body portion 1310f is in contact with each other, and one side of the clutch protrusion 1310d of the reducer clutch portion 131d and the impact preventing protrusion ( The impact preventing member 131f is coupled to the reducer clutch portion 131d so that the other side surfaces of the 1311f are in contact with each other.

After the impact prevention member 131f is coupled to the reduction gear clutch portion 131d as described above, the motor clutch portion 131e and the clutch protrusion 1311e are prevented from impacting the other side of the clutch protrusion 1310d of the reduction gear clutch portion 131d. The motor clutch unit 131e is arranged on the rotation shaft 140 of the driving motor 14 so as to be inserted between one side surface of the protrusion 1311f, and at this time, a key (not shown) of the rotation shaft 140 of the driving motor 14. Is inserted into the key groove 1310e formed on the inner circumferential surface of the motor clutch unit 131e so that the motor clutch unit 131e can be rotated in cooperation with the rotation shaft 140 of the driving motor 14.

As described above, after the motor clutch unit 131e is laid out on the rotation shaft 140 of the driving motor 14, a fixing member (not shown) is attached to the plurality of fixing holes 1312e formed in the motor clutch unit 131e. By screwing, the outer peripheral surface of the driving motor 14 rotating shaft 140 is pressed by the fixing member, thereby preventing the motor clutch unit 131e from moving in the direction of the central axis of the driving motor 14 rotating shaft 140.

As described above, the water treatment flocculator according to the present invention includes not only the reducer clutch unit 131d integrally provided on the input shaft 131, but also the motor clutch unit 131e that is flexibly connected to the reducer clutch unit 131d. By being provided at 131 itself, the length of the adapter 130 of the cycloid reducer 101, which is a portion that is connected to the input shaft 131 by the rotational shaft 140 of the driving motor 14, can be greatly reduced.

Thus, the agglomerator for water treatment according to the present invention improves the power transmission straightness from the rotational shaft 140 to the output shaft 101a of the driving motor 14 by significantly reducing the length from the speed reduction means 10 to the driving motor 14. At the same time, power transmission distance can be minimized.

As described above, the aggregator for water treatment according to the present invention can improve the power transmission straightness, and can greatly reduce vibration and noise, thereby preventing the breakage of components such as bearings, thereby greatly reducing maintenance costs. In addition, there is an effect that can greatly extend the service life.

In addition, the agglomerator for water treatment according to the present invention significantly reduces the length from the deceleration means 10 to the drive motor 14, thereby minimizing the power transmission distance, thereby improving stirring efficiency and significantly shortening the power transmission distance. Due to the reduced rolling resistance, low-power operation is possible, which not only reduces operating costs but also minimizes installation space constraints in the left and right length directions.

Next, referring to Figures 6 to 8, the impeller 12 of the aggregator for water treatment according to the present invention, the outer blade portion 122b of the stirring blade 122 is the end portion 1221b at the bent portion 1220c ), The angle of bending is gradually increased toward the) direction, and the pitch angle is gradually reduced toward the end portion 1221b in the bend portion 1220c, and the outer wing portion 122b is the end portion at the bending portion 1220c. As the width becomes narrower toward the direction 1221b, the pitch angle is small at the end 1221b of the outer wing 122b in proportion to the radius of the outer wing 122b, and the bending angle 1220c is small. ), The pitch of the outer blade 122b is slower, and the pitch angle is large, so that the stirring energy generated at the end portion 1221b and the bent portion 1220c of the outer blade 122b is uniform. (I) to distribute the fluid energy evenly.

In addition, the outer wing portion 122b of the impeller 12 is formed to be bent toward the lower direction of the inner wing portion 122a, so that the bent portion 1220c is formed at regular intervals, so that the impeller of the conventional water treatment flocculator Compared to manufacturing the outer wing 122b with a thin iron plate, the outer wing 122b can be manufactured by using a thin iron plate, and the outer wing 122b can be folded back despite the manufacturing of the outer wing 122b with a thin iron plate. To prevent it.

In addition, the outer wing portion 122b of the impeller 12 is formed to be bent toward the lower direction of the inner wing portion 122a, so that water is collected as much as possible by hand to push the water as much as possible in the desired direction. By pushing it out, the stirring effect can be maximized.

In addition, the outer wing portion 122b of the impeller 12 is formed to extend so as to narrow in the outer direction toward the outer end portion of the inner wing portion 122a as shown in Figure 8 compared with the conventional water treatment agitator impeller The length L of the outer wing 122b can be further extended by the narrower width A of the outer wing 122b, thereby minimizing the occurrence of dead zones in the tank 20. Of course, it is possible to obtain a more effective stirring efficiency at a predetermined power.

In addition, a winglet for minimizing the tremor width of the stirring blade 122 due to the vortex generated from the end portion 1221b of the outer wing portion 122b to the end portion 1221b of the outer wing portion 122b. By forming the bent portion 123, the radius of the stirring blades 122 can be formed longer than that of the conventional water treatment flocculator impeller, so that the lower portion of the wall portion of the base is lower than the impeller of the conventional water treatment flocculator. Since sediment deposition can be more effectively prevented, there is an advantage that the mixing and flocculation efficiency can be further improved, and the winglet 123 functions as a stabilizer so that a separate water storage device is provided at the bottom of the impeller 12. It is possible to stably rotate the agglomerator rotating shaft (11) without being installed in.

That is, at the end of the stirring blade of the conventional water treatment flocculator impeller, the fluid rises from the lower part of the stirring blade to the upper part of the stirring blade, and vortex, that is, vortex occurs, which causes the stirring blade to shake up and down. . However, a winglet portion 123 is formed at the end portion 1221b of the outer wing portion 122b of the impeller 12 according to the present invention, thereby allowing the flow of fluid by the winglet portion 123. By blocking the vortices from the end portion 1221b of the outer blade portion 122b to prevent the vortex, that is, the stirring blades 122 to minimize the phenomenon of shaking up and down to minimize the length of the stirring blade 122 for the conventional water treatment flocculation Since it can be formed longer than the impeller of the group, it is possible to more effectively prevent the deposition of sediment at the bottom of the wall portion of the paper than the impeller of the conventional water treatment agglomerator, which can further improve the coagulation efficiency, thereby improving the water treatment efficiency. By minimizing the shaking of the stirring blade 122 up and down, the fatigue life of the stirring blade 122 is greatly improved and power loss can be greatly reduced. Therefore, the maintenance cost can be reduced, and the operation noise can also be greatly reduced. The stirring blade 122 minimizes the shaking up and down, thereby stably maintaining the agglomerator rotating shaft 11 without installing a separate water storage device. By allowing it to rotate, the manufacturing cost is also greatly reduced.

In addition, the impeller 12 has an auxiliary stirring blade 124 is further attached to the hub plate 121, as well as the bottom of the wall portion of the branch, as well as the bottom surface of the branch where the hub 120 of the impeller is located. It is possible to significantly improve the water treatment efficiency by preventing the occurrence of sediment in the central portion to further improve the flocculation efficiency compared to the conventional water treatment flocculator.

In addition, the impeller 12 is a conventional stirrer impeller formed by simply bending a plurality of predetermined angles so that the pitch angle is gradually reduced from the root portion (1220a) toward the end of the flat blade-shaped stirring blade 122 In contrast, the outer wing portion 122b is formed to extend toward the outer end portion of the inner wing portion 122a so as to be narrower in the outward direction and is bent to face the lower direction of the inner wing portion 122a, and the inner wing The angle of bending gradually increases toward the end portion 1221b from the bend portion 1220c formed at the boundary with the portion 122a, and the pitch angle gradually decreases toward the end portion 1221b from the bend portion 1220c. The length of the stirrer blade 122 is longer than that of the conventional stirrer blade under the same resistance condition by being formed in multiple stages so as to be inclined downward in both directions from the center portion. It is possible to flocculation tank: enables low occurrence of blind spots (Dead Zone) in (Tank 20) can be stirred by the intensity of the water flow uniform improve coagulation efficiency.

In addition, the impeller 12 is formed by bending the outer wing portion 122b toward the lower direction of the inner wing portion 122a, so that the flow of water flows toward the hub 120, so that the output power is increased to increase the cohesive efficiency. It can greatly improve.

In addition, the aggregator for water treatment according to the present invention is not limited to being installed and used only in the agglomeration tank 20, but an anoxic tank, an anaerobic tank, an aerobic tank, a sludge storage tank, a sludge storage tank, a storage tank, or wastewater in an advanced treatment process. It can also be installed and used in slow stirring tanks, condensation tanks, and neutralization tanks in the treatment process.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

(10): Reduction means (11): Agitator rotating shaft
(12): impeller 13: clutch means
14: drive motor 15: oil compartment
16: hollow shaft 17: oil seal
100: gear portion 101: cycloid reducer
(110) (162): Taper portion 120: Hub
121: hub plate 122: stirring blade
123: winglet 124: auxiliary stirring wing
(130): housing 131: input shaft
150: ring groove 151: guard portion
152: barrier wall 161 gear
161a: Helical Gear 161b: Pinion Gear
163: end plate 164: fixing member

Claims (12)

Deceleration means comprising a gear portion provided on an upper surface of the coagulation tank and a cycloidal reducer provided on an upper end portion of the gear portion;
A hollow shaft rotatably installed in the gear unit, connected to the cycloid reducer, and having a tapered portion having a predetermined height at the lower end of the inner circumferential surface thereof, the diameter of which gradually decreases in an upward direction;
The upper end is inserted into the hollow shaft, and the upper end is screwed to the end plate provided on the upper surface of the hollow shaft by a fixing member, and the upper end is formed with a taper part inserted into a taper formed on the hollow shaft, and screwed by the fixing member. An agglomerator rotating shaft which is fastened and rises along the hollow shaft to be inserted into the hollow shaft in an interference fit manner;
An impeller installed at the lower end of the agglomerator rotating shaft;
A drive motor connected by the cycloid reducer and clutch means; And
And an oil receiving part surrounding the outside of the hollow shaft to prevent leakage of lubricating oil filled in the gear part between the gear part and the hollow shaft.
The clutch means includes: a support part inserted into and supported by a bearing inserted into an expansion connection part of an output shaft of a cycloid reducer;
An eccentric installation portion formed on one side of the support portion to have a larger diameter than the support portion, and an outer circumferential surface formed with a key groove into which an eccentric key is inserted;
A stepped support part extended to have a larger diameter than the eccentric mounting part on one side of the eccentric mounting part;
A reducer clutch portion formed to extend in a hollow shape to have an outer diameter smaller than a diameter of the step support portion on one side of the step support portion, and a plurality of clutch protrusions protrude at a predetermined interval on one side; And
It is formed in a hollow shape so as to be arranged on the drive motor rotation shaft, the inner peripheral surface is formed with a key groove into which the key of the motor rotation shaft is inserted, the other side is a plurality of clutch projections are inserted and coupled between the neighboring clutch projection of the reducer clutch portion Agglomerator for water treatment, comprising an input shaft consisting of; a motor clutch portion protruding at intervals.
The method of claim 1,
The oil storage unit,
A ring groove formed in a bottom portion of a gear provided in the hollow shaft;
A guard portion fixedly installed in the gear portion and having a center portion penetrated by the hollow shaft; And
And a blocking wall having an upper end inserted into the ring-shaped groove and fixed to an upper surface of the guard part so as to surround the outer side of the hollow shaft.
delete The method of claim 1,
The clutch protrusion of the motor clutch unit is inserted into and coupled between the adjacent clutch protrusions of the reducer clutch unit so that both sides are spaced apart from the side surfaces of the clutch clutch unit adjacent to each other by a predetermined distance.
The method of claim 4, wherein
And an impact preventing member is interposed between both side surfaces of the clutch protrusion of the motor clutch portion and side surfaces of the clutch protrusion adjacent to each other of the reducer clutch portion.
The method of claim 5, wherein
The impact preventing member,
A ring-shaped body portion interposed between the other side surface of the reducer clutch portion and the other side surface of the motor clutch portion; And
A plurality of impact preventing protrusions protruding at regular intervals on the outer circumferential surface of the body portion so as to be interposed between both side surfaces of the clutch protrusion of the motor clutch portion and the side of the clutch protrusion adjacent to each other of the reducer clutch portion; .
The method according to claim 6,
In the direction from the outer peripheral surface of the motor clutch portion to the inner circumferential surface of the water treatment agglomerator characterized in that a plurality of fixing holes formed with a threaded line for screwing the fastening member for fastening the motor clutch unit to the drive shaft rotation shaft is further formed at regular intervals .
The method of claim 1,
The impeller,
A hub arranged at a lower end of the agglomerator rotating shaft;
A hub plate radially attached to the outer circumferential surface of the hub to be inclined in one direction;
An inner wing portion having a root portion attached to the lower surface of the hub plate, and an end portion of the inner wing portion extending to be narrower in an outer direction toward the outer side of the hub plate so as to be bent toward the lower direction of the inner wing portion; From the bent portion formed at the boundary with the wing portion, the angle of bending gradually increases toward the tip direction, and the outer wing portion bent in multiple stages inclined downward in both directions from the center portion to the pitch angle gradually decreases toward the tip direction from the bending portion. Agitated vanes; And
And a winglet portion extending from the tip of the outer wing portion and bent upwardly inclined upwardly toward the upper direction of the outer wing portion.
The method of claim 8,
The outer wing portion, the agglomerator for water treatment, characterized in that the bending portion that is the boundary between the inner wing portion and the outer wing portion is bent toward the lower direction of the inner wing portion to be formed in a diagonal form.
The method of claim 8,
The hub plate is characterized in that the auxiliary stirring blade is further attached to the water treatment flocculator
The method of claim 10,
The auxiliary stirring blade, characterized in that consisting of a fixed portion attached to the hub plate to be in close contact with the inner wing portion, and a wing portion formed extending to the end of the fixed portion to be bent toward the lower direction of the fixed portion Agglomerator for water treatment.
The method of claim 11,
The wing portion of the auxiliary stirring blades, the agglomerator for water treatment, characterized in that bent to be inclined downward in a diagonal form to face in the lower direction of the fixing portion.

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