KR940001655Y1 - Cohesive device - Google Patents

Abstract

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Description

Agglomerator

Figure 1 is a vertical agglomerator display of the present invention is installed.

Figure 2 is a horizontal agglomerator display of the present invention is installed.

3 is an eshido connecting the subject innovation to the VS motor installed in the aggregate.

Figure 4 is an illustration of connecting the subject innovation to the inverter motor installed in the aggregate.

5 is a driving system diagram of the present invention.

6 is a diagram showing a circuit configured to interlock operation of a function of an operation panel in a central control room.

7 is a diagram showing a horizontal agglomerator using a G value setter instead of a G-point indicator and eliminating the PID controller and power sequence.

8 is a vertical agglomerator display using a G-value setter instead of a G-value indicator and power controller without PID controller.

9 is a G value setter system diagram.

10 is an operating system diagram by the G value setter.

FIG. 11 is a diagram showing a circuit configured to interlock and operate the continuously variable servo controller by the G value setter in the central control room. FIG.

* Explanation of symbols for main parts of the drawings

1: motor 2: continuously variable transmission

3: Reducer 4: G value instruction calculator

5: PID controller 6: CVT servo controller

6-1: VS Controller 6-2: Inverter

7: operation panel 8: power cleaner

9: Temperature 쎈 12: Impeller

16: G value setter 17: Temperature indicator

18: agglomerator control panel

The present invention is to install the operation panel assembled with the G value indicating operator, the PID controller and the continuously variable transmission servo controller in rotating the impeller in the flocculation basin with the motor, and installs a power sensor between the operation panel and the power line of the motor and connects it with the signal line. It is installed in the flocculation basin so that the end of the temperature sensor is submerged in water, and it is connected to the control panel by the signal line, and the output of the control panel is connected to the servo device so that a constant velocity gradient value (hereinafter referred to as G value) regardless of the temperature change of the water in the flocculation basin The present invention relates to an agglomerator for maintaining good agglomeration and exerting good flocculation and precipitation effects.

In waterworks or industrial water treatment, admixtures and flocculators are important equipments used to increase sedimentation capacity and to remove turbidity. According to the sedimentation theory, G value suitable for coagulation is the best when it is near 1st stage 100, 2nd stage 50, 3rd stage 10 in the 3rd step of TAPEREDFLOCCULATI0N, or about 1st stage 75, 2nd stage 50, 3rd stage 25 and so on. Precipitation takes place.

However, the conventional flocculator cannot display the G value directly, so it is impossible to know the operation state accurately, and the situation is adjusted by experience. In addition, since the G value is affected by the water viscosity coefficient, when the temperature of the water changes due to seasonal effects and the viscosity coefficient changes, the G value also changes, resulting in poor coagulation sedimentation.

The present invention will be described in detail based on the accompanying drawings as completely solved the drawbacks of the conventional flocculator as described above.

In the vertical type agglomerator of FIG. 1, a pedestal 13 is fixed on the upper structure (b) of the agglomeration paper and the gearhead 3 in which the motor 1 and the mechanical continuously variable transmission 2 are directly connected thereto. In the case in which the agglomerator shaft 11, which is integrally assembled with the impeller 12, is connected to the output shaft 3-1 of the reduction gear 3 by a coupling 10, the G-value indicating operator 4 is provided. , Install the control panel 7 assembled with the PID controller 5 and the stepless speed servo controller 6, and install the power sequencer 8 between the control panel 7 and the power of the motor 1 1), in the agglomeration paper (A) is installed in the upper structure (b) of the aggregate paper so that the end of the temperature sensor (9) is submerged in water, and connected to the control panel (7) by a signal line (9-1), The output of the operation panel 7 was connected to the servo adjuster 2-1 through the electric wire 2-3.

2 shows another embodiment of the present invention, in which a pedestal 20 is fixed to the bottom of the machine room (a) of the agglomeration paper (a) in a horizontal agglomerator, and a motor (1) and a continuously variable transmission (2) are directly connected thereon. The gearhead 3-3, 15-1 and the chain 3-3 between the output shaft of the speed reducer 3 and one end of the agglomerator shaft 13, respectively. In the agglomerator shaft 13, the wing arm 15 fixed with the blade 14 is condensed, and the G value indicating operator 4, PID controller 5, continuously variable transmission servo controller 6 in the machine room C. ) Install the control panel (7) assembled, but install the power sequence 8 between the control panel (7) and the power line of the motor (1) and connect it with the signal line (8-1). It is installed in the aggregate structure upper structure (9-2) so that the end of the temperature beam (9) is submerged in water and connected to the operation panel by the signal line (9-1), and the output of the operation panel (7) through the wire (2-3) Connected to servo adjuster (2-1) .

3 shows another embodiment of the present invention, in which an impeller driving device uses a VS motor, in which a G value indicating operator (4), a PID controller (5), and a VS controller (6-1) are assembled. A power coder 8 is installed between the power line of the motor and the VS motor 1-1 and connected to the signal line 8-1, and between the temperature source 9 and the operation panel 7 to the signal line 9-1. The output of the control panel 7 was connected to the servo control device 2-1 through the wire 2-3.

4 shows another embodiment of the present invention, in which an inverter motor is used for an impeller driving device, a G-value instruction calculator (4), a PID controller (5), and an inverter (6-2) are assembled with a control panel (7) and an inverter. An electric power sensor 8 was installed between the power lines of the motor 1-2 and connected by a signal line 8-1, and between the temperature sensor 9 and the operation panel by a signal line 9-1.

7 and 8 show another embodiment of the present invention, in which the PID controller and the power sensor are removed and the G value setter 16 shown in FIG. 9 is used instead of the G value indicating operator. The continuously variable servo controller 6 detects the speed of the continuously variable transmission 2 with a tachometer and feeds it back to match the set speed with the actual speed.

Referring to the operation of the present invention is as follows.

Where p: motor power ㎏-m / sg: gravitational acceleration 9.8 m / sec ² u: absolute viscosity of water ㎏ / ms v: volume of agglomerated paper ㎥ c: shape factor of agglomerator blades 1.5-1.8 p: density of water u: circumferential speed of the flocculator blade m / sy: overall mechanical efficiency <1

As shown in Equation A, if the power is constant, the G value is inversely proportional to the water's viscosity coefficient u, and it can be seen that ³ must be changed as u changes to maintain the constant G value.

Moreover, the relationship of water temperature and viscosity is as follows.

u = u ₀ / (1 + C ₁ t + C ₂ t ² ) (B)

uo = 1.829 CP (water at 0 ° C)

C ₁ = 0.03488

C ₂ = 0.000215

t = water temperature ℃

TABLE 1

As shown in Table 1, when the temperature decreases, the G value decreases, so that aggregation becomes poor, and when the temperature rises, the G value increases and the aggregation may be prevented by excessive stirring. Equation A also shows that motor power P, mechanical efficiency y, and viscosity coefficient u are needed to obtain G value.

It can be seen from Equation C that the speed value to make the G value constant is proportional to the third power of u. First, when the G value is set by the G value instruction operator 4, the PID controller 5 outputs an output signal, and the continuously variable transmission servo controller 6 operates the servo adjusting device 2-1 of the continuously variable transmission 2 By changing the output speed of the continuously variable transmission 2, the impeller 12 of the agglomerator connected to the reduction gear shaft 3-1 is rotated. When the impeller 12 rotates, power is consumed and a corresponding current flows in the motor 1, and the power sequencer 8 detects the power and sends it to the G value indicating operator 4. On the other hand, the temperature sensor 9 submerged in the water in the flocculation basin detects the temperature of the water and sends it to the G-value indicating operator 4. The G-value instruction operator (4) receives the temperature of the water and the power signal, and finds u by the operation u = u ₀ / (1 + C ₁ t + C ₂ t ² ), If the G value signal is larger or smaller than the set G value input to the PID controller 5, the PID controller 5 issues an appropriate signal to match the G value of the coagulator. Since the G value is directly displayed, and the G value is set, the blade rotation speed of the flocculator changes so that a constant G value is automatically maintained even if the water temperature changes.

The operation principle is the same when a VS motor or an inverter motor is used in a horizontal agglomerator as shown in FIG. 2 or in a driving device as shown in FIGS. 3 and 4.

The same applies to any type of flocculator or admixture.

Manual adjustment handle (2-2) of the continuously variable transmission (2) is for operating the flocculator by manual operation in case of automatic device failure.

Another operation of the seventh and eighth degrees of indicating and adjusting G is as follows.

Install the flocculator, rotate the impeller at the maximum speed designed, and measure the motor power (P) and water temperature (t) by measuring power and temperature with separate portable power crab and thermometer. If the maximum velocity is N RPM, then in equation B, the viscosity u = u ₀ / (1 + C ₁ t + C ₂ t ² ), so G is Obtained from

If we transform Equation A, Where 2. VCAp is regarded as a constant unchanged at about 0 ° C to 30 ° C, and is replaced by another constant K ₁ , and the agglomerator blade circumferential speed u is proportional to the rotational speed N PRM, so the relationship coefficient between u and N If we put K ₁ into the constant K ₂

As in Equation D, impeller rotation speed N is a function of G and t only.

K ₃ is determined by a specific ptN above.

The G value display and the speed controller of FIG. 9 perform the following calculations.

1) Calculate u by taking the water temperature t ℃. (Formula B)

2) Enter the power meter and u value of G into the keyboard to display the G value on the indicator.

3) Calculate the rotational speed signal by calculating the equation 4 based on the G and t values.

4) If the G value is artificially set by the above calculation result, the G value is constant by automatically adjusting the impeller rotation speed as the water temperature t changes.

The agglomerator of the present invention configured as described above can directly operate at the optimum G value by directly instructing the G value, so that it is easy to operate and maintains a constant G value regardless of the water temperature or season so that good flocculation and precipitation are possible. .

In addition, only one temperature sequencer (9) and a G value setter are installed for each coagulation step so that the values of the coagulators can be operated simultaneously at the same time in the central control room.

Claims (2)

In rotating the impeller 12 in the agglomerator in the vertical or horizontal agglomerator with the motor 1, the G value instruction operator 4, the PID controller 5, the continuously variable servo controller 6 ) Install the control panel (7) assembled, but install the power sequencer (8) between the control panel (7) and the power line of the motor (1) and connect it with the signal line (8-1). It is installed on the agglomerator upper structure (b) so as to be submerged in water at the end of the processor (9) and connected to the operation panel (7) by the signal line (9-1), and the output of the operation panel (7) is connected to the wire (2-3). Agglomerator characterized in that the rotation of the impeller changes in accordance with the indication of the G value by configuring the connection to the servo control device (2-1) through. The method according to claim 1, wherein the PID regulator and the power sequence are eliminated, and the G value setter 16 is used instead of the G value indicating operator. The continuously variable speed servo controller 6 detects the rotation speed of the continuously variable transmission 2 with a tachometer. Agglomerator configured to bend back to match set speed and actual speed.