KR100732197B1 - Uv lamp ballast system in sewage treatment plant - Google Patents

Abstract

A UV(UltraViolet) ballast system of a sewage treatment plant is provided to increase a life span of a UV lamp and reduce power consumption by varying an optical output generated from the UV lamp. A UV ballast system of a sewage treatment plant includes a controller(30), a plurality of ballasts(10), and a plurality of UV lamps(20). The controller(30) has a sensor which detects a quantity of sewage continuously. The controller(30) generates a control signal as a frequency variable signal which varies an operation frequency of the plurality of ballasts(10) by analyzing data which is detected in the sensor. The plurality of ballasts(10) generates a variable output signal according to the control signal of the controller(30). The plurality of UV lamps(20) is connected to the plurality of ballasts(10) respectively, and generates variable light corresponding to the variable output signal outputted from the ballasts(10).

Description

Lamp ballast system in sewage treatment plant

1 is a block diagram of a UV lamp ballast system of a conventional sewage treatment plant.

2 is a block diagram of the UV lamp ballast system of the sewage treatment plant applied to the present invention.

3 is a graph showing the light output of the UV lamp according to the variable frequency of the ballast, according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: a plurality of ballasts 20: a plurality of UV lamps

30 controller 31 frequency variable control signal

33: on / off control signal

The present invention relates to a UV lamp ballast system of the sewage treatment plant, in particular by adjusting the output of the ballast connected to the UV lamp according to the amount of sewage to vary the light output generated by the UV lamp, thereby increasing the life of the UV lamp The present invention relates to a UV lamp ballast system of a sewage treatment plant that can reduce power consumption.

Nowadays, the virus detection incidents of tap water have increased the concern about the pollution of the water we use, and it has been found that the cause of the virus is found in the sewage treatment plant effluent. have.

Sterilization of sewage water can be classified into three types: chlorine sterilization, ozone sterilization and ultraviolet (UV) sterilization.

The chlorine sterilization method has been used as a sterilization method for wastewater for a long time, but chlorine has been known to adversely affect the generation of THM, a carcinogen, and the destruction of downstream stream ecosystems due to residual chlorine due to the mutual interaction between chlorine and organic matter in the effluent. Sterilization by began to be ruled out.

The ozone sterilization method is a method of using the strong oxidizing power of ozone for the sterilization of microorganisms. Ozone deactivates microorganisms by easily destroying the cell walls of microorganisms due to its unique strong oxidation power. However, since ozone reacts before the microorganism in the reaction with organic matter, it is necessary to maintain a very high concentration rate in the effluent containing the organic matter. That is, the sterilization power is excellent, but the operation of the high concentration injection and generating device is not secured, and most of the treatment plants avoid application.

The ultraviolet sterilization method is a method of sterilizing microorganisms in water passing through an ultraviolet irradiation region by immersing a lamp horizontally in a water flow channel. As such, sterilization using ultraviolet rays that can be used in sewage treatment plants has been evaluated as being environmentally friendly.

The sterilization method using ultraviolet rays used in the conventional sewage treatment plant may use a UV lamp ballast system.

The UV lamp ballast system of the conventional sewage treatment plant is composed of a system for processing in a fixed light output method, as shown in FIG. That is, it was a method of producing a constant output regardless of the amount of sewage.

Specifically, all of the N UV lamps 20 were turned on, and the output was a method of outputting a rated output. In general, the life of the UV lamp is determined based on the rated output and increases below the rated output. On the other hand, the price of the UV lamp 20 is more than the price of the ballast 10, the UV lamp 20 is a consumable and should be replaced when the end of its life.

Since the amount of sewage in the sewage treatment plant changes greatly with time, the UV lamp ballast system that always outputs a constant output not only maximizes the life of the UV lamp, but also generates power unnecessarily. have.

On the other hand, the ballast is generally a method of adjusting the width of the pulse is not a method that can be used in all ballast structures. That is, a problem occurs that cannot be used in the ballast structure in which the pulse width cannot be adjusted.

The present invention was made to solve the problems of the prior art as described above, by adjusting the output of the ballast connected to the UV lamp according to the amount of sewage by varying the light output generated by the UV lamp, thereby improving the life of the UV lamp It is an object of the present invention to provide a UV lamp ballast system in a sewage treatment plant that can increase and reduce power consumption.

In order to solve the technical problems as described above, the constituent means of the UV lamp ballast system of the sewage terminal treatment plant proposed by the present invention, in the UV lamp ballast system of the sewage terminal treatment plant, having a sensor for continuously detecting the amount of sewage A controller for generating a control signal by analyzing the sensed data of the sensor, a plurality of ballasts for generating a variable output signal according to the control signal of the controller, and being connected to each of the plurality of ballasts, which are output from the ballast It characterized in that it comprises a plurality of UV lamps for generating a variable light corresponding to the variable output signal.

In addition, the control signal of the controller is characterized in that the frequency variable signal for varying the operating frequency of the plurality of ballasts. That is, the output light can be controlled by varying the output light of the UV lamp in a manner of varying the operating frequency of the ballast according to the control signal of the controller.

In addition, the control signal of the controller is characterized in that the on / off signal to maintain or stop the operation of the plurality of ballasts. That is, the light output from the UV lamp may be controlled by turning on or off the operation of the ballast according to the control signal of the controller.

In addition, the operating frequency of the ballast is characterized in that it is initially set to the lowest frequency that occurs when the amount of sewage is maximum. And, the operating frequency of the ballast is characterized in that it is increased variably by the control signal of the controller, as the amount of sewage is variably reduced. That is, the initial operating frequency of the ballast is set to a frequency capable of generating light enough to maximize the purification capacity of the sewage when the amount of sewage is maximum, the frequency as the amount of sewage is variable Is constantly changing.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation and preferred embodiment of the UV lamp ballast system of the sewage terminal treatment plant of the present invention consisting of the above configuration means.

Figure 2 is a block diagram showing a UV lamp ballast system of the sewage treatment plant applied to the embodiment of the present invention.

As shown in Figure 2, the UV lamp ballast system of the sewage terminal treatment plant according to the present invention is connected to each of the plurality of ballasts (stabilizer 1 ~ ballast N) (10), each of the plurality of ballasts (1) A plurality of UV lamps (UV lamp 1 ~ UV lamp N) 20, and a controller 30 for generating a control signal for controlling the plurality of ballasts (10).

In the UV lamp ballast system of the sewage treatment plant, the controller 30 is provided with a sensor for continuously detecting the amount of sewage that changes with time. Therefore, the controller 30 continuously analyzes the data sensed by the sensor and generates a control signal corresponding to the amount of sewage that changes with time. The control signal is transmitted to the plurality of ballasts (10).

The ballasts 10 receiving the control signal from the controller 30 generate a variable output signal corresponding to the control signal and transmit the variable output signal to the plurality of UV lamps 20.

Control signals transmitted from the controller 30 to the ballast 10 may be classified into two types. That is, the control signal is a frequency variable signal 31 for varying the operating frequencies of the plurality of ballasts 10 or an on / off signal 33 for maintaining or stopping the operation of the plurality of ballasts 10.

The frequency variable signal 31 controls the operating frequency of the plurality of ballasts 10 so that the controller 30 analyzes the amount of sewage so that the light output of the UV lamp 20 can be adjusted. The signal is transmitted to the ballast (10).

In addition, the on / off signal 33 is similar to the frequency variable signal 31, so that the controller 30 analyzes the amount of sewage, so that the light output of the UV lamp 20 can be interrupted, The signal is transmitted to the ballast 10 to control the operation of the plurality of ballasts (10).

The frequency variable signal 31 and the on / off signal 33 may be selectively generated or generated in parallel under the control of the controller 30.

Under the control of the controller 30, the initial operating frequency of the ballast 10 in which the operating frequency is changed to generate an output is set to the lowest frequency among the operating frequencies. The lowest frequency among the operating frequencies is the frequency at which the ballast 10 occurs when the amount of sewage is maximum.

The operating frequency of the ballast 10 initially set to the lowest operating frequency is changed together as the amount of sewage varies. Specifically, when it is determined by the controller 30 that the amount of sewage is reduced, the controller 30 outputs a frequency variable signal 31 that increases the operating frequency of the ballast 10. To pass). Then, the ballast 10 generates an output signal corresponding to the increased operating frequency and transmits it to the UV lamp 20.

As described above, the ballast 10 generating an output signal corresponding to the increased operating frequency receives a frequency variable signal 31 that reduces the operating frequency from the controller 30 as the amount of sewage increases again. In this case, an output signal corresponding to the reduced operating frequency is generated and transmitted to the UV lamp 20.

The plurality of UV lamps 20 receiving the output signal generated from the ballast 10 generates a corresponding variable light to sterilize the sewage.

It can be seen by simple experiments that the light output from the UV lamp is controlled by the UV lamp ballast system of the sewage treatment plant described above.

The UV lamp is made of an acrylic box to perform the experiment in water to perform the experiment.

UV light quantity can be measured with IL1400A (International Light. INC.), Power can be measured with Universal Power Analyzer PM3000 (Voltech Instrments Ltd.), and the oscilloscope is used to determine the shape of the voltage and current supplied to the UV lamp. It can be measured.

Figure 3 is a graph showing the change in the amount of light over time using Lab view 6.1 to see the amount of UV light measured through the IL1400A. The IL1400A makes measurements every 0.5 seconds, and there is a noise coming from the serial communication with the computer. Therefore, for 2 seconds, that is, discarding the first two of the four data and graphing the average of the remaining two.

Specifically, FIG. 3 is a light output of the UV light quantity measuring IL1400A measured at a distance of 1 cm from the UV lamp, and shows a graph of the light output when the operating frequency is changed to 32 kHz, 37 kHz, and 41 kHz, respectively. That is, according to time, the operating frequency is 32 kHz (a section shown in FIG. 3) → 37 kHz (b section shown in FIG. 3) → 41 kHz (c section shown in FIG. 3) → 37 kHz (d shown in FIG. 3). Section) → 32 kHz (e section shown in Figure 3), while changing the light output of the UV lamp graphically.

 As can be seen from the graph, the light output at the operating frequency of 41 kHz was reduced by 25% compared to 32 kHz. At this time, the input power decreased to 252W, 220W, and 185W as the light output decreased.

As described above, the light output of the UV lamp can be reduced by controlling the ballast according to the amount of sewage, and the life of the ballast can be extended by the reduced light output, and the power charge due to the reduction of the input power can be reduced. Can be.

According to the UV lamp ballast system of the sewage terminal treatment plant of the present invention having the configuration and operation and the preferred embodiment as described above, by varying the output of the ballast connected to the UV lamp according to the amount of sewage, the light output generated from the UV lamp is variable Therefore, it is possible to increase the life of the UV lamp, thereby reducing the purchase cost and replacement cost of the UV lamp.

In addition, since the output of the ballast and the light output of the UV lamp is adjusted according to the amount of sewage, there is an advantage that can significantly reduce the power consumption.

Claims (4)

In the UV lamp ballast system of sewage treatment plant, A controller having a sensor for continuously detecting an amount of sewage, and generating a control signal which is a frequency variable signal for varying operating frequencies of a plurality of ballasts by analyzing the sensed data of the sensor; A plurality of ballasts for generating a variable output signal in accordance with a control signal of the controller; And a plurality of UV lamps connected to each of the plurality of ballasts, the plurality of UV lamps generating variable light corresponding to the variable output signals output from the ballasts. delete The method according to claim 1, The control signal of the controller is a UV lamp ballast system of the sewage terminal treatment plant, characterized in that the on / off signal to maintain or stop the operation of the plurality of ballasts. The method according to claim 1, The operating frequency of the ballast is UV lamp ballast system of the sewage treatment plant, characterized in that the variable is increased by the control signal of the controller, as the amount of sewage is variably reduced.

Images