Model of Sustainable Electrical Power Management: Lamp Efficacy of the National Street Lighting in North Sumatera Province

2.1. Material

The measurement of the electrical quantities was performed using the following multitester measuring instruments: Heles YX-360 TRNB Reg.271-488, voltmeter, ammeter: Digital Multimeter CD772 Sanwa, tangmeter: Clampmeter 8 model 3908 VIP Electrical Instruments Works, Ltd., and luxmeter: Digital Luxmeter 1010 specification with a measurement range of 0.1–100×500 Lux.

2.2. Methods

2.2.3. Light efficacy

The efficacy of light is the ratio of the lumen output to the power consumption expressed in Lumen/W units.

$$K=\phi /P$$

where K is the light efficacy (Lm/W), φ is flux light (Lm), and P is the electric power (W).

In street lighting, the height of the lamppost affects the spreading of light. The higher the pole is the wider the resulting light will be with a smaller level of illumination.

The angle of the tilt, the line connecting the endpoint of the lamp and the point in the middle of the path with a horizontal line as seen in Figure 1, can be determined using the following equation:

$$\begin{array}{lll}r\hfill & =\hfill & \sqrt{h^2+c^2}\hfill \\ \mathrm{C}\mathrm{o}\mathrm{s}\psi \hfill & =\hfill & h/r\hfill \end{array}$$

where r is the side of beveled line, the distance from the end of the lamp to the point in the middle of the road; c is the horizontal line, the distance from the projection point of the lamp end to the point in the middle of the road; h is the pole height; and ψ is the angle between r and c.

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Figure 1.

Effect of lamppost height on illumination

The intensity of light (I) in units of candela (cd) can be determined using the following equation:

$$\begin{array}{c}I=\phi /\omega \\ \omega =4\pi \\ K=\phi /P\text{ or }\phi =K\times P\end{array}$$

Then,

$$I=K\times P/4\pi$$

Illumination E_P in units of Lux at the point P in the middle of the street is

$$E_p=I\times Cos\psi /r^2$$

3.1. The Effect of Height Variation of Light Pole on Illumination

The effect of the height variation of light poles on the illumination produced with certain light efficacy on the primary arterial road at the midpoint of the road is obtained by the using the following calculation:

• (1) Lamp type: SON, 400 W, 110 lumens/WRoad width: 8 m

  $$\begin{array}{lll}h\hfill & =\hfill & 12\mathrm{m}\hfill \\ c\hfill & =\hfill & 2.95\mathrm{m}\hfill \\ r\hfill & =\hfill & \sqrt{{12}^2+{2.95}^2}\hfill \\ \hfill & =\hfill & 12.35\text{m}\hfill \\ \mathrm{C}\mathrm{o}\mathrm{s}\psi \hfill & =\hfill & 12/12.35\hfill \\ \hfill & =\hfill & 0.97\hfill \\ I\hfill & =\hfill & 110\times 400/\left(4\times 3.14\right)\hfill \\ \hfill & =\hfill & \mathrm{3,503.18}\text{cd}\hfill \end{array}$$

  Then,

• (2) Lamp type: MBF, 400 W, 53 lumens/WRoad width: 8 m

  $$\begin{array}{lll}h\hfill & =\hfill & 12\text{m}\hfill \\ c\hfill & =\hfill & 2.95\text{m}\hfill \\ r\hfill & =\hfill & \sqrt{{12}^2+{2.95}^2}\hfill \\ \hfill & =\hfill & 12.35\text{m}\hfill \\ \mathrm{C}\mathrm{o}\mathrm{s}\psi \hfill & =\hfill & 12/12.35\hfill \\ \hfill & =\hfill & 0.97\hfill \\ I\hfill & =\hfill & 53\times 400/\left(4\times 3.14\right)\hfill \\ \hfill & =\hfill & \mathrm{1.687.89}\text{ cd}\hfill \end{array}$$

  Then,

Height variation of lampposts against illumination with SON/MBF, 400 W, generated at the midpoint of the road width 8 m can be seen in Table 1.

SON/MBF Lamp Specifications:

• For lamp types: SON, 180 W, 110 lumens/W and MBF, 180 W, 53 lumens/W, the effect of variations on lamp height to illumination is presented in Table 2.

• For lamp types: SON, 100 W, 110 lumens/Wand MBF, 100 W, 53 lumens/W, the effect of variations on lamp height to illumination is presented in Table 3.

LED Lighting Specifications:

• For lamp type: LED, 150 W, 130 lumens/W, the effect of variations on lamp height to illumination is presented in Table 4.

• For lamp type: LED, 100 W, 130 lumens/W, the effect of variations on lamp height to illumination is presented in Table 5.

3.2. The Electrical Needs of National Road Segment

The electrical energy needs of the national road segment in 2019 are obtained by the following formulation:

• (1) Load of SON on the length of primary arterial road:

  The specified lighting quality of primary arterial road is 11–20 Lux. To obtain the lighting quality, SON lamp, 400 W, is used with lamp height 11 m, and distance between poles being 40 m. Then, the electrical energy consumption of primary arterial road along 1,142 km with the operation time 4,145 h in 1 year is as follows:

  • (a) The number of pole PJU is (the length of the road/40) + 1(b) Electric power required on street lighting PJU

  • (c) Electrical energy needs of street lighting for the length of national primary arterial road segment are as follows:

    $$\begin{array}{lll}{W}_{\text{PJU}-\text{SUTR}}\hfill & =\hfill & 400\mathrm{ W}\times \text{number of poles}\times 4,145\text{h}\hfill \\ \hfill & =\hfill & 400\text{W}\times 28,551\text{poles}\times 4,145\text{h}\hfill \\ \hfill & =\hfill & 47.337\text{GWh}\hfill \end{array}$$

• (2) Load of SON on the length of national primary collector road:The specified lighting quality of primary collector road is 3–7 Lux. To obtain the lighting quality, SON lamp, 180 W, is used with lamp height 8 m, and distance between poles being 40 m. Then, the electrical energy consumption of primary collector road along 1,490.22 km with the operation time 4,145 h in 1 year is as follows:

  • (a) The number of pole PJU is (the length of the road/40) + 1

  • (b) Electric power required on street lighting PJU

    $$\begin{array}{lll}{P}_{\text{PJU}-\text{SUT}}\hfill & =\hfill & 180\text{W}\times \text{number of poles}\hfill \\ \hfill & =\hfill & 180\text{W}\times \text{37,256}\hfill \\ \hfill & =\hfill & 6.706\text{MW}\hfill \end{array}$$

  • (c) Electrical energy needs of street lighting for the length of national primary collector road segment are as follows:

    $$\begin{array}{lll}{W}_{\text{PJU}-\text{SUTR}}\hfill & =\hfill & 180\mathrm{W}\times \text{number of poles}\times 4,145\text{h}\hfill \\ \hfill & =\hfill & 180\text{W}\times 37,256\text{poles}4,145\text{h}\hfill \\ \hfill & =\hfill & 15.442\text{GW h}\hfill \end{array}$$

Thus, the total need of electrical energy for street lighting due to the increase in national roads is 15.442 GW h.

3.3. Potential use of solar cells

The energy needs of national public road lighting in North Sumatera province can be analyzed from the value of electrical energy generated by each solar cell module and the overall need of solar cell panels required to replace the energy generated by conventional power generation.

By using these solar cell modules, the need of electrical energy for public road lighting on national roads in 2019 and its increase can be obtained as follows:

(1) Load of LED light on the total length of national road:The specified lighting quality is 11–20 Lux. To obtain the lighting quality, LED lamp, 100 W, is used with lamp height 7 m, and distance between poles being 40 m. Then, the electrical energy consumption of primary arterial road and primary collector road along 2,632.22 km with the operation time 4,145 h in 1 year is as follows:

• (a) The number of pole PJU is (the length of the road/40) + 1

• (b) Electric power required on street lighting PJU

  $$\begin{array}{lll}{P}_{\text{PJU}-\mathrm{L}\mathrm{E}\mathrm{D}}\hfill & =\hfill & 100\text{W}\times \text{number of poles}\hfill \\ \hfill & =\hfill & 100\text{W}\times \text{65,807}\hfill \\ \hfill & =\hfill & 6.580\text{MW}\hfill \end{array}$$

• (c) Electrical energy needs of street lighting for the total length of national road segment are as follows:

  $$\begin{array}{lll}{W}_{\text{PJU}-\mathrm{L}\mathrm{E}\mathrm{D}}\hfill & =\hfill & 100\text{W}\times \text{number of poles}\times 4,145\text{h}\hfill \\ \hfill & =\hfill & 100\text{W}\times 65,807\text{poles}\times 4,145\text{h}\hfill \\ \hfill & =\hfill & 27.277\text{GWh}\hfill \end{array}$$

(2) Load of LED light due to the increase of national road segment:The increase in the length of the national roads is around 382.56 km. The electrical energy needs of street lighting along the length of national primary collector road segment are as follows

Thus, the total need of electrical energy for street lighting due to the increase in national roads is 3.964 GW h.

(3) Capacity of solar cell module:

Sunlight can generate electrical energy of 1,000 W/m² at peak times. The solar panel efficiency of 15 % with an area of 1m² panel each, can produce output power of 150 Wp.

Solar cell module capacity to serve the load of national street lighting with PJU-LED, 100 W, for 12 h, 18.00–6.00, with 1.1 as multiplier factor, and 5.7 h as the duration of solar exposure, then

Load P_PJU-LED = 100 W

The energy requirement to serve the load P_PJU-LED = 100 W is as follows:

Thus, the need for solar cell modules to meet PJU-LED, 100 W, is two sets of solar cell modules each with a capacity of 130 Wp.

3.4. Effect of efficacy on illumination

Effect of height variation of lamppost on Illumination by using LED/SON/MBF can be seen in Table 6.

Light efficacy affects the energy consumption for the lamp. Hence, by using a high light efficacy lamp, maximum energy conservation is possible.

3.5. Energy Conservation

The growth of national roads in 2019 will be lengthy, around 382.56 km. This needs the growth of electric power also to fulfill the demand of lighting the entire length of the national roads.

When the SON lamp, 180 W, is changed to LED, 150 W, having the value of the illumination close to the same, energy conservation of 30 W per light bulb will be obtained:

When the SON lamp, 180 W, is changed to an LED, 100 W, that has fulfilled the specified illumination level, energy conservation of 80 W per light bulb will be obtained:

3.6. The effect of efficacy on CO₂ emission reduction

Effect of lamp efficacy on CO₂ emission is shown in Table 7.