Proposed Output: typically, an ISA Recommendation, with a working title:

ISA Recommendation,Standard title:

Technical specification on indoor ultraviolet LED mosquito light trap

Goals: please outline goals for the proposed project.

1.       Clarify the light, electricity, reliability and other technical requirements and test methods of UV LED light source used for UV LED mosquito light trap.

2.       Standardize the mosquito control performance evaluation and safety requirements of indoor UV LED mosquito light traps.

Committee or Subcommittee: please list at least three proposed committee or subcommittee members, complete with contact information.

1.       LatticePower (Jiangxi) Corporation, an innovative company that focusing on high-power LEDs with its advanced technology of GaN-on-Si, can provide full range of high-power LEDs solutions from epi &chip to package &module.

Contact: Mr. Yi FU Tel: 13807067155, E-mail: fuyi@latticepower.com

2.       Ningbo Dayang Technology Co,Ltd , is commited to mosquito repellent and light traps research and production.

Contact: Mr. Yuanai NING Tel: 18655551855, E-mail: Pcb2008ning@163.com

3.       Foshan Electric Lighting Co., Ltd., a famous domestic LED lighting enterprise, is committed to providing more intelligent and healthy lighting.

Contact: Mr. Weiming LUO Tel: 13827766611, E-mail: luoweimin22@126.com

4.       Shenzhen Hanhua optoelectronic Co., Ltd., focusing on the field of insect trapping, research and development and application of light source products. It is the only mass production enterprise in China and a pioneer in the industry.

Contact: Yuanchun GAO  15012892881, Email: 806046228@qq.com

5.       Institute of Semiconductor, CAS, it is a comprehensive research institution of semiconductor science and technology, which integrates semiconductor physics, materials, devices and their applications.

Contact: Dr. Hua YANG, (+86)13683182672, E-mail: huayang@semi.ac.cn

6.       CHINA SOLID STATE LIGHTING ALLIANCE (CSA), A new organization that provides a full range of innovative services for strategic industries such as semiconductor lighting. Established in 2003, the output value of alliance members accounted for 70% of China's LED output value in 2016.

Contact: Hao XU, (+86) 13011822622, E-mail: xuh@china-led.net

Timeline: please list approximate dates of completion:

Initial outline: See Appendix.

Initial draft for TCS Chair review: Submit it in six months since the proposal approved.

Draft for TCS member review and comment: Submit it in three months since the amendments of draft proposed and reviewed by chairman.

Committee or Subcommittee final draft: Submit it in two months since the amendments of draft reviewed by TCS member.

Publication: Publish it in one month after passing the voting procedure of ISA TCS.

Appendix:

1. Background

2. The necessity to develop the standard

3. Overview of the content

4. Relevant standards

Appendix 1                           

Background

Status:

Great market demand

According to 360 ResearchReports, Global giant consumption is mainly distributed in Asia Pacific, especially in China and India. Asia Pacific holds unshakable status in this field. China takes the production market share over 48.49% in 2016, followed by North America in 2016.

Price chaos

The price of UV LED mosquito light trap is quite different from base line to the high-end products, which may lead a confuse for the customer to choose.

The quality is uneven

IEC 60335-2-59 Household and similar electrical appliances - Safety - Part 2-59: Particular requirements for insect killers is the safety standard for traditional mosquito light trap. For the UV LED light trap, this standard cannot fully compatible with the safety and technical requirements of optical and electrical properties of UV LED. The quality of UV LED light trap is only control by the manufacturers and their vendors. A specific standard for UV LED light trap should be taken in consideration.

Challenge:

Effective wavelength range of UV LED light source

There are few researches about the field evaluation of different mosquito light traps. The black light trap has shown outstanding performance on ratio of mosquitoes and other non-target insects in some data from U.S.A, While, some researches show,  the UV LED light trap take a leading score for catching Culex and Anopheles mosquitoes in south-eastern Tanzania. Therefore, the effective wavelength range of UV LED still need profound experimental evidences to standardize an appropriate value.

Evaluation of mosquito control performance

The evaluation method of mosquito trap performance is still doubted and tested by different labs and light trap companies. Then, there is not an effective international standard for controlling the number of mosquitos.

Appendix 2

The necessity to develop the standard

Climate crisis and globalization are two important factors in the spread of tropical diseases such as dengue fever or malaria, which are transmitted by arthropods of mosquito. It is estimated that millions of people die every year from mosquitoes.

As an existing mosquito control technology, UV mosquito light trap has been widely used in the global commercial and household markets. In global, the market of mosquito light trap is expected to grow at a CAGR of roughly 14.7% over the next five years, will reach 7630 million USD in 2024, from 3350 million USD in 2020, according to 360 ResearchReports. The light source is mainly ultraviolet mercury lamp tube and ultraviolet LED. UV LED replacing UV mercury lamp has the advantages of energy saving, mercury free, vibration resistance, small size, flexible shape design and easy control. It is estimated that the market replacement rate of UV LED mosquito light trap will reach 90% by 2025.

The existing international standards related to insects in IEC and ISO are mainly concentrated in the field of traditional technology and equipment, such as insecticides, black light lamps, etc. The light, electricity, lifetime and mosquito trapping performance of UV LED light source are not standardized.

Appendix 3

Overview of content

FOREWORD

INTRODUCTION

1  Scope

2  Normative references

3  Terms and definitions    

4  Classification

4.1 According to  mosquito trap methods

4.2 According to mosquito attraction methods

5  Technical requirements

         5.1 Structure and appearance         

5.2 Safety requirements

         5.3 Environmental adaptability

         5.4 Electrical properties

         5.5 Optical properties

         5.6 Life and maintenance factor

         5.7 Radiation, toxicity and similar hazards

         5.8  EMC performance

         5.9  Evaluation of mosquito control performance

        5.10 Installation requirements

        5.11 Control function requirements

6  Test method

         6.1 Test conditions

         6.2 Structure and appearance

         6.3 Safety performance

         6.4 Environmental adaptability

         6.5 Photoelectric properties

         6.6 Life and maintenance factor

         6.7 Radiation, toxicity and similar hazards

         6.8 Electromagnetic compatibility performance

         6.9 Evaluation of mosquito control performance

Appendix 4

Relevant standards

1.         CIE 127:2007 Measurement methods of LED modules for general lighting 

2.         CISPR 15:2015 Limits and methods of measurement of radio disturbance characteristics of electrical lighting and similar equipment

3.         IEC 62471-2006，Photobiological safety of lamps and lamp systems

4.         IEC 60050-845 International Electrotechnical Vocabulary (IEV) - Part 845: Lighting

5.         IEC 60335-2-59 Household and similar electrical appliances - Safety - Part 2-59: Particular requirements for insect killers

6.         IEC 61000-3-2:2018 Electromagnetic compatibility (EMC) - Part 3-2: Limits - Limits for harmonic current emissions (equipment input current ≤16 A per phase)

7.         IEC 61547 Equipment for general lighting purposes—EMC immunity requirements

8.         IES LM-80 Measuring Luminous Flux and Color Maintenance of LED Packages, Arrays and Modules

9.         IES TM-21-19 Projecting Long Term Lumen, Photon, and Radiant Flux Maintenance of LED Light Sources