Legionella and Solar Water Heaters

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Transcription:

Consultancy for renewable energy in the built environment Legionella and Solar Water Heaters Gerard van Amerongen vaconsult (The Netherlands) TC 312 - Thermal Solar Systems and Components - 1

Contents Introduction Involvement of TC312 and current situation Legionella and solar hot water systems Results from literature study Mathematical study How does Legionella dynamically behaves in solar systems Code of practice How to control the risk of Legionella hazard 2

Introduction CEN TC 164 WG2: Technical report 16355 Recommendations for prevention of Legionella growth in installations inside buildings conveying water for human consumption Recommendations on hot water installations Not explicit for solar hot water systems Need for explicit rules for solar hot water systems TC 312 drafted a Code of practice Code of practice The CEN/TR 16355 technical report of CEN/TC 164/WG 2 on Legionella applied to solar hot water systems Focus on solar hot water systems Building on the CEN TR 16355 TC 312 approved for a work item to make it a CEN TR 3

Introduction Project started in 2011/2012 Project team: John Lee (UK) Legionella ecology and control Jean-Marc Sutter (CH) Solar hot water systems & standardization G. van Amerongen (NL) Solar hot water systems & liaison TC164 Reporting and discussions within TC312 Work done: Background report (Legionella and solar water heaters) Literature study Mathematical study Drafting of Code of Practice (Minimizing the risk of Legionella ) 4

Legionella and solar water heaters Origin outbreaks Legionella < 10% from hot or cold water installations or 20% of known cases Can originates from all parts of such installations Piping, valves, devices, also from solar thermal devices No statistical data available on solar share in this probably due to small penetration grade Legionella is to be taken serious in hot water installations 5

Reports on incidences in solar systems Three known outbreaks: Brazil: cause unspecified Antiqua: indirect relation Turkey: mismanagement Reported incidences: Athens: Legionella in 10% SHW and 69% oil fired systems Germany: 4,2% of solar and 13% of others Denmark: 0% of solar and 21% of others Legionella also in solar, but not more often than others 6

Legionella and solar thermal - Dynamic process of stability, growth and dying - 7

Mathematical simulations Simulation by model calculation of development of Legionella Assumptions on the solar hot water system: Typical solar system layouts Different collector orientations and tilts, climate zones and heat demands Hourly calculations for two successive years Assumptions on the Legionella development 98% of Legionellae is on the tank surface A defined maximum allowed concentration in the water Assumed relation temperature and concentration development 8

Building categories and risk levels For interpretation of mathematical study Categories based on SIA 3851/1 (CH) Low risk (concentration < 5x10 5 cfu/l) Housing units, restaurants, stores, Medium risk (concentration < 5x10 3 cfu/l) Residential buildings, schools, sports, High risk (out of the scope of the report) Hospitals, housing for elderly, Out of scope: special Legionella management required 9

Results - examples of results - 10

Results / conclusions Legionellae growths and dies in a solar thermal system Concentrations of Legionella depend on many factors: systems design, climatic region and the operation of the system Lessons can be learned to maintain a low risks On system design in combination with type of application and the TC164 wg2 TR16355 The lessons learned are used to draft the Code of Practice 11

Lessons learned Vulnerable situations Solar collection without heat withdrawal (winter months!) Only workday or weekend use Over dimensioned tank volume related to design load Sub-optimal collector orientation Especially vertical mounted collector southern Europe High ration V sto / A col Solar only systems: More vulnerable due to lack of auxiliary heater Less vulnerable due to higher throughput of tank 12

Code of practice - Design considerations - Applicable materials for containers of potable water E.g.: stainless steel, copper, enameled steel Design of these containers E.g.: hygienic conditions Controllers E.g.: tank temperature < 80 o C Documentation E.g.: safeguards against improper use 13

Code of practice - Design recommendations - 4 system layouts of solar and auxiliary Each a set of recommendations Solar hot water system Storage type Instantaneous type Storage type Auxiliary heater Instantaneous type 14

Installation layout - storage / storage - Risk evaluation: Potential growth solar tank Potential growth auxiliary tank Recommendations: Auxiliary: > 55 o C whole day or >60 o C one hour (TR16355) Solar device options ( or ): Design rules (dimensioning of components) Aimed at V sto / A col Thermal disinfection: 60 o C/20m, 65 o C/10m, 70 o C/5m(TR16355) Medium/low risk: weekly High risk: daily 15

Installation layout - storage / instantaneous - Risk evaluation: Low risk of growth solar tank Potential growth auxiliary tank Recommendations: Auxiliary: > 55 o C whole day or >60 o C one hour (TR16355) None for solar device 16

Installation layout - instantaneous / instantaneous Risk evaluation: Low risk of growth solar tank Low risk of growth auxiliary tank Recommendations: None 17

Installation layout - instantaneous/ storage Risk evaluation: Potential risk of growth solar tank No disinfection in auxiliary tank Recommendations: Solar device options (low risk): Design rules (dimensioning of components), or Aimed at V sto / A col Thermal disinfection: 60 o C/20m, 65 o C/10m, 70 o C/5m(TR16355) Medium/low risk: weekly High risk: daily Solar device options (medium and high risk): Above and Legionella safe design + sampling + maintenance manual 18

Conclusions Code of Practice is a valuable addition to the TR16355 Solar thermal systems are now more explicit Guide to maintain the Legionella risk within acceptable ranges Design and operation Legionella shows a dynamic development within a solar system Stable population and growth and dying Typical systems and operation show an intrinsic safeguard against Legionella hazards However, bad design and operation conditions may prove harmful No indications reported of above average risks related to solar thermal 19

recommendations Upgrade Code of Practice to a more formal status CEN technical report (CEN approved) Preferably with support from TC164 WG2 Common workgroup? More field studies Hot water installations with renewable energy sources Further research to determine more accurately the frequency of thermal disinfection (at 60 o C) Further mathematical studies More system types and thermal stratification in tank 20

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