Operational modeling of a green gas supply chain

B i o m a s s & m a n u r e T r a n s p o r t & S t o r a g e D i g e s t e r D i g e s t a t e C l e a n i n g & U p g r a d i n g I n j e c t i o n

Operational modelling of a green gas supply chain

Costprice (€/nm

green gas)

Percentage

Biomass & Manure

0,095

12,7

Transport & Storage

0,073

9,8

Digester

0,172

23,0

Digestate

0,121

16,1

Cleaning & Upgrading

0,144

19,3

Injection

0,144

19,2

Total

0,750

100,0

Sustainability criteria

Theme

Indicator

Greenhouse gas balance

Reduction in the chain should

be at least 50% when

compared to fossil energy, incl.

application

Competition with food, local

energy supply, medicine and

construction materials

Availability of biomass for food,

local energy supply,

construction materials or

medicine should not decrease

Biodiversity

No deterioration of protected

areas or valuable ecosystems

Profit

No negative effects on local

and regional economy

Prosperity

No negative effects on the

well-being of employees and local

population

Environment

No negative effects on the

environment (waste, chemicals,

erosion, emissions, etc.)

From biomass to injection into the gas grid

Biogas production from codigestion of cattle manure and biomass can have a significant contribution to a sustainable gas supply. Besides technological knowledge on processes, knowledge about the possibilities for biogas production are

usually only available on a macrolevel, when the potential of a certain region, often at the size of a country or larger, for supplying biomass or generating renewable energy is investigated. However, in order to meet the ambitions of a future sustainable gas supply, questions should be answered like:

•

•

•

Therefore, an operational calculation model is under development to explore these questions. Our primary focus is on the northern three provinces of the Netherlands. Preliminary results are presented here. Future developments concern the implementation of matching supply and demand.varying the required gas quality (or blending) en upscaling the model to a regional approach.

J. Bekkering Msc

Costprice as a function of scale level (preliminary results):

Costprice for 300 nm3/hr biogas production and injection (178 nm3/hr green gas):

With operations research techniques optimal transport movements and locations for digesters, upgrading installations and storage can be calculated.

The required gas quality may strongly influence the possibilities for green gas usage. Injection in a high pressure gas grid may require strict specifications of the gas. Local usage of biogas might only need cleaning of the gas after which

it can f.i. be used in a gas engine. The scale levels in between might have their own challenges. The possibilities of blending biogas with natural gas is explored as well. The possibilities for blending depend on specifications of biogas as well as natural gas, and the flow in the gas grid. A project is in preparation to explore these possibilities (Flexigas).

Usually cost prices are calculated in a static way, i.e. the prices are based on production amounts (see also above). It is interesting to see what optimisation can be achieved when the dynamic character of a green gas chain is considered. Therefore the characteristics of supply and demand are investigated.

Based on: combined farming (88 Dutch cows, 65 ha land, 25% of land used for energy maize), total land requirement 284 ha, upgrading PSA, 500 m gas pipeline for injection, digestate used as chemical fertilizer replacement.

3 northern provinces: 831600 ha land (32% farming, 33% grassland, 35% remaining)

100 290 480 670 860 1050 1240 1430 1620 1810 2000 0 0.11 0.21 0.32 0.42 0.53 0.63 0.74 0.84 nm3/hr green gas eu ro /n m 3 0.842 0 biomassmanure transportstorage x( ) digester x( ) digestate cleaningupgrading x( ) injection x( ) total x( ) 2000 100 x x x