Magnel Laboratory for Concrete Research – Department of Structural Engineering

Self-healing concepts for building

materials

1

Nele De Belie

Magnel Laboratory for Concrete Research

Cracking in concrete poses several problems……

Magnel Laboratory for Concrete Research

Bridges, locks, wharfs, piers, tunnels, …

Cracking in concrete poses several problems……

Infrastructure!

Magnel Laboratory for Concrete Research

NBN EN 1992-1-1 (2010): the allowable crack width in

reinforced concrete depends on the environmental class:

300-400 µm

Our results: 10 μm is the critical crack width

Cracking accelerates chloride penetration

Crack width ≤ 10 µm Crack width > 10 µm

Magnel Laboratory for Concrete Research

Cracking in concrete poses several problems……

Magnel Laboratory for Concrete Research

Self-healing concrete may help to solve

the crack-related durability problem

Inspired by nature:

- not designed to withstand everything

- in case of failure :

‣ rapid & autonomous detection

‣ ‘massive’ & efficient action

‣ “after” as strong as “before”

‣ ‘inexhaustable’

‣ cheap

Magnel Laboratory for Concrete Research

Autogenous self-healing

Autogenous healing © N. ter Heide

Magnel Laboratory for Concrete Research

Stimulated autogenous healing: hydrogels

Hydrogel swelling Sealing of the crack

de-swelling Binder hydration, CaCO3

precipitation and healing

& PBM

Magnel Laboratory for Concrete Research

SAPs induce macropores that reduce strength

9

macropore

SAP

micropores

Stimulated autogenous healing: hydrogels

Magnel Laboratory for Concrete Research

But… the macropores increase freeze-thaw resistance

10

w/c=0.5

w/c=0.45

SAP+add (0.45 + 0.05)

SAP (0.45)

AEA (0.45)0

2

4

6

8

10

0 14 28 42 56

Scaled material [kg/m²]

# cycles

with 3% NaCl solution

Amount of scaled material ↓ when using SAPs

(Data of D. Snoeck / RRT in RILEM TC-SAP, confirming work by Jensen and Lautsen)

(Laustsen, S., “Engineered Air-Entrainment of Concrete,” PhD thesis, Lyngby)

Stimulated autogenous healing: hydrogels

Magnel Laboratory for Concrete Research

Autonomous healing by bacteria

& LabMET

High

pH

No

water

Shear

force

Narrowing

pores

Biogenic CaCO3

fills the cracks

Magnel Laboratory for Concrete Research

+

Carrier materials

Wang, J., Van Tittelboom, K., De Belie, N.,

Verstraete, W. (2012). Construction and building

materials, 26, 532–540.

& LabMET

Autonomous healing by bacteria

Magnel Laboratory for Concrete Research 13

Distinct properties:

1) Flexible in wet state and brittle in dry state

2) Impermeable

Bacteria in microcapsules

WANG, J., SOENS, H., VERSTRAETE, W., DE BELIE, N. Self-healing concrete by use of

microencapsulated bacterial spores. Cement and concrete. research, 56, 139-152.

0d 3 weeks

1mm

Crack healing:

500 μm up to

1 mm

Autonomous healing by bacteria (SECEMIN)

Magnel Laboratory for Concrete Research 14

Bacterial spores

0

10

20

30

40

50

60

70

80

90

100

Heali

ng r

ati

o (

%)

R

N

H

HYU

HYUC

HSYU

HSYUC

0-50 50-100 100-150 150-200 200-250 250-300 300-350 350-400 400-700Initial crack width ranges (μm)

0d 7d 14d

Crack width 0.5mm

almost healed

within 7dHydrogel

remains

CaCO3

precipitation

Crack healing ratio in the

bacterial series was much

higher compared with R series:

(50% ~ 100%) / (1% ~ 7%)

Bacteria in SAPs (SECEMIN)

Magnel Laboratory for Concrete Research

Denitrifying ACDC produces

nitrite that inhibits corrosion

ERŞAN, Y.C., VERBRUGGE, H., DE GRAEVE, I., VERSTRAETE, W., DE BELIE, N., BOON, N.

(2016). CaCO3 precipitating bacteria survive in mortar and inhibit steel corrosion. Cement and

concrete research, 83, 19-30.

(ISHECO)

Neg control a1

Autonomous healing by bacteria

Magnel Laboratory for Concrete Research

Nutrients

tank

(10 L)

CH4 Air

Mass

flow

controllers

120 ml/min

for 1min

every 6 hours

Mixing point

Qin=0.2 m3 h-1

Filter bed (x 2 units):

Hbed=0.90 m

Vbed=2.6 l

EBRT= 48 s

E.C.=429.2 gCH4-C d-1m-3

Exit

flow controller

Recirculation

[CH4]in = 960 ppmv I.L.= 1854 gCH4-C d-1 m-3

MBF-B

MBF-A

atmosphere

Bacteria for consolidation and methane removal

(SECEMIN, G. Ganendra)

Magnel Laboratory for Concrete Research

Self-healing concrete based on encapsulated

elastic polymers as healing agents

& PBM

Crack formation

Autonomous release

healing agent

First reloading

Additional release

healing agent

repair

Second reloading

UNCR

REF

MAN-PU

SHC-PU

Crack healed

with semi-rigid

polymer

Healed crack after

reloading

(SECEMIN, A. Araujo, J. Feitera, E. Gruyaert)

Magnel Laboratory for Concrete Research 18

SHEcon: self-healing in sandwich panels

(with Naessens

construct & Recticel)

Magnel Laboratory for Concrete Research 19

Acoustic

Emission

AE Tomography

Optical Microscopy

Ultrasound Pulse

Velocity

Digital Image Correlation

-0,04 0,04εyy - % 0 2εxx - %

2500 wave speed (m/s) 4500

0 2εxx - %

4-point bending on concrete beam

Repeatable cracking & repair

3-point bending on pre-cracked concrete beam

Sealing & local mechanical repair

TDCB polymer

Stick-slip abnormal damage

The capsule breakages are located

into the fracture process zone

of the concrete beam under bending

The wave velocity is restored at the

autonomously healed cracks.

PZT piezoelectric

transducer is embedded into

concrete during casting.

P-wave velocity & damage

index to assess healing.

Experimental assessment of fracture & autonomous healing of concrete & polymer systems

Tsangouri E., Aggelis G. D., Van Hemelrijck D.

Vrije Universiteit Brussel - Dept. Mechanics of Materials & Constructions (MeMC)

Magnel Laboratory for Concrete Research

Reconstructed µCT image (UGCT)

Modelling of self-healing (MMS, UGent)

...or even the capsules

may detach prematurely,

weakening the overall

structure

Cracks may ignore the

presence of capsules…

Magnel Laboratory for Concrete Research

Autonomous crack healing: results (M. Maes)

Chloride diffusion for concrete with healed crack is in

between open crack and virgin concrete

Magnel Laboratory for Concrete Research

Effect of self-healing on service life

0,00

0,10

0,20

0,30

0,40

0,50

0 50 100 150

Pro

b.

of

fail

ure

Pf

[ -]

Time [years]

Pf = 0.1 CR - 0.3 mmREF PU - 0.3 mm (Min.)PU - 0.3 mm (Max.) PU - 0.3 mm (Mean)