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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 48, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Eddy de Rademaeker, Peter Schmelzer
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-39-6; ISSN 2283-9216 

Oppau 1921: Old Facts Revisited 

Ulrich Hörcher, 

BASF SE, GUS/AB - M 940, 67056 Ludwigshafen, Germany 
ulrich.hoercher@basf.com 

 
The likely causes for the explosion of an ammonium sulfate nitrate silo in Oppau 1921 are reviewed on the 
basis of publications from 1922 - 1926.     
Ammonium sulfate nitrate is a mixture of 2 salts: ammonium nitrate (explosive) and ammonium sulfate (inert). 
The explosiveness of the mixed salt is mainly determined by the ratio of these 2 salts. 
The influence of the mixed salt composition on the sensitivity to detonation impact had been thoroughly 
investigated before the accident as it was common practice to use small explosive charges to loosen the salt 
which had solidified during storage in the silo. About 20.000 blasting operations were carried out without any 
notable incident. 
Experiments conducted after the accident revealed that several physical parameters (particle size, density, 
water content, homogeneity of crystal structure) also had an influence. 
The introduction of a new drying process for ammonium sulfate nitrate (spray process, “Spritzverfahren”) 
caused changes in all these parameters resulting in a salt with increased explosiveness. In addition a dust-like 
fine fraction with increased ammonium nitrate content was formed which accumulated at the edge of the silo. 
It can be assumed that on the day of the accident at least one of the explosions for loosening the caked salt 
was carried out in the area of the fine fraction, thus initiating a detonation of this fine fraction and causing the 
detonation of further fractions with approximately “normal” nitrate content. 
This accident is a strong example for the need of Management of Change (MOC) procedures, which are an 
integral part of today´s process safety. 

1. Background 

On 21. September 1921 the explosion of an ammonium sulfate nitrate silo in Oppau killed 507 and injured 
1917 people (the numbers of victims differ depending on the source, see Kast 1925a). Figures 1 and 2 show 
the destructions at the center of the explosion and in the immediate neighbourhood. The possible causes for 
this accident were determined by detailed investigations and published in a series of articles by Kast (1925b 
and 1926a). 
The results of these investigations are well known in the "ammonium nitrate community", but their awareness 
in the general process safety community has decreased over the years. The increased interest in this accident 
on occasion of its 90th anniversary was an occasion to review the old reports on this topic. 
There exist several reports from different investigation committees, but the publications of Kast summarize 
most findings. They are therefore used as main source together with the report of the Bayerische 
Untersuchungskommision (1922). 

2. State of Knowledge before the Accident 

2.1 Basics 

Ammonium sulfate nitrate (ASN) is a mixed salt consisting of ammonium nitrate (AN) and ammonium sulfate 
(AS). It is produced in large scale as fertilizer and stored in silos. During storage ASN can cake forming a 
solidified mass impossible to handle for further loading and shipment. 
It was common practice before the accident to use small charges of explosives (2 - 5 cartridges each with 2 g 
Perastralit) to loosen the caked ASN in the silo. Before the accident about 20,000 blasting operations were 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1648125

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Hörcher U., 2016, Oppau 1921: old facts revisited, Chemical Engineering Transactions, 48, 745-750  
DOI:10.3303/CET1648125  

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carried out without any notable incidents. Figure 3 shows the drilling of the holes and the placement of the 
Perastralit cartridges in preparation of a blasting operation. 

2.2 Explosive Properties of ASN 

The explosive properties of ASN depend mainly upon the ratio of the components AN (explosive) and AS 
(inert). The ASN produced and stored in Oppau had an AN/AS ratio (by weight) of 50:50 ("Oppau salt"). The 
ASN composition which in the Trauzl lead block test could be induced to explode by booster charges 
corresponded to an AN/AS ratio of > 55:45. Based on these results, which were confirmed after the accident, 
it was assumed that the blasting operations for loosening the caked salt could be conducted safely. Basic 
condition for this assumption was the strict adherence to the correct AS/AN ratio of 50:50. This was achieved 
by frequent analyses. Another reason for regular analyses was the fact that the AN content of the mixed salt 
was an important specification feature of the fertilizer. 

 

Figure 1: View of the explosion crater 

 

Figure 2: Destruction in the neighbourhood of the exploded silo 

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Figure 3: Preparation of blasting operation 

3. Accident Investigation 

3.1 Facts around the Drying and Storage Process 

The exploded silo was a wood construction with concrete foundation. It was used for drying as well as for 
storage of the mixed salt. The drying process had been changed at the end of 1920. Originally the ASN was 
dried with a drying screw. To obtain a product quality with less residual humidity, the spray process 
("Spritzverfahren") was introduced and used exclusively since beginning of 1921. In the spray process the hot 
salt solution was sprayed with hot compressed air through an atomizer into the storage area. The dried salt fell 
to the ground like snow and was either removed at once by a conveyer belt in the silo or it formed heaps 
located at different places in the silo depending upon the spray direction. 
On the day of the explosion the silo contained approximately 4,500 t ASN. The size of the crater formed by the 
explosion correlated to the explosion of 300 - 400 t ASN. 

3.2 Search for the cause: first considerations 

The hypotheses on possible causes for the explosion soon focused on factors which may have caused a 
deviation in the chemical composition of the mixed salt (higher AN content) resulting in an increased sensitivity 
to detonation impact. The following causes were discussed: 
- Lack of care by operators induced by introduction of a new bonus system which was linked to the production 
quantity 
- Introduction of the new spray process 
- Deviations from the operating procedures resulting in the addition of wrong amounts of AS (too little) or AN 
(too high) 
The review of operations diaries and analysis reports recovered from the surroundings of the exploded silo did 
not reveal any irregularities. However, this statement is qualified by the fact that the samples taken for 
analysis were average samples. Furthermore some of the samples taken after the explosion from a 
neighboring silo not involved in the explosion showed an AN content above 55 % (Kast, 1926b).  

3.3 Factors influencing the explosive Properties of ASN 

Though the chemical composition of ASN obtained from the changed drying process (spray process) 
remained unchanged (AN/AS ratio of 50:50), the physical properties differed from ASN obtained in the original 
drying process (drying screw). Therefore a series of explosion tests were conducted at the "Chemisch-
Technische Reichsanstalt Berlin" to investigate the influence of various physical parameters on the explosive 

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properties of ASN (Kast 1926c). Additionally the influence of the test conditions (strength of confinement and 
brisance of the   booster charge) were investigated. 
The results are summarized in table 1. It can be seen, that the changes in physical parameters of the mixed 
salt (particle size, density and water content) caused by the transition to the new spray process all lead to an 
increased sensitivity to detonation impact. 
Based on these results it is a realistic possibility that larger portions of ASN in the storage silo could be 
induced to explode by a sufficiently strong detonation impact, though the AN content did not significantly 
exceed 50 %. 

Table 1:  Results of the explosion tests of "Chemisch-Technische Reichsanstalt Berlin"   

Parameter 
 

 Influence of Parameter on sensitivity to
detonation impact 
 

 Influence of spray process on parameter 
 

Particle Size 
 

 Increased by smaller particle size  Particle Size is smaller 
 

Density 
 

 Increased by lower density  Density is lower 
 

Strength of Confine-
ment 
 

 Increased with increasing strength of con-
finement 

 No influence 

Brisance of booster
charge 
 

 Increased with increasing strength of
booster charge 

 No influence (the same cartridges were 
used as before the process change) 

Water content of
mixed salt 
 

 Increased with decreasing water content  Water content is lower (4 % before vs. 2 % 
after process change) 

3.4 Influence of the spray process 

The report of the Bayerische Untersuchungskommision (1922) discussed in detail the effects of the 
introduction of the spray process. Witnesses described that besides the main fraction having the desired 
chemical composition (AN/AS ratio of 50:50) a dust-like fine fraction with very low particle size was formed as 
byproduct. While the main fraction fell to the ground near the spray nozzle, the fine fraction floated in the air 
like dust and settled all over the silo. Those portions of the fine fraction settling at the edge of the silo were 
never removed but formed a layer of ca. 0.5 m corresponding to an estimated quantity of 100 t. The relative 
amount of fine fraction was estimated as 0.1 - 0.2 % of the total production quantity. 
This observation explains the finding that some samples from the adjacent silo taken after the explosion had 
an AN content above 55 %. These analyses were isolated cases only valid for a limited area in the silo. 
Therefore these results are not contradictory to the analyses of the average samples taken for monitoring the 
process and which were in the specified range. 
The hearing of witnesses as well as theoretical considerations confirmed that the spray process could yield a 
certain degree of inhomogeneity of the dried product. 
AN and AS have different water solubilities, AS having a lower solubility. The mixed salt was obtained by 
adding solid AS to a hot concentrated AN solution in an amount corresponding to the desired AN/AS ratio of 
50:50. The AS was not completely dissolved when the hot slurry was subjected to the spray process. So in the 
spray process there was a tendency of AS to crystallize first before AN resulting in a "demixing" of the mixed 
salt: instead of "mixed salt crystals" having the correct AN/AS ratio on a microscopic (or molecular) level, a 
certain fraction of the salt existed as a mixture of AN and AS crystals having the correct AN/AS ratio only on a 
macroscopic level. According to Kast (1926d) this inhomogeneity also resulted in an increased explosiveness. 
In the same way it can be explained that the dust-like fine fraction which accumulated at the edge of the silo, 
had an increased AN content above 55 %. 
In summary, the introduction of the spray process can have resulted in the presence of the following salt 
fractions: 
- A fine fraction (estimated quantity 100 t) at the edge of the silo with an AN content > 55 % sensitive to 
detonation impact from the Perastralit cartridges used for loosening the caked salt 
- An unknown quantity of salt having an AN/AS ratio of approximately 50:50, but sensitive to a strong 
detonation impact due to changes in particle size, density, water content and inhomogeneous crystal 
structure. 

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3.5 Likely Chain of Events 

Based on the results from chapters 3.3 and 3.4 the following chain of events could explain the explosion: 
- Introduction of the spray process at the beginning of 1921 
- Accumulation of a fine fraction with AN content > 55 %. This fine fraction is sensitive to detonation impact 
from Perastralit cartridges. 
- The accumulation of the fine fraction is not noticed since it is located at the edge of the silo and since the 
main fraction has the required AN/AS ratio. 
- The physical parameters of the main fraction have changed, causing an increased sensitivity to a strong 
detonation impact 
- The blasting operation on 21.09.1921 for loosening the solidified salt was carried out at least partially in the 
area of the fine fraction thus initiating a powerful detonation 
- The detonation of the fine fraction acts as booster for further ASN with correct AN/AS ratio, which due to 
changed physical parameters is able to explode  

4.  Assessment 

The chain of events described in 3.5 is in accordance with all known facts and therefore most likely offers an 
explanation for the explosion of 21.09.1921. However, a definite proof is not possible due to the destruction 
caused by the explosion. In particular the ASN fractions which were able to explode (due to higher AN content 
or changes of physical parameters) had disappeared during the explosion. Therefore the exact contribution of 
each factor to the increased sensitivity to detonation impact (AN content, particle size, density, water content, 
homogeneity of crystal structure) cannot be determined. But the chronological sequence of events strongly 
supports the assumption that the introduction of the spray process was the reason for the explosion. This view 
is supported by the fact that the accident occurred already at the 2nd blasting operation carried out after the 
introduction of the spray process. 

5. Handling of ASN Today 

The use of explosives to loosen solidified salt is forbidden since the 1921 explosion. Since it is possible today 
to prevent caking by treatment with anti-caking additives, there is no need for further measures to improve the 
handling of the fertilizer. 

6. Conclusions: Relevance for Process Safety Today 

The following lessons which can be learned from the accident in 1921, are basic rules of process safety now 
for many years, but should be recalled on this occasion: 
- Management of Change: before implementation of a process change the consequences to process safety 
must be checked and the safety concept must be updated 
- In particular the influence of the process change upon the safety characteristics of the handled materials 
must be determined 
- If a process has an extremely high hazard potential, it must be impossible that one single fault (e.g. a 
deviation from the correct chemical composition of ASN) can activate this hazard potential 

7. Summary 

The likely causes for the explosion of an ammonium sulfate nitrate silo in Oppau 1921 are reviewed on the 
basis of publications from 1922 - 1926.  
Before the accident it was assumed that the sensitivity to detonation impact of ammonium sulfate nitrate 
(ASN) only depends on the ratio of the two components ammonium sulfate (AS) and ammonium nitrate (AN). 
Experiments conducted after the accident revealed that several physical parameters (particle size, density, 
water content, homogeneity of crystal structure) also had an influence. 
The introduction of a new drying process for ammonium sulfate nitrate (spray process, “Spritzverfahren”) 
caused changes in all these parameters resulting in a salt with increased explosiveness. In addition a dust-like 
fine fraction with increased ammonium nitrate content was formed which accumulated at the edge of the silo. 
A chain of events is proposed which explains the explosion of the silo and which comprises the following 
essential elements: 
- Introduction of the spray process at the beginning of 1921 
- Accumulation of a fine fraction with AN content > 55 %. This fine fraction is sensitive to detonation impact 
from Perastralit cartridges. 
- The blasting operation on 21.09.1921 for loosening the solidified salt initiates a detonation of the fine fraction 

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- The detonation of the fine fraction acts as booster for further ASN with correct AN/AS ratio, which due to 
changed physical parameters is able to explode  

Reference 

Bayerische Untersuchungskommission zur Aufklärung des Explosionsunglücks in Oppau (1922), Preliminary 
Report, Speyer, 03. January 1922 

Kast H., 1925a, Zeitschrift für das gesamte  Schieß- und Sprengstoffwesen, 20, Nr. 11, 1, Verlag der 
Zeitschrift für das gesamte Schieß- und Sprengstoffwesen, Dr. August Schrimpff in München 

Kast H., 1925b, Zeitschrift für das gesamte  Schieß- und Sprengstoffwesen, 20, Nr. 11-12, 1-8 (Verlag der 
Zeitschrift für das gesamte Schieß- und Sprengstoffwesen, Dr. August Schrimpff in München 

Kast H., 1926a, Zeitschrift für das gesamte  Schieß- und Sprengstoffwesen, 21, Nr. 1-9, 9-43, Verlag der 
Zeitschrift für das gesamte Schieß- und Sprengstoffwesen, Dr. August Schrimpff in München 

Kast H., 1926b, Zeitschrift für das gesamte  Schieß- und Sprengstoffwesen, 21, Nr. 7-9, 27, Verlag der 
Zeitschrift für das gesamte Schieß- und Sprengstoffwesen, Dr. August Schrimpff in München 

Kast H., 1926c, Zeitschrift für das gesamte  Schieß- und Sprengstoffwesen, 21, Nr. 7-9, 33-43, Verlag der 
Zeitschrift für das gesamte Schieß- und Sprengstoffwesen, Dr. August Schrimpff in München 

Kast H., 1926d, Zeitschrift für das gesamte  Schieß- und Sprengstoffwesen, 21, Nr. 7, 33, Verlag der 
Zeitschrift für das gesamte Schieß- und Sprengstoffwesen, Dr. August Schrimpff in München 

 
 
 
 
 

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