Deutsche Shell Tanker Gesellschaft mbH v. Placid Refining Co. ( 1993 )

                  UNITED STATES COURT OF APPEALS
FOR THE FIFTH CIRCUIT
No. 91-3669
DEUTSCHE SHELL TANKER
GESELLSCHAFT mbH,
Plaintiff-Appellant/
Cross-Appellee,
versus
PLACID REFINING COMPANY,
Defendant-Appellee/
Cross-Appellant.
Appeals from the United States District Court
for the Eastern District of Louisiana
(     June 8, 1993    )
Before POLITZ, Chief Judge, JOHNSON and JOLLY, Circuit Judges.
POLITZ, Chief Judge:
This case involves a general average claim arising from the
grounding of the tanker DIALA in the Mississippi River.         Deutsche
Shell   Tanker-Gesellschaft   mbH,   the   vessel   owner,   appeals   the
judgment in favor of the cargo owner, Placid Refining Company.
Finding no reversible error, we affirm.
Background
In 1983 Deutsche Shell contracted to deliver a shipment of
crude to Placid's refinery in Port Allen, Louisiana. The crude was
transpsorted        by    the   tanker   DIALA   which   departed   Sullom    Voe,
Scotland on May 21, 1983.            The Atlantic crossing was uneventful.
Upon reaching the Mississippi River the DIALA took on a compulsory
Mississippi River pilot to guide the vessel upstream.
On June 5, in the Mississippi, the ship passed through
shallow water and experienced a vibration after which its 10-
centimeter radar picture failed. Captain Schätzel radioed Deutsche
Shell's New Orleans agent, Lykes Bros., requesting service for the
10-cm radar and for the 3-cm radar which had a weak picture.
Further upriver, the tanker encountered a squall during which its
3-cm       radar   unit   also   failed   leaving   the    tanker   without    any
operational radar.
Captain Schätzel was able to interswitch the two radar systems
and establish a picture on the 3-cm display.               The pilot, however,
fearful that another radar failure would leave the tanker in the
shipping lanes at night with no radar, and believing that Coast
Guard regulations required the ship to have two operational radar
units, refused to proceed and directed the ship to anchor.1                    The
Mississippi River was at flood stage with a swift current.               Before
the second anchor took hold, the current caught the ship and swept
her two miles downstream where she ran aground.                After a week of
1
There were no qualified radar technicians on board the
vessel.
2
extensive salvage efforts, the DIALA was refloated and delivered
the oil to Placid's refinery.
Deutsche Shell brought suit against Placid asserting a claim
under the general average clause of the shipping contract2 to
recover a portion of the costs of the salvage effort.3      Placid
denied the claim asserting that it did not own the cargo at the
time of the grounding and that the proximate cause of the grounding
was Deutsche Shell's failure to maintain the radar in proper
working order.
The issue of liability was tried to the court which entered a
2
The shipping contract contained the following general
average clause:
General average shall be payable according to the
York/Antwerp Rules 1974 and shall be adjusted in London, but
should the adjustment be made in accordance with the law and
practice of the United States, the following clause shall
apply:
NEW JASON CLAUSE SQ In the event of accident, danger,
damage or disaster before or after the commencement of the
voyage, resulting from any cause whatsoever, whether due to
negligence or not, for which, or for the consequences of
which, the Carrier is not responsible, by statute, contract
or otherwise, the cargo, shippers, consignees or owners of
the cargo shall contribute with the Carrier in General
Average to the payment of any sacrifices, losses or expenses
of a General Average nature that may be made or incurred and
shall pay salvage and special charges incurred in respect of
the cargo.
3
"General average is an ancient maritime doctrine making
all participants in a maritime venture ratably responsible for
losses incurred for their common good." Atlantic Richfield Co.
v. United States, 

, 761 (5th Cir. Unit A 1981).
3
take nothing judgment in favor of Placid.4                   The district court
found that Deutsche Shell failed to prove that a general average
act occurred and, even if such had occurred, Deutsche Shell's
failure to exercise due diligence in maintaining the 3-cm radar was
the proximate cause.             The district court also found that Placid
owned the cargo at the time of the grounding.                       Deutsche Shell
timely appealed; Placid cross-appealed on the issue of cargo
ownership.
Analysis
A    standard     "New    Jason    clause"5   requires   general    average
contribution even if the carrier is negligent, unless the carrier
is responsible for the damage under the Carriage of Goods by Sea
Act.6       Under COGSA a carrier is held at fault for damage to the
cargo       caused   by   unseaworthiness        resulting   from   "want   of   due
diligence on the part of the carrier to make the ship seaworthy."7
A general average claim such as the claim at bar requires a
three step analysis.             The vessel owner has the initial burden to
4
The district court's opinion is reported at: Deutsche
Shell Tanker-Gesellschaft mbH v. Placid Refining Co., 767 F.
Supp. 762 (E.D.La.1991).
5
See The Jason, 

, 

, 

(1912).
6
Atlantic 

; see COGSA, 46 U.S.C.
§ 1301 et seq.
7
46 U.S.C. § 1304(1).
4
establish a general average act and that there was a separate cargo
owner at the time of the act.               If the vessel owner meets this
burden, the cargo owner may avoid liability by establishing that
the vessel was unseaworthy at the start of the voyage and the
unseaworthiness was the proximate cause of the general average act.
Finally, if the cargo owner establishes unseaworthiness, the vessel
owner     may   still   succeed   if   it   proves   that   it   exercised   due
diligence to make the vessel seaworthy at the start of the voyage.8
Deutsche Shell raises several issues on appeal.              First, that
the district court erred as a matter of law in determining that
there was no general average act because the pre-trial order did
not list this as a contested issue of either fact or law.               Deutsche
Shell further contends that, based on the uncontested evidence
presented at trial, the district court's determination that there
was   no   peril    and   hence   no   general   average    act   was   clearly
erroneous.      Deutsche Shell also contends that the district court's
determinations that it failed to exercise due diligence and that
such failure was the proximate cause of the grounding were clearly
erroneous.      In the cross-appeal, Placid contends that the district
court erred in finding that Placid owned the crude oil on board the
DIALA at the time of the grounding, and furthermore that Deutsche
Shell should be held liable under the Pennsylvania Rule.9
8
See Atlantic 

-62; see generally
2 BENEDICT ON ADMIRALTY §§ 181-188 (7th Ed. 1992); G. Gilmore & C.
Black, The Law of Admiralty, ch. V, at 244-71 (2d Ed. 1975).
9
See The Pennsylvania, 86 U.S. (19 Wall.) 125 (1874).
Under the Pennsylvania Rule, "if a party violates a statute which
5
The    determinations     regarding     peril,      due   diligence,    and
proximate cause are findings of fact which are upheld on appeal
unless clearly erroneous.10          "A finding is clearly erroneous only
if   the    appellate   court   is    left   with   the     definite   and    firm
conviction that a mistake has been made."11
I.     The General Average Act
"There is a general average act when, and only when, any
extraordinary     sacrifice     or    expenditure      is   intentionally     and
reasonably made or incurred for the common safety for the purpose
of preserving from peril the property involved in a common maritime
adventure."12    The district court found that Deutsche Shell failed
to prove that a general average act occurred because the tanker was
not in peril.13 Deutsche Shell argues that the district court erred
is designed to preclude an accident from occurring, that party
bears the burden of proof in showing that its fault did not
contribute to the accident." Sheridan Transportation Co. v.
United States, 

, 797 (5th Cir. 1990). Coast Guard
regulations required the DIALA to have two independently
operating radar systems. 33 CFR §§ 164.35(a) and 164.37(a).
Placid argues that violation of this statute requires application
of the Pennsylvania Rule.
10
Elevating Boats, Inc. v. Gulf Coast Marine, 

(5th Cir. 1985); Fed.R.Civ.P. 52(a).
11
Elevating 

.
12
York/Antwerp Rule A (1974), reprinted in 2 BENEDICT            ON
ADMIRALTY § 181, at 13-1.
13
The district court found as follows:
With little more than a citation to York/Antwerp Rule A and
the London adjustor's statement, Shell would have the Court
6
in raising the issue of peril sua sponte because the issue was
never in dispute.   The lists of contested issues of law and fact in
the pretrial order contain no mention of a general average act.
Placid argues, on the other hand, that a general average act
is a necessary element of Deutsche Shell's cause of action, and the
burden is on Deutsche Shell to prove that it occurred.14         The
parties never explicitly stipulated that a general average act
occurred.    Because we uphold the district court's finding that
Deutsche Shell failed to exercise due diligence to maintain the
3-cm radar, we need not decide whether the vessel was in peril nor
whether the issue was raised properly.15
gloss over the initial issue whether Shell's degrounding
efforts constituted a general average act. Shell perhaps
believes that the Court should find the existence of a
general average act here merely because the DIALA was
carrying millions of gallons of crude oil. The Court
rejects this position and does not otherwise find
circumstances sufficient for the Court to conclude that a
general average act occurred 

.
14
See York/Antwerp Rule E (1974):
The onus of proof is upon the party claiming in General
Average to show that the loss or expense claimed is properly
allowable as General Average.
Reprinted in 2 BENEDICT   ON   ADMIRALTY § 181, at 13-2.
15
We note, however, that peril is a flexible concept:
While the courts in some cases have used expressions
indicating that both in general average and in salvage cases
it is essential that the property at risk be subject to an
immediate impending danger, we think the 'imminency' of the
peril is not the critical test. If the danger be real and
substantial, a sacrifice or expenditure made in good faith
7
II.    Lack of Due Diligence
The district court held that even if a general average act
occurred, such act was caused by Deutsche Shell's failure to
exercise due diligence to maintain the vessel's radar in seaworthy
condition.       The   district   court   found   that   Deutsche   Shell's
inadequate maintenance practices contributed to the failure of the
3-cm radar.16    The court concluded that the 3-cm radar failed for
two reasons:      (1) "water incursion into the antenna/waveguide
components of the unit from Shell's improper maintenance;" and
(2) "the T/R cell's having reached its actual useful life capacity,
which far exceeded either T/R cell type's average minimum life
expectancy."17     Although we find the district court's conclusion
regarding the T/R cell in error, we find no clear error in the
court's findings that water incursion contributed to the vessel's
grounding and that the water incursion was a result of Deutsche
Shell's failure to exercise due diligence in maintaining the 3-cm
radar.
for the common interest is justified, even though the advent
of any catastrophe may be distant or indeed unlikely.
Navigazione Generale Italiana v. Spencer Kellogg & Sons, Inc., 

, 43 (2d Cir.), cert. denied, 

(1937). A
tanker, fully laden with crude oil, unintentionally grounded in
the Mississippi River at flood stages is quite likely to be in a
perilous position.
16
The district court found that the failure of the 10-cm
radar was not caused by a lack of due diligence by Deutsche
Shell.

.
8
The Equipment
The DIALA was equipped with two independent radar units SQ a
10-cm unit and a 3-cm unit, both installed in 1973.   Each unit has
a 16-inch display screen on the bridge of the vessel which leads to
an MTR (modulator/transmitter/receiver) unit in the next room. The
3-cm unit's MTR is connected to a hollow metal waveguide that leads
to a 12-foot antenna array unit on the mast atop the bridge.     The
antenna array units are covered with fiberglass, and contain rotary
ball bearings above and below the array so the antenna may make 360
degree sweeps.
The district court provided the following helpful "layman's
explanation" of certain radar components:
A modulator sends power to a magnetron, which converts
the power to dense RF (radio frequency) energy for
transmitting out the radar unit. This RF energy passes
through a T/R (transmitter/receiver) cell and then, for
the 3-cm unit, through a waveguide . . . to the antenna
array, where the RF energy is transmitted into the
atmosphere. A small fraction of this transmitted energy
returns, or echoes, back to the antenna and back down the
waveguide . . . again. The same T/R cell then directs
this much weaker returning energy into receiver mixer
crystals; the T/R cell is designed and is able, when
functioning properly, to prevent the stronger, outgoing
RF energy from passing through and thereby damaging these
delicate mixer crystals. A klystron sends another, "base
line" RF signal into the mixer crystals. "Mixing" these
two incoming signals, the mixer crystals produce useful
electronic information, which is finally sent to the
display unit. The modulator, magnetron, T/R cell, mixer
crystals, and klystron are all components of the MTR
unit.18
The DIALA also was equipped with an interswitch device which

.
9
permits the antenna and MTR unit of one radar system to be operated
with the display unit of the other.    Prior to the radar failures on
June 5, 1983 no member of the DIALA crew had ever operated the
interswitch device.
Symptoms of Radar Failure
When a radar malfunctions, a white spot may appear on the
display screen and render the unit unfit for use.          Among the
sources for such malfunction are:        "a defective magnetron, a
defective modulator, blown or defective mixer crystals, possibly a
defective klystron, or water ingress into the waveguide."19     When
a T/R cell fails, it allows the high power transmitting RF energy
to go directly through the mixer crystals causing them to blow out.
Such failure of the T/R cell and crystals also causes a small white
spot in the center of the display screen and the loss of the rest
of the display picture.
Water incursion generally does not directly effect the T/R
cell.     However, the presence of water in the waveguide may act as
a close-range reflector of transmitting RF energy which may cause
damage to the mixer crystals.    In addition, a weak display picture
may be caused either by a magnetron malfunction or water in the
waveguide.20
Based upon the expert testimony at trial, the district court
identified three ways in which water may get inside the waveguide:

.
20

flanges or seams on the waveguide, through the front
or edges of the fiberglass scanner array unit (to which the
waveguide connects), and through the rotary ball bearing
components just above or below the scanner.       Because the
antenna cover is continuously exposed to the harsh elements of
the maritime environment, it may become soft and porous over
time or otherwise in need of fiberglass recoating to prevent
water leakage in the waveguide.21
The   heat   produced   by   transmitting   RF   energy   may   produce   a
"microwave" effect and dissipate or boil off small quantities of
water that enter the waveguide, thus leaving little or no evidence
of the water incursion.22
Maintenance Practices
Although the radar manufacturer recommended that a radar log
be kept of all service to the radar units, Deutsche Shell did not
do so.     Instead, Deutsche Shell maintained a Gerätetagebuch, or
equipment book, containing invoices from radar repair technicians.
It also appears that no one regularly checked or followed up on the
recommendations made by service technicians in the Gerätetagebuch.
For example, a service report made on March 11, 1980 indicated that
the upper antenna array's ball bearing needed to be replaced; there
was no evidence in subsequent reports that this recommendation was
ever followed. As further evidence of Deutsche Shell's poor record
keeping, the Chief Officer's December 1982 quarterly report noted
the condition of the radar as "keine Störungen seit der Werft" or
"no problems since drydock," when the Gerätetagebuch showed three
service calls regarding the radar during that period.
21

(footnote and record citations omitted).

.
11
The manufacturer's instructions advised that the antenna array
should be removed and thoroughly overhauled every second year. The
Gerätetagebuch's radar repair records bear no evidence that this
was ever done during the entire ten years that the 3-cm radar had
been installed on the DIALA.
Radar Repairs Made After the Grounding
At 2:00 a.m. the morning after the grounding, Ben Kempf, a
radar technician came aboard the DIALA to work on the radar
systems. He did not testify at trial, but his work order indicates
the following regarding the 3-cm radar:
[T]he transmitter is inoperative; all power supply
voltages are normal; replaced blown receiver mixer
crystals, but still no targets; replaced klystron with
ship's spare; crystal current appears normal at this time
but still unable to tune. [N]o other replacement parts
are available.     [S]uspect both klystrons 2K25 are
defective, because it was necessary to decrease crystal
attenuation to achieve any reading of receiver mixer
crystal current. No t/r cell replacement aboard ship;
suspect water in waveguide or in array. [D]isassembled
waveguide at transmitter but no water there. [R]emoved
waveguide from pedestal; but no evidence of water
intrusion. [W]ill return tomorrow to finish repairs.
Later that same day, Michael St. Romain, another radar technician
came to complete the radar repairs.       His report indicated the
following:
Picture on radar showed signs of water in waveguide very
weak picture and large spot in center. No evidence of
water could be found below.         Removed scanner and
inspected upper assembly. Some slight evidence of water
was shown from scanner. The front of scanner in dire
nee[d of] recoating. It is very porous and could get
water inside during a severe storm. Recommend recoating.
Also noted that top ball bearing is badly worn and should
be replaced. . . . After reassembling the waveguide parts
a very slight improvement in picture was noted, but not
enough. Changed defective TR cell and blown crystals.
This improved picture further. Tuning of klystron cavity
12
showed no change in picture.     Changed klystron from
ship's spares. This improved picture further, now out to
6 miles. Made several other checks in TR unit with no
help in picture. Changed out klystron with one from our
kit. Tuned up radar now to have targets 24 miles.
St. Romain also returned the next day and recoated both the 3-cm
and 10-cm scanners.
A.   Water Incursion
The district court found that the circumstances surrounding
the failure of the 3-cm radar were most consistent with water
incursion in the waveguide and scanner areas.            This finding is
amply supported by the evidence.         First, a white dot appeared upon
the screen just before the unit failed. This symptom suggests that
there was water in the waveguide.          In addition, the weak picture
noticed   by   Captain   Schätzel   is      also   symptomatic   of   water
incursion.23   St. Romain, the radar service technician, also found
evidence of water in the scanner.24 While St. Romain found no water
remaining in the waveguide, he did find some improvement of the
23
The district court noted that the only causes for a weak
display picture are water in the waveguide or a defective
magnetron, and there was no evidence of a defective magnetron in
this case. T/R cell failure, alone, would not cause a weak

.
24
Another service technician worked on the radars the
night of the grounding, but his testimony was not presented at
trial. His report indicates that he suspected water in the
waveguide, but found no evidence of water. The district court
discounted his failure to find traces of water based upon the
facts that his inspection took place during evening hours and
that he spent only 2 1/2 hours on the vessel to work on both
radars, and spent most of his time repairing the 10-cm radar.
The district court's determination regarding the reliability of
the report is not clearly erroneous.
13
radar      picture    after   disassembling    and   then    reassembling    the
waveguide.         From this the district court made the reasonable
inference that in the process, St. Romain cleaned out any water
that was in the waveguide.            Finally, the failure of the 3-cm radar
coincided with the ship hitting a squall, thus providing the
opportunity for water incursion.
St. Romain discovered that the scanner array was extremely
porous and in "dire nee[d of] recoating."             He also found evidence
of   water    in     the   scanner.     Deutsche   Shell's   own   expert,   Mr.
Stakelum, recognized that the extremely porous condition of the
scanner array could not have suddenly manifested itself, but must
have existed when the vessel left Sullom Voe.25
In addition, Deutsche Shell argues that any damage to the ball
bearing could not have caused the water incursion because water was
found only in the scanner and not in the waveguide where it would
be if it entered through the ball bearing.             We do not agree.      The
evidence demonstrated that water could enter the waveguide through
a defective ball bearing.             The district court found, consistent
with the expert testimony, that "the effects of evaporation may
explain the absence of more water."26           Thus, the fact that no water
was found in the waveguide after it failed, does not mean that
25
When asked if the porous condition existed when the
DIALA left Sullom Voe, Stakelum testified: "Well the condition
as Mr. St. Romain saw it in June of 1983 I think in effect
existed the same way two weeks prior to that."

.
14
water was not present at the time the radar failed.
The district court concluded that the water incursion was a
result of Deutsche Shell's failure to exercise due diligence in
maintaining the 3-cm radar unit.
Where the standard of due diligence is applicable, it
comprehends inspection and investigation, where prudent, to
determine the existence of deficiencies before they become
critical, and the failure to discover defects which
examination would necessarily have disclosed is the very
absence of due diligence.27
Deutsche Shell argues that regardless of whether water incursion
occurred, they proved that the DIALA was seaworthy when it left
Sullom Voe.   We agree with the district court that Deutsche Shell
focuses on too narrow a time frame.
The district court specifically rejected Deutsche Shell's
effort to focus on the period between the drydocking in August 1982
and the grounding in June 1983.      The antenna was not overhauled
while the vessel was in drydock.     While the vessel was in drydock
in 1982, Jens Pedersen, then a young, inexperienced technician,
spent only five hours on the vessel examining both radar units and
the directional finding device.      The radar also passed a German
classification inspection.   There was no indication, however, that
the classification inspector conducted more than a cursory review.
As the district court noted, "[i]f a shipowner is to enjoy the safe
harbor of an inspector's okay, the shipowner must show that it
27
Ionian Steamship Co. v. United Distillers, 

,
84 (5th Cir. 1956).
15
revealed sufficient facts to the inspector; Shell did not."28
Accordingly, the district court gave little weight to the lack of
problems   detected   by   Pedersen    or   the    German   classification
inspector.
The district court found, consistent with the evidence, that
if Deutsche Shell had followed the manufacturer's recommendation to
keep an accurate radar log and to overhaul the radar array every
two years, Deutsche Shell would have avoided the surprises that led
to the grounding in June 1983.        Deutsche Shell's actions did not
even approach the standard suggested by the radar manufacturer.29
There was no evidence that either the 3-cm or the 10-cm radar
underwent the recommended overhaul during the entire ten year
period they were installed on the DIALA.          During such an overhaul,
the severe porosity problems, the defective ball bearing, and other
opportunities for water incursion would have been remedied, thereby

.
29
We find no merit in Deutsche Shell's argument that the
district court improperly excluded evidence of actual practices
within the industry. The district court refused to allow the
corporate representative, Martin Buck, to testify as to
statements made by other vessel owner's representatives regarding
their maintenance practices. The district court correctly noted
that the corporate representative had no personal expert
knowledge on these matters, and that the statements of these
undisclosed other vessel owners were inadmissible hearsay.
Deutsche Shell contends that these statements were not offered
for the truth of the matters asserted, but to demonstrate
Deutsche Shell's understanding of the industry practices. We
agree with the district court. Deutsche Shell's understanding of
industry practices is irrelevant to the question of whether it
exercised due diligence. Due diligence is an objective standard;
therefore, to the extent that these statements attempted to
demonstrate what that standard is, they are rank hearsay.
16
averting the failure of the 3-cm radar.
B.     The T/R Cell
The district court indicated that "[t]he record contains no
evidence that the 3-cm unit's T/R cell from 1973 had ever been
replaced at any time."         We agree with Deutsche Shell that this
finding is not supported by the record.      The radar repair invoices
submitted by the defendants indicate that a VDX 1047s type T/R cell
was replaced in June 1982,30 one year before the radar failure which
led to the grounding.      This type of T/R cell is used in the 3-cm
radar unit but not in the 10-cm unit.31       These T/R cells have an
average useful life expectancy of 2000-5000 hours; Deutsche Shell's
radar expert, Mr. Stakelum, estimated that the average use of the
3-cm radar on a vessel such as the DIALA was 1500 to 2500 hours per
year.     The T/R cell in the 3-cm radar, having been replaced only
one year before, was not so dangerously close to the end of its
usefulness that it would have been a failure of due diligence not
to replace it prior to the voyage.         We find, however, that the
water incursion contributed to the failure of the      3-cm radar and
30
See Exhibit P24A.
31
See Exhibit P26-B pp. 5-11. The source of the district
court's error appears to have been the abstract of repair
invoices admitted as Placid's exhibit D-3 which indicated that
the VDX 1047s T/R cell was replaced in the 10-cm radar. Placid
attempts to argue that Deutsche Shell stipulated to the contents
of the abstract and therefore cannot now argue that the T/R cell
in the 3-cm radar had been replaced. We find no such
stipulation. Deutsche Shell agreed to the admissibility of the
abstract, it did not stipulate to the accuracy of its contents
particularly when the abstract contradicts the document from
which it purports to abstract.
17
is sufficient to support the district court's judgment in favor of
Placid.
III. Proximate Cause
Deutsche Shell also argues that even if the district court
properly   found    that    it    failed       to   exercise    due     diligence   in
maintaining the 3-cm radar, the district court's conclusion that
the grounding was proximately caused by that unseaworthy condition
was clearly erroneous.
The district court found that the flood stages of the river,
the pilot's      decision   not     to    continue     the     voyage    without    two
reliable radar units, and the subsequent decision to anchor were
all foreseeable events.          These findings are not clearly erroneous.
Certainly, grounding is one of the risks a vessel faces when its
radar   fails.      The    fact    that    the      vessel   was   grounded    while
attempting to anchor does not make the result unforeseeable.
Finding no reversible error, we AFFIRM.
18