U.S. patent application number 15/882630 was filed with the patent office on 2018-05-31 for additives for hydrogen/bromine cells.
The applicant listed for this patent is BROMINE COMPOUNDS LTD.. Invention is credited to Vered ATIYA-ZUCKERMAN, Mira BERGSTEIN-FREIBERG, Yasmin HERSCOVITZ-LEVY, David ITZHAK, Eli LANCRY, Ben-Zion MAGNES.
Application Number | 20180151905 15/882630 |
Document ID | / |
Family ID | 51654676 |
Filed Date | 2018-05-31 |
United States Patent
Application |
20180151905 |
Kind Code |
A1 |
MAGNES; Ben-Zion ; et
al. |
May 31, 2018 |
ADDITIVES FOR HYDROGEN/BROMINE CELLS
Abstract
The invention relates to the use of 1-alkyl-2-alkyl pyridinium
halide (e.g., 1-ethyl-2-methyl pyridinium bromide), 1-alkyl-3-alkyl
pyridinium halide (e.g., 1-ethyl-3-methyl pyridinium bromide) or
1-alkyl-3-alkyl imidazolium halide (e.g., 1-butyl 3-methyl
imidazolium bromide) as additives in an electrolyte used in
hydrogen/bromine cells, for complexing the elemental bromine formed
in such cells. The invention also provides an electrolyte
comprising aqueous hydrogen bromide and said additives, and
processes for operating an electrochemical flow cell selected from
the group consisting of hydrogen/bromine or vanadium/bromine
cells.
Inventors: |
MAGNES; Ben-Zion; (Meitar,
IL) ; LANCRY; Eli; (Ashdod, IL) ;
BERGSTEIN-FREIBERG; Mira; (Omer, IL) ; ITZHAK;
David; (Tel Aviv, IL) ; HERSCOVITZ-LEVY; Yasmin;
(Kfar Saba, IL) ; ATIYA-ZUCKERMAN; Vered; (Beer
Sheva, IL) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
BROMINE COMPOUNDS LTD. |
Beer Sheva |
|
IL |
|
|
Family ID: |
51654676 |
Appl. No.: |
15/882630 |
Filed: |
January 29, 2018 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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14210976 |
Mar 14, 2014 |
9905874 |
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15882630 |
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PCT/IL2012/000349 |
Sep 23, 2012 |
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14210976 |
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61537622 |
Sep 22, 2011 |
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61781141 |
Mar 14, 2013 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
H01M 8/188 20130101;
Y02E 60/50 20130101; H01M 2300/0002 20130101; Y02E 60/528
20130101 |
International
Class: |
H01M 8/18 20060101
H01M008/18 |
Claims
1) An electrolyte suitable for use in an electrochemical flow cell,
said electrolyte comprising aqueous hydrogen bromide and a liquid
complex composed of at least one of 1-alkyl-2-alkyl pyridinium
halide, 1-alkyl-3-alkyl pyridinium halide or 1-alkyl-3-alkyl
imidazolium halide combined with one or more bromine molecules.
2) An electrolyte according to claim 1, comprising a liquid complex
composed of at least one of 1-ethyl-2-methyl pyridinium bromide,
1-ethyl-3-methyl pyridinium bromide or 1-butyl 3-methyl imidazolium
bromide combined with one or more bromine molecules.
3) An electrolyte according to claim 2, comprising a liquid complex
composed of at least one of 1-ethyl-2-methyl pyridinium bromide or
1-ethyl-3-methyl pyridinium bromide, combined with one or more
bromine molecules.
4) An electrolyte according to claim 3, comprising a mixture of
1-ethyl-2-methyl pyridinium bromide and 1-ethyl-3-methyl pyridinium
bromide.
5) Use of at least one of 1-alkyl-2-alkyl pyridinium halide,
1-alkyl-3-alkyl pyridinium halide or 1-alkyl-3-alkyl imidazolium
halide as bromine-complexing agents in an electrochemical flow cell
which contains an electrolyte comprising aqueous hydrogen bromide,
said cell being hydrogen/bromine cell or vanadium bromine cell.
6) Use according to claim 5, wherein the 1-alkyl-2-alkyl pyridinium
halide is 1-ethyl-2-methyl pyridinium bromide.
7) Use according to claim 5, wherein the 1-alkyl-3-alkyl pyridinium
halide is 1-ethyl-3-methyl pyridinium bromide.
8) Use according to claim 5, wherein a mixture of 1-ethyl-2-methyl
pyridinium bromide and 1-ethyl-3-methyl pyridinium bromide is
used.
9) A process for operating an electrochemical flow cell selected
from the group consisting of hydrogen/bromine or vanadium/bromine
cells, comprising adding to HBr-containing electrolyte solution of
said cell an additive selected from the group consisting of
1-alkyl-2-alkyl pyridinium halide, 1-alkyl-3-alkyl pyridinium
halide, 1-alkyl-3-alkyl imidazolium halide or their mixture.
10) A process according to claim 9, comprising adding
1-ethyl-2-methyl pyridinium bromide, 1-ethyl-3-methyl pyridinium
bromide or a mixture thereof to the HBr-containing electrolyte in
hydrogen/bromine cell.
11) An energy storage device comprising: a plurality of
hydrogen/bromine cells arranged in a stack configuration, each cell
having therein spaced apart bromine and hydrogen electrodes which
are in electrical contact with means for supplying electrical
current to the cell and collecting electrical current generated by
the cell; a separator positioned in the space between said
electrodes dividing the cell into a first and second compartments;
and an aqueous hydrogen bromide electrolyte in which
1-alkyl-2-alkyl pyridinium halide, 1-alkyl-3-alkyl pyridinium
halide or a mixture thereof is present; hydrogen storage tank and
HBr/Br.sub.2 aqueous electrolyte storage tank connected by means of
one or more conduits to the cell compartments; wherein at least one
component of said device comprises high density polyethylene
(HDPE).
12) An energy storage device according to claim 11, wherein the
electrolyte storage tank and/or conduit(s) used for electrolyte
circulation comprise HDPE.
13) An energy storage device according to claim 11, wherein the
1-alkyl-2-alkyl pyridinium halide and 1-alkyl-3-alkyl pyridinium
halide are 1-ethyl-2-methyl pyridinium bromide and 1-ethyl-3-methyl
pyridinium bromide, respectively.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of U.S. application Ser.
No. 14/210,976 filed Mar. 14, 2014, which claims the benefit of
U.S. Provisional Application No. 61/781,141 filed on Mar. 14, 2013,
and is a continuation-in-part (CIP) of International Application
No. PCT/IL2012/000349 filed on Sep. 23, 2012, which claims the
benefit of U.S. Provisional Application No. 61/537,622 filed Sep.
22, 2011, the entire contents of all of which are incorporated
herein by reference.
[0002] The invention relates to compounds suitable as additives for
an electrolyte used in hydrogen/bromine cells, for complexing the
elemental bromine formed in such cells.
[0003] There exists a need, in electrochemical flow cells which
involve the generation of elemental bromine, to keep the bromine in
a form which can be readily stored and pumped over a broad
temperature range, such that it can be used without interfering
with the operation of the flow cell.
[0004] The hydrogen/bromine cell is an example of a regenerative
fuel cell. The operation of hydrogen/bromine regenerative fuel
cells is based on the electrolysis of hydrogen bromide, and the
conversion of the electrolysis products, i.e., hydrogen and
elemental bromine, back to hydrogen bromide. During charge, an
electric current supplied from an external source drives the
electrolysis of hydrogen bromide, generating hydrogen (H.sub.2) and
elemental bromine (Br.sub.2), which are stored separately in
suitable tanks located externally to the cell. H.sub.2 and Br.sub.2
are fed back to the cell during discharge and are reacted to give
hydrogen bromide, thereby producing electric energy.
[0005] A characteristic hydrogen/bromine cell is shown
diagrammatically in FIG. 1. While this figure depicts a single
cell, it is to be noted that a plurality of such cells can be
assembled in series. Numerals 1 and 2 represent the hydrogen and
bromine electrodes, respectively, and numeral 3 represents a
separator (e.g. an ion exchange membrane) positioned between the
electrodes. The term "hydrogen electrode" is used herein to
indicate the electrode where hydrogen gas is formed (during charge)
and oxidized (during discharge). The term "bromine electrode" is
used herein to indicate the electrode where elemental bromine is
formed (during charge) and reduced (during discharge).
[0006] A first storage tank, for collecting the hydrogen gas, is
indicated by numeral 4. A second storage tank, which contains a
concentrated aqueous solution of hydrogen bromide, is indicated by
numeral 5. Flow paths 4a and 5c, connecting the hydrogen storage
tank 4 and the HBr storage tank 5 to the respective sides of the
cell, and pumps for driving the fluids along the flow paths are
also shown in FIG. 1.
[0007] The charge/discharge cycle is represented by the following
pair of chemical equations:
##STR00001##
[0008] During charge, the electrolyte which comprises hydrobromic
acid is fed from storage tank 5 to that side of the cell where the
bromine electrode 2 is placed (which is the cathodic side of the
cell at the charge state). The hydrobromic acid undergoes
electrolysis, resulting in the formation of elemental bromine at
the cathode. The electrolyte, enriched with elemental bromine, is
removed from the cathodic side of the cell and is transferred to
the storage tank 5. Hydrogen ions concurrently pass across the
membrane 3 to the anodic side, where hydrogen gas evolves at the
anode 1, and is collected in tank 4.
[0009] During discharge, the hydrogen gas and the
bromine-containing electrolyte are fed from their storage tanks 4
and 5, respectively, to the respective sides of the cell, where the
hydrogen and bromine electrodes are positioned (it is to be noted
that the anodic/cathodic sides are reversed relative to previous
stage). The reaction between hydrogen and bromine yields
hydrobromic acid, with electric current being drawn from the
cell.
[0010] It should be understood that the electrolyte, with which the
electrolysis stage starts, is not necessarily free of elemental
bromine. In practice, the electrolysis stage starts with an
electrolyte which contains, in addition to hydrobromic acid, also
up to 10% elemental bromine. For example, the concentrations of HBr
and Br.sub.2 in the aqueous electrolyte prior to the electrolysis
may be from 5% to 52% (more preferably 10% to 45%) and from 0% to
10% (more preferably 0.1% to 5%), respectively. During the
electrolysis stage (i.e., the charging process), the concentration
of the hydrobromic acid in the electrolyte is gradually decreased,
while the concentration of the elemental bromine increases. Upon
completion of the charge state, the electrolyte typically comprises
from 5% to 35% HBr and from 0.2M to 3.5M Br.sub.2. It follows that
the composition of the electrolyte varies significantly during the
charge/discharge cycle.
[0011] Bromine is a dark red, fuming liquid. It is reactive and
corrosive and has a high vapor pressure at room temperature. In
cells utilizing bromine as an electrochemically active element,
there is a need to deactivate the bromine, i.e., convert it into a
form with reduced vapor pressure, which form is less likely to
interfere with the operation of the cell. It is known in the art
that this goal can be achieved by adding a bromine-complexing agent
to the electrolyte. The bromine-complexing agent combines with
bromine molecule(s) to form a polybromide complex. As a result, the
vapor pressure above the complexed bromine solution is
decreased.
[0012] In regenerative fuel cells the electrolyte reservoir is
separated from the electrodes stack, with the electrolyte being
pumped from the reservoir to the electrodes and back. The
flowability of the electrolyte must be maintained with respect to
different compositions corresponding to different states of charge,
and over the entire operational temperature range (typically
between -15.degree. C. and 50.degree. C.). In other words,
throughout the operation of the cell, the formation of a solid
phase in the electrolyte is unacceptable.
[0013] In the past, bromine complexing agents were investigated for
the deactivation of elemental bromine in zinc bromine flow
batteries. Bromine deactivation in these batteries may be achieved
by the use of cyclic quaternary ammonium bromides (abbreviated
quats) as complexing agents. In their most general form, these
salts are represented by the following formula:
##STR00002##
where R.sub.1 and R.sub.2 indicate the alkyl groups (which are
generally different from one another) and X indicates the halide
counter ion. It should be particularly noted that in this formula,
the cation is a non-aromatic heterocyclic system. Specifically,
N-methyl-N-ethyl pyrrolidinium bromide (abbreviated MEP) and
N-methyl-N-ethyl morpholinium bromide (abbreviated MEM) are both
commercially used for that purpose. However, the experimental
results reported below indicate that neither N-methyl-N-ethyl
pyrrolidinium bromide nor N-methyl-N-ethyl morpholinium bromide is
suitable for use in hydrogen/bromine regenerative fuel cells, for
the reason that they crystallize under certain working conditions
employed in such cells.
[0014] It has now been found that 1-alkyl-2-alkyl pyridinium
bromide, such as 1-ethyl-2-methyl pyridinium bromide (abbreviated
2-MEPy), 1-alkyl-3-alkyl pyridinium bromide, such as
1-ethyl-3-methyl pyridinium bromide (abbreviated 3-MEPy), and 1,3
dialkyl imidazolium bromide such as 1-butyl 3-methyl imidazolium
bromide (abbreviated BMIBr) and mixtures thereof are effective as
complexing agents for a hydrogen/bromine cells, e.g., a
hydrogen/bromine regenerative fuel cell. Having tested HBr/bromine
containing electrolytes with varied compositions corresponding to
distinct states ensuing during the charge/discharge cycle of
hydrogen/bromine cell, it has been surprisingly found that the
presence of said compounds in the electrolyte allows the formation
of polybromide complexes which do not solidify under the relevant
working conditions.
[0015] Heretofore, 1-alkyl-2-methyl-pyridinium (also named N-alkyl
picolinium) halide salts were proposed in the art for the following
uses. U.S. Pat. No. 5,260,148, for example, describes the
preparation of an electrolytic solution for lithium secondary
batteries by adding N-methyl picolinium ions to a solvent which is
an equimolar mixture of propylene carbonate and
1,2-dimethoxyethane. Barlet, R. et al. [Journal de Chimie Physique
et de Physico-Chimie Biologique (1984), 81(5), 349-54] describes
the use of pyridinium halides as room temperature battery
electrolytes. EP 0404188 discloses a non-aqueous electrolytic
aluminum plating bath composition comprising, inter alia, halide
such as an N-alkyl picolinium halide. Shlyapnikov, D. S. [Khimiya
Geterotsiklicheskikh Soedinenii (1972), (7), 966-9] describes
SO.sub.2 complexes with quaternary halide salts of e.g.
.alpha.-picoline.
[0016] The present invention is therefore primarily directed to the
use of 1-alkyl-2-alkyl pyridinium halide, 1-alkyl-3-alkyl
pyridinium halide, 1,3 dialkyl imidazolium halide or their
mixtures, wherein the halide is preferably bromide, as bromine
complexing agents in electrochemical flow cells selected from the
group consisting of hydrogen/bromine cell and vanadium/bromine
cell. The alkyl groups attached to the aromatic ring are
independently selected from the group of C1-C5 alkyl. Preferably,
the alkyl groups are different from one another. In the case of
1-alkyl-2-alkyl pyridinium bromide and 1-alkyl-3-alkyl pyridinium
bromide, it is preferred to have an ethyl group attached to the
nitrogen atom and a methyl group attached to the carbon ring (i.e.,
either at the 2- or 3-position of the pyridine ring).
[0017] In another aspect, the invention provides an electrolyte
suitable for use in electrochemical flow cells selected from the
group consisting of hydrogen/bromine cell and vanadium bromine
cell, said electrolyte comprising aqueous hydrogen bromide and a
liquid complex composed of at least one of 1-alkyl-2-alkyl
pyridinium halide (e.g., bromide), 1-alkyl-3-alkyl pyridinium
halide (e.g., bromide) or 1,3 dialkyl imidazolium halide (e.g.,
bromide) combined with one or more bromine molecules. The liquid
complex is preferably composed of 1-ethyl-2-methyl pyridinium
bromide, 1-ethyl-3-methyl pyridinium bromide or 1-butyl 3-methyl
imidazolium bromide and bromine molecules.
[0018] In another aspect, the invention is directed to a process
for operating an electrochemical flow cell selected from the group
consisting of hydrogen/bromine and vanadium bromine cell,
comprising adding 1-alkyl-2-alkyl pyridinium halide (e.g.,
bromide), 1-alkyl-3-alkyl pyridinium halide (e.g., bromide), 1,3
dialkyl imidazolium halide (e.g., bromide) or their mixtures as set
forth above, to the HBr-containing electrolyte of said cell.
[0019] The preferred complexing agents according to the invention,
1-ethyl-2-methyl pyridinium bromide and 1-ethyl-3-methyl pyridinium
bromide are prepared by reacting 2-picoline or 3-picoline,
respectively, with ethyl bromide, as illustrated by the following
reaction schemes:
##STR00003##
[0020] The reaction is carried out by charging a pressure reactor
with the reactants and optionally also with a solvent, which may be
either an aqueous or organic solvent. Alternatively, the reaction
is solvent free, with one of the reactants being optionally used in
excess. It is possible to introduce the entire amounts of the
reactants into the reactor and then start the reaction by heating
the reaction mixture. However, it is also possible to gradually
feed one or more of the reactants (e.g., the ethyl bromide) into
the reactor over a period of not less than one hour under
heating.
[0021] The reaction mixture is heated, preferably to a temperature
of not less than 90.degree. C., and the reaction is allowed to
proceed under pressure for a few hours. The product is conveniently
collected in the form of an aqueous solution, which can be directly
applied as an additive for the HBr electrolyte solution in
accordance with the present invention. To this end, upon completion
of the reaction, the organic solvent and/or residual amounts of the
starting materials are removed from the reaction vessel by means of
methods known in the art, e.g., distillation. Water can then be
added into the reactor, to afford the complexing agent in an
aqueous form. The concentration of the aqueous solution of 2-MEPy
or 3-MEPY or their mixture which can be used as an additive for the
HBr electrolyte is preferably from 50 to 90 wt %.
[0022] Another complexing agent suitable for use according to the
invention, 1-butyl 3-methyl imidazolium bromide, is commercially
available from Chemada Israel, and can be also prepared by methods
known in the art.
[0023] The electrolyte according to the invention is prepared by
combining together aqueous hydrogen bromide, the complexing agent,
e.g., 1-ethyl-2-methyl pyridinium bromide, 1-ethyl-3-methyl
pyridinium bromide, 1-butyl 3-methyl imidazolium bromide or a
mixture thereof, and the electrochemically generated bromine, which
is formed in-situ in the cell on charging, or chemically (e.g.,
peroxide) generated bromine. To an aqueous solution of hydrogen
bromide, with HBr concentration of 5%-52% by weight, e.g., 10-wt %,
will be added the complexing agent such that its concentration in
the resulting solution is not less than 0.25M, up to a
concentration capable of complexing the maximal bromine content. On
charging, the hydrogen bromide is consumed and bromine is
generated. On discharging, the aqueous phase of the electrolyte is
again concentrated with respect to HBr, and the concentration of
bromine is reduced.
[0024] As noted above, the bromine complexing agents of the
invention may be used either in individual form or in the form of
mixtures, e.g., binary mixtures, in which the molar ratio between
the two components of the mixture may be from 1:5 to 5:1, more
preferably from 1:4 to 4:1 and even more preferably, from 1:3 to
3:1. One preferred mixture consists of 1-ethyl-2-methyl pyridinium
bromide and 1-ethyl-3-methyl pyridinium bromide in a molar ratio
between 1:2 to 1:4. The comlexing agents are preferably added to
the electrolyte in the form of concentrated aqueous solutions in
which the concentration of the complexing agent may be from 40 to
92% by weight, e.g., 65 to 90% by weight.
[0025] The process of the invention is carried out utilizing a
hydrogen/bromine cell of the type described above with reference to
FIG. 1, with the addition of the complexing agent into the storage
tank used for holding the aqueous HBr (indicated by numeral 5 in
FIG. 1). Another example of hydrogen/bromine cell which can be used
in the process of the invention is illustrated in U.S. Pat. No.
4,520,081. Vanadium/bromine cells which can be operated according
to the invention are illustrated, for example, in U.S. Pat. No.
7,320,844 or US 2006/0183016.
[0026] The invention also relates to a structural material suitable
for use in the construction of hydrogen/bromine energy storage
device. Such structural materials ought to exhibit a combination of
high mechanical strength and good chemical resistance over broad
range of working temperatures, due to the highly corrosive nature
of the HBr/Br.sub.2 aqueous electrolyte circulating in the cell.
For example, in the usual construction of hydrogen/bromine energy
storage device, a plurality of cells such as the one illustrated in
FIG. 1 are assembled together adjacent to one another in a stack
configuration to produce the desired voltage within the stack.
Various parts of the hydrogen/bromine energy storage device, such
as the tank used to hold the bromine-containing aqueous HBr
electrolyte, and pipes used to supply and withdraw the reactants
and reaction products to and from the cell stacks, are continually
exposed to elemental bromine and hydrobromic acid, which are both
corrosive substances. Therefore, structural materials in
hydrogen/bromine energy storage device must be chosen
carefully.
[0027] The problem of finding a structural material suitable for
use in hydrogen/bromine-based systems was addressed in U.S. Pat.
No. 4,520,081, where various materials for making the frame of the
cell which surrounds the electrodes are considered, including inert
plastics and specifically polytetrafluoroethylene, i.e.,
fluorine-containing polymers which are well known for their high
chemical inertness. In U.S. Pat. No. 4,520,081, a modified form of
graphite having a layer of pyrographite disposed on its surface was
used for making the frames of the cells.
[0028] High density polyethylene (HDPE) is increasingly used as a
structural material, for example in piping systems for gas
distribution and water lines. However, HDPE is not considered as a
structural material of choice in systems where exposure to bromine
is expected to occur. Indeed, the experimental work conducted in
support of this invention indicates that HDPE is incompatible with
the electrolyte operable in hydrogen/bromine cells, as it is unable
to withstand an attack by HBr/Br.sub.2 aqueous solution under the
relevant working conditions, e.g., at a temperature of 50.degree.
C.; under these conditions, HDPE is severely damaged.
[0029] We have now found that HDPE can serve as a structural
material in energy storage devices comprising hydrogen/bromine
cells, if an additive selected from the group consisting of
1-alkyl-2-alkyl pyridinium halide, 1-alkyl-3-alkyl pyridinium
halide or their mixture (e.g., 2-MEPy, 3-MEPy or a mixture thereof)
is added to the electrolyte, i.e., to the aqueous hydrogen bromide
solution. The experimental results reported below indicate that
when said additive(s) is(are) present in the electrolyte solution,
then HDPE can withstand the electrolyte corrosiveness and is
capable of maintaining its mechanical properties.
[0030] Accordingly, the invention also relates to an energy storage
device comprising: [0031] a plurality of hydrogen/bromine cells
arranged in a stack configuration, each cell having therein spaced
apart bromine and hydrogen electrodes which are in electrical
contact with means for supplying electrical current to the cell and
collecting electrical current generated by the cell; a separator
positioned in the space between said electrodes dividing the cell
into first and second compartments; and an aqueous hydrogen bromide
electrolyte in which 1-alkyl-2-alkyl pyridinium halide (for
example, 1-ethyl-2-methyl pyridinium bromide), 1-alkyl-3-alkyl
pyridinium halide (for example, 1-ethyl-3-methyl pyridinium
bromide) or a mixture thereof is present; [0032] hydrogen storage
tank and HBr/Br.sub.2 aqueous electrolyte storage tank connected by
means of conduits to the cell compartments; wherein at least one
component of said device (e.g., a tank and/or a conduit used for
electrolyte storage and circulation) is made of HDPE.
[0033] Hydrogen/Bromine cell which can be used in the energy
storage device of the invention contains hydrogen electrode (which
may be made of carbon covered with platinum, supported on one face
of the membrane); bromine electrode (e.g., in the form of a carbon
felt); cell frames made of graphite; sulfonated
polytetrafluoroethylene (e.g., Nafion.RTM.) membrane; current
collectors and end plates, as described, for example, in U.S. Pat.
No. 4,520,081. An energy storage device based on hydrogen/bromine
cells is described in US 2012/0299384; parts of such a device,
which may be made of HDPE according to the present invention,
include the electrolyte storage tank and electrolyte feed lines.
HDPE for use in the construction of the cell preferably has a
density greater than 0.941 g/cm.sup.3, e.g., greater than 0.945
g/cm.sup.3. For example, PE-HWST which is commercially available
from SIMONA can be used.
BRIEF DESCRIPTION OF THE DRAWINGS
[0034] FIG. 1 illustrates the structure of a typical
hydrogen/bromine cell.
[0035] FIG. 2 is photograph of a reference white test HDPE specimen
and a test specimen following exposure to an electrolyte solution
which contains HBr and bromine.
[0036] FIG. 3 is photograph of a reference white test HDPE specimen
and a test specimen following exposure to an electrolyte solution
which contains HBr, bromine and the additives of the invention.
[0037] The following non-limiting working examples illustrate
various aspects of the present invention.
EXAMPLES
[0038] Methods [0039] 1) The specific conductivity of the hydrogen
bromide acid solutions containing the complexing agents were
measured at room temperature, before the addition of bromine to the
samples using Innolab 740 instrument with graphite conductivity
cell.
[0040] 2) The temperature at which the formation of a solid phase
takes place in the electrolyte solution was determined by gradually
cooling the samples from RT (approximately 25-30.degree. C.) to
-15.degree. C. The cooling regime was as follows: the temperature
was decreased from RT down to 15.degree. C. with a cooling rate of
0.2.degree. C./min, and kept at 15.degree. C. for 4 hours and so
forth down to -15.degree. C. At each of the following temperatures:
15.degree. C., 10.degree. C., 5.degree. C., 0.degree. C.,
-5.degree. C., -10.degree. C. and -15.degree. C., the solution was
maintained at a constant temperature for four hours. The cooling
test was performed in polyethylene glycol solution, until the
formation of crystals was observed.
[0041] 3) The bromine concentration in the aqueous phase above the
polybromide complex-oily phase was determined by a conventional
iodometric titration technique. Each vial was sampled three times
at room temperature.
[0042] 4) The vapor pressure above the electrolyte solutions
containing the complexing agents was measured at 20-26.degree. C.
according to "Vapor pressures of bromine-quaternary ammonium salt
complexes for zinc-bromine battery applications" Satya N. Bajpal J.
Chem. Eng. Data 1981, 26, 2-4.
Example 1
Preparation of 2-MEPy in Aqueous Medium
##STR00004##
[0044] A pressure reactor was equipped with a mechanical stirrer
with a magnetic relay and a thermocouple well. The reactor was
purged with nitrogen, charged with 2-picoline (101.3 g) and
de-ionized water (DIW) (20 mL), sealed and the mixture was heated
to 92.degree. C. Ethyl bromide (97.9 g) was slowly added during 3
hours, at 92-100.degree. C. The mixture was heated at
94-100.degree. C. for additional 2 hours, then cooled, and the
pressure was released. The crude solution was diluted with DIW (24
mL) and excess 2-picoline was distilled-off as aqueous azeotrope,
under reduced pressure. Finally, the residue was diluted with DIW.
Final product: 251 g; 66.1 weight % (argentometric titration);
yield, 91.5%.
Example 2
Preparation of 2-MEPy in Acetonitrile as a Solvent
[0045] A pressure reactor was equipped with a mechanical stirrer
with a magnetic relay and a thermocouple well. The reactor was
purged with nitrogen, charged with 2-picoline (57.9 g), ethyl
bromide (69 g) and acetonitrile (69 g). The reactor was sealed and
the mixture heated to 97.degree. C. Heating at 97.degree. C. was
continued for 6 hours. Distillation of the solvent was controlled
by the upper valve of the reactor followed by vacuum distillation
(without cooling). DIW (31 mL) was added to dissolve the crude
mixture and vacuum was applied to remove residual acetonitrile.
Finally, the solution was diluted with DIW (10.5 g). Final product:
149 g; 80.0 weight % (argentometric titration); yield, 95%.
Example 3
Preparation of 2-MEPy with Excess Ethyl Bromide
[0046] A pressure reactor was equipped with a mechanical stirrer
with a magnetic relay and a thermocouple well. The reactor was
purged with nitrogen, charged with 2-picoline (95 g) and ethyl
bromide (145 g). The reactor was sealed and the mixture heated to
97.degree. C. Heating at 97.degree. C. was continued for 18 hours.
Distillation of excess ethyl bromide was controlled by the upper
valve of the reactor followed by vacuum distillation. Finally, the
solution was diluted with DIW (47 g). Final product: 250 g; 79.3
weight % (argentometric titration); yield, 96%.
Example 4
Preparation of 3-MEPy or 4-MEPy
##STR00005##
[0048] A pressure reactor was equipped with a mechanical stirrer
with a magnetic relay and a thermocouple well. The reactor was
purged with nitrogen, charged with 3-picoline (101.3 g) and DIW (25
mL). The reactor was sealed and the mixture was heated to
96.degree. C. Ethyl bromide (97.9 g) was slowly added during 2
hours, at 96-104.degree. C. The mixture was heated at 100.degree.
C. for additional 3.5 hours, after which time the pressure was
released. The crude solution was diluted with DIW and excess
3-picoline was distilled-off as aqueous azeotrope, under reduced
pressure. Finally, the residue was diluted with DIW. Final product:
260 g; 66.6 weight % (argentometric titration); yield, 95.6%.
4-MEPy was prepared in a similar manner, starting from
4-picoline.
Examples 5-7 (of the Invention) and 8-10 (Comparative)
Preparing and Measuring the Properties of Electrolyte Solutions
which Correspond to Electrolyte Solutions at the Beginning of the
Charge Stage
[0049] Samples of hydrogen bromide acid solutions containing the
complexing agents (abbreviated Quats), were prepared with final HBr
concentration of 34% by weight, 0.8M of Quat and 0.2M of bromine,
namely, with a composition corresponding to the composition of an
electrolyte at the beginning of a charging process in
hydrogen/bromine cell. The total volume of each sample was 12 ml in
a closed vial. The samples were stored at room temperature (RT) for
24 hours after preparation before any measurement was conducted.
The samples were tested for the following properties: the
temperature at which a solid phase is formed in the electrolyte,
free bromine concentration, conductivity and vapor pressure. The
results are given in the following table:
TABLE-US-00001 TABLE 1 Temperature at which a [Br.sub.2] in
Specific Vapor solid phase aqueous conductivity pressure Ex. Quat
was observed phase (%) (mS/cm) (mm Hg) 5 2-MEPy 5.degree. C. 0.9
588 24 6 3-MEPy -5.degree. C. 0.65 623 24 7 BMIBr -10.degree. C.
0.13 534 22 8 4-MEPy 25.degree. C. N/A 610 N/A 9 MEP 20.degree. C.
N/A 600 N/A 10 MEM 20.degree. C. N/A 597 N/A
[0050] The results show that 2-MEPy, 3-MEPy and BMIBr are suitable
for use as bromine complexing agents in electrolyte solutions of
hydrogen/bromine cells at the beginning of the charge state.
Example 11-13 (of the Invention) and 14-16 (Comparative)
Preparing and Measuring the Properties of Electrolyte Solutions
which Correspond to Electrolyte Solutions at the End of the Charge
Stage
[0051] The procedures and measurements as set forth in the previous
examples were repeated. However, the amounts of HBr and elemental
bromine were adjusted to form samples of electrolyte solutions that
represent the composition of the electrolyte at the end of the
charge process. Hence, samples were prepared with final HBr
concentration of 22% by weight, 0.8M of Quat and 1M of bromine. The
total volume of each sample was 12 ml in a closed vial. The samples
were stored at room temperature for 24 hours after preparation
before any measurement was conducted. The samples were tested for
the following properties: the temperature at which a solid phase is
formed in the electrolyte, free bromine concentration, conductivity
and vapor pressure. The results are shown in Table 2.
TABLE-US-00002 TABLE 2 [Br.sub.2] in Specific Vapor solidification
aqueous conductivity pressure Ex Quat temperature phase (%) (mS/cm)
(mm Hg) 11 2-MEPy -10.degree. C. 1.05 582 21 12 3-MEPy -10.degree.
C. 0.99 605 18 13 BMIBr -7.degree. C. 0.85 530 19 14 4-MEPy
25.degree. C. N/A 597 N/A 15 MEP 5.degree. C. 1.21 593 24 16 MEM
5.degree. C. 2.14 591 30
[0052] The results show that 2-MEPy, 3-MEPy and BMIBr are suitable
for use as bromine complexing agents in electrolyte solutions of
hydrogen/bromine cells at the end of the charge stage.
Examples 17-21 (of the Invention) and 22-23 (Comparative)
[0053] In this set of examples, various mixtures of complexing
agents were tested in electrolyte solutions having a composition
which corresponds to the composition of an electrolyte solution at
the beginning of the charge process (see the procedure of Examples
5-10). The results are tabulated in Table 3.
TABLE-US-00003 TABLE 3 [Br.sub.2] in Specific aqueous conduc- Vapor
Quats Quats solidification phase tivity pressure Ex mixture ratio
temperature (%) (mS/cm) (mmHg) 17 2-MEPy/3- 3:1 -5.degree. C. 0.93
561 22 MEPy 18 2-MEPy/3- 1:1 -10.degree. C. 0.81 456 35 MEPy 19
2-MEPy/3- 1:3 -10.degree. C. 0.49 600 36 MEPy 20 2-MEPy/3- 1:1:1
-10.degree. C. 1.38 598 -- MEPy/4- MEPy 21 2-MEPy/4- 3:1 -5.degree.
C. 0.8 572 -- MEPy 22 2-MEPy/4- 1:1 20.degree. C. N/A N/A N/A MEPy
23 2-MEPy/4- 1:3 20.degree. C. N/A N/A N/A MEPy
Examples 24-29 (of the Invention) and 30 (Comparative)
[0054] In this set of examples, various mixtures of complexing
agents were tested in electrolyte solutions having a composition
which corresponds to the composition of an electrolyte solution at
the end of the charge process (see the procedure of Examples
11-16). The results are tabulated in Table 4.
TABLE-US-00004 TABLE 4 [Br.sub.2] in Specific aqueous conduc- Vapor
Quats Quats solidification phase tivity pressure Ex mixture ratio
temperature (%) (mS/cm) (mmHg) 24 2-MEPy/3- 3:1 -10.degree. C. 1.12
569 27 MEPy 25 2-MEPy/3- 1:1 -10.degree. C. 0.88 562 34 MEPy 26
2-MEPy/3- 1:3 -10.degree. C. 1.16 566 38 MEPy 27 2-MEPy/3- 1:1:1
-10.degree. C. 1.12 576 -- MEPy/4- MEPy 28 2-MEPy/4- 3:1
-10.degree. C. 0.92 571 43 MEPy 29 2-MEPy/4- 1:1 -5.degree. C. 1.25
-- -- MEPy 30 2-MEPy/4- 1:3 20.degree. C. -- -- -- MEPy
Examples 31-36
[0055] Samples were prepared with HBr concentration of 10% by
weight. The complexing agent that was tested was 2-MEPy. The
concentration of 2-MEPy in each sample was 0.8M. Different amounts
of elemental bromine were added to the samples and some properties
of interest (the concentration of elemental bromine in the aqueous
phase, the conductivity and vapor pressure) were measured at two
temperatures: 22.degree. C. and 45.degree. C.
[0056] The following is noted with respect to the measurements
relevant to this set of examples (31-36) and the next two sets of
examples (37-42 and 43-48):
[0057] The samples were stored at 25.degree. C. for at least 24
hours after preparation before any measurement was conducted.
[0058] Conductivity measurements were carried out at 22-24.degree.
C. on solutions which contain bromine.
[0059] Sample preparations for iodometric titration and the
titration itself were done at 22-24.degree. C.
[0060] The equilibrium total pressure above the electrolyte at the
desired temperature has been measured using mercury manometer vs
equilibrium pressure of liquid for which exact values of
equilibrium vapor pressure are well known in all range of
temperatures. Distillated water was used as the reference. Two
round-bottom flasks of the same volume and with the same volume of
the measured electrolyte and water, closed by vacuum valves, were
connected to the mercury manometer. Each flask was accurately
equilibrated at the desired temperature and the vacuum valves were
opened. After the system was equilibrated the difference between
the levels of mercury in both side of manometer tube was measured.
The accurate value of water pressure at temperature of water flask
is known. The measured difference in mercury levels has been added
to this value.
[0061] The results are tabulated in Table 5.
TABLE-US-00005 TABLE 5 [Br.sub.2] in aqueous Vapor pressure Vapor
pressure Br.sub.2, M phase Conductivity, at 22.degree. C., at
45.degree. C., Ex. added (%) mS/cm mmHg mmHg 31 -- -- 352 17 78 32
1.0 0.42 479 -- -- 33 1.5 0.79 480 -- -- 34 2 1.92 485 10 63 35 2.5
3.72 481 14 77 36 3 6.07 479 18 82
Examples 37-42
[0062] Samples were prepared with HBr concentration of 10% by
weight. The complexing agent that was tested was a mixture
consisting of 2-MEPy and 3-MEPy at molar ratio of 3:1. The
concentration of the mixture of 2-MEPy and 3-MEPy in each sample
was 0.8M. Different amounts of elemental bromine were added to the
samples and some properties of interest (the concentration of
elemental bromine in the aqueous phase, the conductivity and the
vapor pressure) were measured at three temperatures: 22.degree. C.,
45.degree. C. and 60.degree. C. The results are tabulated in Table
6.
TABLE-US-00006 TABLE 6 Vapor [Br.sub.2] [Br.sub.2] pressure in aq.
in aq. Vapor Vapor at Br.sub.2, phase phase pressure pressure
60.degree. C., M (%) (%) Cond. at 22.degree. C., at 45.degree. C.,
.+-.3 Ex. added 22.degree. C. 45.degree. C. mS/cm .+-.1 mmHg .+-.2
mmHg mmHg 37 -- 365 15 80 165 38 1.0 0.64 0.75 460 -- -- -- 39 1.5
0.95 1.20 478 -- -- -- 40 2 1.17 2.73 475 -- -- -- 41 2.5 2.79 5.31
467 16 75 176 42 3 5.16 8.76 462 17 77 185
Examples 43-48
[0063] Samples were prepared with HBr concentration of 10% by
weight. The complexing agent that was tested was a mixture
consisting of 2-MEPy and 3-MEPy at molar ratio of 1:3. The
concentration of the mixture of 2-MEPy and 3-MEPy in each sample
was 0.8M. Different amounts of elemental bromine were added to the
samples and some properties of interest (the concentration of
elemental bromine in the aqueous phase, the conductivity and the
vapor pressure) were measured at three temperatures: 22.degree. C.,
45.degree. C. and 60.degree. C. The results are tabulated in Table
7.
TABLE-US-00007 TABLE 7 [Br.sub.2] [Br.sub.2] Vapor in aq. in aq.
Vapor Vapor pressure Br.sub.2, phase phase pressure pressure at M
(%) (%) Cond. at 22.degree. C., at 45.degree. C., 60.degree. C.,
Ex. added 22.degree. C. 45.degree. C. mS/cm mmHg mmHg mmHg 43 --
380 17 74 158 44 1.0 0.69 1.90 463 -- -- -- 45 1.5 0.94 1.79 472 --
-- -- 46 2 1.40 2.15 475 -- -- -- 47 2.5 2.82 5.56 465 17 67 170 48
3 6.66 8.36 466 17 70 183
[0064] It is apparent from Tables 5, 6 and 7 that at temperatures
of 22.degree. C. and 45.degree. C., the increase at the amount of
elemental bromine in the electrolyte does not result in an increase
of the vapor pressure, indicating that the additives of the
invention form strong complexes with the elemental bromine in HBr
solutions. It should be noted that at a temperature of 60.degree.
C. a small increase of the vapor pressure is observed, but this
temperature is beyond the temperature range at which
electrochemical cells normally operate.
Example 49 (Comparative) and Example 50 (of the Invention)
[0065] HDPE test specimens (PE-WHST.TM. with density of 0.947
g/cm.sup.3, available from SIMONA) were exposed to aqueous HBr
solutions which contain elemental bromine under the experimental
conditions set forth below and were then subjected to various
tests. The average dimensions of the test specimens were as
follows: length--6.2 cm; width--1.2 cm; thickness--0.3 cm.
[0066] In a first set of experiments, a test specimen was immersed
in 200 ml aqueous solution which contains hydrogen bromide and
elemental bromine at concentrations of 10 wt % and 3M,
respectively. The solution was heated to 50.degree. C. under
reflux. The solution was maintained under stirring at 50.degree. C.
for a period of time of 30 days, following which the test specimen
was removed from the solution.
[0067] A second set of experiments was carried out similarly to the
first one, with the difference that a mixture of 2-MEPy and 3-MEPy
at a concentration of 0.8M was present in the solution. The molar
ratio between 2-MEPy and 3-MEPy in the mixture was 3:1.
[0068] The test specimen which was removed from the solution was
inspected visually, to evaluate color and structural changes
occurring on the surface of the specimen. The test specimen was
also weighed immediately at the end of the experiment. The
mechanical stability of the test specimens was assessed by
comparing the (average) impact strength with that of a reference
specimen; the impact strength was measured using the Izod notched
test (ASTM D-256-92 with pendulum of 10.8 J). The experimental
conditions and results are tabulated in Table 8. Examples 49 and 50
correspond to the first and second sets of experiments,
respectively.
TABLE-US-00008 TABLE 8 Example 49 (comparative) 50 Experimental
conditions Test specimen HDPE HDPE Composition of the aqueous HBr
10 wt % HBr 10 wt % solution Br.sub.2 3M Br.sub.2 3M 2-MEPy +
3-MEPy Temperature 50.degree. C. 50.degree. C. Properties of the
specimen Visible properties Color change from Color change from
white-to- white to yellow- reddish brown; orange; surface Blisters
were remained unchanged formed on the surface of the specimen
weight change (%) 13.41.sup.a 2.4.sup.c Impact strength 679.sup.a
638.sup.c (Izod notched J/m) (Reference: 622.sup.b) (Reference:
636d) .sup.athe average of 10 measurements .sup.bthe average of 10
measurements .sup.cthe average of 10 measurements .sup.dthe average
of 10 measurements
[0069] Regarding the results of Example 49, it is noted that HDPE
test specimens exposed to bromine-containing aqueous hydrogen
bromide solutions absorbed an appreciable amount of elemental
bromine, as indicated by the severe color change and the large
increase in the weight of the specimen. FIG. 2 is photograph of a
reference white test specimen and a typical test specimen obtained
following the experiment (on the left and right sides of the
photograph, respectively; the photograph was taken before the Izod
notched test). The photograph shows the severe color change. In
addition, the surface of the HDPE test specimen was seriously
damaged, as indicated by the formation of small blisters marked by
an arrow in FIG. 2, i.e., small "pockets" with liquid trapped
therein.
[0070] Regarding the results of Example 50, it is noted that in the
presence of the complexing agents, the resistance of HDPE to the
electrolyte is markedly improved. The amount of bromine absorbed by
the HDPE test specimen is acceptable, as indicated by a small
increase in the weight of the specimen and the
white-to-yellow/orange color change. FIG. 3 is photograph of a
reference, white test specimen and a typical test specimen obtained
following the experiment (on the lower and upper sides of the
photograph, respectively; the photograph was taken after the Izod
notched test). No damage is observed on the surface of the HDPE
test specimen. Furthermore, HDPE exposed to elemental bromine in
the presence of the complexing agents retains its mechanical
strength as indicated by the fact that the impact strength of the
reference specimen and the test specimen are comparable.
* * * * *