Method and apparatus of storing ice slurry and its use for cooling purposes

Apparatus and methods of cooling which include the storage of cooling capacity or thermal energy in the form of an ice slurry or slush and the subsequent use of the ice for any cooling purpose, including air conditioning and industrial installations which require cooling or refrigeration. A tank is disclosed with equipment for uniformly depositing ice slurry in the tank and for draining liquid through the ice to cool it for use in cooling a facility.

This invention relates to apparatus for, and methods of, cooling. More 
particularly, this invention is concerned with novel apparatus and methods 
of cooling which include the storage of cooling capacity or thermal energy 
in the form of an ice slurry or slush and the subsequent use of the ice 
for any cooling purpose, including air conditioning and industrial 
installations which require cooling or refrigeration. 
BACKGROUND OF THE INVENTION 
Cooling and refrigeration of industrial installations, as well as the 
central air conditioning of commercial buildings and industrial plants, 
require large amounts of electrical energy to operate the refrigeration 
plants needed for these purposes. This places a high demand on electric 
utilities during on-peak periods, which usually are from about 9 A.M. to 
10 P.M. Monday through Friday. Utilities must provide enough generating 
capacity to meet this demand. This requires a very high capital investment 
for plants and equipment which are fully utilized only in hot weather in 
daylight hours. Evenings and weekends are off-peak demand periods and much 
less of the total generating capacity is used then. In addition, less 
generating capacity is used on cool days in the spring and fall periods of 
the year in the United States. 
To encourage a better or more uniform demand for electric power, many 
utilities charge a reduced rate for electricity used during off-peak 
periods. Business and industry have accordingly been looking for ways to 
shift or transfer as much as possible of their electrical consumption to 
off-peak periods to take advantage of the reduced rates and also to 
minimize future electric rate increases by making additional electric 
generating plants unnecessary, or at least delaying generating plant 
expansion. 
It has been recognized for some time that a substantial potential savings 
could be realized if much of the refrigeration or air conditioning load 
could be moved from on-peak to off-peak periods. To do this, it has been 
proposed to operate refrigeration plants during off-peak periods to 
produce cold or chilled water or ice for storage. During on-peak periods 
the cold or chilled water or ice would then be used to provide cooling. 
Because ice provides greater cooling capacity per unit volume than chilled 
water (a ratio of about 7:1) much commercial interest has been directed 
toward providing so-called ice building equipment for this purpose. 
At this time it appears that the type of ice builder of greatest interest, 
and one which has been put into use in a number of installations, 
constitutes a tank, for holding water, through which a large number of 
small pipes run in one of several different patterns or arrangements. A 
liquid refrigerant is fed through the small pipes. As the refrigerant 
absorbs heat from the water, a layer of ice about 1 to 3 inches thick 
forms on each pipe. Ice is produced in this manner during off-peak 
periods. 
When it becomes desirable to utilize the cooling potential stored in the 
ice for air conditioning or other purposes, a stream of water is fed 
through the tank to cool the water by exchange of heat to the ice. The 
cooled water is withdrawn from the tank and fed to a heat exchanger to 
cool or air condition a building or for other cooling purposes. The 
resulting warm water is then returned to the tank to be cooled again by 
contact with the ice. This system can continue to provide cooling until 
all the ice is melted. 
Ice builders of the described type are costly to fabricate and operate. The 
pipes are not readily repaired or serviced. In addition, as the ice layer 
on the pipes increases in thickness, heat exchange between the water and 
refrigerant decreases because of the insulating effect which the ice 
provides. Furthermore, a very large heat exchange surface must be provided 
by the pipes to obtain the cooling needed to produce the desired quantity 
of ice. 
Another method proposed is to feed an aqueous liquid through a freeze 
exchanger in indirect heat exchange with a refrigerant to convert at least 
part of the aqueous liquid to ice; feed the aqueous liquid-ice mixture 
from the freeze exchanger to an ice storage tank to provide an ice slurry 
and aqueous liquid therein; and remove cold aqueous liquid from the ice 
storage tank and feed it through a heat exchanger in indirect heat 
exchange with a fluid to be cooled and used for cooling purposes, and then 
return the warm aqueous liquid exiting from the heat exchanger to the ice 
storage tank to be cooled by contact with the ice therein. 
One of the problems with the method just described involves proper 
distribution of the ice bed in the storage tank. For efficient operation 
and maximum ice storage in the tank, the ice should be stored in a bed 
uniformly thick and with an approximately horizontal or level upper 
surface. Additionally, the aqueous liquid must drain readily through the 
ice bed so it can be used for cooling purposes or be recycled to the 
freeze exchanger to produce more ice to be fed to the tank. An additional 
problem is inherent in the highly adhesive nature of ice, which clings and 
sticks to many materials and surfaces. 
From the above it is believed clear that a need exists for apparatus and 
methods of storing ice and using it for cooling purposes. 
SUMMARY OF THE INVENTION 
According to one aspect of the invention, a method is provided comprising 
removing aqueous liquid from an ice storage tank, desirably insulated, and 
feeding the aqueous liquid through a freeze exchanger in indirect heat 
exchange with a refrigerant to convert at least part of the aqueous liquid 
to ice crystals; feeding an aqueous liquid-ice crystal mixture from the 
freeze exchanger to a distribution conduit system, located in the upper 
part of the ice storage tank above the maximum storage capacity of the 
tank, through which the mixture flows to and through a plurality of 
horizontally spaced apart outlets to nozzles which disperse the mixture so 
that it descends uniformly and deposits the ice crystals evenly as a bed 
of ice of uniform thickness with a substantially horizontal surface; and 
removing cold aqueous liquid, which trickles through the ice crystal bed, 
from the lower part of the tank and feeding it through a heat exchanger in 
indirect heat exchange with a fluid to be cooled and used for cooling 
purposes, and then returning the now warm aqueous liquid exiting from the 
heat exchanger to the ice storage tank to be cooled by downward trickling 
flowing contact with the ice therein. 
The described method makes it possible to store more ice, and thus a 
greater quantity of refrigeration, in the tank than would be possible if 
the ice were permitted to cone up in the center of the tank as would 
happen with a central inlet at the top of the tank. In addition, the 
uniformly dispersed ice facilitates drainage of liquid through the ice, 
resulting in more efficient operation of the system. Furthermore, the 
outlet holes in the conduit distribution system and the nozzles can be 
comparatively large, i.e. 0.5 to 1 inch in diameter, so there is a very 
low pressure drop across each nozzle, and little opportunity for ice 
build-up plugging either the nozzles or outlets. Also, there is very 
little vertical drop needed to distribute the liquid mixture over a large 
diameter. Other advantages of the system are that it does not use any 
moving parts, uses inexpensive parts and minimum labor to fabricate. 
In practicing the method, it is desirable to trickle the cold aqueous 
liquid through the ice crystal bed into a plurality of upright perforated 
drain tubes in the tank; drain the liquid through the tubes to a liquid 
accumulating means in the lower part of the tank; and feed the cold 
aqueous liquid from the lower part of the tank to the freeze exchanger to 
produce more ice crystals. 
By vertically impinging the liquid mixture containing ice crystals on a 
horizontal target surface constituting part of each nozzle, the liquid 
mixture and ice crystals are readily uniformly dispersed in the tank. 
The distribution conduit system, the nozzles and horizontal target surface 
constituting part of each nozzle, and the upright perforated drain tubes, 
can be made of rigid noncorrosive polymeric material which is resistant to 
ice adhesion to prevent ice from building up and blocking liquid flow or 
altering uniform distribution of liquid and ice in the tank. 
The warm aqueous liquid is desirably returned to the tank through the 
distribution conduit system used to deposit the ice bed. This makes it 
possible to cool the warm liquid by passing it uniformly through the 
porous ice bed. The resulting ice melting is uniform so that the ice bed 
thickness remains quite even when the method is operated in a cooling 
mode, as distinguished from an ice making mode. The later addition of ice 
thus has a uniformly thick ice bed on which to build. 
According to a second aspect of the invention, an ice storage tank, 
desirably insulated, is provided having a bottom, circular cylindrical 
vertical wall and a roof supported by the wall; a distribution conduit 
system, located in the upper part of the ice storage tank above the 
maximum storage capacity of the tank, to which an aqueous liquid-ice 
crystal mixture originating outside of the tank can be fed to flow 
therethrough to a plurality of horizontally spaced apart outlets; nozzles, 
communicating with the outlets, which disperse the liquid mixture so that 
it descends uniformly and deposits the ice crystals evenly as a bed of ice 
of uniform thickness with a substantially horizontal surface; and means to 
remove cold aqueous liquid from the lower internal space of the tank. 
The storage tank desirably has a plurality of upright spaced apart 
perforated drain tubes extending from near the tank bottom to a height 
near the maximum ice storage capacity of the tank, and through which 
liquid can drain from the ice crystal bed to the lower internal space of 
the tank from which cold aqueous liquid is removed. 
The tank can have a false bottom or floor above the tank bottom, with said 
false bottom having means through which liquid can be drained from the ice 
bed to the lower internal space of the tank between the false bottom and 
the tank bottom. 
Each nozzle can include a horizontal target surface on which the liquid 
vertically impinges to facilitate uniform distribution of liquid and ice 
crystals in the tank. 
The distribution conduit system, the nozzle and horizontal target surfaces, 
and the upright perforated drain tubes, in the tank are desirably made of 
rigid polymeric material which is resistant to ice adhesion.

DETAILED DESCRIPTION OF THE DRAWINGS 
To the extent it is reasonable and practical, the same or similar elements 
or parts which appear in the various views of the drawings will be 
identified by the same numbers. 
With reference to FIG. 1, the freeze exchanger 10 is of the vertical shell 
and tube falling film type such as disclosed in U.S. Pat. No. 4,286,436. 
The shell side of the freeze exchanger 10 is cooled by means of a closed 
loop refrigeration system 12. Gaseous refrigerant, such as ammonia, is 
removed from the shell side of freeze exchanger 10 by conduit 14 and fed 
to compressor 16 driven by electric motor 18. The compressed refrigerant 
is fed from compressor 16 to conduit 20 which delivers it to condenser 22. 
The liquid refrigerant is removed from condenser 22 by conduit 23 and 
delivered to refrigerant receiver 24 and then by conduit 25 to expansion 
valve 26 through which it is expanded to conduit 28 for delivery to the 
shell side of freeze exchanger 10. 
During ice building, a solution of water and ethylene glycol is withdrawn 
from ice storage tank 70 through conduit 50 and fed to pump 52. The tank 
may contain only liquid as shown in FIG. 17 or a layer of ice crystals on 
liquid as shown in FIG. 18. The liquid is fed from pump 52 to conduit 54 
which feeds it through three-way valve 56 to conduit 30. Conduit 30 feeds 
the liquid to the top of freeze exchanger 10. The liquid flows as a thin 
falling film down the inner surface of the vertical tubes in the freeze 
exchanger 10. The liquid is cooled in the tubes and a portion of the water 
is converted to small ice crystals, thereby forming an ice slurry. The ice 
slurry flows from freeze exchanger 10 through outlet 32 to receiving 
vessel 34. 
The ice slurry collected in receiving vessel 34 is withdrawn by conduit 36 
and fed to pump 38 which delivers it to conduit 40. Conduit 40 delivers 
the ice slurry to conduit 40A which feeds it to inlet port 42 (FIG. 2) in 
the upper part of tank 70. The ice slurry flows through inlet port 42 to 
slurry distribution system 82 located in the upper portion of tank 70. 
Tank 70 rests on insulating concrete foundation 72, desirably placed 
directly on earth of good load bearing quality. Tank 70 has a flat metal 
circular horizontal bottom 74 in direct contact with foundation 72. 
Vertical cylindrical circular metal wall 76 is joined at its lower edge to 
tank bottom 74. The upper edge of wall 76 supports dome metal roof 78. 
Thermal insulation 80 is placed on the exterior surface of wall 76 and 
roof 78. 
Slurry distribution system 82, as shown in FIGS. 2 to 5, includes an ice 
slurry supply conduit 84 in communication with inlet port 42 and header 
conduit 86, and a series of spaced apart lateral conduit arms 88, 90, 92, 
94, 96, 98, 100 extending outwardly from both sides of header 86. The end 
of each arm 88-100 is closed by a cap 102 (FIG. 5). It will be seen (FIG. 
3) that the ends 86A and 86B of header 86 drop to a lower level to 
accommodate the slope of roof 78. However, the inner portion 84A of supply 
conduit 84 is raised slightly (FIG. 4) to place it closer to the tank 
roof. 
A plurality of short small tubular members or nipples 104 (FIGS. 5 to 8) 
are threaded into holes in the bottom of arms 88-100 and secured in place 
by lock nut 106. A nozzle 110 is slipped over the end of each nipple 104 
and held in place by a cotter pin 112. 
The nozzle 110 (FIGS. 6 to 11) is a commercial item available from Marley 
Co. and has been previously used in cooling towers to distribute water. 
Each nozzle has a tubular body 114 with a flange or ring 116 at the top. 
Thin narrow arced leg 118 projects downwardly from the lower edge of 
tubular body 114 and supports horizontal petal plate 120. Each petal 122 
of plate 120 is arranged like the blades of a propeller when viewed 
axially. The top of each petal 122 is concave or dished 124 (FIG. 11). 
All of the conduits and fittings constituting the slurry distribution 
system 82 are desirably made of polyvinylchloride since it is 
noncorrosive, inexpensive, lightweight, easily assembled and because ice 
does not adhere or stick to it readily. 
A false bottom or floor 130 (FIGS. 1, 13) is supported above tank bottom 74 
on base members 134. The false floor contains suitable openings which 
permit liquid, but not ice crystals, to flow through from the top to the 
space below it so that liquid can be withdrawn by conduit 50. 
A plurality of hollow vertical drain columns 136 (FIGS. 1, 13, 14) are 
positioned in spaced apart arrangement in tank 70. Each column 136 can be 
supported at the bottom on a base 134. The columns 136 can be made in one 
piece or of two or more sections 136A, 136B telescoped together and joined 
by a bolt 138. 
The top of each column 136 is fitted with a cap 140 having a plurality of 
vertical tabs 142. Rods or pipes 144, some provided with turnbuckles 146, 
extend between and are joined at their ends to tabs 142 on the caps 140 of 
adjacent columns 136. The rods are arranged in two patterns of parallel 
rows which intersect as shown in FIG. 12. Short rods 144A extend from the 
outermost columns 136 to tank wall 76 thereby tying the described support 
system for the column tops into the tank itself. 
Each column 136 and cap 142 can be made of polyvinylchloride for the 
reasons given above in discussing the slurry distribution system. 
Horizontal slits 150 are cut in each column so that liquid can drain into 
each column but not ice crystals. Liquid which flows through the slits 
travels down the inside of the column and collects in the tank beneath 
false floor 130. 
In the ice building or forming mode, the ice slurry flows from inlet port 
42, through header 86 into arms 88-100, through nipples 104 and out each 
stationary nozzle 110 and onto petal plate 120. Some slurry flows between 
petals 122 but most of it impinges on the top of the petals. Because of 
the flat upper surface of the petals 122, as well as the petal concave 
portions 124, the ice slurry splashes outwardly in an umbrella pattern 
which very evenly distributes the slurry over the entire horizontal area 
of the tank 70. This is achieved without use of any moving parts in the 
nozzles or elsewhere. This enhances the ice storage volume by almost 10%. 
Additionally, the slurry distribution system requires very little vertical 
distance to distribute ice slurry over large areas so that it does not 
adversely affect ice storage capacity. There is also a very low pressure 
drop across the nozzles so that power is not wasted. 
The liquid phase of the ice slurry drains uniformly through the porous ice 
pack which builds up in the tank. Some liquid drains directly down and 
through false floor 130 while a substantial portion of the liquid enters 
columns 136 through slits 150 and drains through the columns to beneath 
false floor 130. The described drainage system leads to maximum liquid 
drainage, thus permitting that the greatest amount of ice possible be 
stored in the tank. Additionally, it prevents ice from being returned to 
freeze exchanger 10. 
The described method of ice building can continue as long as desired, but 
generally will proceed until the ice storage tank 70 is about one-half to 
three-fourths full of ice with the balance liquid as shown in FIG. 19. For 
most economical ice building, the apparatus is operated for ice building 
when electricity rates are the lowest, i.e. at off-peak periods, which 
usually are from Monday through Thursday evenings from about 10 P.M. to 9 
A.M. the following morning, and weekends from 10 P.M. Friday to 9 A.M. 
Monday. Of course, off-peak periods will vary with location and ambient 
conditions. 
When it is desired to utilize the cooling capacity stored in the form of 
ice for cooling purposes, cold aqueous liquid can be withdrawn from ice 
storage tank 70 by conduit 50 and fed to pump 52. Pump 52 delivers the 
cold aqueous liquid to conduit 54 which feeds it through three-way valve 
56 to conduit 58. Conduit 58 feeds the cold liquid to heat exchanger 60 to 
indirectly cool a warm fluid fed thereto by conduit 62 and withdrawn 
therefrom through conduit 64 as cold fluid. Conduit 64 feeds the cold 
fluid to one or more coils 66 in facility 68 to provide cooling thereto. 
Warm fluid is removed from coil 66 by conduit 62 and returned to heat 
exchanger 60 to be recooled. Warm aqueous liquid being circulated from the 
tank is withdrawn from heat exchanger 60 through conduit 69 and is fed by 
conduit 40A into the distribution system 82 in ice storage tank 70. The 
warm liquid is distributed uniformly by nozzles 110 over the ice pack. As 
the warm liquid flows through the ice in tank 70 it is cooled by transfer 
of heat to the ice, thereby causing the ice to melt. The tank 70 can be 
full of ice crystals as shown in FIG. 19 at the start of cooling. As 
heated liquid is returned to tank 70 to be cooled it melts the ice thereby 
reducing the ice volume (FIG. 18) until finally all the ice is melted 
(FIG. 17). Thus, this system can continue to operate so long as ice is 
available in the ice storage tank. Desirably, the amount of ice in the 
tank available for cooling should be adequate for the intended cooling 
period. 
The described ice building and cooling system can be used as the main 
cooling system for air conditioning a building, whether operated entirely 
or primarily during on-peak or off-peak electrical usage periods, or a 
combination thereof. The system also can be used to shift part of a 
present existing cooling load to off-peak periods by using it to 
supplement an existing conventional air conditioning system. Furthermore, 
the system can be used in air conditioning load leveling by using it in 
combination with a smaller conventional refrigeration system. 
Additionally, the system can be used in any industrial installation 
requiring cooling or refrigeration. 
One advantage of the ice building apparatus of the invention is that it 
employs a freeze exchanger which facilitates ice making with less 
refrigerant evaporation surface area and better heat transfer than those 
using extensive pipes in a tank of water on which ice builds to a 
thickness of about 1 to 3 inches. Another important feature of the 
apparatus of the invention is that it permits usage of the same liquid in 
common in the freeze exchanger 10, ice storage tank 70 and heat exchanger 
60. 
The foregoing detailed description has been given for clearness of 
understanding only, and no unnecessary limitations should be understood 
therefrom, as modifications will be obvious to those skilled in the art.