Title of Invention	DEVICE AND METHOD FOR COOLING SOLID PARTICLES
Abstract	A cooling arrangement adapted to be used in a process of preparing a fine powder, and a method for using same are described. The cooling arrangement comprises: a solid particle.s feed ingress means, a solid particles mixing means, a plurality of cooling air discharging devices and a solid particles egress means. The cooling arrangement is characterized in that the averaged diameter of the solid particles fed the said solid particles ingress means is essentially less than 6 mm. Preferably, the solid particles are fed to the cooling arrangement and free fall onto the bottom section thereof.

Title of Invention

DEVICE AND METHOD FOR COOLING SOLID PARTICLES

Abstract

A cooling arrangement adapted to be used in a process of preparing a fine powder, and a method for using same are described. The cooling arrangement comprises: a solid particle.s feed ingress means, a solid particles mixing means, a plurality of cooling air discharging devices and a solid particles egress means. The cooling arrangement is characterized in that the averaged diameter of the solid particles fed the said solid particles ingress means is essentially less than 6 mm. Preferably, the solid particles are fed to the cooling arrangement and free fall onto the bottom section thereof.

Full Text	DEVICE AND METHOD FOR COOLING SOLID PARTICLES FIELD OF INVENTION The present invention relates to a method and apparatus for providing air at semi cryogenic temperatures during preparation of various products. In particularly, this invention relates to a method and apparatus for distributing air at semi cryogenic temperatures in cooling chambers during the process of preparing fine powders. BACKGROUND OF THE INVENTION One of the well known environmental challenges nowadays is the handling of used tires. Tnere are estimations that at least one billion tires are discarded around the world every year. These scrap tires are an ecological predicament in all countries in which automobiles and trucks are a standard mode of transportation. Over the years, many more, tires cast off in monumental piles than recycled or burned. It is estimated that in the US alone there are in excess of 1 billion tires in illegal tire piles, generating dangerous conditions of uncontrollable fires, air pollution as well as health hazards. To date, most discarded tires were destined to be burned, assisting in alleviating an unending energy crisis. However, since the recognition by meteorologists of pending earth warming trends, burning tires is quickly becoming unacceptable solution and in some countries even illegal. Also, to date, many of the waste tires are simply shredded and buried in landfills. This too has become an undesirable solution as more and more countries recognize the danger in underground buried tires or tire parts, due to the adverse effect on the diminishing underground supplies of fresh water. Finally, tire piles serve as breeding grounds to colonies of disease infected rodents and incubation hot beds for dangerous and deadly insects. It is therefore clear that recycling must be the only acceptable and sustainable solution to the increasing problem of scrap tires. Recognizing all of the above, several attempts have been made to reduce the increasing number of scrap tires discarded annually by recycling them. Tire recycling has traditionally been accomplished using three distinctly different technologies: • All mechanical ambient grinding the rubber; • Cryogenically, freezing and crushing the rubber; and Pyrolysis or microwave treatment to melt rubber. There are quite few aspects involved in the implementation of the second type of technology, namely, the cryogenically, freezing and crushing the rubber to produce granular rubber which may be used as a supplementary material in fuel or in road building, etc. One of the aspects involved in this technology is the step of exposing the crushed rubber to reduced temperatures e.g. to a point of embrittling the synthetic rubber. Many conventional cryogenic recycling processes require the use of liquid nitrogen or solid carbon dioxide to lower the temperature of the material to be recycled to a point where a proceeding step of the process can yield a granular material such as a powder. However, such cryogenic processes are usually expensive to implement and to operate. Many solutions were proposed in the past to improve this cooling step of the process. Few of these solutions are the following: US 4,273,294 discloses an improvement of conventional cryogenic grinding system incorporating an impact mill by providing means to allow at least 70V of the embrittled material entering the mill to bypass the mill's inlet and means to restrict the flow of the cold gas through the impact mill. US 5,408,846 describes a cooling device for lowering the temperature of rubber or polystyrene materials for recycling purposes. The cooling device has an input feeder which inputs the material to be treated into a cooling chamber. The cooling chamber is an elongated chamber. The cooling chamber receives cold air from an external air refrigeration unit and circulates that air within the chamber. The material input into the cooling chamber is circulated therein by a circulating shaft. After 15-20 minutes, the input material is discharged through an output on the opposite end of the cooling chamber.- The material discharged temperature is -8C°C or lower. US 5,568,731 discloses an ambient air freezing system for producing chilled air in the cryogenic range of -120°C to -180°C without the use of cryogenic chemicals or other refrigerants. US 6,360,547 describes a method for cryogenically freezing materials, such as rubber, food, plastics by compressing ambient air to a first level, cooling the air back to an ambient temperature, compressing the air again, and then cooling the air followed by expanding the compressed air thereby cooling it down to cryogenic temperatures that is fed to the material to be processed. US 6,397,623 describes a cooling device in which the compressor and the expander are coupled to one crank shaft or interlocked crank shafts so as to use the expansion energy from the compressed air in the expander as an energy for compressing the outside air in the compressor, thereby reducing the running cost. US 7,125,439 discloses a method for providing clean air to an environment, by cooling incoming air, which may be contaminated with chemical, nuclear or biological contamination and removing water from the cooled air. The cooled air is passed through a regenerative pressure swing absorption system which removes the contaminants. The resulting, cleaned, air is expanded by an expander and is provided to the environment. SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and apparatus for efficiently lowering the temperature of used tires, rubber, polymeric materials and the like, to cryogenic levels. It is another object of the present invention to provide a method and apparatus for rapid lowering the temperature of used tires, rubber, polymeric materials and the like, to cryogenic levels thereby reducing the period required for the material being cooled to remain within the cooling chamber. It is still another object of the present invention to provide a method and apparatus for use in a process of producing fine powders. Other objects of the present invention will become apparent from the following description. According to a first embodiment of the invention, there is provided a cooling arrangement adapted for use in a process of producing fine powder, and comprising: a solid particles feed ingress means, a solid particles mixing means, a plurality of cooling air discharging devices and a solid particles egress means, and wherein the cooling arrangement is characterized in that the averaged diameter of the solid particles fed via the solid particles ingress means is essentially less than 6 mm. According to a preferred embodiment of the invention, each of the plurality of the cooling air discharging devices is located at a side of the cooling arrangement different from any of the other air cooling air discharging devices, e.g. having one or more pairs of cooling air discharging devices where each pair's member located at an opposite wall than the other member of that pair. By yet another preferred embodiment, each of the plurality of the cooling air discharging devices is an air compressing/expanding device. In accordance with another preferred embodiment, the solid particles feed ingress means is located essentially at the top section of the cooling arrangement whereas the solid particles egress means is located essentially at the bottom section of that cooling arrangement. By still another embodiment of the invention, the cooling arrangement is further adapted to allow the solid particles fed via the solid particles feed ingress means, to free fall onto the bottom section of the cooling arrangement, where preferably they are mixed by a mechanical mixing means for the rest of a pre-defined period of time, thereafter they are conveyed to the next step of the powder preparation process. According to another aspect of the present invention there is provided a method for use in a process of producing a fine powder. The method comprises the steps of: providing a plurality of solid particles having an averaged diameter of less than 6 mm; feeding the plurality of solid particles into a cooling chamber; mechanically mixing the solid particles during a pre-defined period of time while cooling them down by air provided via a plurality of cooling air discharging devices; and removing the cooled brittle solid particles out of the cooling chamber. In accordance with another embodiment of this aspect of the invention, the method provided further comprising a step of cleaning and drying ambient air intake 'prior to introducing that ambient air to the plurality of the cooling air discharging devices. Preferably, the temperature to which the solid particles are cooled down by the plurality of air cooling air discharging devices is in the range of -70°C to - 110°C. By yet another embodiment, the method provided further comprises a step of allowing the solid particles to reach the bottom section of the cooling chamber by free fall from the top section thereof. Preferably, the method provided is carried out as a batch process for a pre-defined period of time. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 illustrates- a schematic diagram of the cooling arrangement according to the present invention for air cooling particles in a batch operation to cryogenic temperatures; and FIG. 2 exemplifies a method of carrying out the present invention. DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT A better understanding of the present invention is obtained when the following non-limiting detailed examples are considered in conjunction with the accompanying drawings. As previously discussed, one of the objects of the present invention is to provide method and means to cool down solid particles such as recycled tires particles so that the end product of the whole recycling process, of which the cooling process described and claimed herein- is a part, are particles that are in a form of fine or even ultrafine powder, typically particles of lu or less, as the unique way of cooling provided by the present invention results in frozen and highly brittle particles which may easily be pulverized into a fine or even ultrafine particles. Although various processes were suggested in the past to produce fine powders, still, they are rather expensive to operate as they either make use of refrigerants or cryogenic chemicals, or characterized by being an inefficient ambient grinding processes. Due to high production cost and other inefficiencies, ultra fine products have not been produced in large quantities from recycled materials. The solution provided by the present invention aims to overcome these obstacles. Although the invention is described hereinafter in connection with a process of recycling synthetic rubber such as rubber that originates from used tires, still, this is done for the convenience of the reader and the scope of the invention should not be understood to be restricted to that specific process. Turning now to the drawings, Fig. 1 illustrates a cooling arrangement 100 to which a pre-defined quantity (e.g. by weight) of synthetic rubber particles derived from processing used tires is conveyed by using any applicable solids conveying means known in the art per se such as conveying belt (not shown in this Fig.) . Typically, the particles which are of an averaged diameter in the range of 1 to 5 mm are fed into the top section of chamber 110, and they free fall 120 to the bottom of chamber 110, where they are subjected to mixing operation of mixer/stirrer 140. During their fall, there is an initial cooling of the particles. The mixer/stirrer (e.g. a rotary device) operates to ensure that no big lumps of particles are formed and that all the particles will be subjected to the cooling air, in order to obtain a substantially homogenous temperature at the range of -80°C to -100°C of the synthetic rubber particles present in the chamber. Once the quantity of particles is introduced into the chamber, it is closed and preferably sealed, and a plurality of cooling air discharging devices 130 are operative to cool down the particles. Four such cooling air discharging devices are illustrated in Fig. 1, demonstrating the introduction of cooling air from each side of the chamber. The air reaching each of these cooling air discharging devices is preferably cleaned, dried and compressed prior to reaching the air discharging devices, although in the alternative all these operations can be carried out within the cooling air discharging devices themselves and hence this alternative ¦should also be considered to be encompassed by the present invention. In the present example, the cooling air is introduced to the chamber at -9Q°C and at a pressure of few atmospheres. When introduced into the chamber, the air expands, thereby causing its own temperature to further reduce. The discharge section of each of the cooling air discharging devices is preferably designed to blow air somewhat above the particles being mixed/stirred to avoid too much turbulences among the particles that might results in particles flowing all over the chamber, but near enough to the particles to get an efficient cooling thereof. Typically, the particles stay in the chamber for about 10 to 15 minutes. Thereafter, the particles are discharged at the chamber's bottom section airlock after they have become brittle and consequently easy to pulverize, to another solid conveying means for further processing the frozen granules, e.g. they can then be further ground or crushed to produce the desired ultra fine powder. Although the present invention was described in the above example in connection with synthetic rubber particles obtained from used tires, as will be understood by those skilled in the art it can be used for cryogenically cooling materials such as polymers, rubber based materials and the like without using refrigerants or cryogenic chemicals in the process. In order to obtain the cooling air required for the process any method known in the art per se, that is applicable to produce the air at the right physical conditions of temperature and pressure and the right cleanness and dryness levels can be used. For example, by taking ambient air, compressing and expanding it by using multiple' turbo expander machines. The oil resulting from the compression is removed and the air is cleaned and dried before compression. The cooled air may then be fed into the cooling chamber, after reaching a temperature of -80 to -100 degree C. A suitable filter for the air preparation process could be an inertial separator. This may be achieved by passing the air through a filter, such as a Borosilicate micro-fiber filter, in which water, oil and particles are removed using a coalescing effect. Alternatively a silica gel or an activated alumina could be usea as an adsorbent, so as to dry the air by chemically reacting to the water vapor in the air within the filter to adsorb and remove the water vapor. Another option is using a thermodynamic cycle, otherwise known as the "Russian cycle", where the compressor and turbo expander are located in one cylinder and chamber connected horizontally with the motor so as to use the expansion energy from the compressed air in the expander as an energy for compressing the outside air in the compressor, thereby reducing the running cost. The unit is environmentally friendly low-temperature cycle (up to -110°C) enclosed in one functional block aggregate, and can be fully automated. As will be appreciated by those skilled in the art, although the particles themselves undergo a batch type of operation as they are maintained within the chamber for a predefined period of time, still, the discharge of the cooling air may be a continuous type of operation, as long as the particles are introduced and removed from the cooling chamber through sealed means such as airlocks. Fig. 2 exemplifies a method for use in a process of cooling materials that eventually should be pulverized such as rubber based materials, polymers ana the like, carried out according to the present invention. At first, a plurality of particles is provided (step 200) having an average diameter of less than 6 mm, and are preferably between 1 to 5 mm. The particles are fed through a top section of a cooling chamber (step 210) where they are allowed to free fall to the bottom section of the chamber. There they are mechanically stirred (step 220) for a pre-defined period of time of about 10-15 minutes while cooling the particles down by air provided via a plurality of air cooling air discharging devices (step 230). Upon expiring the pre-defined period of time, the frozen particles are removed (step 240) from the cooling chamber. While only the above embodiments of the present invention have been illustrated and described, it is to be understood that many changes and modifications may be made thereto without departing from the spirit and scope of the invention as defined in the appended claims. The present invention has been described using non- limiting detailed descriptions of preferred embodiments thereof that are provided by way of example and are not intended to limit the scope of the invention. It should be understood that features described with respect to one embodiment may be used with other embodiments. Variations of embodiments described will occur to persons of the art. Furthermore, the terms "comprise", "include", "have" and their conjugates shall mean, when used in the claims "including but not necessarily limited to". Also when term was used in the singular form it should be understood to encompass its plural form and vice versa, as the case may be. 1. A cooling arrangement adapted to be used in a process of preparing a fine powder, and comprising: a solid particles feed ingress means, a solid particles mechanical mixing means, a plurality of cooling air discharging devices and a solid particles egress means, and wherein said cooling arrangement is characterized in that a) the averaged diameter of the solid particles fed via said solid particles ingress means is essentially less than 6 mm, and b) said mechanical mixing means is operative to ensure that no big lumps of particles are formed within said cooling arrangement. 2. A cooling arrangement according to claim 1, wherein each of said plurality of cooling air discharging devices is located at a side of said cooling chamber different from any of the other cooling air discharging devices. 3. A cooling arrangement according to claim 1, wherein the solid particles feed ingress means is located essentially at the top section of said cooling arrangement whereas the solid particles egress means is located essentially at the bottom section of said cooling arrangement. 4. A cooling arrangement according to claim 1, further adapted to allow said solid particles fed through said solid particles feed ingress means to free fall onto the bottom section of said cooling arrangement. 5. A method for use in a process of preparing fine powdered material, and comprising the steps of: providing a plurality of solid particles having an averaged diameter of less than 6 mm: feeding said plurality of solid particles into a cooling chamber; mechanically mixing said solid particles for a pre-defined period of time while cooling them down by air provided via a plurality of cooling air discharging devices and wherein said mechanical mixing is carried out to ensure that no big lumps of particles are formed; and removing the cooled solid particles out of said cooling chamber. 6. A method according to claim 5, further comprising a step of cleaning and drying ambient air intake prior to introducing said ambient air to said plurality of cooling air discharging devices. 7. A method according to claim 5, wherein the temperature to which said solid particles are cooled down, is in the range of -70°C to -110°C. 8. A method according to claim 5, further comprising a step of allowing said solid panicles to reach the bottom section of said cooling chamber by a free fall from the top section thereof 9. A method according to claim 5, wherein said method is carried out as a batch process for a pre-defined period of time. 10. A cooling arrangement according to claim 1, wherein said mechanical mixing means comprises a rotary device. A cooling arrangement adapted to be used in a process of preparing a fine powder, and a method for using same are described. The cooling arrangement comprises: a solid particle.s feed ingress means, a solid particles mixing means, a plurality of cooling air discharging devices and a solid particles egress means. The cooling arrangement is characterized in that the averaged diameter of the solid particles fed the said solid particles ingress means is essentially less than 6 mm. Preferably, the solid particles are fed to the cooling arrangement and free fall onto the bottom section thereof.

Full Text

DEVICE AND METHOD FOR COOLING SOLID PARTICLES
FIELD OF INVENTION
The present invention relates to a method and
apparatus for providing air at semi cryogenic
temperatures during preparation of various products. In
particularly, this invention relates to a method and
apparatus for distributing air at semi cryogenic
temperatures in cooling chambers during the process of
preparing fine powders.
BACKGROUND OF THE INVENTION
One of the well known environmental challenges
nowadays is the handling of used tires. Tnere are
estimations that at least one billion tires are discarded
around the world every year. These scrap tires are an
ecological predicament in all countries in which
automobiles and trucks are a standard mode of
transportation. Over the years, many more, tires cast off
in monumental piles than recycled or burned. It is
estimated that in the US alone there are in excess of 1
billion tires in illegal tire piles, generating dangerous
conditions of uncontrollable fires, air pollution as well
as health hazards.
To date, most discarded tires were destined to be
burned, assisting in alleviating an unending energy
crisis. However, since the recognition by meteorologists
of pending earth warming trends, burning tires is quickly
becoming unacceptable solution and in some countries even
illegal. Also, to date, many of the waste tires are
simply shredded and buried in landfills. This too has
become an undesirable solution as more and more countries
recognize the danger in underground buried tires or tire
parts, due to the adverse effect on the diminishing
underground supplies of fresh water. Finally, tire piles
serve as breeding grounds to colonies of disease infected
rodents and incubation hot beds for dangerous and deadly
insects. It is therefore clear that recycling must be the
only acceptable and sustainable solution to the
increasing problem of scrap tires.
Recognizing all of the above, several attempts have
been made to reduce the increasing number of scrap tires
discarded annually by recycling them. Tire recycling has
traditionally been accomplished using three distinctly
different technologies:
• All mechanical ambient grinding the rubber;
• Cryogenically, freezing and crushing the rubber; and
Pyrolysis or microwave treatment to melt rubber.
There are quite few aspects involved in the
implementation of the second type of technology, namely,
the cryogenically, freezing and crushing the rubber to
produce granular rubber which may be used as a
supplementary material in fuel or in road building, etc.
One of the aspects involved in this technology is the
step of exposing the crushed rubber to reduced
temperatures e.g. to a point of embrittling the synthetic
rubber.
Many conventional cryogenic recycling processes
require the use of liquid nitrogen or solid carbon
dioxide to lower the temperature of the material to be
recycled to a point where a proceeding step of the
process can yield a granular material such as a powder.
However, such cryogenic processes are usually expensive
to implement and to operate.
Many solutions were proposed in the past to improve
this cooling step of the process. Few of these solutions
are the following:
US 4,273,294 discloses an improvement of
conventional cryogenic grinding system incorporating an
impact mill by providing means to allow at least 70V of
the embrittled material entering the mill to bypass the
mill's inlet and means to restrict the flow of the cold
gas through the impact mill.
US 5,408,846 describes a cooling device for lowering
the temperature of rubber or polystyrene materials for
recycling purposes. The cooling device has an input
feeder which inputs the material to be treated into a
cooling chamber. The cooling chamber is an elongated
chamber. The cooling chamber receives cold air from an
external air refrigeration unit and circulates that air
within the chamber. The material input into the cooling
chamber is circulated therein by a circulating shaft.
After 15-20 minutes, the input material is discharged
through an output on the opposite end of the cooling
chamber.- The material discharged temperature is -8C°C or
lower.
US 5,568,731 discloses an ambient air freezing
system for producing chilled air in the cryogenic range
of -120°C to -180°C without the use of cryogenic
chemicals or other refrigerants.
US 6,360,547 describes a method for cryogenically
freezing materials, such as rubber, food, plastics by
compressing ambient air to a first level, cooling the air
back to an ambient temperature, compressing the air
again, and then cooling the air followed by expanding the
compressed air thereby cooling it down to cryogenic
temperatures that is fed to the material to be processed.
US 6,397,623 describes a cooling device in which the
compressor and the expander are coupled to one crank
shaft or interlocked crank shafts so as to use the
expansion energy from the compressed air in the expander
as an energy for compressing the outside air in the
compressor, thereby reducing the running cost.
US 7,125,439 discloses a method for providing clean
air to an environment, by cooling incoming air, which may
be contaminated with chemical, nuclear or biological
contamination and removing water from the cooled air. The
cooled air is passed through a regenerative pressure
swing absorption system which removes the contaminants.
The resulting, cleaned, air is expanded by an expander
and is provided to the environment.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide
a method and apparatus for efficiently lowering the
temperature of used tires, rubber, polymeric materials
and the like, to cryogenic levels.
It is another object of the present invention to
provide a method and apparatus for rapid lowering the
temperature of used tires, rubber, polymeric materials
and the like, to cryogenic levels thereby reducing the
period required for the material being cooled to remain
within the cooling chamber.
It is still another object of the present invention
to provide a method and apparatus for use in a process of
producing fine powders.
Other objects of the present invention will become
apparent from the following description.
According to a first embodiment of the invention,
there is provided a cooling arrangement adapted for use
in a process of producing fine powder, and comprising: a
solid particles feed ingress means, a solid particles
mixing means, a plurality of cooling air discharging
devices and a solid particles egress means, and wherein
the cooling arrangement is characterized in that the
averaged diameter of the solid particles fed via the
solid particles ingress means is essentially less than 6
mm.
According to a preferred embodiment of the
invention, each of the plurality of the cooling air
discharging devices is located at a side of the cooling
arrangement different from any of the other air cooling
air discharging devices, e.g. having one or more pairs of
cooling air discharging devices where each pair's member
located at an opposite wall than the other member of that
pair.
By yet another preferred embodiment, each of the
plurality of the cooling air discharging devices is an
air compressing/expanding device.
In accordance with another preferred embodiment, the
solid particles feed ingress means is located essentially
at the top section of the cooling arrangement whereas the
solid particles egress means is located essentially at
the bottom section of that cooling arrangement.
By still another embodiment of the invention, the
cooling arrangement is further adapted to allow the solid
particles fed via the solid particles feed ingress means,
to free fall onto the bottom section of the cooling
arrangement, where preferably they are mixed by a
mechanical mixing means for the rest of a pre-defined
period of time, thereafter they are conveyed to the next
step of the powder preparation process.
According to another aspect of the present invention
there is provided a method for use in a process of
producing a fine powder. The method comprises the steps
of:
providing a plurality of solid particles having an
averaged diameter of less than 6 mm;
feeding the plurality of solid particles into a
cooling chamber;
mechanically mixing the solid particles during a
pre-defined period of time while cooling them down by air
provided via a plurality of cooling air discharging
devices; and
removing the cooled brittle solid particles out of
the cooling chamber.
In accordance with another embodiment of this aspect
of the invention, the method provided further comprising
a step of cleaning and drying ambient air intake 'prior to
introducing that ambient air to the plurality of the
cooling air discharging devices.
Preferably, the temperature to which the solid
particles are cooled down by the plurality of air cooling
air discharging devices is in the range of -70°C to -
110°C.
By yet another embodiment, the method provided
further comprises a step of allowing the solid particles
to reach the bottom section of the cooling chamber by
free fall from the top section thereof.
Preferably, the method provided is carried out as a
batch process for a pre-defined period of time.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 illustrates- a schematic diagram of the cooling
arrangement according to the present invention for air
cooling particles in a batch operation to cryogenic
temperatures; and
FIG. 2 exemplifies a method of carrying out the present
invention.
DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT
A better understanding of the present invention is
obtained when the following non-limiting detailed
examples are considered in conjunction with the
accompanying drawings.
As previously discussed, one of the objects of the
present invention is to provide method and means to cool
down solid particles such as recycled tires particles so
that the end product of the whole recycling process, of
which the cooling process described and claimed herein- is
a part, are particles that are in a form of fine or even
ultrafine powder, typically particles of lu or less, as
the unique way of cooling provided by the present
invention results in frozen and highly brittle particles
which may easily be pulverized into a fine or even
ultrafine particles. Although various processes were
suggested in the past to produce fine powders, still,
they are rather expensive to operate as they either make
use of refrigerants or cryogenic chemicals, or
characterized by being an inefficient ambient grinding
processes. Due to high production cost and other
inefficiencies, ultra fine products have not been
produced in large quantities from recycled materials. The
solution provided by the present invention aims to
overcome these obstacles.
Although the invention is described hereinafter in
connection with a process of recycling synthetic rubber
such as rubber that originates from used tires, still,
this is done for the convenience of the reader and the
scope of the invention should not be understood to be
restricted to that specific process.
Turning now to the drawings, Fig. 1 illustrates a
cooling arrangement 100 to which a pre-defined quantity
(e.g. by weight) of synthetic rubber particles derived
from processing used tires is conveyed by using any
applicable solids conveying means known in the art per se
such as conveying belt (not shown in this Fig.) .
Typically, the particles which are of an averaged
diameter in the range of 1 to 5 mm are fed into the top
section of chamber 110, and they free fall 120 to the
bottom of chamber 110, where they are subjected to mixing
operation of mixer/stirrer 140. During their fall, there
is an initial cooling of the particles. The mixer/stirrer
(e.g. a rotary device) operates to ensure that no big
lumps of particles are formed and that all the particles
will be subjected to the cooling air, in order to obtain
a substantially homogenous temperature at the range of
-80°C to -100°C of the synthetic rubber particles present
in the chamber. Once the quantity of particles is
introduced into the chamber, it is closed and preferably
sealed, and a plurality of cooling air discharging
devices 130 are operative to cool down the particles.
Four such cooling air discharging devices are illustrated
in Fig. 1, demonstrating the introduction of cooling air
from each side of the chamber. The air reaching each of
these cooling air discharging devices is preferably
cleaned, dried and compressed prior to reaching the air
discharging devices, although in the alternative all
these operations can be carried out within the cooling
air discharging devices themselves and hence this
alternative ¦should also be considered to be encompassed
by the present invention. In the present example, the
cooling air is introduced to the chamber at -9Q°C and at
a pressure of few atmospheres. When introduced into the
chamber, the air expands, thereby causing its own
temperature to further reduce. The discharge section of
each of the cooling air discharging devices is preferably
designed to blow air somewhat above the particles being
mixed/stirred to avoid too much turbulences among the
particles that might results in particles flowing all
over the chamber, but near enough to the particles to get
an efficient cooling thereof. Typically, the particles
stay in the chamber for about 10 to 15 minutes.
Thereafter, the particles are discharged at the chamber's
bottom section airlock after they have become brittle and
consequently easy to pulverize, to another solid
conveying means for further processing the frozen
granules, e.g. they can then be further ground or crushed
to produce the desired ultra fine powder.
Although the present invention was described in the
above example in connection with synthetic rubber
particles obtained from used tires, as will be understood
by those skilled in the art it can be used for
cryogenically cooling materials such as polymers, rubber
based materials and the like without using refrigerants
or cryogenic chemicals in the process.
In order to obtain the cooling air required for the
process any method known in the art per se, that is
applicable to produce the air at the right physical
conditions of temperature and pressure and the right
cleanness and dryness levels can be used. For example, by
taking ambient air, compressing and expanding it by using
multiple' turbo expander machines. The oil resulting from
the compression is removed and the air is cleaned and
dried before compression. The cooled air may then be fed
into the cooling chamber, after reaching a temperature of
-80 to -100 degree C.
A suitable filter for the air preparation process
could be an inertial separator. This may be achieved by
passing the air through a filter, such as a Borosilicate
micro-fiber filter, in which water, oil and particles are
removed using a coalescing effect. Alternatively a silica
gel or an activated alumina could be usea as an
adsorbent, so as to dry the air by chemically reacting to
the water vapor in the air within the filter to adsorb
and remove the water vapor.
Another option is using a thermodynamic cycle,
otherwise known as the "Russian cycle", where the
compressor and turbo expander are located in one cylinder
and chamber connected horizontally with the motor so as
to use the expansion energy from the compressed air in
the expander as an energy for compressing the outside air
in the compressor, thereby reducing the running cost. The
unit is environmentally friendly low-temperature cycle
(up to -110°C) enclosed in one functional block
aggregate, and can be fully automated.
As will be appreciated by those skilled in the art,
although the particles themselves undergo a batch type of
operation as they are maintained within the chamber for a
predefined period of time, still, the discharge of the
cooling air may be a continuous type of operation, as
long as the particles are introduced and removed from the
cooling chamber through sealed means such as airlocks.
Fig. 2 exemplifies a method for use in a process of
cooling materials that eventually should be pulverized
such as rubber based materials, polymers ana the like,
carried out according to the present invention. At first,
a plurality of particles is provided (step 200) having an
average diameter of less than 6 mm, and are preferably
between 1 to 5 mm. The particles are fed through a top
section of a cooling chamber (step 210) where they are
allowed to free fall to the bottom section of the
chamber. There they are mechanically stirred (step 220)
for a pre-defined period of time of about 10-15 minutes
while cooling the particles down by air provided via a
plurality of air cooling air discharging devices (step
230). Upon expiring the pre-defined period of time, the
frozen particles are removed (step 240) from the cooling
chamber.
While only the above embodiments of the present
invention have been illustrated and described, it is to
be understood that many changes and modifications may be
made thereto without departing from the spirit and scope
of the invention as defined in the appended claims.
The present invention has been described using non-
limiting detailed descriptions of preferred embodiments
thereof that are provided by way of example and are not
intended to limit the scope of the invention. It should
be understood that features described with respect to one
embodiment may be used with other embodiments. Variations
of embodiments described will occur to persons of the
art. Furthermore, the terms "comprise", "include", "have"
and their conjugates shall mean, when used in the claims
"including but not necessarily limited to". Also when
term was used in the singular form it should be
understood to encompass its plural form and vice versa,
as the case may be.
1. A cooling arrangement adapted to be used in a process of preparing a fine powder, and
comprising: a solid particles feed ingress means, a solid particles mechanical mixing means, a plurality
of cooling air discharging devices and a solid particles egress means, and wherein said cooling
arrangement is characterized in that a) the averaged diameter of the solid particles fed via said solid
particles ingress means is essentially less than 6 mm, and b) said mechanical mixing means is
operative to ensure that no big lumps of particles are formed within said cooling arrangement.
2. A cooling arrangement according to claim 1, wherein each of said plurality of cooling air
discharging devices is located at a side of said cooling chamber different from any of the other cooling
air discharging devices.
3. A cooling arrangement according to claim 1, wherein the solid particles feed ingress means is
located essentially at the top section of said cooling arrangement whereas the solid particles egress
means is located essentially at the bottom section of said cooling arrangement.
4. A cooling arrangement according to claim 1, further adapted to allow said solid particles fed
through said solid particles feed ingress means to free fall onto the bottom section of said cooling
arrangement.
5. A method for use in a process of preparing fine powdered material, and comprising the steps
of:
providing a plurality of solid particles having an averaged diameter of less than 6 mm:
feeding said plurality of solid particles into a cooling chamber;
mechanically mixing said solid particles for a pre-defined period of time while cooling them
down by air provided via a plurality of cooling air discharging devices and wherein said mechanical
mixing is carried out to ensure that no big lumps of particles are formed; and
removing the cooled solid particles out of said cooling chamber.
6. A method according to claim 5, further comprising a step of cleaning and drying ambient air
intake prior to introducing said ambient air to said plurality of cooling air discharging devices.
7. A method according to claim 5, wherein the temperature to which said solid particles are
cooled down, is in the range of -70°C to -110°C.
8. A method according to claim 5, further comprising a step of allowing said solid panicles to
reach the bottom section of said cooling chamber by a free fall from the top section thereof
9. A method according to claim 5, wherein said method is carried out as a batch process for a
pre-defined period of time.
10. A cooling arrangement according to claim 1, wherein said mechanical mixing means
comprises a rotary device.

A cooling arrangement adapted to be used in a process of
preparing a fine powder, and a method for using same are
described. The cooling arrangement comprises: a solid
particle.s feed ingress means, a solid particles mixing
means, a plurality of cooling air discharging devices and
a solid particles egress means. The cooling arrangement
is characterized in that the averaged diameter of the
solid particles fed the said solid particles ingress
means is essentially less than 6 mm. Preferably, the
solid particles are fed to the cooling arrangement and
free fall onto the bottom section thereof.

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=pJ0jAWtV3wqz7Bye4tfhIQ==&loc=wDBSZCsAt7zoiVrqcFJsRw==

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Patent Number

279105

Indian Patent Application Number

353/KOLNP/2011

PG Journal Number

02/2017

Publication Date

13-Jan-2017

Grant Date

11-Jan-2017

Date of Filing

21-Jan-2011

Name of Patentee

OLEG GOLOBRODSKY

Applicant Address

17/9 SHARET STREET,PETACH TIKVA 49502

Inventors:

#	Inventor's Name	Inventor's Address
1	MEKHTI LOGUNOV	17/86 DANILEVSKOGO STREET,KHARKOV
2	ALEXANDER KATZ	20/31 PUSHKINA BLVD.,DONETSK
3	OLEG GOLOBRODSKY	17/9 SHARET STREET,PETACH TIKVA 49502
4	GIDEON DRORI	10 EHUD STREET SHAAREI TIKVA 44810

PCT International Classification Number

B29B17/00 B02C19/18

PCT International Application Number

PCT/IL2009/000672

PCT International Filing date

2009-07-06

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	192797	2008-07-14	Israel