PROCESS FOR ISOLATING AND PREPARING A DRY PROTEINACEOUS MATERIAL FROM WASTE WATER
Background of the Invention
The present invention relates generally to a process for recovering the protein, fatty and water components of a material, such as a float material which is produced from a waste water treatment system. More specifically, this invention relates to a treatment process for separating and recovering as a dry product the protein component of a waste material, in order that the dry product may be used as a source of protein in the preparation of, for example, animal feed.
Most cities and counties have enacted requirements for industries which discharge water into municipal sewer systems. These municipalities generally require the waste water to meet certain standards before being discharged, and these standards usually relate to the level of pollutants which interfere with the efficient operation of the municipal waste water treatment facility.
Waste water with a high biochemical oxygen demand, total suspended solids and ammonia increases the treatment cost to the city or county. The term "biochemical oxygen demand" ("BOD") refers to the quantity of oxygen utilized in the biochemical oxidation of organic matter; and the term "total suspended solids" ("TSS") refers to the total suspended solids which float on the surface of, or are suspended in, waste water and which are removable by filtering.
In some instances, a surcharge may be levied on an industrial plant that produces waste water which does not meet the standards as established by the municipality. For example, these standards may
prohibit waste water containing greater than 300 mg/liter of BOD, 300 mg/liter of TSS, and/or 18 mg/liter of ammonia. Cities and counties may also prohibit industrial plants from discharging waste water having a fat, oil and grease ("FOG") concentration greater than 150 mg/liter.
A city or county also has the authority to revoke an industrial plant's waste water discharge permit if that plant continues to discharge waste water which does not meet the standards set by that city or county. Therefore, an industrial plant must effectively treat its waste water to reduce the level of pollutants and thereby meet such standards.
An effective waste water treatment process for an industrial or municipal plant should cause the solid organic and inorganic matter to flocculate and form a sludge cake. This sludge cake accumulates to a certain thickness and, after being separated from the liquid portion of the waste water, is disposed of by land application, further processing in a rendering plant, or discharge to the industrial or municipal plant's own lagoon system.
However, problems exist with all of the options available. Land application and sludge discharge to a lagoon system are undesirable, primarily because of environmental concerns, and rendering is costly. For example, many rendering plants impose a surcharge on sludge with a high percentage of water (i.e., a resulting sludge cake under 18% solids), because material having a much lower water content, or much higher solids content, must be added in order for the float material to be further processed, thus making it more expensive for the rendering plant to process sludge with a high water content.
One method of treating waste water from an industrial plant is disclosed by Stewart (U.S. Patent 4,981,599) . This process results in the formation of a sludge cake on top of the waste water. The sludge cake is removed, and the treated waste water is discharged into the sewer system. However, the sludge cake (also generally referred to as a float material) produced by the Stewart process is not ideally suited for subsequent treatment at a rendering plant because (1) the water content of the float material is higher than desired and (2) the float material is comprised of fatty and protein components which desirably should be separated from the water component .
Therefore, a need exists for a process which can be used to separate the protein, fatty and water components of a float material produced by a waste water treatment system. Additionally, this process should provide protein and fatty component products with a high percentage of solids (i.e., a low water content) .
Summary of the Invention
Among the objects of the present invention, therefore, is the provision of a process for treating a float material obtained from a waste water treatment system or other industrial or municipal process; the provision of such a process wherein the float material is separated into its respective protein, fat and water components; the provision of such a process wherein other waste material, such as animal carcasses, may similarly be separated; the provision of such a treatment process wherein a carrier material is used to form a treatment mixture with the float material; the provision of such a process wherein a suitable carrier material is used such that a solvent removal step,
which is typical for waste treatment processes that employ conventional organic solvents, is not necessary; the provision of such a process wherein the protein and fatty components are separated and recovered as products having a low water content; the provision of such a process wherein the water component product may be recycled or discharged into a sewer system; the provision of such a process wherein the stability of the protein and fatty component products is substantially improved; the provision of such a process wherein the protein component is dried on-site, thus eliminating the need for further processing to obtain a useable dry product, and in particular to avoid the need to further process the material in a conventional rendering process; and, the provision of a process which enables a protein product to be obtained which is suitable for use in an animal feed preparation without additional treatment.
Generally, therefore, the present invention is directed to a process for isolating a dry protein product from a waste material comprising a protein component, a fatty component and a water component. The process comprises heating a treatment mixture comprising the waste material and having a solids content ranging from about 2 to about 20 weight percent to a temperature and for a time sufficient to liquefy fats, oils and grease which are present. A protein component product is then separated from the heated treatment mixture, and then moisture is removed from the separated protein component product by transferring moisture to a gas phase which is in contact with the protein product .
The present invention is further directed to a process for isolating a dry protein product from a
waste material comprising a protein component, a fatty component and a water component. The process comprises heating a treatment mixture comprising the waste material to a temperature and for a time sufficient to liquefy fats, oils and grease which are present, and then separating a protein component product from the heated treatment mixture. Moisture is then removed from the separated protein component product in a way which ensures the temperature of the protein component product does not exceed about 120°C during the removal of moisture therefrom.
The present invention is still further directed to a process for isolating a dry protein product from a waste material comprising a protein component, a fatty component and a water component. The process comprises heating a treatment mixture comprising the waste material to a temperature and for a time sufficient to liquefy fats, oils and grease which are present by passing the mixture through a plug flow reactor. A protein component product is separate from the mixture, and then moisture is removed from the separated protein component product. Finally, a dry protein product is collected.
These and other objects, features and advantages of this invention will become apparent from the following detailed description.
Brief Description of the Drawings
FIG. 1 is an elevation view of a preferred apparatus to be used in the process of the present invention for separating components of a treatment mixture ;
FIG. 2 is a plan of the apparatus of FIG. 1;
FIG. 3 is an end view of the apparatus of FIG. 1;
FIG. 4 is a section taken in the plane of line 4-4 of FIG. 1; FIG. 4a is an enlarged view of a portion of the section of FIG. 4;
FIG. 4b is an enlarged view of another portion of the section of FIG. 4;
FIG. 5 is a section taken in the plane of line 5-5 of FIG. 1;
FIG. 6 is a fragmented section taken in the plane of line 6-6 of FIG. 2;
FIG. 7 is a fragmented section taken in the plane of line 7-7 of Fig. 6; FIG. 8 is a top plan view of a tank in which, in one embodiment of the present process, a treatment mixture may be formed;
FIG. 9 is a top plan view of a clarification tank in which, in one embodiment of the present process, a liquid mixture may be separated into a fatty component product phase and a water component product phase;
FIG. 10 is an elevation view of a clarification tank in which, in a preferred embodiment of the present process, a liquid mixture may be separated into a fatty component product phase and a water component product phase; and,
FIG. 11 is a flow diagram representing a preferred embodiment of the process of the present invention.
Detailed Description of the Invention
As used in the instant specification, various terms appearing herein have the following meaning:
(1) float material - a material obtained from an industrial or municipal plant comprising proteinaceous solids, as well as fats, oils and grease
("FOG"); preferably, a waste material comprising the sludge cake or solid materials which are produced by the waste water treatment system of such a plant; most preferably, a material which has been separated from an underlying water phase after first subjecting waste water to an aeration process in a flotation zone in the presence of a flocculent;
(2) dead stock - a raw waste material comprising, for example, animal carcasses which have not previously been subjected to any other type of processing (such as rendering) , but which have been subjected to a procedure to reduce the skin, flesh, bones, etc. to a size suitable for the present process;
(3) protein component product - the proteinaceous material recovered from the float material or dead stock, which typically comprises animal protein but which may also include other types of protein depending upon the nature of the industry from which the float material or dead stock is obtained;
(4) fatty component product - the component which is recovered in the water-immiscible liquid phase from the float material or dead stock, and which principally comprises fats, oils and grease;
(5) water component product - water recovered from the float material or dead stock; (6) carrier material - a liquid which affords the means by which to achieve one or more of the following results: (a) provide heat to a float material or dead stock, and (b) ensure that the fats, oils and grease which become liquefied as a result of heating remain in a liquid state; and,
(7) solids - unless otherwise stated, this term shall be understood to refer to ash, metal salts, proteinaceous material or solids, as well as any fats, oils and grease which may be present; stated another way, for purposes of determining the "solids content" of a given sample or material, any fats, oils or grease which are present shall be considered as "solids," in addition to any proteinaceous solids, ash and metal salts which may be present. In a first embodiment, the carrier material may be a water-immiscible liquid compatible with, or fully miscible with, the fatty component of the float material. The carrier may advantageously comprise an oleaginous material, preferably comprising a natural oil. In this embodiment, particularly preferred carrier materials include natural oils, such as animal fat, vegetable oil and fish oil, which are of feed- grade quality or better. If the carrier material comprises a natural oil, such as animal fat, the animal fat content is typically greater than about 85 weight percent, preferably greater than about 90 weight percent, most preferably greater than about 95 weight percent. Similar proportions preferably prevail where the carrier predominantly comprises a vegetable oil, fish oil, or some other oil of feed-grade quality or better.
If a water- immiscible carrier is used, the density of the carrier is typically lower than one, preferably lower than about 0.95 g/cc . Where the carrier is an organic oil, its density is preferably between about 0.85 and about 0.95 g/cc. It is particularly preferred that an organic oil carrier comprise a heat stable material having a low vapor pressure so as to minimize both degradation of the carrier and generation of fumes in heating the carrier
and mixing it with the float material. Advantageously, the decomposition temperature of the carrier is at least about 110°C (230°F) . The vapor pressure of the carrier is typically not greater than about 25 mm Hg at 100°C (212°F) and, preferably, is not greater than about 15 mm Hg at 100°C. In addition, the vapor pressure of the organic oil carrier generally differs from a vapor pressure of the fatty component by not more than about 50 mm Hg at 100°C. Preferably, these vapor pressures will differ by no more than about 25 mm Hg at 100°C and, more preferably, by no more than about 10 mm Hg at 100°C. Most preferably, the vapor pressure of the carrier and the fatty component are substantially the same . To facilitate mixing of the carrier with the float material and separation of the fatty component from the resulting mixture, it is preferred that an organic oil carrier have a dynamic viscosity no greater than about 100 cps at 60°C (140°F) . It is further preferred that the surface tension of an organic oil carrier be between about 15 and about 60 dynes/cm at 25°C (77°F) , and a solubility in water of no greater than about 10 percent. It is still further preferred that the solubility of water in such organic oil carrier be no greater than about 3 percent.
In a second embodiment, the carrier material is aqueous, typically comprising at least about 70 weight percent liquid water. Preferably, however, the aqueous carrier material comprises at least about 80 weight percent liquid water, more preferably at least about 90 weight percent liquid water, and most preferably at least about 95 weight percent liquid water. However, the precise composition of the aqueous carrier may vary, particularly if a continuous process is employed and recycling of the carrier occurs. If
recycling of a resulting aqueous phase, or water component product phase, occurs, the aqueous carrier material may additionally comprise small amounts of insoluble solids (such as proteinaceous solids, fats, oils, and grease) , various metal salts introduced or produced in the initial DAF process (such as aluminum or iron salts) , as well as materials or compounds derived therefrom. In such cases, preferably the recycled aqueous carrier will contain less than about 1000 mg/liter of total suspended solids (TSS) and less than about 5000 mg/liter of BOD. Additionally, the recycled aqueous carrier will preferably contain less than about 500 mg/liter of fats, oils and grease, and less than about 600 mg/liter of TKN (Total Kjeldahl Nitrogen) .
Regardless of whether the first or second embodiment of the present invention is employed, it is to be noted that preferably the carrier material is introduced in liquid form. Furthermore, use of the above-referenced carrier materials is advantageous because the resulting protein and fatty component products which are collected may be further processed without the need of a solvent removal step, such as vacuum distillation, which is typical for waste treatment processes that employ conventional organic solvents (see, e.g., U.S. Patent No. 5,458,780). Accordingly, the present invention provides the means by which to eliminate the need for such a costly and time consuming process step. In the present process, a treatment mixture is formed by mixing the carrier material with a float material . The carrier material may first be heated to a temperature below the boiling point of water, in order to minimize the evaporation of any water or other volatile substances which may be present. Typically,
the carrier is heated to a temperature below about 105°C. Preferably, the carrier is heated to a temperature within the range of about 65°C to about 100°C. More preferably, the carrier is heated to a temperature within the range of about 77°C to about 93°C.
When the carrier material is an oil, heating is preferred in order to ensure the carrier material is in a liquid or flowable form, which will enhance its use in the present invention. In addition, for both the water and oil carrier materials, heating also affords a means by which to liquefy fat and grease contained within the float material, which tend to exist in a solid and/or semi-solid form in the sludge collected from a waste water treatment system. In this regard it is to be noted that while direct heating of the float material will cause the fat and grease to liquefy, in the absence of a carrier material, the float material becomes essentially saturated with liquefied fat and grease, causing the material to become sticky and "tar" -like; that is, if the float material is too dry, the liquefied fat and grease are not effectively separated from the protein, which may cause the material to become a sticky, tar-like substance. Without being held to any particular theory, it is believed that this may occur because of the concentration of flocculent or other processing chemicals, such as alum or ferric chloride, added during the waste water treatment process. These chemicals may cause the fats to polymerize or otherwise congeal after liquefaction. , The carrier material, therefore, acts as a diluent to ensure that the fats and grease remain in a liquefied form.
It is to be noted in this regard, however, that direct heating of the float material may be an
acceptable alternative if the flotation process and/or the waste water treatment equipment are modified such that a float material having a higher water content, or lower solids content, may be obtained. For example, float material obtained from a typical waste water treatment process contains about 20 to 25 weight percent solids, or about 75 to 80 weight percent water. If the waste water treatment process and/or equipment are modified such that a float material having a water content in excess of about 75 to 80 weight percent, preferably in excess of about 85 weight percent, and more preferably in excess of about 90 weight percent, is skimmed or collected, such float material will have a sufficiently high water content such that, upon heating, the fats, oils and grease remain in a liquefied form. Accordingly, it is to be noted that if a float material containing a sufficiently high water content, or sufficiently low solids content, can be collected from the waste water treatment system, the water present in the float material may serve as an adequate carrier and additional carrier material is not necessary in order to perform the process of the present invention.
In one embodiment, the treatment mixture is formed by mixing a heated carrier material with the float material. In this embodiment, prior to forming the treatment mixture, the float material is preferably first skimmed or collected from the waste water treatment system and transferred to a pre-mix tank where an antioxidant may be added. Generally speaking, any commercially available antioxidant which is suitable for stabilizing the particular materials of interest under the present process conditions may be used. Typically, an antioxidant such as ethoxyquin (commercially available under the trademark Santoquin®
from Novus International, Inc.) is added to prepare a stabilized float material, which may comprise proteins, fats, oils and grease derived from poultry, beef, dairy, swine, sheep or fish, as well as various food processing or slaughter operations, among other things. Other antioxidants which may be suitable for use in the stabilization of these materials, as well as soy- related proteins, fats, oils and grease, include tetrabutylhydroquinone (TBHQ) , 2 , 6-di-tert-butyl-4- methylphenol (BHT) , and 2- or 3-tert-butyl-4- methoxyphenol (BHA) .
Typically, the antioxidant is added in a quantity which is commercially recommended for the particular type of material that is to be stabilized, given the previal conditions of the process (i.e., the composition and pH of the float material, and the temperature of the process, among other things) . Preferably, about 0.5 pounds to about 20 pounds of the antioxidant, such as ethoxyquin, are added per 2000 pounds of solids (i.e., material such as proteinaceous solids, fats, oils, grease, metal salts and ash) present in the float material; that is, about 0.02 to about 1 weight percent of the antioxidant is added, based on the approximate weight of solids present. More preferably, about 1 to about 4 pounds of the antioxidant are added, or about 0.05 to about 0.2 weight percent .
The antioxidant acts to slow, or prevent, the further production of peroxides during the present process. In addition, this stability is imparted to these materials for a period of time, after the process has been completed, which is sufficient to allow for the resulting protein component product and fatty component products to be further processed on-site or suitably transferred to a rendering facility.
Accordingly, more preferably, a sufficient quantity of an antioxidant is added such that the peroxide content of the resulting protein and fatty component products, immediately after separation and collection, may exceed the initial content in the float material (as determined just prior to the addition of the antioxidant) by not more than about 20 milliequivalents per kilogram of fat (meq/kg fat) , and preferably by not more than about 10 meq/kg fat. Most preferably, however, a quantity of the antioxidant is added such that, in conjunction with the optimization of other process conditions, the peroxide content of the protein and fatty component products is about equal to the initial peroxide content in the float material. It is to be noted, however, that as the concentration of unsaturated fats in the float material increases, the quantity of the antioxidant to be added may also need to be increased. Furthermore, the hydrolysis process may become autocatalytic if the peroxide concentration becomes too high. Accordingly, therefore, it is additionally preferred that a quantity of the antioxidant be added which is sufficient to ensure that the peroxide content does increase to a level at which the hydrolysis process may become autocatalytic.
The quantity of the antioxidant which is added is preferably sufficient to produce a fatty component product which generally has an antioxidant content which ranges from about 200 to about 1250 ppm or more, and preferably from about 400 to about 800 ppm, depending upon the type of material that is to be stabilized. In this regard, it is to be noted that the resulting fatty component product desirably contains a higher antioxidant concentration as the storage temperature increases. It is to be further noted that,
to the extent the collected solids (i.e., the protein component product) contain fats, oils and grease, they too should have a concentration of the antioxidant which is in proportion to the amount of fats, oils and grease they contain.
In addition to adding an antioxidant to the float material in order to impart prolonged stability, the pH may optionally be monitored and adjusted to aid in preventing hydrolysis. Hydrolysis may begin to occur to some degree under either basic or acidic conditions, with the rate of hydrolysis increasing as the float material becomes more basic or more acidic. Therefore, typically the pH of the float material is maintained within the range of about 3 to about 10. However, the pH may be monitored and adjusted, if necessary, to ensure the pH preferably ranges from about 4 to about 8, and more preferably from about 6 to about 7.
During the addition of the antioxidant in the pre-mix tank, agitation of the float material is preferred in order to ensure the thorough dispersal of the antioxidant throughout the float material . Furthermore, because the float material continues to lose water (i.e., "dewater") even after being skimmed from the surface of the waste water, agitation is imposed to ensure that the solids which are present generally remain evenly suspended. In this way, agitation acts to ensure that the composition of the float material being used to prepare the treatment mixture is generally consistent.
The treatment mixture is typically prepared by mixing about equal quantities of the carrier material with the float material. Preferably, the treatment mixture will have a ratio of float material to carrier material between about 1:1 and about 1:20,
and more preferably between about 1:2 and 1:10. Most preferably, the treatment mixture will have a ratio of float material to carrier material between about 1:3 and about 1:10. However, the ratio of float material to carrier material is in part a function of the composition of the float material. For example, as the water content of the float material decreases and the solids content increases, preferably more carrier material is used to form the treatment mixture. Alternatively, as the water content of the float material increases and the solids content decreases, preferably less carrier material is used. Typically, therefore, the treatment mixture is formed by mixing quantities of float material and carrier material, to the extent needed, such that the resulting treatment mixture has a solids content (i.e., the combined content of proteinaceous material, fats, oils and grease, as well as ash and salts) ranging from about 2 weight percent to about 20 weight percent. Preferably, the solids content in the treatment mixture will range from about 3 weight percent to about 10 weight percent. Most preferably, the solids content in the treatment mixture will range from about 4 weight percent to about 6 weight percent. Accordingly, it is to be understood that additional carrier material is not required if the float material is obtained having a solids content in this range because the water present in the float material acts as a sufficient carrier material. The ratio of float material to carrier material is also in part a function of the desired result of the process. For example, the process of the present invention may be used primarily to dewater the solids contained in the float material. Alternatively, the present process may be used to both dewater and maximize the removal, or isolation, of the fatty
component product from the float material. If dewatering of the solids is the desired result, then a treatment mixture having a solids content ranging from about 10 to about 20 weight percent may be preferred. However, if maximizing the production of fats, oils and grease from the float material is desired, then a solids content ranging from about 3 to about 10, and preferably about 4 to about 6, weight percent is preferred, as noted above. Regardless of the desired result, the volume of carrier material is preferably sufficient to ensure the thorough suspension of the solids contained in the float material. In addition, the volume of the carrier material is preferably sufficient to improve the flowability, and reduce the viscosity, of the treatment mixture. Furthermore, with the aid of agitation or mixing, the thorough suspension of solids acts to prevent solids from coming to rest on heated surfaces within the heating tank, or other apparatus within which the treatment mixture is contained and heated, thus preventing the solids from sticking to these surfaces. As a result, heat transfer efficiency is preserved and clean up of the equipment can be more easily performed once the treatment process is complete.
Heating of the carrier material, as well as formation of the treatment mixture, may be carried out using methods and apparatus which are well known in the art. Referring now to FIG. 8, one embodiment of an apparatus suitable for heating the treatment mixture will herein be described. A vertical tank, indicated generally at 1, of horizontal cross-section includes side walls 2 and 3, end walls 4 and 5, and a bottom wall 6. A vertical baffle 7 extends from bottom wall 6 and end wall 4 substantially parallel to and
equidistant from side walls 2 and 3. The end of baffle 7 opposite end wall 4 is spaced from end wall 5 to define a flow path therebetween. Float material may be introduced into the tank through an inlet 8 in end wall 4 between baffle 7 and side wall 2, and carrier material may be introduced through another inlet 9 in the same region of the interior of tank 1. The mixture of carrier and float material may be removed from tank 1 via an exit port 10 in end wall 4 between baffle 7 and side wall 3. Thus, the walls of tank 1 and baffle 7 define a longitudinal horizontal flow path of relatively high length to lateral dimension for passage of the treatment mixture through the tank.
Tank 1 is further provided with at least one agitator which extends vertically into the tank, thus causing the float material and carrier material to be intimately mixed in a dispersion zone within the tank. As illustrated, tank 1 includes three agitators 11 longitudinally spaced along the flow path of treatment mixture through tank 1, so that substantially the entire working volume of the tank constitutes a dispersion zone for intimate contact and thorough mixing of carrier and float material. Heating coils 12 are positioned within tank 1 to provide heat to the treatment mixture in order to ensure the mixture remains in liquefied form.
If a pre-mix tank is not employed (i.e., if the float material and carrier are not pre-mixed before entry into tank 1) , the treatment mixture is formed as the carrier material and float material enter tank 1 and become mixed by agitators 11. The rate of agitation is sufficient to avoid settling of the solids which are present in the float material, and yet it is not so vigorous that shearing of these solids occurs. This agitation also acts to maximize the surface area
of the float and carrier materials, in order to allow for intimate contact between them. Such contact acts to provide a means by which to efficiently transfer heat from the carrier material to the float material, and to cause the carrier material to coalesce and form a single phase with the components of the float material with which the carrier material is miscible. Mixing at this stage is therefore sufficient to create a substantially homogeneous mixture, which is to be understood herein as the thorough dispersion of the float material in the carrier material, or the carrier material in the float material, and which is sufficient to promote the coalescence of the carrier material with the components of the float material with which it is miscible. Stated another way, mixing is sufficient to ensure thorough dispersion such that a substantially uniform treatment mixture is formed.
The treatment mixture proceeds through the tank substantially in a thoroughly dispersed state until it exits the tank through port 10. Residence time of the treatment mixture in the dispersion zone typically ranges from at least about 30 seconds to about 1 hour, depending upon the characteristics of the carrier and float materials. Preferably, the residence time ranges from about 10 minutes to about 40 minutes. More preferably, the residence time ranges from about 15 minutes to about 30 minutes. Most preferably, the residence time is at least about 20 minutes. However, the preferred residence time is in part a function of the temperature at which the treatment mixture is maintained; that is, as the temperature of the treatment mixture decreases, the residence time of the treatment mixture may need to be increased.
The temperature of the treatment mixture, as well as the residence time of the treatment mixture
within the heating tank, are important for purposes of maximizing the amount of the fatty component product which may be isolated from the float material . Without being held to any particular theory, it is believed that the heating of the treatment mixture acts to
"cook" the proteinaceous solids which are present, thus causing the fats, oils and grease to liquefy and escape. Stated another way, it is believed that heating of the treatment mixture acts to denature proteins and break down any emulsion present, such that fats, oils and grease are released from the floe and proteinaceous solids. As a result, preferably the temperature and residence time are controlled to optimize the yield of the fats, oils and grease. Furthermore, experience to date suggests that a residence or exposure time of at least about 20 minutes, within the temperature range of about 75°C and about 95°C, is sufficient to deactivate proteolytic and lipolytic enzymes which would otherwise act to degrade the protein and fatty component products. Such process conditions also act to kill pathogens (such as salmonella and e-coli) which are harmful to animals or humans. As a result, as further discussed below, the process of the present invention enables protein and fatty component products to be obtained which are essentially pathogen-free and which have prolonged stability, as compared to the typical protein and fatty components contained in a float material obtained from conventional waste water treatment processes. Accordingly, it is desirable to extend the exposure time as necessary in order to ensure the thorough destruction of such harmful enzymes and pathogens. It is to be understood that the means by which heating and mixing are accomplished may be other than that which is herein described and still fall
within the scope of the present invention. For example, referring now to FIG. 11, rather than using the treatment mixture tank, as described above, a plug flow reactor 510 may be employed. Such a reactor, or cooker, may be preferred because it acts to eliminate short-circuiting problems that may otherwise occur in the continuous operation of a treatment mixture tank. A plug flow reactor is preferably designed to provide a residence time within those ranges noted above. More preferably, the reactor is designed to maintain the treatment mixture within the temperature range of about 75°C to about 95°C for at least about 20 minutes.
The reactor 510 may be constructed of materials and by means common in the art. Typically, however, the reactor comprises stainless steel piping having an L/D ratio in the range of about 300 to about 1200, preferably about 350 to about 800, more preferably about 400 to about 500, and most preferably about 450. The reactor further comprises insulation adequate to maintain the mixture within the designated temperature range as it passes therethrough. For example, in one embodiment the reactor comprises stainless steel piping having a diameter of about 8 inches with a length of about 300 feet or more. Typically, the float material and, to the extent necessary, a carrier material are introduced simultaneously into the line or pipe which feeds the reactor either separately or after having first been mixed in a pre-mix tank 500. Heat may be provided by means common in the art, including jacketing the reactor pipe itself to supply heat externally or supplying heat internally by sparging steam into the mixture as it enters the reactor. For example, in one embodiment steam is injected into the plug flow reactor at about 50 to about 120 psi. However, it is to be
noted that steam pressure is not narrowly critical to the present invention, provided it is sufficient to heat the material in the reactor to the desired temperature range, for the desired period of time. When steam is sparged into the mixture directly, the quantity of additional water to be added to prepare the treatment mixture is metered or controlled to allow for the water resulting from steam condensation, such that the solids content of the treatment mixture remains within the ranges noted above; that is, if a plug flow reactor is employed in the present process, formation of the treatment mixture, as well as heating the treatment mixture, may be other than that herein described without departing from the scope of the invention. For example, it is to be noted that a carrier material may not be necessary with the embodiment of the invention utilizing a plug flow reactor to heat the float material. In this instance, condensation of the steam which is introduced into the plug flow reactor with the float material provides sufficient water content to effectively act as a carrier material. The condensation then enables the float material to remain in liquified form and a carrier material may not be necessary to perform the process of the present invention.
In order to avoid the settling of solids and subsequent plugging of the reactor pipe, the reactor is preferably designed to provide a turbulent flow. Typically, the flow rate for the above-described L/D ratios ranges from about 5 to about 70, and preferably from about 15 to about 40, gallons per minute (gpm) . Most preferably, the flow rate will fall within a range that maximizes the throughput of the present process while ensuring that the solids remain suspended in the
mixture and that the phases remain thoroughly dispersed.
It is to be noted, however, that experience to date suggests turbulent flow is not narrowly critical. For example, tests suggest that laminar flow is also acceptable, provided that settling of solids does not occur. In addition, it is to be further noted that axial back mixing is generally not of concern so long as the average residence time is sufficient to ensure an adequate residence time at all points along the diameter of the pipe.
An alternative to a plug flow reactor is a cascaded series of batch-type reactors of the type described above. A series of such reactors resolves any short-circuiting concerns and ensures that the desired exposure time is achieved. Using such a configuration, the treatment mixture is formed in a first reactor and, after mixing for a specified period of time, it is then transferred to a second reactor, where mixing continues. The specific number of reactors to be employed in such a system would be, in part, a function of the desired residence or exposure time. However, a limited number, e.g., two or three reactors, is ordinarily sufficient to eliminate any adverse effects of back mixing.
After the treatment mixture has been maintained within the desired temperature range for the specified period of time, a protein component product may be separated from the treatment mixture by any means known to the art for removing solids from solution. For example, a centrifuge, a pre-coated filter (such as a rotary drum filter) , a belt press, or a straight-line vacuum filter may be used to separate the protein. Alternatively, a shaker screen may be used which comprises one or more screens (i.e.,
filters) which progressively screen out and discharge the protein component product . The treatment mixture is passed through the shaker screen to remove the protein component product, and then a liquid mixture is collected and discharged through an opening located in the lower portion of the equipment.
In a preferred embodiment, however, separation of the protein component product is achieved by transferring the hot treatment mixture onto a belt filtration apparatus comprising a non-corroding mesh belt. For example, a stainless steel belt having a mesh size ranging from about 80 to about 150 mesh, and preferably about 100 mesh, may be employed. Alternatively, a non-corroding polypropylene belt rated at about 100 to about 400 cfm, and preferably about 200 cfm, may be employed. Such filter belts are preferred because they are capable of receiving the hot treatment mixture, which typically ranges in temperature from about 75°C to about 95°C, without deforming and allowing proteinaceous solids to pass therethrough.
It is to be understood however that, generally speaking, essentially any type of belt may be employed, provided it is constructed of a material which inhibits deformation of the pores or openings (e.g., stretching of the screen) of the belt when exposed to the heated treatment mixture, and which is compatible with the mixture (e.g., corrosion resistant) . More specifically, the filtering belt may be made of a material other than stainless steel or polypropylene, as long as the belt maintains the dimensional stability of the openings and is substantially corrosion resistant when exposed to the treatment mixture and the high temperatures associated with the mixture (e.g., up to about 105°C) .
One particularly preferred embodiment of such a solids separation or belt filter system is disclosed in greater detail below, under the section denoted BELT FILTRATION APPARATUS. This preferred embodiment enables the gravity separation of the protein component product to begin almost immediately upon the depositing of the mixture onto the belt. Gentle, positive pressure may additionally be applied to the solids which are collected on the surface of the belt to aid in the further removal of the fatty and water component phases from the solids. However, such pressure is preferably not so significant that proteinaceous solids are forced through the mesh belt. Forcing solids through the belt is not desirable because it acts to limit the efficiency of the process (i.e., it reduces the amount of protein component product recovered in a single cycle of the process) , and also because blinding of the belt may occur. If blinding does occur, clean up may be more time consuming and may generate more waste water, due to the additional rinsing required to clean the belt.
Depending upon the particular means employed to recover the protein component product, one or more flocculating agents may preferably be added to enable a more efficient and complete recovery. For example, experience to date suggests that the addition of a cationic polymer flocculating agent is preferred when the above-referenced filtration apparatus is employed to recover the protein component product. The addition of one or more flocculating agents is believed beneficial to solids separation because, during the formation of the treatment mixture, floe present in the float material is destroyed or disrupted by the agitation and heat of the process. Although disruption of the floe is considered favorable to the removal of
water, as well as fats, oils and grease present within the floe, a more efficient and complete removal of the protein component product from the treatment mixture may be achieved when flocculated particles are formed prior to filtration.
Once the flocculating agent has been added, the treatment mixture is preferably passed through a pre- filtration mix tank in order to ensure the thorough mixing of the flocculating agent. In a preferred embodiment, this tank is filled from the bottom which, with the aid of gentle agitation, acts to create an upward spiral in the mixture that aids with mixing of the flocculating agent and with floe formation. Agitation is preferably gentle in order to avoid the shearing of the floe which is formed.
The time spent adding and incorporating the flocculating agent into the treatment mixture is preferably minimized in order to prevent any significant drop in the temperature of the mixture. For example, typically the time required to form the flocculated particles results in less than about a 10°C drop in the temperature of the treatment mixture. Minimizing this temperature drop is preferred in order to maximize the amount of fatty component product that is obtained after filtration and phase separation is complete. More specifically, minimizing this temperature drop is preferred because higher filtration temperatures help to ensure that the fatty component remains in a liquefied form, thus limiting the amount of fatty component that is filtered out of the mixture as part of the proteinaceous solids which are collected.
The flocculating agent is preferably added to the treatment mixture prior to the mixture being transferred to the filtration apparatus, thus ensuring
sufficient time for mixing and floe formation. More specifically, the floe agent is preferably added directly to the bottom of the mix tank with the treatment mixture. Alternatively, the flocculating agent may be added to the line or pipe through which the treatment mixture passes as the mixture is transferred to the filter using a combination of pumps and valves common in the art .
Many polymeric flocculating agents, both natural and synthetic, which are standard to the waste water treatment industry are suitable for use in the present invention. Common synthetic flocculating agents include polyacrylamides (such as Polyhance 4153, commercially available from Wacon Technical Services, Inc.), polyamines (such as poly-2-hydroxypropyl-N,N- dimethyl-ammonium chloride) , as well as polymeric ammonium salts (such as poly-dimethyl -diallylammonium chloride), among others. The type and quantity of a flocculating agent to be added are in part a function of the composition, pH and temperature of the treatment mixture. In addition, the solids content in the treatment mixture is a factor to be considered, with a higher solids content mixture requiring a higher quantity of flocculating agent. However, generally speaking, about 1 to about 150 parts of the agent should be added per million parts of the treatment mixture. Preferably, a quantity of the agent is added such that the concentration ranges from about 25 to about 125 ppm, and more preferably from about 50 to about 100 ppm.
It is to be noted that the particular flocculating agent added, as well as the quantity to be added and the point of addition, may be other than that herein described without departing from the scope of the present invention.
The protein component product which is recovered typically comprises a wet particulate having a solids content (i.e., a combined content of proteinaceous solids, fats, oils and grease, as well as ash, salts and other non-aqueous materials) of at least about 25 percent by weight, preferably at least about 30 percent, more preferably at least about 35 percent, still more preferably at least about 40 percent, and most preferably at least about 50 percent. Stated another way, the protein component product typically has a moisture content which is less than about 75 percent by weight, preferably less than about 70 percent, more preferably less than about 65 percent, still more preferably less than about 60 percent, and most preferably less than about 50 percent. In addition, operating conditions of the present process will preferably be controlled such that the amount of fats, oils and grease left behind with the protein component product is minimized. Typically, therefore, the' protein component product has a ratio of proteinaceous solids to the combined content of fats, oils and grease which ranges from about 0.5:1 to about 1:1. Preferably, the protein component product has a ratio of proteinaceous solids to the combined content of fats, oils and grease which ranges from about 1:1 to about 2:1. More preferably, however, the ratio of proteinaceous solids to the combined content of fats, oils and grease is about 3:1, or more.
The process of the present invention advantageously produces a protein component product which, in addition to having a low moisture content, additionally possesses improved stability, as compared to the stability of the float material produced by standard waste water treatment processes. For example, as discussed above, the conditions of the present
process act to deactivate proteolytic and lipolytic enzymes which would otherwise act to degrade the protein and fatty component products. Such process conditions act to kill pathogens which are harmful to both animals and humans, as well. Accordingly, immediately following filtration, the protein component product is essentially pathogen-free; that is, the protein component product is essentially free of microbial activity (such as that associated with salmonella and e-coli) , having a total gram negative plate count which is less than about 50 cfu/g (colony forming units per gram of sample tested) , preferably less than about 40 cfu/g, more preferably less than about 20 cfu/g, still more preferably less than about 10 cfu/g, and still more preferably less than about 5 cfu/g, as determined by standard test methods (see, e.g., American Organization of Analytical Chemists Official Methods 989.12 and 991.13). Most preferably, the protein component product will have essentially a zero gram negative plate count, testing negative for both salmonella and e-coli.
Once collected, the protein component product is preferably subjected to an optional drying step in order to form a dry, flowable product that can be directly incorporated into an animal feed formulation as an alternative source of energy (i.e., fat) and protein, without any additional treatment. For example, experience to date suggests that the dried protein component product is suitable to be blended into a poultry feed formulation as a poultry meal supplement (i.e., an alternative source of protein and fat) . More specifically, experience to date indicates that the dried protein component product (resulting from a float material obtained from a poultry processing plant) has a protein content ranging from
about 25 to about 50, or about 30 to about 35 weight percent, and a fat content ranging from about 25 to about 50, or about 40 to about 45 weight percent. In comparison, poultry meal typically contains about 65 weight percent protein and about 15 weight percent fat or less. It has been found that such a dried protein product can be mixed with poultry meal on, for example, about a 1 weight percent basis or more, the resulting mixture then being used in a poultry feed formulation. In this regard it is to be noted that the nutrient profile of the protein product is directly related to the nature of the float material from which it was derived; that is, the amino acid profile of the dried product will correspond with the amino acid profile of the waste making up the float material. For example, experience to date has shown that the dried protein product obtained from the float material of a poultry processing plant has an amino acid profile which corresponds to poultry meal . The absolute concentrations of each amino acid in the dried product are in proportion to the protein content but less than that in poultry meal, however, based on the concentration of other waste components in the float material. For example, if the float material has a high concentration of feathers, this "feather meal" in the dried product will act to reduce the overall concentration of amino acids. Accordingly, in some embodiments of the present process, it is desirable to remove such waste components by means of, for example, filtering the float material prior to initiating the process, or screening the dried product.
The protein component product is preferably dried immediately following separation, as part of a continuous recovery process. Alternatively, batch drying on-site may also be performed. However, when
batch drying is employed, it is preferable to limit batch size, and thus the amount of time the material is stored wet, in order to prevent decomposition and/or growth of bacteria. Drying the protein component product acts to reduce process costs typically associated with storage, rendering, shipping and handling, as well as provides a finished product that can be directly incorporated in animal feed as an alternative source of protein and fat. The protein component product may be dried by any means common in the art provided that the drying times and temperatures may be sufficiently controlled in order to obtain a high quality, dry, flowable material while ensuring that the protein component product does not burn or decompose and that process costs are minimized. It is contemplated that such drying means will typically employ contacting the wet particulate protein component product with a gas phase in a gas/solid contact zone while agitating the particulate protein component during such gas/solid contact to remove moisture. Further, such drying means will also typically promote such gas/solid contact by tumbling or mechanically agitating the particulate protein component product within the gas/solid contact zone. Accordingly, the protein component product will typically be dried under conditions sufficient to yield a material having a moisture content of less than about 20%, preferably less than about 15%, more preferably less than about 10%, and, in some cases, preferably less than about 5%. Additionally, it is to be noted that the precise conditions under which the protein component product is dried will vary depending upon, for example, the particular drying technique employed, the initial moisture and fat content of the protein component product, and the nature of the protein
component product (i.e., the type of protein will mandate different drying conditions based on variables associated with decomposition or denaturing of the protein component product) . Typically, however, the protein component product will be dried such that the temperature of the protein component product ranges from about 60°C to about 120°C, and preferably about 90°C to about 100°C, for tens of seconds (about 10 to about 15 seconds), several tens of seconds (about 20, 30, 40 seconds or more), up to about an hour, with higher operating temperatures requiring less drying time and lower operating temperatures requiring more drying time. However, it is to be noted that the temperature of the protein component product should be sufficiently controlled, preferably to a temperature less than about 100°C, to reduce the risk of burning or denaturing the proteinaceous material .
In a preferred embodiment, the protein component product is dried by means of a gas-fired rotary dryer, such as one of the type commercially available from International Technology Systems, Inc. of Houlton, Wl or from Scott Equipment Company of New Prague, MN (see, e.g., U.S. Patent No. 5,570,517). For example, in one embodiment, a rotary dryer is employed which is capable of drying about 900 pounds per hour (lb/hr) of protein component product, utilizing about 2000 cubic feet per minute (cfm) of heated air flowing co-currently with the protein component product and providing an exposure or residence time of the protein component product in the rotating dryer drum in the range of about 10 to about 30 seconds, and preferably about 15 to about 20 seconds. The dryer is typically designed to provide an inlet air temperature ranging from about 140°C to about 430°C, preferably from about 170°C to about 400°C, and an outlet air temperature
ranging from about 90°C to about 140°C, preferably from about 100°C to about 135°C.
It is to be noted that the design of the dryer, as well as the drying means generally, may vary without departing from the scope of the present invention. For example, in addition to the factors noted above that affect drying conditions (i.e., water content, fat content and protein source, etc.) the amount of material to be processed within a desired amount of time will also affect both the drying method selected as well as the design of the dryer. Furthermore, while the present invention has been described above in relation to a rotary dryer using a co-current flow of heated air, it is contemplated that any alternative drying means may be employed wherein moisture is removed from a wet particulate protein component product by contacting the protein product with a gas phase in a gas/solid contact zone. For example, such alternative means may include, but are not limited to, indirect vacuum drying below atmospheric pressure, tray drying, or drying in a fluidized bed, as well as the method described above using countercurrent gas flow.
Additionally, it is to be noted that, depending upon the nature of the dryer employed and the fat content of the protein component product, additional dry material may need to be added to, or "back mixed" with, the protein component product to achieve more efficiently drying. More specifically, the protein component product may be back mixed with previously dried protein component, or another material suitable for animal consumption (e.g., corn, wheat, offal), during drying. For example, experience to date suggests that if the fat content of the proteinaceous material to be dried is too high, there is not enough
dry surface area to provide for efficient gas/solid contact. Accordingly, liquefied fat from the protein component product is not carried out of the dryer and may collect inside the rotary dryer, which can result in plugging, increased residence times and a high risk of burning the proteinaceous material . To avoid these potential problems, dry material is therefore added to the protein component product, providing for more gas/solid contact area to facilitate drying and the absorption of any excess fat released in the dryer, thus allowing the excess fat to be carried out of the dryer with the dried protein product. However, it is also to be noted that, in view of the low fat content of the protein component product of the process of the instant invention, back mixing is not required. Accordingly, the present process advantageously provides an alternative to conventional rendering processes because the protein product may be dried on- site (i.e., at the same location where the float material is generated, and separated into its respective protein, fat and water component products) without the need for back-mixing.
Once the protein component product has been separated, a liquid mixture remains which comprises a water-immiscible phase comprising the fatty component product (i.e., the fatty component phase) and an aqueous phase which contains the water component product (i.e., the water component phase). Typically, the liquid mixture has a fatty component, or fat, content ranging from about 1 weight percent to about 6 weight percent or more. However, this content may vary as the concentration of the fat in the starting float material increases or decreases. The liquid mixture may additionally comprise a small amount of
proteinaceous solids which were not removed during the solids separation step. However, if such proteinaceous solids are present, preferably this concentration is less than about 2 percent, and more preferably less than about 1 percent, by weight of the liquid mixture. The phases of the liquid mixture may be separated using various types of dewatering equipment known to the art, including a centrifuge. Preferably, however, phase separation is achieved by transferring the liquid mixture to a conventional clarifier commercially available from, for example, Waterlink (e.g., model SRC100) or Facet (e.g., model MCT-23-2) . It is to be noted that, in a preferred embodiment, the liquid mixture is fed by gravity from the belt filter, or other means by which the solids are separated. More particularly, the liquid mixture flows through the filter medium and to a well, sump or receiver, such as a clarifier. Experience to date suggests a gravity feed system is preferred because it ensures that the phases are not re-emulsified during the transfer. As a result, phase separation may occur more quickly. However, a pump may be used to transfer the liquid mixture, provided it does not create agitation sufficient to re-emulsify the phases. Referring now to FIG. 9, in one embodiment, the liquid mixture is separated in a clarifier comprising a vertical tank, indicated generally at 13, of horizontal cross-section which includes side walls 14 and 15, end walls 16 and 17, and a bottom wall 18. Preferably, a two compartment clarifier is used, the first compartment 19a and second compartment 19b being separated by a vertical baffle or weir 20, which extends from bottom wall 18 and between side walls 14 and 15. The mixture is introduced into the first
compartment 19a of the clarifier in which the lighter fatty component phase rises to the top.
In batch operation or during start-up of a continuous process, the fatty component product phase accumulates above the aqueous phase until it eventually overflows the top of the weir 20 into the second compartment 19b. In a continuous operation, charge of liquid mixture to the first compartment 19a and flow of fatty component product phase over the weir 20 thereafter continues in steady state. The water component product phase is withdrawn from the lower part of the first compartment through a port (not shown) . Further dewatering of the fatty component product phase may take place in the second compartment of the clarifier.
Referring now to FIG. 10, in a preferred embodiment the liquid mixture is separated in a clarifier comprising a vertical tank, indicated generally at 400. Preferably, a slant rib coalescing clarifier is used, consisting of an inlet diffusion chamber 401, a separation chamber 410, two coalescing plates 410a and 410b, a fat reservoir 420, and an effluent chamber 430. The mixture is introduced into the inlet diffusion chamber 401 of the clarifier through an inlet port 401a and is forced to flow through the coalescing plates 410a and 410b which aid the separation of the lighter fatty component phase from the water component phase, forcing such fat component to rise to the top of the separation chamber 410.
In batch operation or during start-up of a continuous process, the fatty component product phase accumulates above the aqueous phase in the separation chamber 410 until it eventually overflows the top of the fat reservoir 420. In a continuous operation,
charge of liquid mixture to the influent diffusion chamber 401 and flow of fatty component product phase into the fat reservoir 420 thereafter continues in steady state . The water component product phase may be withdrawn from the lower part of the separation chamber 410 through a port 410c or from the lower part of the effluent chamber through a port 430a. The fatty component product is withdrawn from a port (not shown) in the fat reservoir 420. Optionally, a rope skimmer (not shown) , of the type commercially available from
Oil Skimmers, Inc. of Cleveland, OH (e.g., Model 5-H) , may be employed to aid in fat collection. Such a rope skimmer operates to collect the fatty component product as it rises to the top of the separation chamber 410 and to move the fatty component product to the fat reservoir 420.
Although some impurities may be present, the fatty component product which is collected has a water content which is typically less than about 4 percent by weight and, preferably, less than about 2 percent by weight. Additionally, as noted above, the process of the present invention provides a fatty component product which possesses improved stability due to the addition of an antioxidant to the float material, the antioxidant ultimately becoming incorporated into the fatty component product. The antioxidant acts to slow or limit the increase in the concentration of peroxides in the fatty component product. The pH of the product, which typically ranges from about 4 to about 7, also acts to impart stability to the product.
Furthermore, like the protein component product, process conditions act to provide an essentially pathogen-free fatty component product; that is, the fatty component product is essentially free of microbial activity, having a total gram negative plate
count which is less than about 50 cfu/g (colony forming units per gram of sample tested) , preferably less than about 40 cfu/g, more preferably less than about 20 cfu/g, still more preferably less than about 10 cfu/g, and still more preferably less than about 5 cfu/g, as determined by standard test methods (see, e.g., American Organization of Analytical Chemists Official Methods 989.12 and 991.13). Most preferably, the fatty component product will have essentially a zero gram negative plate count, testing negative for both salmonella and e-coli.
In addition, the process of the present invention yields a fatty component product which, immediately after separation and collection, has a free fatty acid content which exceeds the initial free fatty acid content in the float material (as determined just prior to the addition of the antioxidant) by not more than about 10 weight percent (as determined based on the fat content of the sample) , and preferably by not more than about 5 weight percent. Most preferably, however, the fatty component product has a free fatty acid content which is about equal to the initial free fatty acid content in the float material .
The carrier material is contained in the phase with which the carrier is compatible. If the carrier is compatible with the fatty component phase, in addition to simply collecting this phase as a product, the fatty component product phase may alternatively be divided into a plurality of fractions, including a fatty component product fraction and a fatty recycle fraction, the carrier material thus comprises the fatty recycle fraction.
The water component product phase which remains in the first compartment is discharged and returned to an industrial waste water treatment system,
where it may be further processed into the sewer system if all discharge requirements have been met. Typically, the water component product has a fat content which is less than about 1 weight percent, preferably less than about 0.5 weight percent, and most preferably less than about 0.1 weight percent . Additionally, if the carrier material is comprised of water, the water component product phase may be divided into a water component effluent fraction and an aqueous recycle fraction, the carrier material thus comprises the aqueous recycle fraction.
In another alternative embodiment of the process of the present invention, the float material may be separated into its respective protein, fatty and water component products by first subjecting the treatment mixture to a dewatering process . A clarifier, as discussed above, may be used. Preferably, however, a clarifier comprising a single, round compartment with a conical shaped bottom is employed. The treatment mixture is added to this tank and the fatty component product phase and the water component product phase are allowed to separate. A side port near the top of the tank is used to remove the fatty component product. The water component phase, along with the protein component product which settles near the bottom of the tank, are removed through a centrally located port at the bottom of the cone. The protein component product may then be collected by passing the liquid component phase through a shaker screen, or by using some other means for removing solids as discussed above. However, it is to be noted that the rate at which the proteinaceous solids settle can be low, while the angle of repose for such solids can be high. As a result, process time may be increased.
The process of the present invention affords a means by which to obtain a protein component and a fatty component product from a float material in a form which is sufficiently free of water such that it may be sent directly to a renderer, feed mill, or further processed, without additional treatment. Furthermore, due to the improvement in stability, such products may be supplied in higher quality, or better condition, as compared to typical waste water treatment sludge or float material.
The process of the present invention also affords a more energy efficient means by which to separate the various components of a float material, as compared to conventional processes employing standard evaporation techniques for example, because energy is not spent on the evaporation of water or organic solvents .
It is to be noted that, during the practice of this invention, various systems and controls can be employed to monitor and control the process steps and the flow rate of the various substances. These systems and controls can be based on computer calculations and/or manual adjustments.
It is to be further noted that the process of the present invention has been described in detail with particular reference to preferred embodiments for use in the treatment of a float material. However, variations and modifications can be made without departing from the spirit and scope of the invention as defined by the claims which follow. Such variations or modifications may include, among other things: (i) treating dead stock, in accordance with the embodiments described herein, rather than a float material; (ii) forming a treatment mixture by either (a) heating the float material or dead stock, to liquefy fats, oils and
grease and then mixing with a carrier material, (b) mixing the float material or dead stock and the carrier material, and then applying heat to the mixture, or (c) heating the float material or dead stock directly, provided a suitable solids content is present to enable separation. It is to be noted, however, that while the above-described conditions may be employed equally well for the processing of dead stock, when such waste material is process higher treatment temperatures (e.g., 100°C, 105°C or more) may be beneficial, as well as longer treatment times (e.g., 60 minutes or more) . Furthermore, when a pipe cooker, or plug flow reactor is employed to process such material, alternative means common in the art may be needed in order to move the material through the pipe efficiently.
Finally, it is to be noted that the process of the present invention can be effectively used in either a batch or continuous system. For reasons of process economy, however, a continuous system is preferred.
BELT FILTRATION APPARATUS
Now referring to the drawings, and particularly to Fig. 1, the reference numeral 21 generally indicates a preferred filtration apparatus, suitable for use in the process of the present invention for separating and recovering the various components (i.e., the protein component product, the fatty component product and the water component product) of the treatment mixture for further processing. In general, the filtration apparatus 21 comprises a feed tank 23 (i.e., a pre-filtration mix tank) for receiving treatment mixture from the source of treatment mixture, a separation system, indicated generally at 25, for receiving treatment mixture from
the feed tank and separating the various components of the mixture, a fluid recovery system, generally indicated at 27, for recovering water and fatty components separated from the mixture as well as any waste mixture remaining after separation of the mixture components, and a control panel (not shown) for controlling operation of the apparatus.
The feed tank 23 is generally cylindrical, having a side wall 51, a bottom wall 53 and support legs 55 supporting the tank in an upright orientation. An inlet port 57 is disposed in the side wall 51 adjacent the bottom wall 53 in fluid communication with the conduit in which the treatment mixture is formed. The pump forces the treatment mixture through the conduit and into the tank 23 via the inlet port 57. Thus it can be seen that the tank 23 may be located remotely from the treatment mixture source. In the illustrated embodiment, the inlet port 57 is disposed in a generally tangential relationship with the side wall 51 of the tank 23 so that mixture pumped into the tank generates a circumferential swirling of the mixture at the bottom of the tank to inhibit stagnation of the mixture .
An outlet port 59 is disposed in the side wall 51 of the tank 23 substantially adjacent the top of the tank. The treatment mixture fills the tank 23 as it enters through the inlet port 57 and, once the level of the mixture in the tank rises to the height of the outlet port 59, the mixture flows out of the tank via the outlet port. In this manner, treatment mixture continually rises within the tank 23 upward to the outlet port 59 at the top of the tank, thereby inhibiting stagnation of the mixture at the bottom of the tank. However, it is contemplated that feed tanks in which treatment mixture enters the tank 23 other
than at its bottom, such as where the mixture enters through the top of the tank, fall within the scope of this invention. A feed tube 61 in fluid communication with the outlet port 59 of the tank directs the mixture to the separation system. A drain opening 63 and associated closure 65 are provided in the bottom wall 53 of the tank 23 for selective draining of the mixture from the tank when cleaning is necessitated.
The top of the tank 23 is open to permit monitoring of and access to the interior of the tank. A frame 67 is mounted on the upper rim of the tank 23 to support a mixture agitator 69 above the open top of the tank. The agitator 69 comprises a motor 71 attached to the frame 67 generally centrally above the open top of the tank 23. A shaft 73 connected to the motor 71 for driven rotation about the rotation axis of the shaft extends down into the tank 23 through the open top of the tank. Blades 74 of a propeller 75 extend radially outward from the bottom of the shaft 73 for conjoint rotation with the shaft. Rotation of the propeller 75 agitates the treatment mixture to further effect the generally circumferential swirling of the mixture so that the mixture spirals upward within the tank 23 to the level of the outlet port 59. The rate of agitation is preferably sufficient to avoid settling of the proteinaceous solids which are present in the treatment mixture, but not so vigorous that shearing of these solids occurs. It is also to be understood that agitators other than the type shown and described herein may be used without departing from the scope of this invention, as long as the agitator is capable of inhibiting settling of the solids without resulting in shearing of the solids.
The separation system 25 is disposed adjacent the feed tank 23 and is supported by a separator frame
101 with an upstream end 103 of the separation system positioned generally beneath the feed tube 61 for receiving treatment mixture from the feed tank. The separation system 25 is capable of separating the various components of the treatment mixture and carrying solids, which contain the particulate protein component product of the mixture, to a downstream end 105 of the system. The separator frame 101 includes a pair of longitudinally extending lower rails 107 mounted on support legs 108 and a corresponding pair of upper rails 109 supported in parallel spaced relationship above the lower rails. The separator frame 101 is constructed of stainless steel tubing, preferably square in cross-section and having a cross- sectional dimension of about 1.5 in. x 1.5 in. As an example of the overall dimensions of the separator frame 101, the frame of the illustrated embodiment is approximately 11 ft. long and 5 ft . - 4 inches wide. It is understood, however, that these dimensions may be altered depending upon mixture processing requirements and remain within the scope of this invention. With reference to Figs. 1 and 2, the separation system 25 comprises an endless filtering belt 111 constructed for allowing the water and fatty components of the treatment mixture (e.g, the liquified components of the mixture) to pass through the belt while carrying any unfiltered components toward the downstream end 105 of the separation system. The belt 111 is sufficiently wide to extend transversely generally between the upper rails 109 of the separator frame 101. For example, the belt 111 shown in Fig. 1 is approximately 4 ft. - 8 in. wide. The filtering belt 111 is preferably constructed of a polypropylene screen having a mesh size rated within the range of about 100-400 cfm. The polypropylene construction of
the belt 111 is designed to inhibit deformation of the mesh openings (e.g. stretching of the screen) of the belt when exposed to the heated treatment mixture carried by the belt, and is compatible with the mixture (e.g., corrosion resistant). It is understood, however, that the filtering belt 111 may be made of materials other than polypropylene, as long as the belt maintains dimensional stability of the mesh openings and is substantially corrosion resistant when exposed to the treatment mixture and the high temperatures associated with the mixture (e.g., up to about 105°C) . The mesh size of the belt 111 may vary depending on the size of particulate components to be separated from the mixture and remain within the scope of this invention. Opposing guide rails 113 extend longitudinally from the upstream end 103 of the separation system to the downstream end 105 in spaced relationship above the filtering belt. As seen best in Fig. 4, the guide rails 113 are disposed inward of the upper rails 109 of the separator frame 101 and are attached to the upper rails by mounting brackets 115 so that a small margin of each side of the belt 111 extends outward beyond the guide rails. Downwardly extending rectangular slots 117 (as shown in Figs. 1 and 6) , the purpose of which will become apparent later herein, are formed in the guide rails 113 at generally equally spaced intervals along the length of the rails. Rubber sealing strips 119 depend from the guide rails 113 along the length of the rails in generally sealing engagement with the filtering belt 111 to inhibit treatment mixture on the belt from spreading transversely outward of the guide rails to the edge margins of the belt. The sealing strips 119 are releasably attached to the guide rails 113, such as by threaded fasteners (not shown) extending through the
strips and through vertically oriented slots (not shown) in the guide rails so that the strips can be selectively positioned vertically relative to the guide rails. Thus it can be seen that the strips 119 may be lowered relative to the guide rails 113 as the strips become worn down due to friction between the strips and the filtering belt.
Referring again to Figs. 1 and 2, a chute 121 extends transversely between the guide rails 113 generally at the upstream end 103 of the separation system 25 for receiving a stream of treatment mixture exhausted from the feed tube 61. The chute 121 is constructed of stainless steel and has an upper end 123 attached to support arms (not shown) extending from the feed tank 23. The chute 123 inclines forward and downward to a lower end 125 disposed slightly above the filtering belt 111 to direct the mixture onto the belt. Tabs (not shown) extending from the sides of the chute 121 are attached to the guide rails 113, such as by welding, to further secure the chute against movement.
A pair of fins 127 are mounted on the surface of the chute 121 in spaced relationship with each other, with the lower ends of the fins being flush with the lower end 125 of the chute. The fins 127 angle outward relative to the central axis of the separation system 25 as they extend down the chute 121 so that some of the mixture flowing down the chute is directed laterally outward by the fins to more evenly spread the mixture along the width of the belt 111 upon reaching the lower end 125 of the chute.
A pair of endless chains 131 comprised of interconnected links 133 (Figs. 4 and 4a) are attached to respective edge margins of the filtering belt 111 for use in driving movement of the belt . A preferred attachment arrangement is disclosed in U.S. Patent No.
4,081,375 (Deal et al . ) , which is incorporated herein by reference. Chain extensions 135 are attached to each of the links 133 of the chains 131 and extend inward over the edge margins of the filtering belt 111. An annular spacer 137 is positioned between each extension 135 and the filtering belt 111, and a rivet 139 secures the extension, spacer and belt together so that the chains 131 are secured to the belt. Angle irons 141 (one of which is shown in Fig. 4a) extend longitudinally between the upstream and downstream ends 103, 105 of the separation system 25 and are mounted to the separator frame 101 to define opposing support surfaces for supporting the upper reaches of the chains. Teflon wear strips 143 attached to the support surfaces of the angle irons 141, such as by screw fasteners 145, reduce friction between the chains and the angle irons.
A motor support frame 147 (seen best in Fig. 3) mounted on the upper rails 109 of the separator frame 101 at the downstream end 105 of the separation system 25 supports a motor 149 for driving the chains 131. The motor 149 is connected by way of a drive shaft 151 to a drive gear 153. A drive chain 155 extends downward from the drive gear 153 to a drive sprocket 157 mounted on a shaft 159 extending transversely outward from one side of the separator frame 101 at the downstream end 105 of the separation system 25. The driven shaft 159 further extends between the sides of the separator frame 101 and is journalled in the frame for rotation relative thereto. A chain idler 161 is rotatably connected to the separator frame 101 in contact with the drive chain 155 to maintain tension in the drive chain.
As illustrated in Fig. 3, a pair of driven sprockets 163 are mounted on the driven shaft 159 in
spaced relationship with each other. The sprockets 163 are positioned between the upper rails 109 of the separator frame 101, with the spacing between the sprockets being slightly greater than the width of the filtering belt 111 so that the sprockets are aligned with the endless chains 131 at the edge margins of the belt. The teeth of the sprockets 163 are sized for meshing with the links 133 of the chains 131 for driving movement of the chains in a conventional manner upon rotation of the sprockets. Thus, it may be seen that the endless chains 131 are driven conjointly by the shaft 159 and sprockets 163 to move the upper reach of the belt 111 toward the downstream end 105 of the separation system 25. A support roller 165 having a length substantially equally to the width of the belt 111 is mounted on the driven shaft 159 for conjoint rotation therewith and extends between the sprockets 163 along substantially the entire width of the filtering belt to support the belt as the endless chains 131 are driven around the sprockets. The roller
165 has a rubber outer surface to maintain sufficient friction between the roller and the filtering belt 111 to inhibit slipping of the belt relative to the roller. Tension sprockets 169 (Fig. 2) are mounted on another shaft 171 extending transversely between the sides of the separator frame 101 generally at the upstream end 103 of the separation system 25. The shaft 171 is journalled at its ends in mounting brackets 173 for rotation relative to the frame 101. A support roller 175 (shown in phantom in Fig. 1) is also mounted on the shaft 171 between the tension sprockets 169 for conjoint rotation therewith to support the belt 111 as the endless chains 131 are driven around the sprockets. The tension sprockets 169 and shaft 171 are preferably positioned in horizontal alignment with the
driven sprockets 163 and shaft 159 so that the upper reach of the belt 111 is supported by the respective support rollers 165, 175 in a relatively horizontal orientation as the belt moves forward between the upstream and downstream ends 103, 105 of the separation system 25.
The mounting brackets 173 supporting the tension shaft 171 are connected to the separator frame 101 by threaded rods 177 (one of which is shown in Fig. 1) extending longitudinally between the brackets and the separator frame. Rotation of the threaded rod 177 relative to the frame 101 causes longitudinal movement of the brackets 173 relative to the frame such that the tension shaft 171 and sprockets 169 are moved longitudinally relative to the driven shaft 159 and sprockets 163. Movement of the tension shaft 171 away from the driven shaft 159 creates additional tension in the belt 111 to maintain the belt generally taut for inhibiting the belt from sagging and also for inhibiting the chains 131 against slipping off of the sprockets 163, 169. Movement toward the driven shaft 159 releases tension to permit removal of the belt 111 for replacement or repair.
Idler sprockets 179 (Figs. 1 and 3) are mounted on an idler shaft 181 extending transversely between support brackets 183 depending from the lower rails 107 of the separator frame 101 intermediate the driven shaft 159 and the tension shaft 171. The idler shaft 181 is journalled at its ends for rotation relative to the frame 101. The idler sprockets 179 aid in controlling alignment and tracking of the belt 111 (e.g., to inhibit transverse movement of the belt) . A support roller 185 is mounted on the idler shaft 181 for conjoint rotation therewith and extends between the idler sprockets 179 along substantially the entire
width of the filtering belt 111 to maintain pressure against the belt as the endless chains 131 are driven around the sprockets 179.
In the illustrated embodiment, the endless chains 131, the motor 149 and associated shafts 159,
171, 181, sprockets 163, 169, 179 and rollers 165, 175, 185 broadly define a drive system for driving movement of the filtering belt 111. The motor 149 preferably has sufficient power to drive the filtering belt 111 at speeds over 25 ft. /min., up to about 50 ft. /min.
Referring particularly to Figs. 1 and 6, wiper bars 187 extend transversely beneath the upper reach of the filtering belt 111 in close contacting relationship with the belt. Contact between the bars 187 and the belt 111 breaks the surface tension of liquid suspended in the mesh of the upper reach of the belt to help the liquid fluid filter down through the belt. The wiper bars 187 are equally spaced, such as about 1.5 inches apart, substantially the entire distance between the support rollers 165, 175 at the upstream and downstream ends 103, 105 of the separation system 25. Longitudinally extending mounting brackets 189 are fastened to the inner surfaces of the upper rails 109 for supporting the wiper bars 187. As shown in Fig. 4a, the mounting brackets 189 are generally Z- shaped to define vertical mounting sections 191 spaced inward toward each other from the upper rails 109. The wiper bars 187 are preferably constructed of Teflon. The bars 187 of the illustrated embodiment are cylindrical, each having a diameter of about 1 inch. Extensions 193 projecting from the opposite ends of each wiper bar 187 are generally square in cross- section for seating respectively within squared notches (not shown) in the vertical mounting sections 191 of
the mounting brackets 189 to secure the bars to the brackets .
A spreader plate 201 is positioned downstream of the lower end 125 of the chute 121 and extends transversely between the guide rails 113 above the belt 111. The spreader plate 201 is generally rectangular and is preferably constructed of stainless steel to withstand exposure to the high temperature of the treatment mixture carried by the filtering belt 111. The top edge of the plate 201 is attached along its length to a rod 203 extending transversely between the guide rails 113. The diameter of the rod 203 is sized for loosely seating within an opposing pair of the downwardly extending slots 117 in the guide rails 113 downstream of the lower end 125 of the chute 121 to secure the spreader plate 201 between the guide rails. A lower edge 205 of the spreader plate 201 rests on the filtering belt 111 and is slightly rounded to reduce the risk of damage to the filtering belt by the lower edge of the spreader plate. The ends of the rod 201 are capable of pivoting movement within the slots 117 of the guide rails 113 so that the rod and attached spreader plate 201 can be conjointly pivoted relative to the separator frame 101 and belt 111 about the rotation axis of the rod. Permitting free rotation of the rod 203 and spreader plate 201 inhibits excessive downward pressure applied by the plate against the filtering belt 111 to reduce wearing of the belt and inhibit excessive squeezing of the mixture against the belt as the mixture passes beneath the spreader plate.
Downstream of the spreader plate 201, a wedging unit, generally indicated at 211, extends transversely between the guide rails 113 in opposed relation with the filtering belt 111 for pressing or squeezing the mixture between the unit and the belt to
further remove water and fatty components from the mixture. The wedging unit 211 is located sufficiently downstream of the spreader plate 201 so that water and liquified fatty components have already filtered down through the belt 111 for recovery by the recovery system 27 before the mixture approaches the wedging unit, resulting in a generally cake-like consistency of the mixture .
The wedging unit 211 includes opposing side walls 213, a horizontal top wall 215 and a bottom wall defining an inclined lower surface 217 of the wedging unit. The wedging unit 211 is oriented so that a lower end 219 of the inclined lower surface 217 is downstream of an upper end 221 of the surface and rests on the filtering belt to define a nip 212 between the wedging unit and the belt through which the mixture passes as the mixture is carried downstream by the belt. As an example, the wedging unit 211 illustrated in Fig. 6 is approximately 9 inches long and 4 inches high. The inclination angle of the inclined lower surface 217 of the wedging unit 211 is preferably in the range of about 10° - 30°. The wedge unit 211 of the illustrated embodiment is constructed of steel, with the inclined lower surface 217 of the wedging unit being lined with a rubber material (not shown) to prevent the metal surfaces of the wedging unit from contacting the filtering belt.
Extension members 223 (seen best in Fig. 7) are attached, such as by welding, to the side walls 213 of the wedging unit 211 and project laterally outward therefrom. The extension members 223 are generally square in cross-section and are sized for seating freely within the vertically extending slots 117 in the guide rails 113 to support the wedging unit 211 at the desired height above the filtering belt 111 and to
secure the unit against longitudinal movement relative to the separator frame 101. The extension members 223 are capable of vertical movement within the slots 117, so that the wedging unit 211 can be moved vertically toward and away from the filtering belt 111. As such, the wedging unit 211 "floats" above the filtering belt 111 so that the downward pressure applied by the wedging unit 211 to the mixture is a function of the weight of the wedging unit . When the mixture moves beneath the wedging unit 211, the mixture engages the inclined lower surface 217 of the wedging unit and is thus inhibited from moving further downstream. It has been found that the wedging unit 211 effectively breaks up the mixture, rolling portions of the mixture back over on itself.
This reduces the thickness of the mixture and tends to spread the mixture more evenly along the width of the belt 111. The force of the moving mixture against the inclined lower surface 217 of the wedging unit 211 pushes the wedging unit upward against the weight of the wedging unit so that the mixture can pass through the nip 212 between the lower end 219 of the inclined surface and the filtering belt 111. As the mixture passes through the nip, the weight of the wedging unit 211 exerts a downward or squeezing pressure against the mixture to squeeze the mixture between the wedging unit and the filtering belt 111 to squeeze additional water and fatty components from the mixture for filtering through the belt and to reduce the thickness of the mixture. For example, after passing through the nip
212, the thickness of the mixture is preferably in the range of about 1/16 to % inches.
The weight of the wedging unit 211 must be such that the squeezing pressure exerted by the wedging unit against the mixture squeezes a desired amount of
water and fatty components from the mixture, while still allowing the mixture to move the wedging unit away from the filtering belt so that the mixture can pass through the nip. An excessive downward pressure exerted by the wedging unit 211 would result in the mixture becoming dammed behind the nip 212, and would also result in particulate components of the mixture (i.e., solids) being mashed by the wedging unit down into the mesh of the filtering belt 111 such that the particulate components undesirably become entrained in the mesh. Vertically extending weight bars 225 are threadably mounted on the top of the wedging unit 211 in transversely spaced relationship between the guide rails 113 for receiving weights (not shown) thereon to adjust (e.g., increase) the downward squeezing pressure applied by the wedging unit to the mixture. The squeezing pressure exerted by the wedging unit 211 of the illustrated embodiment is preferably less than about 30 psi and is more typically about 0.25 - 1 psi. Downstream of the wedging unit 211, a press roller 231 extends above the filtering belt 111 transversely across the width of the belt 111 to define a nip 232 between the press roller and the belt. The roller 231 is mounted on an axle 233 (Figs. 4 and 4a) comprising a cylindrical center portion 235 and generally square end extensions 237. Bearings 239 are positioned on the axle 233 for rotatably mounting the roller 231 on the cylindrical center portion 235 of the axle so that the roller is capable of free rotation about a central longitudinal axis (not shown) of the axle. The end extensions 237 of the axle 233 are sized for seating freely within the vertically extending slots 117 in the guide rails 113, with the roller 231 resting on the filtering belt 111, to secure the roller
against longitudinal movement relative to the belt and separator frame 101.
The extensions 237 are capable of vertical movement within the slots 117, so that the roller 231 can be moved vertically toward and away from the filtering belt 111. As such, the roller 231 "floats" above the filtering belt 111 in the same manner as the wedging unit 211 so that downward squeezing pressure applied by the press roller 231 to the mixture is a function of the weight of the press roller. Vertically extending weight bars 241 are attached to the squared end extensions 237 of the axle 233 for receiving weights (not shown) thereon to adjust (e.g., increase) the squeezing pressure applied by the roller against the mixture.
The roller 231 of the illustrated embodiment is preferably 6 inches in diameter so as to minimize the relative approach angle between the roller and the filtering belt 111. It has been found that a smaller relative approach angle inhibits the mixture from sticking to and wrapping around the roller 231 as the mixture passes through the nip between the roller and the belt 111. However, it is understood that the roller 231 may be sized smaller or larger than 6 inches in diameter without departing from the scope of this invention.
Now referring to Figs. 1 and 3, a scraper unit, generally indicated at 251, extends transversely along the width of the filtering belt 111 at the downstream end 105 of the separation system 25 to scrape the remaining solids off of the belt for delivery to a receptacle (not shown) via a recovery chute 252 positioned adjacent the downstream end 105 of the system. The scraper unit 251 comprises a pair of mounting brackets 253 attached to the separator frame
101 beneath the driven support roller 165 and extending longitudinally outward from the frame. A support rod 255 extends transversely between the brackets 253 and is seated within slots 257 extending longitudinally within the brackets. A mounting plate 259 is attached to the rod 255, such as by welding, to extend generally upward from the rod. A scraper blade 261, preferably constructed of Teflon, is connected to the mounting plate 259 by suitable fasteners 263 in closely spaced relationship with the filtering belt 111 as the belt moves around the driven support roller 165.
The rod 255 is capable of sliding movement within the slots 257 of the mounting brackets 253. In this manner, the angle of the scraper blade 261 relative to the filtering belt 111 can be adjusted by changing the position of the rod 255 within the slots 257 of the brackets 253. Suitable end nuts 265 releasably fix the rod 255 in its desired position. In the illustrated embodiment of Fig. 2, the rod 255 is bent at one end to a 90° angle to extend longitudinally inward of the scraper blade 261 for receiving weights thereon. It will be seen that weights may be loaded onto the bent end of the rod 255 to apply a torque to the scraper unit 251 to better hold the scraper blade 261 against the filtering belt 111.
The separation system 25 shown in the various figures herein includes a single wedging unit 211 disposed upstream of a single press roller 231. However, it is understood that the press roller 231 may be located upstream of the wedging unit 211 and remain within the scope of this invention. It has also been discovered that it is easier to squeeze water from the treatment mixture when the mixture is relatively thin as it passes beneath the wedging unit 211 and/or press roller 231. Where additional separation of water
components is desired, it is contemplated that multiple wedging units 213 may be used, with the downward pressure exerted by the wedging units progressively increasing from the furthest upstream unit to the furthest downstream unit . Each of the wedging units
213 would be secured in a respective pair of the slots 117 in the guide rails 113. Multiple press rollers 231 may also be used in a manner similar to the multiple wedging units 211. Also, for purposes herein, the wedging unit
211 and press roller 231 broadly comprise a press for applying a squeezing pressure to the mixture for squeezing the mixture against the filtering belt. It is contemplated, however, that the press may also comprise a single wedging unit by itself, a single press roller by itself, multiple wedging units, multiple roller units, or any combination of wedging units and roller units. The wedging unit 211 and press roller 231 are show and described herein as resting on the filtering belt when no mixture is passing through the nips 212, 232. However, it is contemplated that the wedging unit 211 and press roller 231 may be mounted on the guide rails 113 such that the roller and the lower end 219 of the inclined surface 217 of the wedge unit are spaced an initial distance from the filtering belt, such as about 1/16 - % inches, without departing from the scope of this invention.
In addition, the weights added to the wedging unit 211 and press roller 231 broadly comprise a biasing member for increasing the squeezing pressure applied by the press to the mixture as the mixture passes through the nips 212, 232. It is contemplated that biasing members other than weights may be used to increase the squeezing pressure applied by the wedging unit 211 and press roller 231 to the mixture, such as
springs (not shown) that are sufficiently tensioned to inhibit the wedging unit and press roller against being pushed upward by the mixture, and remain within the scope of this invention. Referring again to Fig. 1, the recovery system comprises upper and lower drain pans, respectively designated as 301 and 303, and a belt washer assembly, generally indicated at 305. The upper drain pan 301 extends longitudinally between the upstream and downstream ends 103, 105 of the separation system 25 and is attached to the lower rails 107 of the separator frame 101 beneath the upper reach of the filtering belt 111 for recovering substantially all of the water and fatty components passing through the upper reach of the filtering belt. The upper drain pan 301 is generally V-shaped so that liquid components recovered by the drain pan flow toward a central collection channel 307 extending transversely along the bottom of the drain pan. A suitable pipe (not shown) in fluid communication with the collection channel 307 receives the liquid components from the channel and carries the components to a clarifying station (not shown) where the recovered water and fatty components of the mixture may be separated in a conventional manner.
As shown in Fig. 5, the belt washer assembly 305 is secured by support brackets 311 connected to and depending from the bottom of the upper drain pan 301 for washing the lower reach of the filtering belt 111 as it returns from the downstream end 105 of the separation system 25 back to the upstream end 103. The washer assembly 305 includes a transversely extending pipe 313 having a length greater than the width of the filtering belt 111. One end of the pipe 313 is fitted with an end cap 315 while the other end is fitted with
a nipple 317. The nipple 317 is adapted for connection, such as by suitable hosing (not shown) to a source of cleaning water (not shown) . Spray nozzles 319 are fitted within openings (not shown) equally spaced along the length of the pipe 313 to direct pressurized water down against the lower reach of the filtering belt 111. The pressure of the water is preferably sufficient to dislodge any solids lodged in the mesh of the filtering belt 111. The lower drain pan 303 is attached to the separator frame 101 beneath the lower reach of the filtering belt 111 for recovering cleaning water from the washer assembly 305 along with any solids (or treatment mixture components) washed from the filtering belt. As with the upper drain pan 301, the lower drain pan 303 is generally V-shaped so that the components recovered by the drain pan flows toward a central collection channel 321 extending transversely across the bottom of the drain pan. A suitable pipe (not shown) in fluid communication with the collection channel 321 receives the mixture of components from the channel and carries the mixture to the waste treatment station for reprocessing and further separation of the components . Operation of the apparatus 21 of the present invention will now be described. Before activating the apparatus 21, the spreader plate 201, wedging unit 211 and press roller 231 are secured on the longitudinally extending guide rails 113 of the separator frame 101 at the desired positions between the upstream and downstream ends 103, 105 of the separation system 25 in the manner described above. Weights may be placed on the vertically extending weight bars 225, 241 of the wedging unit 211 and press roller 231 to adjust the downward pressure to be applied by the wedging unit and
press roller against the mixture being processed. The conduit carrying the treatment mixture is connected to inlet port 57 of the feed tank 23. The treatment mixture in the conduit is at a temperature in the range of about 75°C to about 105°C so that the fatty components of the mixture are generally liquified.
The control panel is then used to activate the apparatus 21, turning on the filtering belt motor 149, the agitator motor 71 and the pumps associated with the treatment mixture. The filtering belt motor 149 drives rotation of the drive gear 153, thereby driving rotation of the drive sprocket 157 via the drive chain 155. The driven shaft 159 is rotated by the drive sprocket to drive rotation of the driven sprockets 163 about the rotation axis of the shaft.
The teeth of the sprockets 163 mesh with the links 133 of the endless chains 131 attached to the filtering belt 111 to move the chains around the sprockets. The chains 131 are continuously driven by the motor 149 to drive the attached filtering belt 111 so that the upper reach of the belt moves continuously from the upstream end 103 of the separation system 25 to the downstream end 105.
The pumps associated with the treatment mixture pump the heated mixture through the conduit leading to the feed tank 23. The treatment mixture enters the feed tank 23 through the inlet port 57 adjacent the bottom wall 53 of the tank. The level of the treatment mixture within the tank 23 continues to rise as the mixture is pumped into the bottom of the tank. Pumping the mixture into the bottom of the tank tangential to the tank side wall 51 imparts a continuous upward swirling movement to the mixture already in the tank to inhibit stagnation of the mixture at the bottom of the tank. The agitator motor
71 drives rotation of the shaft 73 and propeller 75 so that once the level of the mixture reaches the propeller, the mixture is agitated by the propeller. Agitation of the treatment mixture inhibits settling of the solids present in the mixture and promotes the swirling or spiraling motion of the mixture as it rises within the tank 23.
When the feed tank 23 fills to the level of the outlet port 59, treatment mixture flows from the feed tank 23 via the outlet port and is carried by the feed tube 61 to the upstream end 103 of the separation system 25. Treatment mixture flows from the feed tube 61 down onto the chute 121 above the filtering belt 111. As the mixture flows forward and downward on the chute 121, the fins 127 on the chute spread the mixture outward so that the mixture is distributed more evenly along the width of the belt upon reaching the lower end 125 of the chute.
Treatment mixture on the chute 121 flows down onto the moving filtering belt 111 and is carried by the belt toward the downstream end 105 of the separation system 25. The liquified components (i.e., the water and fatty components) of the mixture begin filtering down through the belt 111 and are recovered in the upper drain pan 301 beneath the belt for delivery to the clarifier. The wiper bars 187 in contact with the underside of the filtering belt 111 break the surface tension of liquid components in the mesh of the belt to promote passing of these components down through the belt to the upper drain pan 301. As mixture approaches the spreader plate 201 downstream of the chute 121, the plate is lifted by the mixture so that the mixture can pass downstream of the plate. Some of the mixture begins to dam behind the plate 201 and tends to move laterally along the width of the belt
111 to areas where the mixture is less thick, thereby more uniformly distributing the mixture along the width of the belt.
When the mixture reaches the wedging unit 211 downstream of the spreader plate 201, a sufficient amount of liquid components have been filtered out of the mixture so that the remaining protein and liquid components have a cake-like consistency. The inclined lower surface 217 of the wedging unit 211 resists forward movement of the mixture and acts to compact or squeeze the mixture against the filtering belt 111. More particularly, the inclined surface 217 pushes portions of the mixture backward, such that the mixture tends to churn, or roll backward onto additional incoming mixture. The churning or agitating action tends to work additional water and fatty components from the mixture for filtering through the belt 111, and also promotes tumbling of the mixture to areas of less thickness, thereby spreading the mixture more uniformly along the width of the filtering belt for further processing of the mixture.
As the mixture engages the inclined lower surface 217 of the wedging unit 211, the force of the forward moving mixture against the inclined surface increases. The floating arrangement of the wedging unit 211 allows the wedging unit to be lifted by the mixture away from the filtering belt so that the mixture can pass through the nip 212. The squeezing pressure exerted by the wedging unit 211 resists the upward lifting by the mixture and squeezes the mixture between the lower end 219 of the inclined surface 217 and the filtering belt 111 to promote the further squeezing of water and fatty components from the mixture for filtering through the belt 111.
The mixture is then carried further downstream by the filtering belt 111 to the press roller 231 where the mixture is further squeezed to remove additional water and fatty components. As with the wedging unit 211, when the mixture engages the press roller 231, an upward pressure is applied by the mixture to the roller. The floating arrangement of the press roller 231 allows it to be lifted by the mixture so that the mixture can pass through the nip 232 and be carried further downstream by the belt 111. The squeezing pressure exerted by the press roller 231 squeezes the mixture between the roller and the filtering belt 111.
Upon reaching the downstream end 105 of the separation system 25, solids remaining on the filtering belt 111 engages the scraper blade 261 as the belt and chains 131 move around the driven sprockets 163 and associated support roller 165. The scraper blade 261 removes the solids from the belt so that the mixture falls onto the recovery chute 252 for delivery into the receptacle. Any solids or treatment mixture components adhering to or remaining enmeshed in the belt 111 after scraping are carried by the lower reach of the belt beneath the washer assembly 305 above the lower drain pan 303. The remaining solids or components are washed from the filtering belt 111 and recovered by the lower drain pan 202 for delivery back to the waste treatment system to be reprocessed.
It will be observed from the foregoing that the apparatus 21 and process described herein satisfies the various objectives of the present invention and attains other advantageous results. Constructing the filtering belt 111 of polypropylene, stainless steel, or some other type of heat-resistant material, inhibits the belt from deforming due to the high temperatures
(e.g., in the range of about 75°C to about 105°C) of the treatment mixture. Thus, the apparatus 21 is capable of processing a heated treatment mixture in which the fatty components of the mixture are generally liquified.
Importantly, mounting the wedging unit 211 and press roller 231 on the guide rails 113 for floating movement toward and away from the filtering belt prevents excessive squeezing pressure from being applied to the mixture so that solids are not mashed into and entrained in the mesh of the filtering belt 111. As such, the belt 111 requires little cleaning after the solids have been scraped off at the downstream end 105 of the separation system 25. More particularly, it has been found that the amount of cleaning water used by the washer assembly 305 to sufficiently clean the filtering belt 111 may be less than or equal to about 10 gallons per minute. Moreover, the filtering belt is cleaned intermittently or on an as needed basis, so that the 10 gallons per minute rate of cleaning water usage occurs for only about 1-5 minutes per hour. This is a substantial reduction in water usage over the 40 gallons per minute, continuous usage associated with conventional separating apparatus to process a similar volume of mixture. Since the cleaning water must be recovered and sent back to the waste treatment system for reprocessing, the reduction in cleaning water usage directly results in a reduction of processing costs. Also, because the fatty components are generally liquified, a substantial amount of water and fatty components are separated from the mixture prior to squeezing of the mixture by the wedging unit 211 and press roller 231. In addition, less pressure is needed by the wedging unit 211 and press roller 231 to squeeze
additional water and fatty components from the mixture. However, even without applying substantial squeezing pressure to the mixture, it has been found that at least about 75% of the water components of the initial treatment mixture can be separated from the mixture by the present apparatus; that is, the protein component product will typically have at least about a 25% solids content. Thus, only a single filtering belt 111 is needed (as opposed to the twin belts employed by conventional apparatus) along with the longitudinally stationed wedging unit 231 and press roller 231 to adequately separate the water and fatty components from the mixture. A large number of compression rollers, as well as the complicated compression roller pattern, is no longer required, resulting in a reduced cost to manufacture and maintain the apparatus 21.
The less complicated design of the apparatus 21 and the ability of the filtering belt 111 to maintain dimensional stability of the belt mesh upon exposure to the high temperatures of the treatment mixture also allow the filtering belt to be driven at higher speeds, such as about 25 ft/min. or more, and particularly up to about 50 to about 60 ft/min. This results in greater processing capabilities. While the above apparatus and process are described herein in relation to the separation of water and liquified fatty components from a treatment mixture that also includes proteinaceous solids, it is to be understood that the apparatus and process may be used for processing any mixture comprised of liquid components and particulate components and remain within the scope of this invention.
As various changes could be made in the above constructions without departing from the scope of the invention, it is intended that all matter contained in
the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.
The process of the present invention is further illustrated by the following Examples. These Examples are designed to teach those of ordinary skill in the art how to practice this invention. These Examples, however, are not to be interpreted in a limiting sense.
EXAMPLE 1
A quantity of animal fat (i.e., the carrier material) is heated using steam in a jacketed vessel until the temperature of the liquefied animal fat is within the range of about 75 to about 90°C. The liquefied animal fat is then pumped into a mixer equipped with a stirring mechanism. Simultaneously, the float material produced by a waste water treatment system at a food processing plant is introduced into the mixer. The heated carrier material and float material are mixed for approximately 30 minutes until a treatment mixture is obtained. The mixture is then pumped into a shaker screen apparatus having 3 concentric screen sections of 80 (top) , 120 (middle) , and 150 (bottom) mesh sizes. The screens permit the water and fatty components of the mixture to pass through. These components are then discharged through an opening located at the bottom of the apparatus. The screen sizes are selected so that the protein component will not pass through in any substantial amount but, instead, will be screened and discharged from the apparatus through openings located immediately after each screen but before the next
screen or bottom opening. The protein component, which is collected from the apparatus and then transported to a rendering plant, has a solids content of about 30 to about 40 percent by weight. The liquid mixture which remains after being discharged from the bottom of the shaker screen apparatus is primarily comprised of a fatty component product phase and a water component product phase . This mixture is transferred to a clarifier apparatus, which is rectangular and has 2 compartments separated by a baffle. This mixture is transferred into a first compartment after which the water component phase, being heavier than the fatty component phase, begins to sink toward the bottom. As additional liquid mixture from the shaker screen apparatus is introduced into the first compartment, the level rises toward the top of the baffle. When the level reaches the top of the baffle, the lighter fatty component product phase spills over into the second compartment. The fatty component product, which has a moisture content of less than about 2 percent by weight, is discharged from the second compartment and can be recycled into this process or transported to a rendering process .
To maintain the proper level in the first compartment, the water component phase is discharged from the bottom of the first compartment. This water component phase can be returned to the waste water treatment process or further treated, as necessary, before discharge into a municipal sewer or use in other applications.
EXAMPLE 2
Referring generally to FIG. 11, approximately 5000 gallons per day of a float material from a DAF waste water treatment process was continuously obtained
from a poultry slaughtering facility. The float material, having a solids content of about 10 weight percent, was pumped into an agitated pre-mix tank 500 along with about 800 ppm of the antioxidant ethoxyquin, the type commercially available under the trademark Santoquin® from Novus International, Inc. The materials were mixed in the tank for a period of 90 minutes to form a stabilized float material.
The float material was then pumped at about 15 gallons per minute (gpm) through a plug flow reactor 510 comprising a stainless steel pipe having a diameter of about 4 inches and a length of about 350 feet. Heat was supplied to the plug flow reactor in-line by sparging about 400 pounds per hour of steam at about 60 psi into the reactor along with the treatment mixture. The reactor was insulated to maintain the treatment mixture within a temperature range of about 75 to about 95°C. The treatment mixture had a residence time in the reactor of about 20 minutes, after which it was pumped to a floe tank 520 wherein 125 ppm of a eationic polymer flocculent was added. The flocculated mixture was then pumped onto a belt filtration apparatus 530 comprising a non-corroding polypropylene belt rated at 200 cfm, and a protein component product was removed from the mixture.
The resulting liquid mixture (i.e., a mixture comprising a fat component product and a water component product) was gravity fed to a clarifier 550 wherein the fat component product was separated from the water component product. The resulting fat product consisted of about 98 weight percent fat and about 2 weight percent water. The resulting water product was then returned to the waste water pre-treatment process. The separated protein component product comprised about 65% water and about 35% solids. The
protein component product was then dried in a gas-fired rotary dryer 540 (of a type commercially available from, for example, International Technology Systems, Inc. of Houlton, Wl) . The dryer used 2000 cfm of heated air flowing co-currently with the protein product . The inlet temperature of the air entering the dryer was about 230°C, and the outlet temperature of the air exiting the dryer was 125°C. The protein component product had a residence or exposure time of about 20 seconds in the dryer resulting in a dried product consisting of about 35 weight percent protein and about 45 weight percent fat with a moisture content of about 10 weight percent.