This invention relates generally to a method and apparatus for insoluble reduction in tallow, and more specifically to a method and apparatus for insoluble reduction in tallow using water and a polisher.
At various stages during meat production, trimmings of fat are recovered and are rendered down to edible and inedible tallows. Edible tallows are commonly used as frying fats, as shortening for use in baking, as oleic oil for use in baker products, and as confectionary and industrial margarine. Inedible tallows are commonly used to make soap, lubricants, animal feed, leather dressings, candles, and tallow for tanning.
The OIE international animal health code provides that only protein-free tallow (maximum level of insoluble impurities of 0.15% in weight) and derivatives made from this tallow may be included in ruminant feeds. While the United States and Canada do not currently have a similar requirement, meeting this level is still considered of value. Further, insolubles reduction in tallow eliminates or reduces the cost of tank cleaning and railcar cleaning, provides increased consistency to the finished product, and opens additional market opportunity.
A method and apparatus for insoluble reduction in tallow using water and a polisher is provided. The system for insoluble reduction in tallow includes a tallow tank, a mixer and a separator. The tallow is pumped into and held in the tallow tank. The tallow is mixed with water using the mixer. The tallow and water are pumped to a separator. The separator separates insolubles from the cleaned tallow.
While multiple embodiments are disclosed, still other embodiments of the invention will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. As will be realized, the invention is capable of modifications in various obvious aspects, all without departing from the spirit and scope of the invention. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not restrictive.
A method and apparatus for insoluble reduction in tallow is provided. More specifically, a method and apparatus for insoluble reduction in tallow using water and a polisher is provided.
Reduction of insolubles in tallow provides several benefits both during production and to the end product. During meat production, reduction of solids facilitates tank cleaning. With regards to the final product, reduction of solids in tallow positively impacts its functional use as beef meat and bone meal (MBM) free for cattle feeding and other applications that may be sensitive to MBM. Reduction of solids also reduces free fatty acid (FFA) growth.
Prior to mixing with water, the tallow may be heated or cooled to a predetermined temperature, for example approximately 205° F., using a first heat exchanger shown at block 12. After mixing, the tallow and water mixture may be held for a predetermined retention time or dwell time, shown at block 16. Holding may be effected using a holding tube assembly. One suitable retention time is approximately five minutes. After the holding and prior to processing by the polisher, the mixture of tallow and water may pass through a second heat exchanger to maintain a predetermined temperature, for example approximately 205° F., shown at block 17. After polishing, the solids may be removed and fed back to a cooker of a rendering process—thus, the solids may be recovered and put back into MBM, for example. The clean tallow may be dried using a tallow dryer to remove excess water, shown at block 24. After the clean tallow is dried, it may be cooled using a third heat exchanger, shown at block 26.
A specific embodiment of tallow processing is as follows. At blocks 10 and 12, the tallow (or product) enters a supply tank and is pumped to a product-heating or cooling skid, for example using an off skid supply/CIP pump. The tallow is heated or cooled to a predetermined temperature, for example approximately 205° F., using a plate and frame heat exchanger, where temperature may be monitored, for example using an RTD, and flow rate may be monitored using a flow meter. At block 14, the tallow passes through a mixer and onto a holding tube skid. The tallow and water are mixed at the mixer and flow through the holding tube assembly for a predetermined retention time, shown at block 16. The mixture passes through a jacketed holding tube and associated valves on the way to a plate and frame heat exchanger, for heating or cooling to a predetermined temperature, for example approximately 205° F. The mixture is then processed to a separator. The separator separates solids (insolubles such as protein) from the tallow, shown at block 18-22. After the separator, the tallow falls into an off skid balance tank and is pumped to a tallow dryer skid. The tallow is dried, at block 24, checked for excessive water content and cooled, at block 26, before being sent to storage.
The mixing and retention time (dwell time) to combine the tallow and water is set for maximizing the suitability of the mixture for processing by the polisher. The retention time is determined such that the water and tallow are able to bond with the solids. Generally, a suitable retention time is at least approximately five minutes. Such a retention time enables the water and solids to bond such that when going through the separator, the solids are heavier and more easily separated out. In a tallow reduction apparatus, the piping and sizing may be configured to provide such a retention time. Thus, the retention time may be integrally provided while the tallow or mixture travels from one process to the next. Alternatively, holding areas may be provided for holding the tallow or mixture for the retention time before feeding the tallow or mixture to a further process.
Using the method for insoluble reduction in tallow, the color and insolubles of the product are altered. Further, with reduced moisture and insolubles, the free fatty acid (FFA) content of the product is generally stabilized and will not grow.
A method and apparatus for insoluble reduction in tallow was run in the example of which the results are shown in Table 1 below. The table gives only example results and is not intended to be limiting. Further, while the table reflects an “after” insolubles level of 0.02, the method and apparatus are generally suitable for achieving an “after” insolubles level of approximately 0.15 or less.
Overall Tallow Polishing System
As shown in
Thus, a system for insoluble reduction in tallow according to the embodiment of
A tallow tank for use in the polishing system may be provided in any suitable configuration for holding any suitable capacity. One example of a tallow tank is a 200,000 gallon tank.
First and second heat exchangers may be used for heating or cooling the tallow to a predetermined temperature. In one embodiment, the first heat exchanger brings the tallow to approximately 205° F. and the second heat exchanger brings the tallow and water mixture to approximately 205° F. The first and second heat exchangers may be configured as plate and frame heat exchangers and may be skid-mounted. A feed pump, a control panel, a modulating valve, and a mass flow meter may be associated with each heat exchanger. In some embodiments, one or both of the first and second heat exchangers may be omitted.
A mixer is provided for mixing the tallow with water (in liquid or gas form). A suitable mixer is a Westfalia ZA 40-66-905 Mixer, 3 KW/4 HP 480 volt 60 Hz 3 phase, available from Westfalia Separator, Inc. Alternatively a static mixer or other suitable mixer may be used.
A holding tube assembly 36 is provided through which the water and tallow mixture flow for a retention time. The size of the holding tube assembly 36 may be configured to provide a predetermined dwell time while the mixture flows through the holding tube assembly. In one embodiment, the size of the holding tube assembly 36 is configured to provide a dwell time of approximately five minutes. The holding tube assembly 36 may comprise two or more separate sections of jacketed hold tube connected to one another. Alternatively, the holding tube assembly 36 may comprise a single section of jacketed hold tube. In lieu of a holding tube assembly, piping may be provided for transporting the mixture from the mixer to a holding tank and from the holding tank to the separator with the holding tank holding the mixture for a dwell time.
A separator (or polisher) 38 processes the mixture and separates the solids from the tallow. The separator may include process valves, an electronic timing unit, and a motor starter. A suitable separator is a Westfalia Separator SA 100-06-177 available from Westfalia Separator, Inc. Alternatively, other suitable separators may be used. In one embodiment, the process valves include a feed, flush, discharge and air/water control unit. The timing unit may be used to monitor and sequence separator operation. A suitable electronic timing unit is an Allen Bradly PLC mounted in a NEMA 4× stainless steel enclosure. Alternatively, other suitable timing units may be used. A suitable motor starter is a Special Toshiba VFD Motor Starter mounted in a NEMA 12 carbon steel painted enclosure, 460 volt, 60 cycle, 3 phase. Alternatively, other suitable starters may be used.
In a specific embodiment, the polisher 38 is a two-phase vertical centrifuge. The polisher 38 may be configured with a mixing pump and jacketed piping to ensure contact time for a continuous flow. Other configurations of polisher may alternatively be used.
A balance tank, a pump, and a control assembly may be provided. The balance tank receives the tallow and water mixture from the separator prior to processing to the dryer. The balance tank may be skid mounted. A monitoring system may be provided to monitor the level of tallow in the balance tank and the tallow dryer, described below, and adjust flow rate of the tallow to maintain appropriate levels. The level of the balance tank may be maintained by controlling pump speed. The pump speed may be controlled, for example, using a variable frequency drive (VFD) and a high temperature pressure transmitter. The monitoring system may be skid-mounted.
A tallow dryer is provided for drying the separated tallow. The tallow dryer may be skid mounted. Flow rate to the dryer may be automatically adjusted to maintain appropriate levels in the balance tank and the dryer. The tallow dryer may be configured to lower the moisture level of the tallow after the polisher. The dryer further may be configured to automatically remove excess water from liquid tallow using a vacuum tank. Once the tallow is dried, it may be cooled using a plate and frame heat exchanger.
Tallow Polishing System
A tallow polishing system in accordance with one embodiment comprises three skid-mounted components, two off skid pumps, and one off skid balance tank. The first skid mounted system is a jacketed holding tube, the second skid mounted system is a tallow cooling skid, and the third skid mounted system is the tallow dryer. The jacketed holding tube is a component of a tallow holding system, discussed more fully below. The tallow dryer is also discussed more fully below.
Specifications for one embodiment of a tallow polishing system are provided. The specifications are exemplary only and are not intended to be limiting.
Field Piping Connections:
Field Electrical Connections:
System Includes the Following:
Item 1: Off Skid Balance Tank & Supply Pump
Item 2: Off Skid Supply/CIP PUMP
Item 3: Tallow Dryer Skid:
Item 4: Product Cooling Skid
Item 5: Holding Tube Skid
In accordance with one embodiment, the tallow holding system comprises three components: a heat exchanger and pump assembly, a holding tube assembly, and a balance tank.
The heat exchanger brings the tallow to a predetermined temperature. A feed pump processes the mixture from the heat exchanger to the holding tube assembly. A control panel, a modulating valve, and a vortex flow meter may further be provided.
The holding tube assembly provides passage from heat exchanger to the separator and also provides a dwell time for the tallow and water mixture. The duration of the dwell time may be set by adjusting the size and length of the holding tube assembly. The holding tube assembly may include two or more separate sections of jacketed hold tube. In one embodiment, the sections of jacketed hold tube are sized to provide an approximately five-minute dwell time and is approximately 1200 feet long. The 1200 feet may be provided using two sections of hold tube, each section being approximately 600 feet. Alternately, a single section of hold tube, for example a single 1200 feet section, may be used.
The balance tank receives the tallow and water mixture from the separator assembly prior to processing to the tallow dryer. The balance tank may be skid mounted. A pump and control panel assembly may be provided with the balance tank. The balance tank level may be maintained by controlling pump speed using a variable frequency drive, and a high temperature transmitter.
A monitoring system monitors the level of tallow in the balance tank and the tallow dryer and automatically adjusts the flow rate to maintain appropriate levels. The monitoring system may be skid-mounted.
Specifications for one embodiment of a tallow holding system for a system for insoluble reduction in tallow are provided. The specifications are exemplary only and are not intended to be limiting.
Item 1: Product Feed System
Item 2: Hold Tube
Item 3: Clean Product Feed System
A tallow dryer may be provided to remove excess water from liquid tallow using a vacuum tank. The monitoring system monitors the level of tallow in the balance tank and tallow dryer and adjusts the flow rate to maintain appropriate levels. Once the tallow is dried, it may be cooled using a plate and frame heat exchanger.
A main control cabinet and air enclosure may be located on the tallow dryer skid. The main enclosure controls product temperatures, flow rates, valve actuation, pump speeds, and tank levels.
Thus, as shown in
Although the invention has been described with reference to preferred embodiments, persons skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.
Number | Date | Country | |
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60599207 | Aug 2004 | US |