The sand controversy--does core sand harm your green sand? Since the 1970s, the integration of nobake binders into green sand systems has been investigated significantly. By updating a previous conclusion, closure to the dilemma might be at hand.Since 1979, the growth of chemical binders--particularly phenolic phe·no·lic adj. Of, relating to, containing, or derived from phenol. n. Any of various synthetic thermosetting resins, obtained by the reaction of phenols with simple aldehydes and used as adhesives. urethane urethane (yoor´ithān´), n ethyl carbamate used as an anesthetic agent for laboratory animals, formerly used as a hypnotic in humans. binders--has been phenomenal. Although usage of most chemical binders has increased during the last 25 years, the Years, The the seven decades of Eleanor Pargiter’s life. [Br. Lit.: Benét, 1109] See : Time use of phenolic urethane binders has grown at the fastest rate. In 1971 the U.S. metalcasting industry used only 2.7 million lbs. of coldbox and nobake phenolic urethanes. In 2003, 150 million lbs. of both resins were projected to have been consumed in the U.S. Estimated worldwide use is considered to be greater than 300 million lbs. These newer binder binder: see combine. An earlier Microsoft Office workbook file that let users combine related documents from different Office applications. The documents could be viewed, saved, opened, e-mailed and printed as a group. systems have helped to meet the increased demands of the metalcasting industry for a variety of reasons including improved dimensional accuracy, increased productivity and reduced energy consumption. However, spanning the same time period has been an ongoing controversy about the effect of recycled chemically bonded sands on green sand properties. In the 1970s, few reports were conducted on the topic. But over the last 25 years, more engineers have investigated the issue, mainly focusing on phenolic urethane binders, and in particular, whether their introduction into a green sand system affects rebonding properties. One of the earlier studies (conducted in 1979) investigated the effects of chemical binder core sand contamination on the properties of a bentonite-bonded green sand. Although the results were relevant at that time, the study was updated this year, reviewing the same tests with additional parameters. Also, the updated investigation studied three different metalcasting facilities and how phenolic urethane binders affect their green sand systems. This article examines both the 1979 and updated studies of such binders as well as results of other investigations found during this 25-year span. Binding Past Knowledge Amid further studies of phenolic urethane binders' performance, some of the investigations have contested one another. Despite this closer examination and a dichotomy di·chot·o·my n. pl. di·chot·o·mies 1. Division into two usually contradictory parts or opinions: "the dichotomy of the one and the many" Louis Auchincloss. of information, one important question remained: "What effect will core butts and shakeout Shakeout A situation in which many investors exit their positions, often at a loss, because of uncertainty or recent bad news circulating around a particular security or industry. Notes: During the dotcom boom and bust, numerous shakeouts occurred. core sands have on green sand properties as they enter a green sand molding system?" Several investigators have looked into possible chemical-related effects of core sand contamination on green sand properties. One study concluded that although specific change to a green sand system might be slight--and in some cases even advantageous--the long term effects might be grave. In those cases where an effect was noticed, it was felt that condensed con·dense v. con·densed, con·dens·ing, con·dens·es v.tr. 1. To reduce the volume or compass of. 2. To make more concise; abridge or shorten. 3. Physics a. resin distillates (a byproduct by·prod·uct or by-prod·uct n. 1. Something produced in the making of something else. 2. A secondary result; a side effect. Noun 1. of binder pyrolysis py·rol·y·sis n. Decomposition or transformation of a chemical compound caused by heat. pyrolysis (pīrol´isis), n ) impeded im·pede tr.v. im·ped·ed, im·ped·ing, im·pedes To retard or obstruct the progress of. See Synonyms at hinder1. [Latin imped the bonding effectiveness of bentonite bentonite (bĕn`tənīt'): see clay. . The effects observed were most apparent in the deterioration of both green compression and wet tensile strengths tensile strength Ratio of the maximum load a material can support without fracture when being stretched to the original area of a cross section of the material. When stresses less than the tensile strength are removed, a material completely or partially returns to its of the molding sands (Founding) a kind of sand containing clay, used in making molds. See also: Molding . Other investigations have declared the benefits of mixing, such as little-to-no difference between the rebonding characteristics of 100% recycled phenolic urethane coldbox (PUCB) process sand and new sand. A similar study revealed that 15% particulated core sand from both phenolic hot box and PUCB cores could be blended into a green sand system with minimal effect on molding properties. The loss-on-ignition (LOI LOI Letter of Indemnity (international trade and carriage business) LOI Letter Of Intent LOI Loss On Ignition LOI Letter of Inquiry LOI Lack Of Information LOI Lack of Interest LOI Letter of Invitation LOI List Of Items ) values of the particulated sands were 2.13%. A different investigation also focused on the effects of core sand dilution with PUCB binders. This study concluded that the spent PUCB sands, regardless of LOI value, had no effect on green properties of the molding sand. Still, examinations have been performed announcing that mixing core and green sands will have significant effects on molding properties. Because the curing mechanisms of all chemical binders involve various modes of acid-base catalysis catalysis Modification (usually acceleration) of a chemical reaction rate by addition of a catalyst, which combines with the reactants but is ultimately regenerated so that its amount remains unchanged and the chemical equilibrium of the conditions of the reaction is not , concern exists on how residual pH changes from shakeout core sands affect clay-bonded sand properties. Past studies have revealed that pH significantly affects green sand properties. These studies note that as the pH value of green sand increased, green compression strength decreased while dry strength, permeability permeability /per·me·a·bil·i·ty/ (per?me-ah-bil´i-te) the property or state of being permeable. per·me·a·bil·i·ty n. 1. The property or condition of being permeable. 2. and flowability increased. Reconditioning of green sand systems has been said to be one of the most difficult steps in molding-sand technology. Bentonite and water preferentially settle on the molding sand grains already coated with clay. Long and intensive mulling mulling (mul´ing), n the final step of mixing dental amalgam; a kneading of the triturated mass to complete the amalgamation. is required before recycled core sands assume the same properties as those of the base molding sand. One investigation found that incorporating lustrous lus·trous adj. 1. Having a sheen or glow. 2. Gleaming with or as if with brilliant light; radiant. See Synonyms at bright. lus carbon forming additives at high levels to improve the refractoriness of sands often leads to the build-up build·up also build-up n. 1. The act or process of amassing or increasing: a military buildup; a buildup of tension during the strike. 2. of an oily film, which further reduces bentonite swelling capacity. Lustrous carbon, several engineers have claimed, hinders green sand properties, and some note high-percentage LOI sands had such a coating. However, lustrous carbon doesn't bum 1. bum - To make highly efficient, either in time or space, often at the expense of clarity. "I managed to bum three more instructions out of that code." "I spent half the night bumming the interrupt code. in a LOI test, hence, lustrous carbon and LOI values are not related. Therefore, the intermediate LOI values were likely the result of some other pyrolysis condensate condensate, matter in the form of a gas of atoms, molecules, or elementary particles that have been so chilled that their motion is virtually halted and as a consequence they lose their separate identities and merge into a single entity. residues. If these condensates from intermediate thermal decomposition For the biological process, see Decomposition. For chemical decomposition in general, see Chemical decomposition. Thermal decomposition is a chemical reaction whereby a chemical substance breaks up into at least two chemical substances when heated. levels produce a slippery or oily film on the sand grains, then one would expect to see reduced ability for bentonites to bond to sand surfaces. This may be partially overcome by additional mulling. The pH and lustrous carbon dilemmas will be discussed later in this article. In addition to chemical contamination See: contamination. , another factor affecting green sand properties is the physical effect from additional core sand entering a green sand system. These sands may be more difficult to mull Mull, island, 351 sq mi (909 sq km), Argyll and Bute, NW Scotland, largest island of the Inner Hebrides, separated from the mainland by the Sound of Mull and the Firth of Lorn. with bentonite if they contain pyrolysis condensate residues. If appropriate tests are not run to make up for deficiencies in bentonite content, loss of bonding properties could result. Then and Now By updating the research from 25 years ago, a more detailed approach can be taken in regards to this controversial topic. The 1979 study dealt exclusively with residual chemical effects, such as acidity acidity /acid·i·ty/ (-i-te) the quality of being acid; the power to unite with positively charged ions or with basic substances. a·cid·i·ty n. The state, quality, or degree of being acid. and basicity contributions from recovered shakeout sand. It did not examine physical interactions, such as pyrolysis condensate residues on sand grain surfaces and/or condensate residues on bentonite particles from binder decomposition decomposition /de·com·po·si·tion/ (de-kom?pah-zish´un) the separation of compound bodies into their constituent principles. de·com·po·si·tion n. 1. . That study showed that recycled nobake core sand additions tip to a 50% substitution rate and after exposure to casting temperatures had little-to-no effect on green sand properties. In all cases, optimum green sand properties were achieved after 25 min. of mulling. With a few exceptions, green sand properties, such as compactability and green compressive strength Compressive strength is the capacity of a material to withstand axially directed pushing forces. When the limit of compressive strength is reached, materials are crushed. Concrete can be made to have high compressive strength, e.g. , for the bentonite-bonded coldbox recycled shakeout sand were essentially equivalent to those of the new base sand. Although some slight shifts in performance were observed, these deviations were usually within one standard deviation In statistics, the average amount a number varies from the average number in a series of numbers. (statistics) standard deviation - (SD) A measure of the range of values in a set of numbers. of the average base green sand system properties. In the current study, the results from 1979 were reviewed to determine the effect of deliberate additions of re cycled shakeout core sands and the effects on the properties of the new bentonite-bonded molding sand. To investigate these effects, varying amounts of recycled nobake sands were added to fresh sand mixtures to determine possible interactions between the recycled core sand and new sand system. Green compressive strength, shear strength For the shear strength of soil, see . Shear strength in engineering is a term used to describe the strength of a material or component against the type of yield or structural failure where the material or component fails in shear. , compactability and permeability were measured in an attempt to determine potential chemical interactions. Other properties measured were moisture, available clay, mean available clay and bonding clay contents. The procedure used was divided into two phases. The first phase consisted of generating shakeout sand from chemically bonded molds after performing casting trials. The second phase evaluated the effects of the recycled sands when added in various proportions to a new sand-clay-water mixture. The sand was a blend of new sand and recycled core sands obtained during casting shakeout. Recycled core sand contaminant contaminant /con·tam·i·nant/ (kon-tam´in-int) something that causes contamination. contaminant something that causes contamination. levels of 1%, 5%, 10%, 25%, 50% and 100% were evaluated. (The 1979 research did not include contaminant levels of 1% and 100%). The Current Event With the addition of the 1% and 100% contaminant levels, one finding was as noticeable in the current study as in 1979--almost all of the binder systems for the various properties stud led were found to be within a standard deviation of i (Tables 1-7). This proves that the properties of a contaminated contaminated, v 1. made radioactive by the addition of small quantities of radioactive material. 2. made contaminated by adding infective or radiographic materials. 3. an infective surface or object. system are similar to those of a standard base green sand system. The only property where more than two binder systems exceeded the 1 standard deviation level was permeability, which had a standard deviation of 10 (Table 8). Tables 9 and 10 examine various properties of recycled core sand and new green sand. When this investigation was moved to three metalcasting facilities (A, B and C) the results were all similar. Facilities A and B, both of which use rigid flasks, run nearly identical green sand properties, whereas facility C, which utilizes vertically parted molds, requires more robust green sand properties. Even though two entirely different base sands were used at facilities A and B, the physical properties of the green sand system were remarkably similar. Facilities B and C reported that PUCB shakeout sand re-entering their green sand systems did not present any problems. Both PUCB shakeout sands had relatively low LOI values and both facilities treated spent PUCB shakeout sand entering the sand system as a new sand addition; they added the appropriate amount of bond and water to compensate for the PUCB sands. These findings are likely clue to the fact that facilities B and C use aromatic aromatic /ar·o·mat·ic/ (ar?o-mat´ik) 1. having a spicy odor. 2. in chemistry, denoting a compound containing a ring system stabilized by a closed circle of conjugated double bonds or nonbonding electron pairs, e.g. and aliphatic aliphatic /al·i·phat·ic/ (al?i-fat´ik) pertaining to any member of one of the two major groups of organic compounds, those with a straight or branched chain structure. al·i·phat·ic adj. solvents, which are normally associated with PUCB systems. On the contrary, facility A used a system based on bio-diesel solvents due to a "brittle-sand" condition that resulted in casting surface deterioration. After converting to the new system, the facility no longer needed to add new sand to the green sand system to restore properties and, like facilities B and C, did not report any green sand property deterioration. Truth Be Told By evaluating the reports from the three facilities as well as the updated laboratory research, these investigations advance the argument that nobake sands do not significantly affect molding characteristics of a green sand system. pH level--Even though certain nobake binders may contain strong acids or bases in either the resin or the catalyst, it is evident that after the binders have undergone curing and casting, they impart very little of their original acidic acidic /acid·ic/ (ah-sid´ik) of or pertaining to an acid; acid-forming. acidic, adj having the properties of an acid; acid-forming properties. or basic character to the reclaimed sand. When such sands enter into a green sand molding system, they do not significantly reduce the bonding effectiveness or molding properties of bentonite clays in the mix, thus, there is no correlation between residual pH and green properties. There are several reasons why residual binders on reclaimed nobake sand do not impart appreciable ap·pre·cia·ble adj. Possible to estimate, measure, or perceive: appreciable changes in temperature. See Synonyms at perceptible. acidic or basic impurity im·pu·ri·ty n. pl. im·pu·ri·ties 1. The quality or condition of being impure, especially: a. Contamination or pollution. b. Lack of consistency or homogeneity; adulteration. c. functionality to a green sand system. In some cases, dining the curing reaction between resin and catalyst, acidic or basic sub stances react to form neutral salts, which are relatively non-reactive with bentonite clays. In addition, acidic or basic catalysts in a nobake system are normally used in such small amounts that after casting and reclamation, only a minimal amount of residual catalyst remains on the sand. It appears likely that in instances where there have been reports of decreased green sand properties because of suspected PUCB contamination, pyrolytic py·rol·y·sis n. Decomposition or transformation of a compound caused by heat. py  ro·lyt condensate residues on either sand grain surfaces or bentonite
particles, from incomplete pyrolysis, may affect resultant green sand
properties. These condensates may impede im·pede tr.v. im·ped·ed, im·ped·ing, im·pedes To retard or obstruct the progress of. See Synonyms at hinder1. [Latin imped file swelling action of bentonite and, for a given mulling time, the smearing Smearing is a term used in rock climbing. It is the practice of using the sole of a shoe against a flat rock face. Smearing can be one of the most insecure and technical techniques used in climbing, requiring a combination of leg/ankle tension, foot placement, and good action of bentonite particles needed to develop green sand properties. Lustrous Carbon--Lustrous carbon defects have been blamed as a cause of many contamination problems. Some investigators of core sand contamination have concluded that lustrous car ban is one cause of reported deterioration green sand molding properties. Lustrous carbon, a brittle (jargon) brittle - Said of software that is functional but easily broken by changes in operating environment or configuration, or by any minor tweak to the software itself. Also, any system that responds inappropriately and disastrously to abnormal but expected external stimuli; e. material measuring 0.0001 in., forms at the mold-metal interface in binder systems that contain high levels of carbon and relatively low levels of oxygen. It cannot coat sand grain surfaces. As additional metal flows into the mold, these films may become dislodged and be flushed ahead of the leading edge of the incoming metal stream. If the films are not dissolved in the metal or oxidized oxidized having been modified by the process of oxidation. oxidized cellulose see absorbable cellulose. , solidification so·lid·i·fy v. so·lid·i·fied, so·lid·i·fy·ing, so·lid·i·fies v.tr. 1. To make solid, compact, or hard. 2. To make strong or united. v.intr. can proceed against these accumulations, resulting in surface wrinkling characteristics of lustrous carbon defects. However, the lustrous carbon-forming tendencies of certain chemical binders are harmful only if large amounts of carbon films form and then are dislodged from the mold-metal interface during pouring. When this happens, wrinkling and surface laps result. If the lustrous carbon films are not dislodged during filling of the mold cavity, lustrous carbon formation may actually improve casting surface finish. As such, the deposits do not have a LOI value be cause they will not burn in a traditional LOI test. Based on the proposed mechanism of lustrous carbon formation, lustrous carbon films from PUCB binders cannot be responsible for some reports of diminished green sand properties, if and when green sand properties deteriorate from PUCB binders, it probably results from unique thermal circumstances occurring within the core during casting, not lustrous carbon. Such problems may be overcome by employing longer mulling cycles. Useful Sand to the Core Despite the 25 controversial years regarding green sand contamination, this recent investigation augments the theory that both recycled core and green sands are compatible in the same system. Although this study showed that reclaimed nobake core sand had little acidic or basic interaction with bentonite clays, such sand should be treated as new, unbonded sand. However, there are a number of methods that may be used if green sand properties need to be restored. These include: * increasing mulling time; * increasing western bentonite levels; * increasing mold venting to help release gaseous gas·e·ous adj. 1. Of, relating to, or existing as a gas. 2. Full of or containing gas; gassy. decomposition products; * reducing binder content in cores; * scalping scalping, taking the scalp of an enemy. The custom, comparable to head-hunting, was formerly practiced in Europe and Asia (Herodotus describes its practice by the Scythians, for example), but it is generally associated with North American natives, although many such or removing core butts from the shakeout system; * if possible, reducing core weight to provide higher levels of thermal breakdown. Other factors that metalcasters using PUCB binders should consider are that, in the investigation, PUCB binders formulated with aromatic and aliphatic solvents generally did not result in green sand property deterioration. In instances where the deterioration of green sand properties is linked to the use of standard PUCB binders, the facility should consider coldbox binder systems that use bio-diesel solvents. Further, appropriate additions of new bentonite clay and water should be made to adjust total clay back to its original value. Thermal conditions within the mold may result in incomplete combustion of PUCB decomposition gases during pouring. Condensate residues generated from such conditions may inhibit the ability of bentonite particles to effectively coat sand grains. Lastly, past studies have claimed the addition of small amounts of sodium carbonate sodium carbonate, chemical compound, Na2CO3, soluble in water and very slightly soluble in alcohol. Pure sodium carbonate is a white, odorless powder that absorbs moisture from the air, has an alkaline taste, and forms a strongly alkaline water or soda ash soda ash: see sodium carbonate. ([Na.sub.2]C[O.sub.3]) to a bentonite green sand system has helped improve the bonding action of bentonite clays as well as soda ashes' ability to cleanse cleanse tr.v. cleansed, cleans·ing, cleans·es To free from dirt, defilement, or guilt; purge or clean. [Middle English clensen, from Old English sand grain surfaces. Although green sand systems might falter as a result of other conditions, after this thorough examination, no indication was found that recycled chemically bonded sands have any deleterious deleterious adj. harmful. effect on the properties of a green sand system.
Table 1. Moisture Content of New/Recycled Sand Blends
% Contamination
Binder System 1% 5% 10% 25% 50% 100%
FNB-Phos 2.70 2.72 2.82 2.74 2.84 2.72
FNB-TSA 2.94 2.86 2.88 2.86 2.88 2.88
FNB-BSA 3.00 2.96 2.74 2.82 3.00 2.80
Phenolic Nobake 2.70 2.64 2.76 2.94 3.00 2.85
Phenolic Urethane 2.96 2.96 2.96 2.82 2.84 2.70
Silicate Nobake 3.00 2.84 3.00 2.98 3.00 2.86
% Contamination
Binder System Average Std. Dev.
FNB-Phos 2.76% 0.05%
FNB-TSA 2.88% 0.03%
FNB-BSA 2.89% 0.10%
Phenolic Nobake 2.82% 0.13%
Phenolic Urethane 2.87% 0.10%
Silicate Nobake 2.95% 0.07%
Standard Green Sand System Moisture Content: 2.87% [+ or -] 0.11%
Table 2. Available Clay Content of New/Recycled Sand Blends
(Determined from IMC Charts)
% Contamination
Binder System 1% 5% 10% 25% 50% 100%
FNB-Phos 5.50 5.60 5.60 5.30 6.10 5.50
FNB-TSA 5.60 5.30 5.70 5.80 5.70 5.80
FNB-BSA 6.00 6.10 5.60 5.70 6.00 6.20
Phenolic Nobake 5.80 5.50 5.70 6.10 6.10 6.00
Phenolic Urethane 5.70 6.00 6.00 5.80 5.70 5.50
Silicate Nobake 6.00 6.00 6.20 6.10 6.00 6.50
% Contamination
Binder System Average Std. Dev.
FNB-Phos 5.60% 0.24%
FNB-TSA 5.65% 0.17%
FNB-BSA 5.93% 0.21%
Phenolic Nobake 5.87% 0.22%
Phenolic Urethane 5.78% 0.18%
Silicate Nobake 6.13% 0.18%
Standard Green Sand System Available Clay: 5.8% [+ or -] 0.20%
Table 3. Bonding Clay Content of New/Recycled Sand Blends
% Contamination
Binder System 1% 5% 10% 25% 50% 100%
FNB-Phos 3.20 3.60 3.60 3.20 3.90 3.30
FNB-TSA 3.10 3.30 3.00 3.80 3.50 3.60
FNB-BSA 3.80 3.90 3.50 3.40 4.10 4.40
Phenolic Nobake 3.90 3.70 3.80 4.00 3.80 4.10
Phenolic Urethane 3.90 4.00 4.10 3.80 3.70 4.10
Silicate Nobake 4.00 3.90 4.00 3.70 3.60 3.90
% Contamination
Binder System Average Std. Dev.
FNB-Phos 3.47% 0.26%
FNB-TSA 3.38% 0.28%
FNB-BSA 3.85% 0.34%
Phenolic Nobake 3.88% 0.13%
Phenolic Urethane 3.93% 0.15%
Silicate Nobake 3.85% 0.15%
Standard Green Sand System Bonding Clay: 3.90% [+ or -] 0.10%
Table 4. Available Clay Content of New/Recycled Sand Blends
(Determined by Methylene Blue Titration)
% Contamination
Binder System 1% 5% 10% 25% 50% 100%
FNB-Phos 7.60 7.80 8.00 7.60 8.00 7.60
FNB-TSA 7.80 7.80 7.80 7.80 8.00 7.80
FNB-BSA 8.00 7.60 8.00 7.80 7.80 7.80
Phenolic Nobake 7.60 7.60 7.40 7.80 7.60 8.00
Phenolic Urethane 7.80 7.80 7.80 7.60 7.80 7.60
Silicate Nobake 8.20 8.20 8.60 8.60 8.40 8.60
% Contamination
Binder System Average Std. Dev.
FNB-Phos 7.80 0.18
FNB-TSA 7.84 0.08
FNB-BSA 7.80 0.13
Phenolic Nobake 7.68 0.20
Phenolic Urethane 7.72 0.10
Silicate Nobake 8.48 0.16
Standard Green Sand System Available (MB) Clay: 7.8% [+ or -] 0.20
Table 5. Effect of Core Sand Contamination on Compactability
% Contamination
Binder System 1% 5% 10% 25% 50% 100%
FNB-Phos 46.00 46.00 55.50 48.00 48.00 47.25
FNB-TSA 52.00 53.00 50.00 51.00 50.00 47.25
FNB-BSA 49.50 49.75 48.50 49.75 49.00 45.75
Phenolic Nobake 50.00 48.75 50.00 47.50 46.75 42.50
Phenolic Urethane 53.00 52.75 51.00 50.75 49.50 47.00
Silicate Nobake 53.00 51.00 46.25 44.75 46.25 33.75
% Contamination
Binder System Average Std. Dev.
FNB-Phos 48.46 3.25
FNB-TSA 50.54 1.82
FNB-BSA 48.71 1.40
Phenolic Nobake 47.58 2.57
Phenolic Urethane 50.67 2.03
Silicate Nobake 45.83 6.13
Standard Green Sand System Compactability: 54% [+ or -] 4%
Table 6. Effect of Core Sand Contamination on Green
Compression Strength
% Contamination
Binder System 1% 5% 10% 25% 50% 100%
FNB-Phos 19.00 19.30 17.50 16.90 21.00 17.35
FNB-TSA 15.65 16.40 17.20 19.30 18.05 19.05
FNB-BSA 18.95 20.90 18.00 17.70 18.87 24.20
Phenolic Nobake 20.50 19.95 19.75 21.50 20.65 22.50
Phenolic Urethane 18.65 19.20 21.20 19.40 19.00 16.65
Silicate Nobake 19.80 20.13 21.95 19.93 19.50 24.85
% Contamination
Binder System Average Std. Dev.
FNB-Phos 18.51 1.42
FNB-TSA 17.61 1.33
FNB-BSA 19.77 2.23
Phenolic Nobake 20.81 0.94
Phenolic Urethane 19.02 1.33
Silicate Nobake 21.03 1.88
Standard Green Sand System Green Compression Strength: 19.0
psi [+ or -] 1.0 psi
Table 7. Effect of Core Sand Contamination on Green Shear Strength
% Contamination
Binder System 1% 5% 10% 25% 50% 100%
FNB-Phos 4.80 4.90 5.50 3.60 5.40 4.50
FNB-TSA 4.35 5.30 4.10 5.15 5.05 5.00
FNB-BSA 4.70 5.27 4.57 5.37 5.27 5.90
Phenolic Nobake 5.50 6.45 5.20 5.60 5.10 4.75
Phenolic Urethane 4.35 5.60 5.60 5.20 5.70 4.50
Silicate Nobake 5.75 5.75 5.65 5.45 4.93 5.00
% Contamination
Binder System Average Std. Dev.
FNB-Phos 4.78 0.63
FNB-TSA 4.83 0.44
FNB-BSA 5.18 0.44
Phenolic Nobake 5.43 0.53
Phenolic Urethane 5.16 0.54
Silicate Nobake 5.42 0.34
Standard Green Sand System Green Shear Strength: 5.10 psi [+ or -]
0.70 psi
Table 8. Effect of Core Sand Contamination on Permeability
% Contamination
Binder System 1% 5% 10% 25% 50% 100%
FNB-Phos 112.00 112.00 117.00 82.00 94.00 72.00
FNB-TSA 103.00 100.00 85.00 91.00 85.00 78.00
FNB-BSA 91.00 91.00 88.00 83.00 94.00 75.00
Phenolic Nobake 110.00 112.00 112.00 111.00 97.00 85.00
Phenolic Urethane 113.00 114.00 108.00 108.00 111.00 77.00
Silicate Nobake 102.00 105.00 98.00 107.00 109.00 79.00
% Contamination
Binder System Average Std. Dev.
FNB-Phos 98.17 16.84
FNB-TSA 90.33 8.79
FNB-BSA 87.00 6.35
Phenolic Nobake 104.50 10.18
Phenolic Urethane 105.17 12.80
Silicate Nobake 100.00 10.03
Standard Green Sand System Permeability Index: 107 [+ or -] 10.0
Table 9. Recycled Shakeout Core Sand Properties
Loss on
Core Sand System Contaminant pH ADV Ignition (%)
Furan Nobake--Phosphoric acid 2.8 -15.2 0.81
Furan Nobake--Toluene Sulfonic acid 4.3 +3.2 0.78
Furan Nobake--Benzene Sulfonic acid 5.2 +4.0 1.08
Phenolic Nobake--Benzene Sulfonic acid 5.2 +5.2 1.03
Phenolic Urethane Nobake (PUN) 7.0 +3.8 0.62
Silicate Nobake (SNB) 8.5 +5.4 0.17 *
New Sand Base Reference 6.3 +3.0 0.06
* Conventional LOI determination is not
applicable to inorganic systems.
Table 10. Standard New Green Sand Properties
Property Average Value Standard Deviation
Moisture 2.87% 0.11
Bonding Clay 1 3.9% 0.10
Available Clay 1 5.8% 0.20
Available (MB) Clay 2 39 ml 1
Green Shear 5.1 psi 0.7
Green Compressive 19 psi 1
Permeability 107 10
Compactability 54 4
Base Sand System Parameters: 3% moisture, 6% seacoal,
8% Western Bentonite, 10 minute mulling time
1--From IMC Sand-Clay-Water Control Charts
2--Determined from Methylene Blue Titration
This article was adapted from paper (04-001) presented at the 2004 Metalcasting Congress For more information "Evaluating Refractory refractory Material that is not deformed or damaged by high temperatures, used to make crucibles, incinerators, insulation, and furnaces, particularly metallurgical furnaces. Coatings for PUCB Binders: A Practical Approach," S.G. Baker, 2002 AFS A distributed file system for large, widely dispersed Unix and Windows networks from Transarc Corporation, now part of IBM. It is noted for its ease of administration and expandability and stems from Carnegie-Mellon's Andrew File System. AFS - Andrew File System Transactions paper No. 02-026. "Influence of Nobake Core Sand Contamination on the Properties of Green Molding Sands," R.L. Naro, T. Zeh and J. Plummet, 1979 AFS Transactions, vol. 98, p. 39-46. Dr. Bodney L. Naro is the president and CEO (1) (Chief Executive Officer) The highest individual in command of an organization. Typically the president of the company, the CEO reports to the Chairman of the Board. of ASI ASI, n See Anxiety Sensitivity Index. International Ltd, Cleveland. He recently received the AFS Joseph S. Seaman SEAMAN. A sailor; a mariner; one whose business is navigation. 2 Boulay Paty, Dr. Com. 232; Code de Commerce art. 262; Laws of Oleron, art. 7; Laws of Wishuy, art. 19. The term seamen, in it most enlarged sense, includes the captain a well as other persons of the crew; in a more confined Gold Medal gold medal traditional first prize. [Western Cult: Misc.] See : Prize for technical contributions to the metalcasting industry. |
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