Krosnies grandinių skystis
Krosnies grandinių vandens grafito dispersija
Grafito kiekis, %
Tankis, prie 15ºC, kg/m3
Vanduo / Sint POE + graft
Grafito tepiklių vandeninė dispersija,
suteikianti saugų ir efektingą atskirimo sutepimą, šalinanti lydomos ar kaitinamos produkcijos prilipimus prie grandinių ir įrankių. Aukštatemperatūrinėms, per ugnį einančioms krosnių grandinėms. Kaip kalvystės ar liejinių gamybos krosnių grandinių skystis.
Atskiedus demineralizuotu vandeniu santykiu 1:5 to 1:10, tepti rankiniu būdu ar automatine purškimo sistema. Kai kuriais atvejais atskiedimas didesniu santykiu iki 1:30 - 1:40 taip pat gali duoti gerus rezultatus.
Apdeginimo krosnies grandinės tepimas
Universalios laboratorinės aukšto tikslumo elektrinės krosnys (L-durys atsidaro į kairę, LZ-durys atsidaro žemyn, LH-durys atsidaro į viršų) skirtos medžiagų ir žaliavų kaitinimui arba džiovinimui. Šių krosnių keramikinė kamera atspari mechaniniams poveikiams. Jėgos grandinės valdimui, krosnių konstrukcijoje, naudojamos puslaidininkinės rėlės suteikia unikalia galimybę tiksliai valdyti sudėtingus terminius procesus. Krosnys gali būti naudojamos mokslinėse laboratorijose, mokymo įstaigose, medicinoje ir pramonėje.
Darbinė temperatūra kamerose 900ºC,
Kameros kaitinamos iš keturių pusių;
Kaitinimo elementai yra keramikinės kameros grioveliuose (atviri arba uždari);
Keramikinė kamera atspari mechaniniams pažeidimams;
Kameros izoliacinės medžiagos sudėtis padidinto atsparumo cheminių elementų poveikiui;
Aukštos kokybės termoizoliacinės medžiagos;
Durų saugos jungiklis;
Dviguba apsauga nuo perkrovos ir trumpo jungimo;
Keramikinė padinė plokštė;
Improving Oven Chain Lubrication
Chains operating at high temperatures can be lubricated in two different ways: with a liquid lubricant, or with a solid lubricant suspended in a carrier fluid. Whether solid or liquid, the lubricating film physically separates contacting metal surfaces, thereby reducing friction and wear.
Fluid Film Lubrication
Fluid film lubrication is the regular oil film lubrication used in most ambient temperature applications. This type of lubrication can also be used at higher temperatures, provided that you take into account the decreased viscosity of the fluid (thinner oil film), the increased oxidation rate of the oil (can leave varnish and sludge), and the volatility of the oil (as it evaporates, there is less oil with which to lubricate).
A variety of synthetic base oils (polyalphaolefins [PAO], esters, silicones) enable lubrication at higher temperatures than petroleum oils. They have the same limitations (thinning out, oxidizing and evaporating) as petroleum oils, just at higher temperatures.
At higher operating temperatures, frequent lubrication is required to replace the fluid lost to evaporation. The evaporation, oxidation and decrease in viscosity make proper lubrication difficult to achieve with a liquid lubricant alone. In such cases, using a solid lubricant provides better wear protection and consumes less lubricant.
Table 1. Various Technologies 2,3,4,5
Solid Film Lubrication
Solid film lubrication is used at high temperatures or in applications where it is impossible or undesirable to use a liquid. The solid is usually suspended in a liquid carrier designed to disperse (evaporate) after the lubricant has been applied and, in the case of chains, after it has penetrated in to the pin area of the chain. The example that most people are familiar with is graphite powder dissolved in kerosene, but technology has advanced well beyond this.
Solid lubricants provide a smooth, low-drag surface, which reduces friction, wear, operating temperatures and electrical energy consumption.
The choice of the specific type of solid lubricant technology has an enormous impact on performance and should not be taken lightly. Materials commonly used as solid lubricants include molybdenum disulfide (MoS2), graphite (C), fluorocarbon polymers such as polytetrafluoroethylene (PTFE, commercially known as Teflon), metallic oxides, and a highly refined powder of aluminum, magnesium and silicate (commercially known as Almasol). Table 1 shows a comparison of these technologies.
On a microscopic level, all metal surfaces are uneven and have high and low spots. The high points, called asperities, on opposing working surfaces meet under heavily loaded conditions and the instantaneous contact temperatures of these asperities often exceed 1,000°F. Pressures in the contact zone can also exceed 175,000 psi.1 Only the Al-Mg-Si technology meets these needs and remains inert and intact under these extremes of temperature and load.
Neither graphite nor PTFE has sufficient load-carrying capacities, and "moly" becomes abrasive, which causes wear. Consequently, NASA has used the Al-Mg-Si solid film technology on every manned U.S. space flight including the lunar landings and the space shuttle.6,7
The size and the morphology of the particles of the Al-Mg-Si powder are carefully controlled. These particles are platelets, which form a single-layer coating on the surface of the metal through particulate attraction. These particles carry the load when the hydrodynamic oil film is gone (squeezed out or evaporated off), preventing metal-to-metal contact.
Figure 1. Tortilla Chips Entering Casa Herrera Tunnel Oven
Reduction in Friction
The reduction in friction translates into less wear, cooler operating temperatures and smaller electricity bills. The energy savings alone typically pay for the lubricant several times over. The most noticeable differences are the elimination of squealing and screaming of the chains. Another benefit is that the Al-Mg-Si powder does not build up on itself or make a mess like graphite does.
Different carriers allow the solid lubricant to be applied at different temperatures. For room-temperature application, light carriers such as kerosene are used. But if the chains are hot, the low flash point of these fluids is a fire hazard, so a variety of synthetic carriers are employed.
The best ones are smokeless and odorless. Unlike lubricants that rely on the fluid to provide the lubrication film, the evaporation rate of these products should be high rather than low because the oil is only a carrier to take the solids to where they are needed - inside the pin and bushing area.
In severe applications, the chain can be lubricated both when it is hot and when it is cool by using the same solid lubricant but with two different carrier fluids. This is exactly what is done at a major light bulb plant in Canada. A low flash point chain lubricant containing Al-Mg-Si is applied during downtime between production runs, when the chain is cool.
The light carrier ensures proper penetration into the links of the chain at these cool temperatures. During extended production runs, a smokeless, odorless, high flash point chain lubricant is applied to the hot chain as required. Because the chain is hot, this heavier carrier rapidly thins out and penetrates into the pin area of the chain.
When using lubricants containing suspended solids, it is important to agitate them before application. Many plants apply them to oven chains by hand using a garden hand sprayer (the type you pump, shake and spray) and apply them only once every week or two. There are also automatic lubrication systems, which circulate or agitate the fluid (to keep the solids in suspension) and then spray the fluid to the appropriate points on the chain.
When switching over from a liquid film lubricant or when lubricating a new chain, the chain needs to be impregnated with the solid lubricant, initially requiring frequent application. Once the solids are in the chain, additional lubricant is required only to replenish the lost solids, and the amount of lubricant can be reduced significantly.
The frequency and amount of lubricant required depends on the temperature and other aspects of the operation, but in general, you should start lubricating every other day and extend lubrication intervals from there. Because most bakeries apply lubricant on the weekends when the chains are cold, they typically apply a solid lubricant in a light carrier once a week, then extend this to once every two or three weeks. If you use a drip system, you will have to apply the lubricant more frequently because it applies less lubricant at a time.
Another way of optimizing the lubrication frequency and amount is to measure the amperage required to drive the chain. As the lubricant gets depleted, the friction increases, using more electricity. This provides a useful feedback loop indicating that more lubricant is required. This is also a great way to evaluate chain lubricants, because the better they work, the lower the amperage draw will be.
A large bakery in Argentina, Bimbo de Argentina, operates Stewart ovens with skate wheel chains operating at more than 200°C (392°F). The chains are lubricated with a centralized system. By changing the type of chain lubricant, personnel eliminated buildup on the chains, recorded significant amperage drops and reduced the amount of lubricant applied. The starting amperage dropped from four amperes (amps) to two amps, and the operating amperage dropped from between 0.70 and 0.90 amp to between 0.50 and 0.80 amp.
Rainbow Powder Coaters Ltd. in Auckland, New Zealand has an overhead bi-planar chain passing through on-line pretreatment, powder booth and gas oven. The paint is cured at 190 to 210°C (375 to 410°F), so the overhead chain is exposed to a variety of conditions. Its carbon buildup and wear caused jerky, noisy operation of the line.
To fix it would require pulling out the chain, costing at least three days downtime plus solvent, and building a soak-trough. Faced with this costly alternative, personnel were open to trying a more technologically advanced chain lubricant to clean and lubricate the chain without stopping production. The chain ran smoothly and remained clean.
"I remember you came in when I was very busy with the most expensive oil I've ever seen and told me it would clean my chain. I didn't believe it could be done. You did a good job. The chain hasn't stopped, there is no mess and it has saved us thousands of dollars," said owner Brian Barton.
Bluebird Baking company is located in Detroit, Mich. It produces a variety of baked goods, including hotdog and hamburger buns, using Wilco tunnel ovens. The company was experiencing heavy carbon deposits on its chains and even on some of its baked goods. In 1989, the bakery decided to try an oven chain lubricant containing the Al-Mg-Si technology.
The change in lubricant resulted in a 26 percent reduction in power consumption, from 4.60 amps to 3.40 amps. This 1.2-amp reduction amounts to more than $288 per year in energy saving on just one Wilco oven. The new lubricant also cleaned up the deposits from the chains.
At Mary Ann's Baking Company in Sacramento, Calif., similar results were observed on its Chubco Super-Flo oven. Amp meter readings on the oven dropped almost 40 percent after converting to the Al-Mg-Si oven chain lubricant.
At the Philips light bulb plant in Weert, The Netherlands, the life of oven chains was substantially increased by switching to the Al-Mg-Si technology, saving at least six hours of downtime at 4,200 lamps per hour.
The Rold Gold Foods division of Frito-Lay Inc. in Canton, Ohio produces a variety of pretzels. One of its ovens has a chain drive kiln screen used in the baking process. The commercial-grade lubricant in use had a graphite base, was black and messy.
If this lubricant was not applied on a regular weekly basis, the chains would bind up, which in turn tripped the main power for the oven and shut down production. This problem occurred six to eight times a year. Temperatures of the oven where the chains pass through are 475°F, with pretzel dust and salt present.
Since switching from graphite to Al-Mg-Si, Rold Gold has never had a power failure due to buildup of graphite or lack of lubrication. The company uses less lubricant than with the old chain lubricant used in the past, and they appreciate the improved cleanliness of the chains.
Significant operational efficiencies can be achieved by selecting chain lubricants and application methods that match the specific operating environment and failure mode of the chain.
As illustrated by several case studies, an application-specific chain lubricant designed to combat the enemy (water, dust, heat, etc.) saves a considerable amount of money in downtime, cleaning, lubrication, repairs, replacement chain and even electricity. Consider the factors that shorten your chain life and what are you're going to do to prevent them.
About the Author
Jeffrey E. Turner is executive vice president for Lubrication Engineers, Inc. Company information can be found at www.le-inc.com.