Window unit cleaning often involves more than just wiping down the exterior. For a truly deep clean, especially if youre battling persistent mustiness or reduced cooling efficiency, disassembly and component cleaning is the way to go. While it might seem daunting, breaking down a window AC unit is usually fairly straightforward, involving basic tools and a bit of patience.
The process begins with safety. Always unplug the unit before you start! Then, depending on your model, youll typically remove the front grill and filter, often secured by clips or screws. Behind this, youll find the evaporator coil, a prime breeding ground for dust, mold, and other allergens. Carefully vacuum the coil with a brush attachment and then wash it with a specialized coil cleaner or a mild detergent solution. Rinse thoroughly and allow it to dry completely.
Next, youll likely encounter the fan. This can often be removed for easier cleaning. Wipe down the fan blades and motor housing, removing any built-up grime. Other components, like the condensate drain pan, should also be cleaned and checked for blockages. A clogged drain can lead to water leaks and further mold growth.
While you have the unit apart, its a good opportunity to inspect other parts. Check the power cord for damage and ensure all connections are secure. If you notice any signs of wear and tear, its best to consult a professional.
Reassembly is simply the reverse of the disassembly process. Make sure everything is securely back in place before plugging the unit back in. By taking the time to disassemble and clean your window units components, youll not only enjoy cleaner, fresher air but also improve its efficiency and prolong its lifespan. Plus, youll have the satisfaction of knowing you tackled a DIY project and won!
Coil cleaning and fin straightening are crucial steps in window unit cleaning that often get overlooked. Sure, wiping down the outside and changing the filter are important, but deep down in the guts of your AC unit, the coils and fins are working hard, and they need some TLC too. Think of it like this: you wouldnt just wash your face and call yourself clean, would you? Youd brush your teeth, floss, the whole nine yards. Your window unit deserves the same comprehensive care.
The coils, those snaking metal tubes, are responsible for absorbing the heat from your room. Over time, they accumulate dust, pet dander, pollen, and all sorts of airborne gunk. This buildup acts like an insulating blanket, preventing the coils from effectively absorbing heat. The result? Your AC has to work harder, using more energy and potentially shortening its lifespan. Cleaning the coils allows them to breathe again, restoring efficiency and saving you money on your energy bill.
Then there are the fins, those delicate metal pieces that surround the coils. They facilitate heat transfer by increasing surface area. However, these fins are easily bent, whether from accidental bumps during cleaning or simply the force of air blowing through them. Bent fins obstruct airflow, again reducing efficiency and putting extra strain on the unit. Straightening the fins allows for optimal airflow, maximizing the units cooling power.
So, while it might seem like a minor detail, coil cleaning and fin straightening are essential for keeping your window unit running smoothly and efficiently. Its a bit more involved than just a surface wipe, but the payoff in terms of performance and longevity is well worth the effort. Think of it as an investment in your comfort and your wallet.
Reassembling your window AC unit after a thorough cleaning can feel a bit like putting together a 3D puzzle, especially if you werent meticulous about noting where everything went. But dont worry, with a little patience and a systematic approach, youll have cool air blowing again in no time. The key is to reverse the disassembly process.
Start by sliding the evaporator coil back into the main housing, making sure it sits properly and connects with any drainage channels or tubes you disconnected. These connections are crucial for proper water drainage and preventing leaks inside your room. Next, reattach any wiring you disconnected, ensuring a snug and secure fit. Loose connections can lead to malfunctions or even safety hazards. Dont force anything – if a connection feels resistant, double-check that youre aligning it correctly.
Now, carefully position the front panel back onto the unit, ensuring it aligns with the clips or screws that hold it in place. Dont forget to reattach the filter, which you hopefully cleaned while the unit was disassembled. A clean filter is essential for efficient cooling and improved air quality. Finally, slide the unit back into the window frame and secure it according to the manufacturer's instructions.
Before plugging the unit back in, give it a visual once-over. Did you remember all the screws? Are the panels flush and securely attached? Taking a few extra seconds to double-check can save you from headaches down the road.
Once youre confident everything is back in its rightful place, plug in the unit and turn it on. Listen for any unusual noises, like rattling or grinding, which could indicate a loose part or improper assembly. Check for leaks around the unit and feel the air coming out – it should be noticeably cooler than the room temperature. If everything seems to be working correctly, congratulations! Youve successfully reassembled your window unit and are ready to enjoy a refreshing, cool environment. If not, dont hesitate to consult your owners manual or seek professional assistance. A little bit of preventative maintenance goes a long way in ensuring your window AC unit keeps you comfortable for years to come.
Keeping your window AC unit humming along happily for years requires more than just switching it on when it gets hot. Preventative maintenance is key to both efficient cooling and a longer lifespan. Think of it like regular check-ups for your cooling companion. Just a little TLC can save you money and headaches down the road.
One of the most important preventative measures is regular cleaning. Dust, pollen, and grime build up on both the inside and outside coils, hindering airflow and making the unit work harder. This not only reduces cooling power but also puts extra strain on the compressor, potentially leading to premature failure. Aim to clean your unit at least twice a year: once before the cooling season starts and once after it ends. For particularly dusty environments, more frequent cleaning might be necessary.
Cleaning is pretty straightforward. First, unplug the unit! Safety first, always. Remove the front grill and filter. Wash the filter with mild soap and water, letting it dry completely before replacing it. Vacuum the coils gently with a brush attachment, and for stubborn grime, you can use a fin comb (available at most hardware stores) to straighten bent fins and improve airflow. The outside condenser unit can be cleaned similarly, using a garden hose to rinse away debris – just be careful not to get any water inside the unit itself.
Beyond cleaning, there are other simple steps you can take to extend the life of your window AC. Make sure the unit is properly sealed in the window frame to prevent drafts and wasted energy. Consider investing in a weatherproof cover for the off-season to protect it from the elements. And finally, listen to your unit. Any unusual noises, like grinding or rattling, should be investigated promptly. Catching small problems early can often prevent them from becoming big, expensive repairs.
By following these simple preventative maintenance tips, you can keep your window AC unit running efficiently and extend its lifespan, ensuring cool comfort for years to come.
The word duct is derived from the Latin word for led/leading. It may refer to:
A chimney is an architectural ventilation structure made of masonry, clay or metal that isolates hot toxic exhaust gases or smoke produced by a boiler, stove, furnace, incinerator, or fireplace from human living areas. Chimneys are typically vertical, or as near as possible to vertical, to ensure that the gases flow smoothly, drawing air into the combustion in what is known as the stack, or chimney effect. The space inside a chimney is called the flue. Chimneys are adjacent to large industrial refineries, fossil fuel combustion facilities or part of buildings, steam locomotives and ships.
In the United States, the term smokestack industry refers to the environmental impacts of burning fossil fuels by industrial society, including the electric industry during its earliest history. The term smokestack (colloquially, stack) is also used when referring to locomotive chimneys or ship chimneys, and the term funnel can also be used.[1][2]
The height of a chimney influences its ability to transfer flue gases to the external environment via stack effect. Additionally, the dispersion of pollutants at higher altitudes can reduce their impact on the immediate surroundings. The dispersion of pollutants over a greater area can reduce their concentrations and facilitate compliance with regulatory limits.
Industrial chimney use dates to the Romans, who drew smoke from their bakeries with tubes embedded in the walls. However, domestic chimneys first appeared in large dwellings in northern Europe in the 12th century. The earliest surviving example of an English chimney is at the keep of Conisbrough Castle in Yorkshire, which dates from 1185 AD,[3] but they did not become common in houses until the 16th and 17th centuries.[4] Smoke hoods were an early method of collecting the smoke into a chimney. These were typically much wider than modern chimneys and started relatively high above the fire, meaning more heat could escape into the room. Because the air going up the shaft was cooler, these could be made of less fireproof materials. Another step in the development of chimneys was the use of built-in ovens which allowed the household to bake at home. Industrial chimneys became common in the late 18th century.
Chimneys in ordinary dwellings were first built of wood and plaster or mud. Since then chimneys have traditionally been built of brick or stone, both in small and large buildings. Early chimneys were of simple brick construction. Later chimneys were constructed by placing the bricks around tile liners. To control downdrafts, venting caps (often called chimney pots) with a variety of designs are sometimes placed on the top of chimneys.
In the 18th and 19th centuries, the methods used to extract lead from its ore produced large amounts of toxic fumes. In the north of England, long near-horizontal chimneys were built, often more than 3 km (2 mi) long, which typically terminated in a short vertical chimney in a remote location where the fumes would cause less harm. Lead and silver deposits formed on the inside of these long chimneys, and periodically workers would be sent along the chimneys to scrape off these valuable deposits.[5]
As a result of the limited ability to handle transverse loads with brick, chimneys in houses were often built in a "stack", with a fireplace on each floor of the house sharing a single chimney, often with such a stack at the front and back of the house. Today's central heating systems have made chimney placement less critical, and the use of non-structural gas vent pipe allows a flue gas conduit to be installed around obstructions and through walls.
Most modern high-efficiency heating appliances do not require a chimney. Such appliances are generally installed near an external wall, and a noncombustible wall thimble[clarification needed] allows a vent pipe to run directly through the external wall.
On a pitched roof where a chimney penetrates a roof, flashing is used to seal up the joints. The down-slope piece is called an apron, the sides receive step flashing and a cricket is used to divert water around the upper side of the chimney underneath the flashing.[6]
Industrial chimneys are commonly referred to as flue-gas stacks and are generally external structures, as opposed to those built into the wall of a building. They are generally located adjacent to a steam-generating boiler or industrial furnace and the gases are carried to them with ductwork. Today the use of reinforced concrete has almost entirely replaced brick as a structural element in the construction of industrial chimneys. Refractory bricks are often used as a lining, particularly if the type of fuel being burned generates flue gases containing acids. Modern industrial chimneys sometimes consist of a concrete windshield with a number of flues on the inside.
The 300 m (980 ft) high steam plant chimney at the Secunda CTL's synthetic fuel plant in Secunda, South Africa consists of a 26 m (85 ft) diameter windshield with four 4.6 metre diameter concrete flues which are lined with refractory bricks built on rings of corbels spaced at 10 metre intervals. The reinforced concrete can be cast by conventional formwork or sliding formwork. The height is to ensure the pollutants are dispersed over a wider area to meet legal or other safety requirements.
A flue liner is a secondary barrier in a chimney that protects the masonry from the acidic products of combustion, helps prevent flue gas from entering the house, and reduces the size of an oversized flue. Since the 1950s, building codes in many locations require newly built chimneys to have a flue liner. Chimneys built without a liner can usually have a liner added, but the type of liner needs to match the type of appliance it services. Flue liners may be clay or concrete tile, metal, or poured in place concrete.
Clay tile flue liners are very common in the United States, although it is the only liner that does not meet Underwriters Laboratories 1777 approval and frequently they have problems such as cracked tiles and improper installation.[7] Clay tiles are usually about 2 feet (0.61 m) long, available in various sizes and shapes, and are installed in new construction as the chimney is built. A refractory cement is used between each tile.
Metal liners may be stainless steel, aluminum, or galvanized iron and may be flexible or rigid pipes. Stainless steel is made in several types and thicknesses. Type 304 is used with firewood, wood pellet fuel, and non-condensing oil appliances, types 316 and 321 with coal, and type AL 29-4C is used with high efficiency condensing gas appliances. Stainless steel liners must have a cap and be insulated if they service solid fuel appliances, but following the manufacturer's instructions carefully.[7] Aluminum and galvanized steel chimneys are known as class A and class B chimneys. Class A are either an insulated, double wall stainless steel pipe or triple wall, air-insulated pipe often known by its genericized trade name Metalbestos. Class B are uninsulated double wall pipes often called B-vent, and are only used to vent non-condensing gas appliances. These may have an aluminum inside layer and galvanized steel outside layer.
Concrete flue liners are like clay liners but are made of a refractory cement and are more durable than the clay liners.
Poured in place concrete liners are made by pouring special concrete into the existing chimney with a form. These liners are highly durable, work with any heating appliance, and can reinforce a weak chimney, but they are irreversible.
A chimney pot is placed on top of the chimney to expand the length of the chimney inexpensively, and to improve the chimney's draft. A chimney with more than one pot on it indicates that multiple fireplaces on different floors share the chimney.
A cowl is placed on top of the chimney to prevent birds and other animals from nesting in the chimney. They often feature a rain guard to prevent rain or snow from going down the chimney. A metal wire mesh is often used as a spark arrestor to minimize burning debris from rising out of the chimney and making it onto the roof. Although the masonry inside the chimney can absorb a large amount of moisture which later evaporates, rainwater can collect at the base of the chimney. Sometimes weep holes are placed at the bottom of the chimney to drain out collected water.
A chimney cowl or wind directional cap is a helmet-shaped chimney cap that rotates to align with the wind and prevent a downdraft of smoke and wind down the chimney.
An H-style cap is a chimney top constructed from chimney pipes shaped like the letter H. It is an age-old method of regulating draft in situations where prevailing winds or turbulences cause downdraft and back-puffing. Although the H cap has a distinct advantage over most other downdraft caps, it fell out of favor because of its bulky design. It is found mostly in marine use but has been regaining popularity due to its energy-saving functionality. The H-cap stabilizes the draft rather than increasing it. Other downdraft caps are based on the Venturi effect, solving downdraft problems by increasing the updraft constantly resulting in much higher fuel consumption.
A chimney damper is a metal plate that can be positioned to close off the chimney when not in use and prevent outside air from entering the interior space, and can be opened to permit hot gases to exhaust when a fire is burning. A top damper or cap damper is a metal spring door placed at the top of the chimney with a long metal chain that allows one to open and close the damper from the fireplace. A throat damper is a metal plate at the base of the chimney, just above the firebox, that can be opened and closed by a lever, gear, or chain to seal off the fireplace from the chimney. The advantage of a top damper is the tight weatherproof seal that it provides when closed, which prevents cold outside air from flowing down the chimney and into the living space—a feature that can rarely be matched by the metal-on-metal seal afforded by a throat damper. Additionally, because the throat damper is subjected to intense heat from the fire directly below, it is common for the metal to become warped over time, thus further degrading the ability of the throat damper to seal. However, the advantage of a throat damper is that it seals off the living space from the air mass in the chimney, which, especially for chimneys positioned on an outside of wall of the home, is generally very cold. It is possible in practice to use both a top damper and a throat damper to obtain the benefits of both. The two top damper designs currently on the market are the Lyemance (pivoting door) and the Lock Top (translating door).
In the late Middle Ages in Western Europe the design of stepped gables arose to allow maintenance access to the chimney top, especially for tall structures such as castles and great manor houses.
When coal, oil, natural gas, wood, or any other fuel is combusted in a stove, oven, fireplace, hot water boiler, or industrial furnace, the hot combustion product gases that are formed are called flue gases. Those gases are generally exhausted to the ambient outside air through chimneys or industrial flue-gas stacks (sometimes referred to as smokestacks).
The combustion flue gases inside the chimneys or stacks are much hotter than the ambient outside air and therefore less dense than the ambient air. That causes the bottom of the vertical column of hot flue gas to have a lower pressure than the pressure at the bottom of a corresponding column of outside air. That higher pressure outside the chimney is the driving force that moves the required combustion air into the combustion zone and also moves the flue gas up and out of the chimney. That movement or flow of combustion air and flue gas is called "natural draught/draft", "natural ventilation", "chimney effect", or "stack effect". The taller the stack, the more draught or draft is created. There can be cases of diminishing returns: if a stack is overly tall in relation to the heat being sent out of the stack, the flue gases may cool before reaching the top of the chimney. This condition can result in poor drafting, and in the case of wood burning appliances, the cooling of the gases before emission can cause creosote to condense near the top of the chimney. The creosote can restrict the exit of flue gases and may pose a fire hazard.
Designing chimneys and stacks to provide the correct amount of natural draft involves a number of design factors, many of which require iterative trial-and-error methods.
As a "first guess" approximation, the following equation can be used to estimate the natural draught/draft flow rate by assuming that the molecular mass (i.e., molecular weight) of the flue gas and the external air are equal and that the frictional pressure and heat losses are negligible: Q = C A 2 g H T i − T e T e \displaystyle Q=C\,A\,\sqrt 2\,g\,H\,\frac T_i-T_eT_e where:
Combining two flows into chimney: At+Af<A, where At=7.1 inch2 is the minimum required flow area from water heater tank and Af=19.6 inch2 is the minimum flow area from a furnace of a central heating system.
Gas fired appliances must have a draft hood to cool combustion products entering the chimney and prevent updrafts or downdrafts.[8][9][10]
A characteristic problem of chimneys is they develop deposits of creosote on the walls of the structure when used with wood as a fuel. Deposits of this substance can interfere with the airflow and more importantly, they are combustible and can cause dangerous chimney fires if the deposits ignite in the chimney.
Heaters that burn natural gas drastically reduce the amount of creosote buildup due to natural gas burning much cleaner and more efficiently than traditional solid fuels. While in most cases there is no need to clean a gas chimney on an annual basis that does not mean that other parts of the chimney cannot fall into disrepair. Disconnected or loose chimney fittings caused by corrosion over time can pose serious dangers for residents due to leakage of carbon monoxide into the home.[11] Thus, it is recommended—and in some countries even mandatory—that chimneys be inspected annually and cleaned on a regular basis to prevent these problems. The workers who perform this task are called chimney sweeps or steeplejacks. This work used to be done largely by child labour and, as such, features in Victorian literature. In the Middle Ages in some parts of Europe, a stepped gable design was developed, partly to provide access to chimneys without use of ladders.
Masonry (brick) chimneys have also proven to be particularly prone to crumbling during earthquakes. Government housing authorities in cities prone to earthquakes such as San Francisco, Los Angeles, and San Diego now recommend building new homes with stud-framed chimneys around a metal flue. Bracing or strapping old masonry chimneys has not proven to be very effective in preventing damage or injury from earthquakes. It is now possible to buy "faux-brick" facades to cover these modern chimney structures.
Other potential problems include:
Several chimneys with observation decks were built. The following possibly incomplete list shows them.
At several thermal power stations at least one smokestack is used as electricity pylon. The following possibly incomplete list shows them.
Nearly all this structures exist in an area, which was once part of the Soviet Union. Although this use has the disadvantage that conductor ropes may corrode faster due to the exhaust gases, one can find such structures also sometimes in countries not influenced by the former Soviet Union. An example herefore is one chimney of Scholven Power Plant in Gelsenkirchen, which carries one circuit of an outgoing 220 kV-line.
Chimneys can also carry a water tank on their structure. This combination has the advantage that the warm smoke running through the chimney prevents the water in the tank from freezing. Before World War II such structures were not uncommon, especially in countries influenced by Germany.
Chimneys can carry antennas for radio relay services, cell phone transmissions, FM-radio and TV on their structure. Also long wire antennas for mediumwave transmissions can be fixed at chimneys. In all cases it had to be considered that these objects can easily corrode especially when placed near the exhaust. Sometimes chimneys were converted into radio towers and are not useable as ventilation structure any more.
As chimneys are often the tallest part of a factory, they offer the possibility as advertising billboard either by writing the name of the company to which they belong on the shaft or by installing advertisement boards on their structure.
At some power stations, which are equipped with plants for the removal of sulfur dioxide and nitrogen oxides, it is possible to use the cooling tower as a chimney. Such cooling towers can be seen in Germany at the Großkrotzenburg Power Station and at the Rostock Power Station. At power stations that are not equipped for removing sulfur dioxide, such usage of cooling towers could result in serious corrosion problems which are not easy to prevent.
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Industrial exhaust ducts are pipe systems that connect hoods to industrial chimneys through other components of exhaust systems like fans, collectors, etc. Ducts are low-pressure pneumatic conveyors to convey dust, particles, shavings, fumes, or chemical hazardous components from air in the vicinity to a shop floor or any other specific locations like tanks, sanding machines, or laboratory hoods. Ducts can be fabricated from a variety of materials including carbon steel, stainless steel, PVC, and fiberglass. [1] They can be fabricated through rolling (preferable for ducts of 12" or more in diameter) or extruded (for ducts up to 18").[2]
HVAC systems do not include this category of industrial application, namely exhaust systems. A distinction from HVAC system ducts is that the fluid (air) conveyed through the duct system may not be homogeneous. An industrial exhaust duct system is primarily a pneumatic conveying system and is basically governed by laws of flow of fluids.[3]
The conveying fluid that flows through the duct system is air. Air transports materials from the hood to a destination. It is also instrumental in capturing the material into the flow system. Air is a compressible fluid, but for engineering calculations, air is considered as incompressible as a simplification, without any significant errors.
Process design of exhaust system will include
The goal is to keep contaminants out using minimum airflow. It is estimated that increase in an inch wg[clarification needed] of static pressure can add a few thousands of dollars to the operation cost per annum.
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