Its Improving Home Energy Efficiency Construction Essay

Its Improving Home Energy Efficiency Construction Essay Introduction The typical home today has an unquenchable thirst for energy and there are many steps homeowners can take to help lower their demand for energy. The main source for todays energy is fossil fuels. The burning of these fossil fuels releases CO2 and CO2 is a major contributor to global warming. It is important that we take a more sustainable approach towards our energy usage. Sustainable energy usage benefits the environment and results in lower energy costs to the consumer. Building Shell The exterior surfaces of a building are called the building shell; this may include the roof, walls, doors, and windows. It is the effectiveness or ineffectiveness rather, of this shell that determines the level of energy demand a building will have. It is the heat exchange through the buildings shell that places the largest demands on energy consumption of the home. Lets take a minute to focus on the walls and structure with respects towards the building shell. A common trend in architecture today is to have many extrusions and intrusions in the walls of a home. This is more aesthetically pleasing to todays homeowner. However, these extrusions require extra framing which results in decreased insulation in corners and potential air leakage. Most single family residential homes are wood framed and any irregularities in the building shell are weak points when it comes to heat loss. Mobile homes are framed with metal studs, generally speaking. The increased metal presence combined with thinner walls and joints between modular sections all create potential weak spots that allow greater thermal conductivity. Multi-family housing units suffer from some of the same design flaws; much of their structural support comes from metal components, larger air handling units, and elevator shafts create weak points, thermally speaking. However from an energy usage point it is better to have an apartment that is surrounded by other apartments, the temperature change from one side of your wall/ceiling will be almost zero, this equates to lower heating and cooling costs. Later I will discuss air leakage and insulation more in-depth, for now just knows that when it comes to the exterior design of a building, simpler is better. Air Leakage What represents 5-40% of building conditioning costs also known as energy consumption, air leakage does. Air leakage is the exchange of air from the exterior to interior, or vice versa, of a building. Air leakage control can increase comfort, reduce damage to intra-wall components, prevent pest infestation, and save energy. While ventilation is needed for the building and human health, the goal is to control that ventilation and have it happen when we deem it necessary. Ultimately this exchange in air is a result of pressure difference from the inside to outside of a structure. The pressure difference is caused by the density difference in warm and cold air. This concept is also known as the second law of thermodynamics that is that warm will always move to cooler areas (when unassisted) until equilibrium is met. Unchecked airflow will seek equilibrium inside and outside by the most direct path. Examples of this process at work during winter months would be warm air exiting the struc ture through leaks in the upper regions of the building and cool air entering through the lower regions, thus creating a cycle that seeks equilibrium. Residents can prevent/reduce air leakage by ensuring that the building shell is properly sealed, air tight. This task can be accomplished by using spray foam around window and door frames as well as checking that the weather-stripping is in proper condition, not worn out. Also, windows and doors must be latched in order to be air tight, it is not uncommon for a window to closed but not latched. Other building practices that should be avoided include duct work, electrical fixtures, and plumbing components being placed in exterior surfaces. This could cause air leakage as well as reduced insulation where these components are present. Insulation Insulation prevents heat transmission through the building shell. In some winter months heat transmission poses a greater threat than air leakage. Insulation is placed in voids/cavities in the building structure to reduce heat transmission. Insulation accomplishes this goal by two means. It forces heat to transfer in the form of a gas, gasses are naturally poor conductors. Second its presence reduces heat convection and radiation. Insulation comes in many forms; it could be foam, fiberglass, wool, cellulose (shredded newspapers), and even straw bales in some construction. Every type of insulation has its own pros and cons. Foam is by far the most effective, it has very high R-values and if sprayed will expand to fill air leaks, on the down side it can be expensive, is not very fire resistant, and does not break down quickly in a land fill (eventually this is where it will end up). Fiber glass is probably the most prevalent form of insulation; it has good R-values, but until the wall is sealed can release particles into the air that are harmful if consumed. Wool/cotton is probably a more sustainable way to insulate a structure, generally it is made out of recycled jeans, can achieve comparable R-values, but due to its unpopularity can be significantly more expensive than more common insulations. Cellulose ranks about the same as wool, it is recycled content, but is blown in place and often will settle over time; this leaves a small section of the cavity insulated once it settles. Straw-bale insulation is a controversial issue, its density makes it a good insulator, and however there is much debate about how long it will last. Each insulation is designated a specific R-value and is labeled as such. The R-value is a measure of how well the material resists heat transmission. The important thing to know about R-values is the higher the better, less heat transfer equals less energy consumption. The inverse of the R-value is the U-value. U-values are used to rate win dows and doors for their efficiency. Windows Doors Windows and doors are the complete opposite of insulation. So much so, that we do not rate them by their ability to resist thermal conductivity, but by their ability to conduct thermal heat transfer. The way we identify windows and doors also known as fenestration is with a U-value. The National Fenestration Rating Council is the private/public group tasked with testing and assigning a U rating to fenestrations. Windows are made up of four basic parts; the glass, sash, frame, and the rough opening, all of these contribute to a windows inefficiency regarding energy. Windows can have several different types of glass including; Low-e, tinted bronze, reflective bronze, and clear glass. The best option for energy savings is to install an insulated, Low-e window. The insulative property is provided by a gas, usually co2 and argon. The gas is injected between the window panes and sealed in place; the use of a gas reduces the rate of convection between panes. The low-e is a coating placed on one pane of glass, usually inside the window, that reflects radiation. This coating is installed on the interior pane for cooler climates and on the exterior pane for warmer climates. The sash/frame is typically made of similar material, being; plastic, metal, or wood. With relation to energy consumption the plastic construction is the way to go. When made of plastic the sash/frame is extruded through a mold and often can be filled with foam insulation. The rough opening refers to the space between the window frame and the structural frame of the opening in the rough framing (the actual opening in the wall). The rough opening is often larger than the frame of the window to allow the builder to make adjustments during installation. Once installed, this space should be filled with insulation; the best to use for this situation is minimal expanding foam spray. Door construction is very similar. Doors can have glazing/fenestration within the door. They too, are given a U-value. When di scussing the U-value of doors/windows the most important for a consumer to know is that the lower the U-value, the better. Lower U-values result in greater energy savings when heating and cooling a building. Heating In North America the heating demands of our homes require a huge amount of energy. This energy comes from mostly from fossil fuels that have been refined, mined, and converted to meet our needs. The residential heating fuels that are used today can be broken down into four major categories; natural gas 53%, electricity 29%, oil 9%, and other types make up the remaining 9%. Huge natural gas reserves have been found in North America and it is considered to be the most environmentally friendly of the fossil fuels. It is the increased availability and societies concern for the environment that has led to exponential growth most recently in the natural gas industry. Electricity is considered to be 100% efficient once harvested. It is the methods by which we harvest electricity that cause environmental damage. The most environmentally degrading method of harvesting electricity is by coal power plants; however more sustainable methods such as harnessing wind and solar power production are b eing developed and implemented. Some electrical providers allow their customers to select the source/means of their power. Oil, once a major source of energy used to heat our homes is becoming quickly outdated as consumers become aware of more efficient and environmentally friendly ways to heat their homes. The other category refers to heat sources such as wood and coal, aside from the environmental impacts these sources are unpopular because they require more work by the consumer. A heating system should be designed to provide the home with heat at approximately the same rate that it is being lost in worst case scenarios. Each fuel type has a distribution system. These systems are given an efficiency rating. This rating measures how well the system operates and can be expressed as; Efficiency = Output Input. The resultant will be a percentage ranging from 35-95% efficient. The efficiency of a system is directly proportionate to the amount of fuel the system consumes. Therefore, the more efficient a system is, the less energy it will consume. High efficiency systems are considered to be any system with an 80-97% efficiency rating. Cooling Second to heating demands are the cooling demands, generally speaking, of a building. There are passive and active methods of cooling a structure. Depending on the designers knowledge and foresight of these methods energy required to cool the structure could vary greatly. Passive methods require no mechanical operations; the result is zero energy consumption. Active methods require the assistance of mechanical operations, although the level of energy consumption is defendant upon the system that is installed. Often it is a combination of these methods that provides the most comfort to the inhabitants of the home. One common passive method of cooling a structure is through the use of landscaping. The use of trees to shade a home is the most cost effective method of cooling. The trees must be deciduous so that they allow the sun to warm the building during winter months. Another passive method is ventilation through windows and other openings. A proper building design can create a chim ney affect, pulling cooler air in at lower portions of the home and releasing warm air in upper portions of the home. Often this chimney affect can be assisted by proper placement of ceiling fans, an example of a combination of passive and active systems. The use of fans to ventilate a home is the most energy efficient way to cool the building. Moving air is more comfortable to the inhabitants and can give the perception of a 4-8 degree temperature change. Window/Room air conditioners are the least energy efficient. The constant start up and shut down process consumes large amounts of energy. They are subject to significant accumulations of dirt, unchecked over time, this causes greater inefficiency and eventual failure of the unit. The use of central air conditioning is another active method to cool a residence. Central air conditioning can provide the most comfort; higher efficiency models reduce energy consumption. Central air conditioning systems are run by a thermostat and slow ly cool a building. This prevents the constant start up and shut down process that occurs with a window unit. Regardless of the system and methods used to cool a building the inhabitants have control over how much energy is used. The warmer the environment the residents can willingly tolerate the less energy will be consumed to cool the structure. Due to the fact that most people do are not present during the construction and design process of their home perhaps the most applicable way to save energy is to perform regular maintenance and select the proper lighting and appliances. Lighting Lighting has a huge effect on a homes energy consumption. There are many different light fixtures and bulbs a one could install in a home. Just as anything else thus far they vary in efficiency. The consumer must read labels to ensure they are actually purchasing the most sustainable, energy efficient light. Often more lighting than what is required is used, different activities require different levels of illumination, be sure to size fixtures adequately. Consumers must monitor their energy use by controlling when lights are on or off. If an area is not being utilized for a period of time the lights should be turned off to conserve energy. Also, residents should clean the globes or covers around the light bulbs, clean fixtures provide more optimal lighting. When purchasing new appliances consumers should purchase energy star rated appliances. Energy Star guidelines are set by the EPA and provide the consumer with a means of determining the efficiency of appliances such as dish washe rs, TVs, clothes washers, and dryers. To help with the cost of these more efficient options some state governments offer a tax rebate to those who purchase high efficiency appliances. Conclusion In conclusion, even with the unquenchable thirst for energy, the consumer has more power than they realize to reduce the energy consumption of the buildings they reside in. With reference to the buildings shell basic is better; irregularities tend to be thermal weak spots. Air leakage can happen anywhere the building shell is penetrated, stopping the unregulated air flow through a buildings shell will result in increased energy savings. The proper insulation is key, to providing comfort and energy efficiency. Windows and doors also known as fenestration create weak points in a buildings shell and must be sealed and properly installed to promote energy efficiency. Heating systems are produced by a wide variety of manufactures, it is crucial that the consumer is well informed with the potential energy consumption of the system before purchasing and installing. Cooling can be accomplished through passive and active means, often the most effective is a combination of both. Lighting fixtu res must be sized and installed properly to promote energy efficiency. Consumers should purchase high efficiency Energy Star appliances to conserve and reduce their homes energy consumption.

Its Improving Home Energy Efficiency Construction Essay

Its Improving Home Energy Efficiency Construction Essay Introduction The typical home today has an unquenchable thirst for energy and there are many steps homeowners can take to help lower their demand for energy. The main source for todays energy is fossil fuels. The burning of these fossil fuels releases CO2 and CO2 is a major contributor to global warming. It is important that we take a more sustainable approach towards our energy usage. Sustainable energy usage benefits the environment and results in lower energy costs to the consumer. Building Shell The exterior surfaces of a building are called the building shell; this may include the roof, walls, doors, and windows. It is the effectiveness or ineffectiveness rather, of this shell that determines the level of energy demand a building will have. It is the heat exchange through the buildings shell that places the largest demands on energy consumption of the home. Lets take a minute to focus on the walls and structure with respects towards the building shell. A common trend in architecture today is to have many extrusions and intrusions in the walls of a home. This is more aesthetically pleasing to todays homeowner. However, these extrusions require extra framing which results in decreased insulation in corners and potential air leakage. Most single family residential homes are wood framed and any irregularities in the building shell are weak points when it comes to heat loss. Mobile homes are framed with metal studs, generally speaking. The increased metal presence combined with thinner walls and joints between modular sections all create potential weak spots that allow greater thermal conductivity. Multi-family housing units suffer from some of the same design flaws; much of their structural support comes from metal components, larger air handling units, and elevator shafts create weak points, thermally speaking. However from an energy usage point it is better to have an apartment that is surrounded by other apartments, the temperature change from one side of your wall/ceiling will be almost zero, this equates to lower heating and cooling costs. Later I will discuss air leakage and insulation more in-depth, for now just knows that when it comes to the exterior design of a building, simpler is better. Air Leakage What represents 5-40% of building conditioning costs also known as energy consumption, air leakage does. Air leakage is the exchange of air from the exterior to interior, or vice versa, of a building. Air leakage control can increase comfort, reduce damage to intra-wall components, prevent pest infestation, and save energy. While ventilation is needed for the building and human health, the goal is to control that ventilation and have it happen when we deem it necessary. Ultimately this exchange in air is a result of pressure difference from the inside to outside of a structure. The pressure difference is caused by the density difference in warm and cold air. This concept is also known as the second law of thermodynamics that is that warm will always move to cooler areas (when unassisted) until equilibrium is met. Unchecked airflow will seek equilibrium inside and outside by the most direct path. Examples of this process at work during winter months would be warm air exiting the struc ture through leaks in the upper regions of the building and cool air entering through the lower regions, thus creating a cycle that seeks equilibrium. Residents can prevent/reduce air leakage by ensuring that the building shell is properly sealed, air tight. This task can be accomplished by using spray foam around window and door frames as well as checking that the weather-stripping is in proper condition, not worn out. Also, windows and doors must be latched in order to be air tight, it is not uncommon for a window to closed but not latched. Other building practices that should be avoided include duct work, electrical fixtures, and plumbing components being placed in exterior surfaces. This could cause air leakage as well as reduced insulation where these components are present. Insulation Insulation prevents heat transmission through the building shell. In some winter months heat transmission poses a greater threat than air leakage. Insulation is placed in voids/cavities in the building structure to reduce heat transmission. Insulation accomplishes this goal by two means. It forces heat to transfer in the form of a gas, gasses are naturally poor conductors. Second its presence reduces heat convection and radiation. Insulation comes in many forms; it could be foam, fiberglass, wool, cellulose (shredded newspapers), and even straw bales in some construction. Every type of insulation has its own pros and cons. Foam is by far the most effective, it has very high R-values and if sprayed will expand to fill air leaks, on the down side it can be expensive, is not very fire resistant, and does not break down quickly in a land fill (eventually this is where it will end up). Fiber glass is probably the most prevalent form of insulation; it has good R-values, but until the wall is sealed can release particles into the air that are harmful if consumed. Wool/cotton is probably a more sustainable way to insulate a structure, generally it is made out of recycled jeans, can achieve comparable R-values, but due to its unpopularity can be significantly more expensive than more common insulations. Cellulose ranks about the same as wool, it is recycled content, but is blown in place and often will settle over time; this leaves a small section of the cavity insulated once it settles. Straw-bale insulation is a controversial issue, its density makes it a good insulator, and however there is much debate about how long it will last. Each insulation is designated a specific R-value and is labeled as such. The R-value is a measure of how well the material resists heat transmission. The important thing to know about R-values is the higher the better, less heat transfer equals less energy consumption. The inverse of the R-value is the U-value. U-values are used to rate win dows and doors for their efficiency. Windows Doors Windows and doors are the complete opposite of insulation. So much so, that we do not rate them by their ability to resist thermal conductivity, but by their ability to conduct thermal heat transfer. The way we identify windows and doors also known as fenestration is with a U-value. The National Fenestration Rating Council is the private/public group tasked with testing and assigning a U rating to fenestrations. Windows are made up of four basic parts; the glass, sash, frame, and the rough opening, all of these contribute to a windows inefficiency regarding energy. Windows can have several different types of glass including; Low-e, tinted bronze, reflective bronze, and clear glass. The best option for energy savings is to install an insulated, Low-e window. The insulative property is provided by a gas, usually co2 and argon. The gas is injected between the window panes and sealed in place; the use of a gas reduces the rate of convection between panes. The low-e is a coating placed on one pane of glass, usually inside the window, that reflects radiation. This coating is installed on the interior pane for cooler climates and on the exterior pane for warmer climates. The sash/frame is typically made of similar material, being; plastic, metal, or wood. With relation to energy consumption the plastic construction is the way to go. When made of plastic the sash/frame is extruded through a mold and often can be filled with foam insulation. The rough opening refers to the space between the window frame and the structural frame of the opening in the rough framing (the actual opening in the wall). The rough opening is often larger than the frame of the window to allow the builder to make adjustments during installation. Once installed, this space should be filled with insulation; the best to use for this situation is minimal expanding foam spray. Door construction is very similar. Doors can have glazing/fenestration within the door. They too, are given a U-value. When di scussing the U-value of doors/windows the most important for a consumer to know is that the lower the U-value, the better. Lower U-values result in greater energy savings when heating and cooling a building. Heating In North America the heating demands of our homes require a huge amount of energy. This energy comes from mostly from fossil fuels that have been refined, mined, and converted to meet our needs. The residential heating fuels that are used today can be broken down into four major categories; natural gas 53%, electricity 29%, oil 9%, and other types make up the remaining 9%. Huge natural gas reserves have been found in North America and it is considered to be the most environmentally friendly of the fossil fuels. It is the increased availability and societies concern for the environment that has led to exponential growth most recently in the natural gas industry. Electricity is considered to be 100% efficient once harvested. It is the methods by which we harvest electricity that cause environmental damage. The most environmentally degrading method of harvesting electricity is by coal power plants; however more sustainable methods such as harnessing wind and solar power production are b eing developed and implemented. Some electrical providers allow their customers to select the source/means of their power. Oil, once a major source of energy used to heat our homes is becoming quickly outdated as consumers become aware of more efficient and environmentally friendly ways to heat their homes. The other category refers to heat sources such as wood and coal, aside from the environmental impacts these sources are unpopular because they require more work by the consumer. A heating system should be designed to provide the home with heat at approximately the same rate that it is being lost in worst case scenarios. Each fuel type has a distribution system. These systems are given an efficiency rating. This rating measures how well the system operates and can be expressed as; Efficiency = Output Input. The resultant will be a percentage ranging from 35-95% efficient. The efficiency of a system is directly proportionate to the amount of fuel the system consumes. Therefore, the more efficient a system is, the less energy it will consume. High efficiency systems are considered to be any system with an 80-97% efficiency rating. Cooling Second to heating demands are the cooling demands, generally speaking, of a building. There are passive and active methods of cooling a structure. Depending on the designers knowledge and foresight of these methods energy required to cool the structure could vary greatly. Passive methods require no mechanical operations; the result is zero energy consumption. Active methods require the assistance of mechanical operations, although the level of energy consumption is defendant upon the system that is installed. Often it is a combination of these methods that provides the most comfort to the inhabitants of the home. One common passive method of cooling a structure is through the use of landscaping. The use of trees to shade a home is the most cost effective method of cooling. The trees must be deciduous so that they allow the sun to warm the building during winter months. Another passive method is ventilation through windows and other openings. A proper building design can create a chim ney affect, pulling cooler air in at lower portions of the home and releasing warm air in upper portions of the home. Often this chimney affect can be assisted by proper placement of ceiling fans, an example of a combination of passive and active systems. The use of fans to ventilate a home is the most energy efficient way to cool the building. Moving air is more comfortable to the inhabitants and can give the perception of a 4-8 degree temperature change. Window/Room air conditioners are the least energy efficient. The constant start up and shut down process consumes large amounts of energy. They are subject to significant accumulations of dirt, unchecked over time, this causes greater inefficiency and eventual failure of the unit. The use of central air conditioning is another active method to cool a residence. Central air conditioning can provide the most comfort; higher efficiency models reduce energy consumption. Central air conditioning systems are run by a thermostat and slow ly cool a building. This prevents the constant start up and shut down process that occurs with a window unit. Regardless of the system and methods used to cool a building the inhabitants have control over how much energy is used. The warmer the environment the residents can willingly tolerate the less energy will be consumed to cool the structure. Due to the fact that most people do are not present during the construction and design process of their home perhaps the most applicable way to save energy is to perform regular maintenance and select the proper lighting and appliances. Lighting Lighting has a huge effect on a homes energy consumption. There are many different light fixtures and bulbs a one could install in a home. Just as anything else thus far they vary in efficiency. The consumer must read labels to ensure they are actually purchasing the most sustainable, energy efficient light. Often more lighting than what is required is used, different activities require different levels of illumination, be sure to size fixtures adequately. Consumers must monitor their energy use by controlling when lights are on or off. If an area is not being utilized for a period of time the lights should be turned off to conserve energy. Also, residents should clean the globes or covers around the light bulbs, clean fixtures provide more optimal lighting. When purchasing new appliances consumers should purchase energy star rated appliances. Energy Star guidelines are set by the EPA and provide the consumer with a means of determining the efficiency of appliances such as dish washe rs, TVs, clothes washers, and dryers. To help with the cost of these more efficient options some state governments offer a tax rebate to those who purchase high efficiency appliances. Conclusion In conclusion, even with the unquenchable thirst for energy, the consumer has more power than they realize to reduce the energy consumption of the buildings they reside in. With reference to the buildings shell basic is better; irregularities tend to be thermal weak spots. Air leakage can happen anywhere the building shell is penetrated, stopping the unregulated air flow through a buildings shell will result in increased energy savings. The proper insulation is key, to providing comfort and energy efficiency. Windows and doors also known as fenestration create weak points in a buildings shell and must be sealed and properly installed to promote energy efficiency. Heating systems are produced by a wide variety of manufactures, it is crucial that the consumer is well informed with the potential energy consumption of the system before purchasing and installing. Cooling can be accomplished through passive and active means, often the most effective is a combination of both. Lighting fixtu res must be sized and installed properly to promote energy efficiency. Consumers should purchase high efficiency Energy Star appliances to conserve and reduce their homes energy consumption.

Its Improving Home Energy Efficiency Construction Essay

Its Improving Home Energy Efficiency Construction Essay Introduction The typical home today has an unquenchable thirst for energy and there are many steps homeowners can take to help lower their demand for energy. The main source for todays energy is fossil fuels. The burning of these fossil fuels releases CO2 and CO2 is a major contributor to global warming. It is important that we take a more sustainable approach towards our energy usage. Sustainable energy usage benefits the environment and results in lower energy costs to the consumer. Building Shell The exterior surfaces of a building are called the building shell; this may include the roof, walls, doors, and windows. It is the effectiveness or ineffectiveness rather, of this shell that determines the level of energy demand a building will have. It is the heat exchange through the buildings shell that places the largest demands on energy consumption of the home. Lets take a minute to focus on the walls and structure with respects towards the building shell. A common trend in architecture today is to have many extrusions and intrusions in the walls of a home. This is more aesthetically pleasing to todays homeowner. However, these extrusions require extra framing which results in decreased insulation in corners and potential air leakage. Most single family residential homes are wood framed and any irregularities in the building shell are weak points when it comes to heat loss. Mobile homes are framed with metal studs, generally speaking. The increased metal presence combined with thinner walls and joints between modular sections all create potential weak spots that allow greater thermal conductivity. Multi-family housing units suffer from some of the same design flaws; much of their structural support comes from metal components, larger air handling units, and elevator shafts create weak points, thermally speaking. However from an energy usage point it is better to have an apartment that is surrounded by other apartments, the temperature change from one side of your wall/ceiling will be almost zero, this equates to lower heating and cooling costs. Later I will discuss air leakage and insulation more in-depth, for now just knows that when it comes to the exterior design of a building, simpler is better. Air Leakage What represents 5-40% of building conditioning costs also known as energy consumption, air leakage does. Air leakage is the exchange of air from the exterior to interior, or vice versa, of a building. Air leakage control can increase comfort, reduce damage to intra-wall components, prevent pest infestation, and save energy. While ventilation is needed for the building and human health, the goal is to control that ventilation and have it happen when we deem it necessary. Ultimately this exchange in air is a result of pressure difference from the inside to outside of a structure. The pressure difference is caused by the density difference in warm and cold air. This concept is also known as the second law of thermodynamics that is that warm will always move to cooler areas (when unassisted) until equilibrium is met. Unchecked airflow will seek equilibrium inside and outside by the most direct path. Examples of this process at work during winter months would be warm air exiting the struc ture through leaks in the upper regions of the building and cool air entering through the lower regions, thus creating a cycle that seeks equilibrium. Residents can prevent/reduce air leakage by ensuring that the building shell is properly sealed, air tight. This task can be accomplished by using spray foam around window and door frames as well as checking that the weather-stripping is in proper condition, not worn out. Also, windows and doors must be latched in order to be air tight, it is not uncommon for a window to closed but not latched. Other building practices that should be avoided include duct work, electrical fixtures, and plumbing components being placed in exterior surfaces. This could cause air leakage as well as reduced insulation where these components are present. Insulation Insulation prevents heat transmission through the building shell. In some winter months heat transmission poses a greater threat than air leakage. Insulation is placed in voids/cavities in the building structure to reduce heat transmission. Insulation accomplishes this goal by two means. It forces heat to transfer in the form of a gas, gasses are naturally poor conductors. Second its presence reduces heat convection and radiation. Insulation comes in many forms; it could be foam, fiberglass, wool, cellulose (shredded newspapers), and even straw bales in some construction. Every type of insulation has its own pros and cons. Foam is by far the most effective, it has very high R-values and if sprayed will expand to fill air leaks, on the down side it can be expensive, is not very fire resistant, and does not break down quickly in a land fill (eventually this is where it will end up). Fiber glass is probably the most prevalent form of insulation; it has good R-values, but until the wall is sealed can release particles into the air that are harmful if consumed. Wool/cotton is probably a more sustainable way to insulate a structure, generally it is made out of recycled jeans, can achieve comparable R-values, but due to its unpopularity can be significantly more expensive than more common insulations. Cellulose ranks about the same as wool, it is recycled content, but is blown in place and often will settle over time; this leaves a small section of the cavity insulated once it settles. Straw-bale insulation is a controversial issue, its density makes it a good insulator, and however there is much debate about how long it will last. Each insulation is designated a specific R-value and is labeled as such. The R-value is a measure of how well the material resists heat transmission. The important thing to know about R-values is the higher the better, less heat transfer equals less energy consumption. The inverse of the R-value is the U-value. U-values are used to rate win dows and doors for their efficiency. Windows Doors Windows and doors are the complete opposite of insulation. So much so, that we do not rate them by their ability to resist thermal conductivity, but by their ability to conduct thermal heat transfer. The way we identify windows and doors also known as fenestration is with a U-value. The National Fenestration Rating Council is the private/public group tasked with testing and assigning a U rating to fenestrations. Windows are made up of four basic parts; the glass, sash, frame, and the rough opening, all of these contribute to a windows inefficiency regarding energy. Windows can have several different types of glass including; Low-e, tinted bronze, reflective bronze, and clear glass. The best option for energy savings is to install an insulated, Low-e window. The insulative property is provided by a gas, usually co2 and argon. The gas is injected between the window panes and sealed in place; the use of a gas reduces the rate of convection between panes. The low-e is a coating placed on one pane of glass, usually inside the window, that reflects radiation. This coating is installed on the interior pane for cooler climates and on the exterior pane for warmer climates. The sash/frame is typically made of similar material, being; plastic, metal, or wood. With relation to energy consumption the plastic construction is the way to go. When made of plastic the sash/frame is extruded through a mold and often can be filled with foam insulation. The rough opening refers to the space between the window frame and the structural frame of the opening in the rough framing (the actual opening in the wall). The rough opening is often larger than the frame of the window to allow the builder to make adjustments during installation. Once installed, this space should be filled with insulation; the best to use for this situation is minimal expanding foam spray. Door construction is very similar. Doors can have glazing/fenestration within the door. They too, are given a U-value. When di scussing the U-value of doors/windows the most important for a consumer to know is that the lower the U-value, the better. Lower U-values result in greater energy savings when heating and cooling a building. Heating In North America the heating demands of our homes require a huge amount of energy. This energy comes from mostly from fossil fuels that have been refined, mined, and converted to meet our needs. The residential heating fuels that are used today can be broken down into four major categories; natural gas 53%, electricity 29%, oil 9%, and other types make up the remaining 9%. Huge natural gas reserves have been found in North America and it is considered to be the most environmentally friendly of the fossil fuels. It is the increased availability and societies concern for the environment that has led to exponential growth most recently in the natural gas industry. Electricity is considered to be 100% efficient once harvested. It is the methods by which we harvest electricity that cause environmental damage. The most environmentally degrading method of harvesting electricity is by coal power plants; however more sustainable methods such as harnessing wind and solar power production are b eing developed and implemented. Some electrical providers allow their customers to select the source/means of their power. Oil, once a major source of energy used to heat our homes is becoming quickly outdated as consumers become aware of more efficient and environmentally friendly ways to heat their homes. The other category refers to heat sources such as wood and coal, aside from the environmental impacts these sources are unpopular because they require more work by the consumer. A heating system should be designed to provide the home with heat at approximately the same rate that it is being lost in worst case scenarios. Each fuel type has a distribution system. These systems are given an efficiency rating. This rating measures how well the system operates and can be expressed as; Efficiency = Output Input. The resultant will be a percentage ranging from 35-95% efficient. The efficiency of a system is directly proportionate to the amount of fuel the system consumes. Therefore, the more efficient a system is, the less energy it will consume. High efficiency systems are considered to be any system with an 80-97% efficiency rating. Cooling Second to heating demands are the cooling demands, generally speaking, of a building. There are passive and active methods of cooling a structure. Depending on the designers knowledge and foresight of these methods energy required to cool the structure could vary greatly. Passive methods require no mechanical operations; the result is zero energy consumption. Active methods require the assistance of mechanical operations, although the level of energy consumption is defendant upon the system that is installed. Often it is a combination of these methods that provides the most comfort to the inhabitants of the home. One common passive method of cooling a structure is through the use of landscaping. The use of trees to shade a home is the most cost effective method of cooling. The trees must be deciduous so that they allow the sun to warm the building during winter months. Another passive method is ventilation through windows and other openings. A proper building design can create a chim ney affect, pulling cooler air in at lower portions of the home and releasing warm air in upper portions of the home. Often this chimney affect can be assisted by proper placement of ceiling fans, an example of a combination of passive and active systems. The use of fans to ventilate a home is the most energy efficient way to cool the building. Moving air is more comfortable to the inhabitants and can give the perception of a 4-8 degree temperature change. Window/Room air conditioners are the least energy efficient. The constant start up and shut down process consumes large amounts of energy. They are subject to significant accumulations of dirt, unchecked over time, this causes greater inefficiency and eventual failure of the unit. The use of central air conditioning is another active method to cool a residence. Central air conditioning can provide the most comfort; higher efficiency models reduce energy consumption. Central air conditioning systems are run by a thermostat and slow ly cool a building. This prevents the constant start up and shut down process that occurs with a window unit. Regardless of the system and methods used to cool a building the inhabitants have control over how much energy is used. The warmer the environment the residents can willingly tolerate the less energy will be consumed to cool the structure. Due to the fact that most people do are not present during the construction and design process of their home perhaps the most applicable way to save energy is to perform regular maintenance and select the proper lighting and appliances. Lighting Lighting has a huge effect on a homes energy consumption. There are many different light fixtures and bulbs a one could install in a home. Just as anything else thus far they vary in efficiency. The consumer must read labels to ensure they are actually purchasing the most sustainable, energy efficient light. Often more lighting than what is required is used, different activities require different levels of illumination, be sure to size fixtures adequately. Consumers must monitor their energy use by controlling when lights are on or off. If an area is not being utilized for a period of time the lights should be turned off to conserve energy. Also, residents should clean the globes or covers around the light bulbs, clean fixtures provide more optimal lighting. When purchasing new appliances consumers should purchase energy star rated appliances. Energy Star guidelines are set by the EPA and provide the consumer with a means of determining the efficiency of appliances such as dish washe rs, TVs, clothes washers, and dryers. To help with the cost of these more efficient options some state governments offer a tax rebate to those who purchase high efficiency appliances. Conclusion In conclusion, even with the unquenchable thirst for energy, the consumer has more power than they realize to reduce the energy consumption of the buildings they reside in. With reference to the buildings shell basic is better; irregularities tend to be thermal weak spots. Air leakage can happen anywhere the building shell is penetrated, stopping the unregulated air flow through a buildings shell will result in increased energy savings. The proper insulation is key, to providing comfort and energy efficiency. Windows and doors also known as fenestration create weak points in a buildings shell and must be sealed and properly installed to promote energy efficiency. Heating systems are produced by a wide variety of manufactures, it is crucial that the consumer is well informed with the potential energy consumption of the system before purchasing and installing. Cooling can be accomplished through passive and active means, often the most effective is a combination of both. Lighting fixtu res must be sized and installed properly to promote energy efficiency. Consumers should purchase high efficiency Energy Star appliances to conserve and reduce their homes energy consumption.

The Lost Duke of Wyndham Chapter Eleven

What Jack saw took his breath away. â€Å"No one comes here but me,† Grace said softly. â€Å"I don't know why.† The light, the ripple through the air as the sun slid through the uneven glass of the ancient windows†¦ â€Å"In the winter especially,† she continued, her voice just a little hesitant, â€Å"it's magic. I can't explain it. I think the sun dips lower. And with the snow†¦Ã¢â‚¬  It was the light. It had to be. It was the way the light trembled, and fell on her. His heart clenched. Like a fist it hit him – this need, this overwhelming urge†¦He could not speak. He could not even begin to articulate it, but – â€Å"Jack?† she whispered, and it was just enough to break his trance. â€Å"Grace.† It was just one word, but it was a benediction. This went beyond desire, it was need. It was an indefinable, inexplicable, living, pulsing thing within him that could only be tamed by her. If he didn't hold her, didn't touch her in that very moment, something within him would die. To a man who tried to treat life as an endless series of ironies and witticisms, nothing could have been more terrifying. He reached out and roughly pulled her to him. He was not delicate, nor was he gentle. He couldn't be. He couldn't manage it, not now, not when he needed her so desperately. â€Å"Grace,† he said again, because that's what she was to him. It was impossible that he'd known her but a day. She was his grace, his Grace, and it was like she had always been there within him, waiting for him to finally open his eyes and find her. His hands cupped her face. She was a priceless treasure, and yet he could not force himself to touch her with the reverence she deserved. Instead, his fingers were clumsy, his body rough and pounding. Her eyes – so clear, so blue – he thought he might drown in them. He wanted to drown in them, to lose himself within her and never leave. His lips touched hers, and then – of this he was certain – he was lost. There was nothing more for him but this woman, in this moment, maybe even for all his moments thereafter. â€Å"Jack,† she sighed. It was the first time all morning she'd used his name, and it sent waves of desire pulsing through his already taut body. â€Å"Grace,† he said in return, because he was afraid to say anything else, afraid that for the first time in his life his glib tongue would fail him, and his words would come out wrong. He'd say something and it would mean too little, or perhaps he'd say something and it would mean too much. And then she would know, if by some miracle she did not already, that she had bewitched him. He kissed her hungrily, passionately, with all the fire within him. His hands slid down her back, memorizing the gentle slope of her spine, and when he reached the more lush curves of her bottom, he could not help it – he pressed her more firmly against him. He was aroused, and wound more tightly than he'd ever imagined possible, and all he could think – if he was thinking at all – was that he needed her close, closer. Whatever he could get, whatever he could have – right now he would take it. â€Å"Grace,† he said again, one of his hands moving to the spot where her dress touched her skin, just at her collarbone. She flinched at his touch, and he stilled, barely able to imagine how he would tear himself away. But her hand covered his, and she whispered, â€Å"I was surprised.† It was only then that he once again breathed. Fingers shaking, he traced the delicately scalloped edge of her bodice. Her pulse seemed to leap beneath his touch, and never in his life had he been so aware of a single sound – the quiet rasp of air, brushing across her lips. â€Å"You are so beautiful,† he whispered, and the amazing thing was that he was not even looking at her face. It was merely her skin, the pale, milky hue of it, the soft blush of pink that followed his fingers. Softly, gently, he bowed his head and brushed his lips along the hollow at the base of her throat. She gasped then, or maybe it was a moan, and her head slowly fell back in silent agreement. Her arms were around him and her hands in his hair, and then, without even considering what it meant, he swept her into his arms and carried her across the room, to the low, wide settee that sat near the window, bathed in the magical sunlight that had seduced them both. For a moment, kneeling at her side, he could do nothing but look at her, then one of his trembling hands reached forth to stroke her cheek. She was staring up at him, and in her eyes there was wonder, and anticipation, and yes, a little nervousness. But there was also trust. She wanted him. Him. No one else. She had never been kissed before, of that he was certain. She could have done. Of that he was even more certain. A woman of Grace's beauty did not reach her age without having refused (or rebuffed) multiple advances. She had waited. She had waited for him. Still kneeling beside her, he bent to kiss her, his hand moving down the side of her face to her shoulder, then to her hip. His passion grew deeper, and hers, too; she was returning his kiss with an unschooled eagerness that left him breathless with desire. â€Å"Grace, Grace,† he moaned, his voice lost in the warmth of her mouth. His hand found the hem of her dress and then slid under, grasping the slender circle of her ankle. And then up†¦up†¦to her knee. And higher. Until he could bear it no longer, and he moved to the settee himself, partially covering her with his own body. His lips had moved to her neck, and he felt her sharply indrawn breath on his cheek. But she did not say no. She did not cover his hand with hers and bring him to a stop. She did nothing but whisper his name and arch her hips beneath him. She couldn't have known what the movement had meant, could never have known what it would do to him, but that ever-so-slight pressure beneath him, rising up against his own desire, brought him to the very peak of need. He kissed his way down her neck, to the gentle swell of her breast, his lips finding the very spot at the edge of her bodice that his fingers had so recently traveled. He lifted himself away from her, just a bit, just enough so he could slide his finger under the hem and slide it down, or maybe push her up – whichever was needed to free her to his devotion. But just when his hand had moved toward his destination, just when he'd had one glorious second to cup the fullness of her, skin to skin, the stiff edge peaking in his palm, she cried out. Softly, with surprise. And dismay. â€Å"No, I can't.† With jerky movements she scrambled to her feet, righting her dress. Her hands were shaking. More than shaking. They seemed filled with a foreign, nervous energy, and when he looked in her eyes, it was as if a knife had pierced him. It was not revulsion, it was not fear. What he saw was anguish. â€Å"Grace,† he said, moving toward her. â€Å"What is wrong?† â€Å"I'm sorry,† she said, stepping back. â€Å"I – I shouldn't have. Not now. Not until – † One of her hands flew up to cover her mouth. â€Å"Not until†¦? Grace? Not until what?† â€Å"I'm sorry,† she said again, confirming his belief that those were the worst two words in the English language. She bobbed a quick, perfunctory curtsy. â€Å"I must go.† And then she ran from the room, leaving him quite alone. He stared at the empty doorway for a full minute, trying to figure out just what had happened. And it was only when he finally stepped into the hall that he realized he hadn't a clue how to get back to his bedchamber. Grace dashed through Belgrave, half walking, half skipping†¦running†¦whatever it was she needed to do to reach her room with the most equal balance of dignity and speed. If the servants saw her – and she couldn't imagine they didn't; they seemed positively everywhere this morning – they must have wondered at her distress. The dowager would not expect her. Surely she would think she was still showing Mr. Audley the house. Grace had at least an hour before she might need to show her face. Dear God, what had she done? If she had not finally remembered herself, remembered who he was, and who he might be, she would have let him continue. She'd wanted it. She'd wanted it with a fervor that had shocked her. When he'd taken her hand, when he'd pulled her to him, he awakened something within her. No. It had been awakened two nights earlier. On that moonlit night, standing outside the carriage, something had been born within her. And now†¦ She sat upon her bed, wanting to bury herself in the covers but instead just sitting there, staring at the wall. There was no going back. One couldn't ever not have been kissed once the deed was done. With a nervous breath, maybe even a frantic laugh, she covered her face with her hands. Could she possibly have chosen anyone less suitable with whom to fall in love? Not that this was the measure of her feelings, she hastened to reassure herself, but she was not so much of a fool that she could not recognize her leanings. If she let herself†¦If she let him†¦ She would fall in love. Good heavens. Either he was a highwayman, and now she was destined to be the consort of an outlaw, or he was the true Duke of Wyndham, which meant – She laughed because really, this was funny. It had to be funny. If it wasn't funny, then it could only be tragic, and she didn't think she could manage that just now. Wonderful. Perhaps she was falling in love with the Duke of Wyndham. Now that was appropriate. Let's see, how many ways was this a disaster? He was her employer, for one, he owned the house in which she lived, and his rank was so far above hers as to be nearly immeasurable. And then there was Amelia. She and Thomas certainly did not suit, but she had every right to expect that she would be the Duchess of Wyndham upon her marriage. Grace could not imagine how crass and overreaching she would appear to the Willoughbys – her good friends – if she were seen to be throwing herself at the new duke. Grace closed her eyes and touched the tips of her fingers to her lips. If she breathed deeply enough she almost relaxed. And she could almost still feel his presence, his touch, the warmth of his skin. It was awful. It was wonderful. She was a fool. She lay down, let out a long, weary breath. Funny how she'd hoped for change, for something to break the monotony of her days attending to the dowager. Life was a mocking sort of thing, wasn't it? And love†¦ Love was the cruelest joke of all. â€Å"Lady Amelia is here to see you, Miss Eversleigh.† Grace jolted upright, blinking furiously. She must have fallen asleep. She could not recall the last time she had done so at midday. â€Å"Lady Amelia?† she echoed, surprised. â€Å"With Lady Elizabeth?† â€Å"No, miss,† the maid informed her. â€Å"She is alone.† â€Å"How curious.† Grace sat up, flexing her feet and hands to awaken her body. â€Å"Please tell her I shall be right there.† She waited for the maid to depart, then went to her small mirror to straighten her hair. It was worse than she'd feared, although she could not be certain whether it had been mussed in sleep or by Mr. Audley. She felt her skin flush at the memory, and she groaned at that. Gathering her determination, she repinned her hair and left the room, walking as briskly as she could, as if speed and a set of squared shoulders could keep all of her worries at bay. Or at the very least, make her look as if she did not care. It did seem odd that Amelia would come to Belgrave without Elizabeth. Grace did not know that she had ever done so before. Certainly not to see her. Grace wondered if her original intention had been to call upon Thomas, who was, as far as she knew, still out. She hurried down the stairs, then turned to make for the front drawing room. But she'd not taken more than a dozen steps before someone grabbed her arm and yanked her into a side room. â€Å"Thomas!† she exclaimed. It was indeed he, somewhat haggard and sporting a nasty bruise under his left eye. His appearance was a shock; she had never seen him looking so rumpled before. His shirt was wrinkled, his cravat missing, and his hair had most definitely not been styled a la Brutus. Or even a la human. And then there were his eyes, which were most uncharacteristically red-rimmed. â€Å"What happened to you?† He put a finger to his lips and shut the door. â€Å"Were you expecting someone else?† he asked, and her cheeks grew warm. Indeed, when she'd felt a strong male hand close around her arm and pull, she had assumed it was Mr. Audley, trying to steal a kiss. Her flush grew deeper as she realized she had been disappointed to realize that it was not. â€Å"No, of course not,† she said quickly, even though she suspected he knew she was lying. She quickly glanced around the room to see if they were alone. â€Å"What is wrong?† â€Å"I needed to speak with you before you see Lady Amelia.† â€Å"Oh, then you know she is here?† â€Å"I brought her,† he confirmed. Her eyes widened. That was news. He had been out all night and was considerably worse for the wear. She glanced at a nearby clock. It was not yet even noon. When could he have collected Amelia? And where? And why? â€Å"It is a long story,† he said, clearly to cut her off before she could ask any questions. â€Å"But suffice it to say, she will inform you that you were in Stamford this morning, and you invited her back to Belgrave.† Her brows rose. If he was asking her to lie, it was very serious, indeed. â€Å"Thomas, any number of people know quite well that I was not in Stamford this morning.† â€Å"Yes, but her mother is not among that number.† Grace wasn't sure if she should be shocked or delighted. Had he compromised Amelia? Why else would they need to lie to her mother? â€Å"Er, Thomas†¦Ã¢â‚¬  she began, unsure of how to proceed. â€Å"I feel I must tell you, given the number of delays thus far, I would imagine that Lady Crowland would be delighted to know – â€Å" â€Å"Oh for God's sake, it is nothing like that,† he muttered. â€Å"Amelia assisted me home when I was† – he blushed then. Blushed! Thomas! – â€Å"impaired.† Grace bit her lip to keep from smiling. It was quite remarkable what a pleasant image that was – Thomas allowing himself to be anything less than perfectly composed. â€Å"That was most charitable of her,† she said, perhaps a little too primly. But really, it couldn't be helped. He glared at her, which only made it more difficult to maintain an even face. She cleared her throat. â€Å"Have you, er, considered tidying up?† â€Å"No,† he snapped, â€Å"I rather enjoy looking like a slovenly fool.† Grace winced at that. â€Å"Now listen,† he continued, looking terribly determined. â€Å"Amelia will repeat what I have told you, but it is imperative that you not tell her about Mr. Audley.† â€Å"I would never do that,† Grace said quickly. â€Å"It is not my place.† â€Å"Good.† â€Å"But she will want to know why you were, er†¦Ã¢â‚¬  Oh, dear, how to put it politely? â€Å"You don't know why,† he said firmly. â€Å"Just tell her that. Why would she suspect that you would know more?† â€Å"She knows that I consider you a friend,† Grace said. â€Å"And furthermore, I live here. Servants always know everything. She knows that.† â€Å"You're not a servant,† he muttered. â€Å"I am and you know it,† she replied, almost amused. â€Å"The only difference is that I am allowed to wear finer clothing and occasionally converse with the guests. But I assure you, I am privy to all of the household gossip.† For several seconds he did nothing but stare, as if waiting for her to laugh and say, Only joking! Finally he muttered something under his breath that she was quite certain she was not meant to understand (and indeed she did not; servants' gossip was occasionally risque, but it was never profane). â€Å"For me, Grace,† he said, his eyes boring into hers, â€Å"will you please just tell her you don't know?† It was the closest she had ever heard him come to begging, and it left her disoriented and acutely uncomfortable. â€Å"Of course,† she said quickly. â€Å"You have my word.† He nodded briskly. â€Å"Amelia will be expecting you.† â€Å"Yes. Yes, of course.† Grace hurried to the door, but when her hand touched the knob, she found she was not quite ready to go. She turned around, taking one last look at his face. He was not himself. No one could blame him; it had been a most extraordinary two days. But still, it worried her. â€Å"Will you be all right?† she asked. And immediately regretted that she had done so. His face seemed to move, and twist, and she could not be sure if he was going to laugh or cry. But she did know that she did not want to be witness to either. â€Å"No, don't answer that,† she mumbled, and she ran from the room.

Mims V Starbucks Case

LAW 150 Mims v. Starbucks Corp. Fact: * Kevin Keevican, Kathleen Mims, and other former managers filed a suit against Starbucks seeking unpaid overtime and other amounts. * In Starbucks Corp. Stores the manager’s responsibilities include supervising and motivating six to thirty employees including supervisors and assistant managers, overseeing customer service and processes employee records, payrolls, and inventory counts. * He or she also develops strategies to increase revenues, control costs, and comply with corporate policies. As a manager Kevin worked seventy hours a week for $650 to $800, a 10 to 20 percent bonus, and fringe benefits that were not available to baristas, such as paid sick leave. * An employee’s primary duty is usually what the employee does that is of principal value to the employer, not the collateral tasks that she may also perform, even if they consume more than half their time. * The Plaintiffs argued that they spent less than 50 percent of the ir time on managing and therefore they should be entitled to unpaid overtime and other amounts. Issue:Are the managers non-exempt from the FLSA’s overtime provisions?Decision: NO Rationale: The court began by stating the even when an employee spends less than 50% of his time on management, as the plaintiffs claim they did, management might still be the employee’s primary duty if certain factors support that conclusion. The factors were 1) the relative importance of managerial duties compared to other duties; 2) the frequency with which the employee makes discretionary decisions; 3) the employee’s relative freedom from supervision; and 4) the relationship between the employee’s salary and the wages paid to employees who perform relevant non-exempt work.The record showed that the managerial duties were more critical to success than other duties. The reasoning behind this was that if the managers of stores that made more than $1 million annually in sales wer e able to spend the majority of their time doing chores that other employees which they hired also perform, it’s still obvious that those activities of the manager were not as importance compared to the significant management responsibilities performed during the lesser part of their time.In other words even though the managers spent more time doing less significant work, it still is not as significant as the management activities that they perform even though they do the management activities with 20 to 30 percent of their time. It was apparent that the plaintiffs were the highest paid being that they were the managers and given the significance of their activities they had to make many decisions such as inventory control and whom to deploy in certain positions.A part of these activities was as the highest-ranking employees in their stores to choose who to hire when to discipline employees etc. This applies to the second factor. They argued that because the district managers had the authority to hire more senior employees and set rates of pay, that they did not have the full power to make discretionary decisions however this does not change that management was their primary duty because the discretion may be limited to the company and its desires for uniformity.The third factor in determining if management was the employee’s primary duty was the employee’s relative freedom from supervision. The plaintiffs had claimed that this factor was not conclusive since the district managers were always coming into their stores. They had claimed that since the district managers came on a frequent basis they did not have the freedom from supervision. The court found that the managers still had enough discretionary power and freedom from supervision to qualify for the executive exemption.In other words even though the district managers spent substantial amounts of time in the Plaintiffs’ stores they still had the responsibility of maintaining th e store and its operations and had enough freedom from supervision according to the courts. The fourth factor was the relationship between the employee’s salary and the wages paid to employees who perform relevant non exempt work. Basically here the court said that there was no evidence that their compensation was close to that of some assistant managers which was the Plaintiffs argument on the matter.And it was without a doubt that they had nearly twice the total annual compensation received by their highest-paid supervisors. And they also received bonuses that were not available to everyone. Thus after looking at all the factors the court decided in favor of Starbucks and dismissed the claims, who were exempt from the FLSA’s overtime provisions as executive employees. The court also said that the plaintiffs’ primary duty was management.

Google And Its Relationship With China - 893 Words

Opening The quick advancement and progress of the internet across the world has led to many great opportunities for American business. However, this advancement has pushed the bounds for some countries on their stance for the free flow of information. This has been the problem for Google and its relationship with China. The restrictions set up by the Chinese government go against the ideas and ethics of Google. However, the presence of Google will likely help push political change by opening some doors for accessing information. This will also have the added opportunity of maximizing Google’s corporate interests. Stats and numbers China has the fastest growing internet base with around 632 million of its citizens online as of†¦show more content†¦A business holds its responsibility to the investors with the end goal of producing profit, but this can be considered to constrictive. Strictly running for profit might not be the main goal for some, employees, stakeholders or customers. This could help give a positive image for the company and its investors. Also, Google has not created its enormous value by making shareholder value the main purpose. â€Å"Maximizing profits is an end from the private point of view; it is a means from the social point of view.†(friedman) A system based on private property and free markets help enable people to use their resources in the most valued way. To build a strong and efficient network infrastructure China will need private business, entrapanuers and shareholders to invest freely. If they are in disagreement with the company they are free to sell their stock. The same goes for customers and their choice to vote with their dollars. Many companies have been created with the purpose to maximize profits for their investors. It is also simply good business for a company to provide for its customers social benefit as long as it’s done by their own choice and not pressured. It is not the job of the company to be altruistic and is the benefit of the company to work towards its own needs. Things have changed over time in the There is no obligation to social responsibility, only in the way of shared values and responsibilities