The world’s first Amazon Alexa-powered bath bomb mold is the culmination of years of tinkering, testing and trial and error.
It’s the result of a joint effort between Amazon and Sitz Baths Australia, a Melbourne-based manufacturer of bath bombs, bath tubs and bath mats.
“We spent months, if not years, looking for the perfect product for our customers,” says Sitz founder and CEO Peter Dukes.
“With the bath bomb mould we wanted to create a product that would stand up to our customers’ expectations and would work with Alexa as well.”
A new study suggests bath towels and baby bath seats are a viable option for preventing accidental bathtub drowning and bath bomb mold infections.
The study found that bath towels can help prevent bath bomb mold infections, which can cause serious infections if left untreated.
Bath towel sets cost around $100, which is cheaper than other bath towels but still expensive compared to a baby bathtub.
But a study from the National Institute of Allergy and Infectious Diseases (NIAID) says they could save lives if you use them in the right manner.
The study examined the efficacy of baby bath towels for bathtub deaths in a number of ways.
They were tested in four settings, including a bathtub, a sink, a bath towel set, and a shower head.
The results showed that bath towel sets can reduce the risk of accidental bath tub drowning by at least 80 percent.
This was an early study, and the study was limited to bathtub tests in which there were no other factors that might have influenced the results, says NIAID spokesperson Joanne Smith.
“There were a few things that were significant.
First of all, we didn’t find any significant differences in the number of people who had died or who died from bathtub-related bathtub drownings,” she says.
This was not a randomized trial, but it was not an observational study either, so it was unable to control for other variables that might affect a bath bath’s effectiveness, Smith says.
So the next step is to find out how bath towels are used in bathtubs.
If bath towels were used consistently and appropriately, then the results would be consistent across settings, Smith explains.
She says the researchers also had to take into account the bathtub’s capacity and the age of the bath.
The researchers found that if the bath was not properly cleaned, the towels might not work as well.
“The study shows that towel use is important in preventing bathtub and bathtub related drownings, and that bathtub towels have a significant role to play in preventing accidental drowning in the bath,” says NIDA’s Elizabeth R. Johnson, a senior scientist in the Division of Research in Health Policy and Management.
The NIAid study will be published in the journal PLoS One.
Babies need to be careful about the amount of towels they use, says Susan S. Dyer, director of the NIAId Laboratory for Research and Development and a professor in the Department of Psychology at the University of Washington.
“I would suggest not using a bathtowel that is too long, or too short, or not wide enough to cover a bath,” she explains.
“It’s best to use towels that are fairly thick, with a width of about three to four inches.
I would never use a towel that is more than two to three inches wide.”
To keep a bath safe, make sure the towel is not in the way, and always use the towel as needed.
And to prevent bath bombs, wash towels regularly, wash your towels after use, and clean towels frequently.
If you want to try one of these new options, read on.
The ability to make bath bombs from simple materials is now being used to create the world’s most complex and expensive-to-make bomb.
The work is the result of years of research by researchers at the University of Nottingham.
A series of experiments have now been published in the journal Science.
The researchers say they’ve succeeded in making a “staple” from simple plastic, a mixture of water and carbon dioxide.
They have been able to create a single bomb weighing a few grams, which they hope will be used to make more bombs and, eventually, to make a new bomb.
It is, as one of the lead authors told BBC News, a “very ambitious” goal.
The bomb was made by placing a glass jar filled with a solution of carbon dioxide, water and sand into a mold.
When the mold was cooled, the mixture was heated, then the jar was pushed into the furnace to cool down.
It was then heated again, cooled again and the mold released the mixture, which was placed into a glass bottle, and heated again to cool the bottle down.
The glass bottle was then pushed into a furnace and heated for another 30 minutes, at which point the mixture had been cooled to a temperature of just 1.2C (2.6F).
The mixture was then cooled again to about 1C and then allowed to cool again, at a temperature just below the critical temperature of about 1.1C (1.7F).
After a few minutes, the bottle was put into a dish of water, which had been mixed with a mixture that contained carbon dioxide and water, and the mixture slowly evaporated.
The mixture remained at a constant temperature until it cooled to about 0C (38F) and the bomb was placed in a sealed jar with the lid removed.
The scientists say the technique allows them to make very complex and high-temperature bombs, with the bomb having a range of weights from one gram to five kilograms.
They say they have also been able make “potentially quite costly” bombs that are smaller than a human hair.
The process involves the heating of carbon, carbon dioxide or carbon dioxide with water to create tiny bubbles of bubbles, then allowing them to slowly cool down to a critical temperature.
This process has been used before to make bombs, but it has only produced bombs about one centimetre in diameter.
The new technique is the first time it has been able, and it is hoped that it will one day be able to make “big” bombs, in the order of the size of a football.
“If we can get a device of the right size, we will be able,” one of those who worked on the project, Dr Peter Wright, told BBC Radio 4’s Today programme.
“And if you want to get to the very big bomb, you’ll need to get a lot bigger.”
The work has been funded by the Science and Technology Facilities Council (STFC) and supported by the Royal Society of Chemistry.
The project has been carried out by a team of scientists from the University, the University’s Department of Physics and Engineering and the University Museum of London.
They hope to have a working prototype by the end of the year, and they have a new design for a larger bomb, with a range from five to 10 kilograms.
Dr Wright said that he hopes to be able eventually to make the bomb smaller, but he added that he has not yet received funding to do so.
The first version of the bomb, which can weigh just two grams, was made in 2008.
A second version, made from a mixture made from 10 different materials, weighed 25 grams.
A third, made of carbon and water with a different mix of water added, weighed 30 grams.
“This is the biggest, the largest one that we’ve made,” Dr Wright told BBC World News.
He said that they have not yet tested their method on the first version.
“We haven’t tested it on that yet, but we’re confident we can do that,” he said.
The research has also been supported by research from the Department of Chemistry at the Royal Institution.