Summertime Data Room Monitoring: Part 2
Filed under: airflow monitoring, Data Center, environmental monitoring
In part one I went over the advantages of Temperature, Humidity, and Water leak monitoring. In this continuation of the saga will continue to focus on more ways to prevent the summer weather from damaging your data center while staying proactive in your defense. Read more
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The future of airconditioning and how the rest of the world can monitor temperature
I just found an entry on Slashdot about a deal between IBM & Carrier to create and market a web enabled air conditioner. Apparently you are able to gain complete control of the unit via the simple web interface. Being a geek, this intrigued me. What about everyone else who cannot obtain one of these units?
Being able to log in and monitor the environment is something you can do with the Ravica line of SensorProbes. I would suggest getting one of the temperature and humidity probes to start with. From my research, high humidity plays a big role in the cost and operation of your air conditioning units. Being able to trend and be alerted during these times can be beneficial.
Next, I would use the airflow probe to tell me when the unit is on. I know, it is an odd way to detect the air conditioners state, but trust me, it’s logical. You can use an airflow sensor on any type of unit. Like the one in the above picture or built-in industrial type. With an airflow sensor, you are not limited to testing current flow or temperature.
Last, but not least, I would use the Sensor Controlled Relay to be able to turn off the unit, if you needed to, in an emergency situation.
So the good news is that you can implement Ravica’s environmental probes in various ways to help monitor your environment. What’s even better is that this technology is available to every one.
- JimmyD
Ravica’s Sensor Controlled Relay – The Rosetta Stone?
Filed under: airflow monitoring, Data Center, environmental monitoring
A few weeks ago I talked about using the sensor controlled relay to turn on lights once an alarm had been triggered. In this blog I wanted to give another example of how versatile these units can be.
Solutions . . .
A great example is the solution that I found for a local amusement park. One of their outdoor venues was having an 
issue with their digital photography equipment overheating. It wasn’t economical to add air condition to the unit, so they needed to find a way to turn on multiple overhead fans automatically.
The management of this unit fell under the IT department, and the admin wanted to remotely monitor the data from his office (or any other portable device). The end solution was to monitor multiple environmental variables with the Ravica Sensor Probe and use the Sensor Controlled Relay to switch on the fan when the room temperature rises beyond the threshold level.
Since the sensor control unit has a user friendly web interface and an autosense feature, setting up the Sensor Controlled Relay is easy. The Sensor Controlled Relay can also be controlled via external computers, using the included SNMP command line utilities either interactively or programmatically.
From the unit itself, you can monitor the status of the Sensor Controlled Relay by four LEDs on the board. You can also monitor the unit remotely by using SNMP traps or the web interface, as well as e-mail and SMS alerts.
Implementation . . .
“The Sensor Controlled Relay provides 1 high-power SPDT 5V relay, with the maximum load up to 15A at 220 VAC. It includes Metal Oxide Varistors (MOVs) and Snubber circuits to protect the open contacts of the relays from high voltage spikes or noise transients. It monitors the power and load, and accepts a control signal, which is sent from the SensorProbe.”
We outsourced a local contractor to do the electrical work and the end result was better then we expected. Not only did we eliminate the equipment from overheating, but we are also able to trend the temp of the units over a given amount of time. This gave the admin a better picture of demand and heat generation.
Another thing to remember is the inlaid protection of this sensor. The Sensor Controlled Relay, it has a built in 16Amp circuit breaker and a 15Amp fuse (380 VAC, 125 VDC) giving it double protection for the external devices and possible damages by electrical fault. This assures protection for your sensor and your investment.
Conclusion . . .
As you can see, the Ravica Sensor Controlled Relay has many uses. It’s ability to control an array of analog devices makes it a versatile solution. It’s ability to monitor and protect itself make it a smart investment. That is why I recommend it every chance that I get.
- JimmyD
Yahoo powers data center using Niagara Falls; Google raises data center temperatures
Filed under: Data Center, environmental monitoring, humidity monitoring, temperature monitoring
If I received an invitation to visit the offices of Google and Yahoo, I wouldn’t want to spend a lot of time snooping 
around the desk of the company founders. I’d rather spend my time checking out their data centers. Just imagine being among the machines that crunch all that search and email data zipping around the world. Just imagine what the physical security must be like at their data centers…
Yahoo last month announced plans to build its greenest data center in Lockport, N.Y. Yahoo co-founder and Chief Yahoo David Filo explains in his blog that the data center will be designed to use 100% outside air to cool the servers. And the resource used to power the data center and the servers will be the renewable hydroelectric power from the Niagara Falls. Read more
5 tips for an energy-efficient data center
Designing a data center is much like designing a nursery for a newborn baby. You want your pride and joy to be happy and thrive in a room that’s not too cold, not too warm, and have the correct humidity. Below are five top tips to a happy data center. The tips are taken from the Green Grid‘s recently released whitepaper Fundamentals of data center power and cooling efficiency zones.
1. Blowing hot and cold: Having parallel rows of equipment racks facing forward may look neat and tidy but it could make a sauna out of your data center. IT equipment sucks in cool air via the front and pushes out hot air from the back. If a machine is spewing out hot air the device behind it is sucking that in when it should be taking in cold air. Imagine how hot the air must be in the last row of machines. The ideal placement for rows of equipment would be to have the front of the servers facing each other. The backs of the rows should also be facing each other to create a hot aisle/cold aisle configuration.
2. Place cables overhead: If the space underneath the raised floor is a spaghetti junction of cables cool air won’t be able to do its job in the data center. Cables should be distributed overhead and unused raised floor cutouts should be blocked to eliminate unwanted air leakage. The Green Grid recommends that perforated tiles, with a design of about 25% open area, should be used to ensure uniform and predictable airflow distribution in lower density areas.
3. Recommended temperatures: The recommended range of temperature for critical enterprise server and storage environments is between 64.4° to 80.6° F (18° to 27° C), according to the American Society of Heating, Refrigeration and Air Conditioning Engineers (ASHRAE), as cited in the whitepaper. ASHRAE also specifies a dew point value of about 5.5° C (41.9° F).
4. Set air conditioners to the same levels: Computer room air conditioning units with humidifiers are a great addition to ensure optimum humidity of the data center but if you have more than one, be sure that they are set to the same settings. If not, they could be operating at odds with one dehumidifying the air while the other is humidifying it.
5. Cool the source. The white paper recommends using row and rack-based cooling to address dynamic hot spots that can form as workloads are constantly shifted from one server to another. Cool air has a much shorter path of distribution, so bringing cooling closer to the heat source is key.