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Sunday, September 8, 2024

What is plastic injection?

 Plastic injection is a manufacturing technique based on pouring liquid plastic into a mold with a desired form. This proces is not knew and it is at the heart of almost all products you see in your daily life: from cars to spaceships passing through dishes and medical devices, for example.

For instance, the plastic bumper of a car is made by plastic injection. The same is true for the caps of some bottles. 

This industrial process requires different machines and different resines or polymers and although it seems a simple process a number of problems arise during operation. Some examples of plastics are,

  • polypropilene (PP),
  • high density polyethylene (HDPE),
  • acrylonitrile butadiene styrene (ABS),
  • polycarbonate (PC),
  • among others.

  • Fig. 01 Here is a photo of the pellets in the form of small cylinders, ready to be used in a plastic injection machine.

Fig. 02 Here is a photo of the bag in which polymer pellets are sold. This is for high density polyethylene (HDPE).

Three important actors

The mold, the machine and the polymer are the most recognizeble actors in this process. Molds are specially designed and manufactured to hold high pressures of the order of thousands of psi. These are very expensive parts of the process. On the other hand, the machine comes in a variety of pressure capacities and automation features. Also, no any mold can work along any plastic injection machine. Finally, the polymer is key because the mold is designed with a given polymer in mind and this has to meet certain physical properties if good quality products are to be manufactured.

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Thursday, August 29, 2024

a and b constants data for the van der Waals equation

 Here are some data for constants a and b appearing in the van der Waals equation:

Gas Formula a (atm L2/mol2) b (L/mol)
Acetylene C2H2 4.390 0.05136
Ammonia NH3 4.170 0.03707
Carbon dioxide CO2 3.592 0.04267
Ethane C2H6 5.489 0.0638
Ethylene C2H4 4.471 0.05714
Helium He 0.03508 0.0237
Hydrogen H2 0.244 0.0266
Hydrogen chloride HCl 3.667 0.04081
Krypton Kr 2.318 0.03978
Mercury Hg 8.093 0.01696
Methane CH4 2.253 0.0428
Neon Ne 0.2107 0.01709
Nitric oxide NO 1.340 0.02789
Nitrogen N2 1.390 0.03913
Nitrogen dioxide NO2 5.284 0.04424
Oxygen O2 1.360 0.03183
Propane C3H8 8.664 0.08445
Sulfur dioxide SO2 6.714 0.05636
Xenon Xe 4.194 0.05105
Water H2O 5.464 0.03049

Please, be aware of the units.

Any question? Write in the comments and I shall try to help.

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Tuesday, March 26, 2024

Does the state equation matter for Boyle's law?

 First, you need to know that the works on which Boyle's law are based are very old.

Boyle's law is due to the investigations of Robert Boyle by the years 1660! Follow this link if you want read the originial text.

On the other hand, the first equation of state, which is that for the ideal gas law,

$PV=n\text{R}T$

was assembled in 1834 by Emil Clapeyron. Notice, that I said assembled because, as in many fields of science, the ideal gas law is based on the findings of researchers before  1834, Robert Boyle included!

On  the other hand, the second most known equation of state is that of van der Waals,

$\left(P+\dfrac{an^2}{V^2}\right)\left(V-nb\right)=n\text{R}T$

in 1873! Then, what is clear at this point, in answer to the question, is that Boyle's law does not care about the state equation you are using.

Why is it that Boyle's law does not care about the state equation?

The answer is simple. Boyle's law describe the behavior of a system and although it was empirically determined it has been demonstrated its validity in many different systems. However, the state equations are based on Boyle's law (or the findings of Robert Boyle) and worst, the state equations (as the two mentioned early), not always work for every condition.

Any question? Write in the comments and I shall try to help.

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Saturday, February 24, 2024

About the encapsulated relay

 An encapsulated relay is a device used for electric isolation between two circuits. One of these can be potentially dangerous (high voltage) while the other one could be safer for operators (low voltage).


Other usages for encapsulated relays are known such as interfacing between actutators and controlling devices, etc.

How does an encapsulated relay looks like?

Well it depends on the model you are referring to. For example you may find some like those sell by ABB,

Fig. 01 ABB encapsulated relays.

Among the features that make these kind of relays we may list,

  • different number of contacts NO/NC are available. You may have one contact only or four or more,
  • there are options for soldering on pcb,
  • other models are suitable for reduce space installation in control panels,
  • other models are design to resist vibrations.
However, one feature all relays in Fig. 01 share is that these can be mounted on rail DIN.

The encapsulated relays are usually made of two parts. The relay module and the socket. The socket is the accesory that allows the relay module to be firmly mounted to the rail DIN.
Fig. 02 Here is an image of an encapsulted relay showing the pins (bottom metal sticks)

Fig. 03 Socket of an encapsulated relay. Notice that the terminals are numbered and are related to the pin and diagram of the encapsulated relay. These may change from one manufacturer to other.


How does an encapsulated relay work?

In order to give a more precise explanation we should refer to the diagram of an encapsulated relay. Take for instance the one shown below,
Fig. 04 Diagram of and 8-pin encapsulated relay. Numbers in parenthesis are related to the pin of the relay while numbers without parenthesis are related to contact numbers in the socket (see Fig. 03).

Contacts are formed with the terminals available. For example, in Fig. 03 terminals 24 and 21 are a normally open contact NO while 21 and 22 make a normally closed contact NC. As you can see, the encapsulated relay in Fig. 04 has two NO contacts and two NC contacts.

Terminals A1 and A2 are devoted to the coil of the relay. As electricity passes through it the coil is energized and an electromagnet is formed. As the electromagnet is formed the contacts change their position. This is, the NC contacts open and the NO contacts close.

Then, you may use low voltage to operate the relay coil and the contacts for higher voltage so that you are using the encapsulated relay to isolate two different circuits. This is why this device can be considered for safety when designing a control loop.
  



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Wednesday, February 7, 2024

Some examples of temperature instruments

 There is a large list of instruments for temperature measurements.

Here, I shall mention some of these as related to industrial processes.

  • Bulb thermometer
A bulb thermometer with screw-port and metallic case


  • Bimetallic
Three different presentations for bimetallic thermometers


  • Infrared thermometer
Two main types of infrared thermometers


  • Thermocouple
Three different presentations for thermocouples


  • RTD
Three different presentations for RTD's


  • Thermsistor
An example of a thermsistor


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