then the liquid would come out of the syringe.
did you really need to know?
nice one!! I'm on you on that one. . .
To draw liquid into a syringe, first, ensure the syringe is sterile and the plunger is fully depressed. Insert the needle into the liquid, then pull back the plunger slowly to create a vacuum that draws the liquid into the barrel. Once the desired amount is collected, remove the needle from the liquid, expel any air bubbles by gently pushing the plunger, and securely cap the needle if necessary.
he pushes the plunger so that he removes the air molecules from the syringe and make it vacuum and then puts it in the medicine and pulls the plunger so that the liquid rises without the air molecules getting in the syringe (arjun)
In the filling of a liquid in a syringe, atmospheric pressure plays a role in pushing the liquid into the syringe barrel when the plunger is pulled back. This pressure difference helps create the suction needed to draw the liquid into the syringe.
The doctor pushes the plunger to expel any air bubbles that may be in the syringe barrel. This ensures that only the liquid medication is drawn up into the syringe and helps with accurate dosage measurement.
When you push down on a syringe plunger, you compress the air or liquid inside, creating increased pressure. Once the plunger is released, the pressure inside the syringe decreases, allowing the plunger to return to its original position due to the force of the surrounding air pressure or liquid pushing back against it. This is an example of how pressure dynamics in a closed system work, causing the plunger to pop back up.
When pushing the plunger of the syringe while my hand was pressing against its end, I noticed that the resistance was significantly increased. This resistance occurred because the pressure applied at the end of the syringe was transmitted through the liquid inside, making it harder to push the plunger.
When the plunger is pulled, the volume inside increases. This reduces the pressure inside, and the air pressure outside forces liquid in, in an effort to make the pressure inside and outside the syringe equal again.
Air pressure helps in pulling medicine from a syringe by creating a difference in pressure between the inside of the syringe and the atmosphere outside. When the plunger is pulled back, it increases the volume inside the syringe, reducing the pressure. This lower pressure allows the higher atmospheric pressure to push the liquid medicine into the syringe, facilitating the withdrawal of the medication. Essentially, the pressure gradient created by the plunger movement enables the liquid to flow into the syringe easily.
To draw 1.1 ml on a syringe, first ensure the syringe is clean and properly calibrated. Pull back the plunger to the 1.1 ml mark, ensuring there are no air bubbles in the barrel. Insert the needle into the liquid and push the plunger slightly to expel any air, then pull back the plunger to the 1.1 ml mark again if necessary. Finally, remove the needle from the liquid and check the measurement before using it.
Oh, dude, it's like this: when you pull back the plunger on a syringe, you decrease the pressure inside, creating a pressure difference with the atmosphere. So, the higher pressure outside pushes the liquid or medication into the syringe. It's basically like nature's way of helping you get that flu shot without even thinking about it.
plunger's tip to accurately measure the volume of liquid being dispensed or drawn into the syringe. The measurement is typically indicated in milliliters and should be read at eye level for precision.
To draw up 6.7 cc (cubic centimeters) of a liquid, first ensure you have the appropriate syringe calibrated in cc. Pull the plunger back to the 6.7 cc mark, then insert the needle into the liquid and push the plunger down to expel any air bubbles. After that, draw back the plunger slowly until the liquid reaches the 6.7 cc mark. Finally, check for air bubbles again before removing the syringe from the vial.