Actually, everyone uses pure Abstract Algebra on a daily basis. In a few paragraphs I will show how but first here's how this new branch relates to the old branch of Elementary Algebra, which is the algebra most people learn first.

One of the fundamental algorithms of Abstract Algebra is an algorithm from Elementary Algebra called the Division algorithm, which states that when one non zero integer divides another integer, the dividend is equal to the divisor times a unique quotient plus a unique remainder.

One of the fundamental algorithms of Abstract Algebra is an algorithm from Elementary Algebra called the Division algorithm, which states that when one non zero integer divides another integer, the dividend is equal to the divisor times a unique quotient plus a unique remainder.

In other words, any 2 integers a, b where b > 0 can be expressed as a = bq + r where q and r are unique integers such that 0 <= r < b where r is the remainder when a is divided by b.

For example, let a = 12 and b = 12 then r = 0 since 12 = 12*1 + 0

This is the same as saying that 12 is congruent to 0 modulo 12 because 12 - 0 is divisible by 12.

Or in other words, 12 = 0 in the set of all integers from 0 to 11.

It can be verified that the sum s of any two integers from the set of all integers from 0 to 11 is still in that set if it is calculated as s = 12q + r

For example, let s = 9 + 5 = 14. While 14 is not in the set from 0 to 11, 14 can be uniquely represented as 14 = 12*1 + 2 so 14 = 2 modulo 12

The fact that the sum of any two elements can be represented by another element in that set means that the set is closed with respect to the operation of addition, and that coupled with a few other properties is what makes this set a group under the operation of addition, it is also a ring under this and the operation of multiplication, and a blank canvas under the operation of exponentiation.

This set is called Z

_{12 }since it is the first positive 12 integers of Z and Z is the set of all integers.
Now let’s get back to how everyone uses this on a daily basis. Enter the clock. Everyone uses the clock except for a few lucky people who don’t care about concrete measurements of time.

At some point of each day most people need to calculate how many hours are left of something, how many hours until something happens and so on. In doing so they are dealing with Abstract Algebra, or more specifically, with the abstract structure of Z

_{12 }under addition.
Note that each row in that table is shifted by 1, which makes it easy to visualize.

Since it is 9 o'clock in City A and City A is 5 hours ahead of City B then it is currently 14 o'clock in City B and since 14 = 12*1 + 2 so 14 = 2 modulo 12 then the clock in City B shows 2.

Further reading:

Algebra by Thomas W. Hungerford

The Theory of Algebraic Number Fields by David Hilbert

Applied Abstract Algebra by Lidl & Pilz

Integers, Polynomials, and Rings by Ronald S. Irving

Since it is 9 o'clock in City A and City A is 5 hours ahead of City B then it is currently 14 o'clock in City B and since 14 = 12*1 + 2 so 14 = 2 modulo 12 then the clock in City B shows 2.

Further reading:

Algebra by Thomas W. Hungerford

The Theory of Algebraic Number Fields by David Hilbert

Applied Abstract Algebra by Lidl & Pilz

Integers, Polynomials, and Rings by Ronald S. Irving