Boxing Day Linx on Mecca Bingo
It certainly looks like it is going to be exciting online bingo times during the festive period over at Mecca Bingo roomies and we can reveal that a massive guaranteed Boxing Day Bingo Linx game will be coming out to play.
Plus if you fancy a few games of bingo on Christmas Day itself, you will be able to bingo for free with Mecca Bingo and there is more in the way of (big money) to play for on New Year’s Day as well……..with the fab New Year’s Day bingo linx game.
So let’s check out these three great bingo deals from Mecca Bingo in more details roomies.
First up of course are those free bingo games which are set to run at Mecca Bingo on Christmas Day. Between 10am in the morning right up until 10am at night all superbooks at Mecca Bingo will be free bingo. You could play for £10 jackpots on every free online bingo game up to 4pm and then £20 jackpots on every free bingo game thereafter……….so Mecca Bingo will certainly be giving away lots and lots of free cash on Christmas Day and what a great pressie that is for all bingo lovers.
Boxing Day falls on a Sunday this year and we can tell you that 26th December will definitely be an exciting day to be playing online bingo with Mecca Bingo. Why? Well a massive guaranteed £26,000 bingo linx game will be coming out to play on Boxing Day and as this is guaranteed cash that we are talking about, it must be won!
As the bingo linx networked jackpot games are played on the traditional 90 ball bingo format of the game, you also get three chances to bag yourself a fab cash prize and the Boxing Day bingo linx game will payout as follows –
One Line – £4,000
Two Lines – £7,000
Full House – £15,000
If you are not lucky enough to win the Boxing Day bingo linx, you could always try for the special New Year’s Day bingo linx jackpot and we can reveal that this one will be worth a whopping guaranteed £11,000 cash prize.
So that’s free bingo and two massive guaranteed bingo linx games from the Mecca Bingo camp……in terms of bingo, what more could you wish for?
