Pressurized fluid flow system for a reverse circulation down-the-hole hammer and hammer thereof

1. A pressurized fluid flow system for a reverse circulation Down-The-Hole hammer, wherein the hammer comprises the following main components:

• a cylindrical outer casing having a front end and a rear end;
  
  a rear sub affixed to the rear end of said outer casing for connecting the hammer to the source of pressurized fluid;
  
  a centrally-bored piston slidably and coaxially disposed inside said outer casing and capable of reciprocating due to the change in pressure of the pressurized fluid contained inside of a front chamber and a rear chamber located at opposites ends of the piston, the piston having outer sliding surfaces and inner surfaces;
  
  a drill bit slidably mounted in the front end of the hammer on a driver sub mounted in the front end of the outer casing, the drill bit being aligned with the outer by means of a drill bit guide disposed inside said outer casing; and
  
  a sample tube coaxially disposed within the outer casing, passing through the central bore of the piston and extending from the drill bit to the rear sub, the sample tube having inner surfaces and outer surfaces;
  
  wherein the pressurized fluid flow system of the invention comprises;
  
  a cylinder coaxially disposed in between the outer casing and the piston, the cylinder extending from the rear sub to the drill bit guide and having an inner surface and an outer surface;
  
  a cylindrical control tube coaxially disposed in between the piston and the sample tube, the cylindrical control tube extending forward from the rear sub to which it is coupled by a coupling portion thereof and having inner surfaces and outer surfaces;
  
  a discharge chamber, defined by one or more recesses in the inner surface of the outer casing and internally delimited by the cylinder, wherein the discharge chamber is in permanent fluid communication with the bottom of the hole for discharging the pressurized fluid from the front and rear chambers; and
  
  an internal chamber formed in a central recess made in the inner surfaces of the piston and delimited by the outer surfaces of the sample tube alone or together with the outer surfaces of the control tube, depending on the position of the piston during the operation of the hammer, wherein the internal chamber is in permanent fluid communication with the source of pressurized fluid for supplying said pressurized fluid to the front and rear chambers;
  
  wherein the cylinder has a front set of pressurized fluid discharge through-ports and a rear set of pressurized fluid discharge through-ports for respectively channeling the pressurized fluid out of the front and rear chambers and into the discharge chamber;
  
  wherein the control tube has at its coupling portion pressurized fluid inlet means connected to an annular passageway formed between the control tube and the sample tube for allowing the pressurized fluid to flow from the rear sub to the internal chamber;
  
  wherein the sample tube comprises a recessed front-end outer surface portion that forms a front annular supply passage with the inner surfaces of the piston for channeling the flow of pressurized fluid into the front chamber;
  
  wherein the control tube comprises a rear-end recessed outer surface portion for creating a rear annular supply passage between the inner surfaces of the piston and said rear-end recessed outer surface portion of the control tube for channeling the flow of pressurized fluid into the rear chamber;
  
  whereby the flow of pressurized fluid discharged from the front and rear chambers is controlled solely by the overlap or relative position of the outer sliding surfaces of the piston with the inner surface of the cylinder, while the inflow of pressurized fluid to the front and rear chambers is controlled by the overlap of the inner surfaces of the piston with the outer surfaces of the cylindrical control tube and the outer surfaces portion of the sample tube.