Counter-top projection laser scanner for omni-directional scanning of code symbols within a narrowly confined scanning volume, while preventing unintentional scanning of code symbols of nearby objects

1. A counter-top projection laser scanner for producing a narrowly confined scanning volume for scanning code symbols presented therein, while preventing unintentional scanning of code symbols on nearby objects located outside thereof, said counter-top projection laser scanner comprising:

• (a) a compact housing having a light transmission window through which laser light can exit said compact housing, travel towards an object bearing a code symbol and reflect therefrom, and at least a portion of said reflected laser light travel back through said light transmission window and enter said compact housing;
  
  (b) an optical bench mounted in said compact housing and extending along a central reference axis;
  
  (c) a laser beam producing means disposed within said compact housing from producing a laser beam;
  
  (d) a laser beam sweeping means mounted within said compact housing with respect to said optical bench for rotation about a rational axis which intersects said central reference axis, and where the intersection of said rotational axis and said central reference axis defines a central reference plane which extends along said optical bench for referencing the relative position of scanner components about said optical bench;
  
  said laser beam sweeping means having at least first, second and third rotating light reflective surfaces each being disposed at a different acute angle with respect to said rotational axis, for sequentially sweeping the laser beam about said rotational axis along a plurality of different paths;
  
  (e) a stationary array of at least first, second, third, and fourth and fifth stationary light reflective surfaces mounted within said compact housing with respect to said optical bench and disposed substantially under said light transmission window;
  
  said first and second stationary light reflective surfaces being symmetrically disposed on opposite sides of said central reference plane, and closely adjacent said beam sweeping means, andsaid third and fourth stationary light reflective surfaces being symmetrically disposed on opposite sides of said central reference plane, and closely adjacent said first and second stationary light reflective surfaces, respectively, andsaid fifth stationary light reflective surface being disposed about said central reference plane, and closely adjacent said third and fourth stationary light reflective surfaces;
  
  (f) a light collection subsystem disposed within said compact housing, and including(1) a light collection element, mounted along said central reference plane, for collecting reflected laser light off said laser beam sweeping means, and(2) light receiving means for receiving laser light from said light collection element at a point substantially within said central reference plane, and detecting the intensity of said received light and producing an electrical signal indicative of said detected intensity;
  
  (g) signal processing means disposed within said compact housing, for processing said electrical signal and producing scan data representative of a scanned code symbol;
  
  (h) control means within said compact housing for controlling the operation of said counter-top projection laser scanner so that, during scanner operation, the laser beam produced from said laser beam producing means passes along a portion of said central reference plane, to the first, second and third rotating light reflective surfaces of said laser beam sweeping means, and as the laser beam sequentially reflects off said first, second and third rotating light reflective surfaces, the laser beam is repeatedly swept across said first, second, third, and fourth and fifth stationary light reflective surfaces thereby producing first, second, third, and fourth and fifth groups of plural scan lines, respectively, which are projected out through said light transmission window and intersect about a projection axis within a narrowly confined scanning volume extending from adjacent said light transmission window to at least about six inches therefrom so as to produce a highly collimated projected scanning pattern within said narrowly confined scanning volume, and(i) said compact housing being supportable relative to a counter-top surface so that, during scanner operation, said highly collimated scanning pattern is projected above said counter-top surface within said highly collimated scanning volume, andwhen a code symbol is presented within said narrowly confined scanning volume,(i) the code symbol is scanned omnidirectionally by said highly collimated scanning pattern while preventing unintentional scanning of code symbols on objects located outside of said narrowly confined scanning volume,(ii) at least a portion of the laser light reflected from said scanned code symbol is directed through said light transmission window, reflected off at least one of said first, second, third, fourth and fifth stationary light reflective surfaces, and then reflected off at least one of said first, second and third rotating light reflective surfaces of said laser beam sweeping means, and(iii) thereafter said reflected laser light off said laser beam sweeping beams is collected by said light collection element, and received by said light receiving means for detection, and said electrical signal is produced for processing by said signal processing means.