Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
  • H04R1/00—Details of transducers, loudspeakers or microphones
  • H04R1/20—Arrangements for obtaining desired frequency or directional characteristics
  • H04R1/22—Arrangements for obtaining desired frequency or directional characteristics for obtaining desired frequency characteristic only 
  • H04R1/28—Transducer mountings or enclosures modified by provision of mechanical or acoustic impedances, e.g. resonator, damping means
  • H04R1/2807—Enclosures comprising vibrating or resonating arrangements
  • H04R1/2815—Enclosures comprising vibrating or resonating arrangements of the bass reflex type
  • H04R1/2819—Enclosures comprising vibrating or resonating arrangements of the bass reflex type for loudspeaker transducers
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
  • H04R1/00—Details of transducers, loudspeakers or microphones
  • H04R1/20—Arrangements for obtaining desired frequency or directional characteristics
  • H04R1/22—Arrangements for obtaining desired frequency or directional characteristics for obtaining desired frequency characteristic only 
  • H04R1/28—Transducer mountings or enclosures modified by provision of mechanical or acoustic impedances, e.g. resonator, damping means
  • H04R1/2807—Enclosures comprising vibrating or resonating arrangements
  • H04R1/2815—Enclosures comprising vibrating or resonating arrangements of the bass reflex type
  • H04R1/2823—Vents, i.e. ports, e.g. shape thereof or tuning thereof with damping material
  • H04R1/2826—Vents, i.e. ports, e.g. shape thereof or tuning thereof with damping material for loudspeaker transducers

Definitions

• the present invention relates to speaker enclosures and particularly to ducted port speaker enclosures.
• Sound may be defined as vibrations produced by an ob ⁇ ject. Whenever an object vibrates, it causes the surround ⁇ ing air to compress and expand and, in turn, the compressions and expansions in the air further away.
• the compressions and expansions are called sound waves.
• the pitch of the sound is determined by the frequency of its vibrations and is meas ⁇ ured in hertz or Hz.
• the intensity of the sound is determined by the amplitude or distance the vibrating object moves as it vibrates and is measured in decibels or dB. Pitch affects the loudness but not the intensity of a sound where loudness is the apparent strength of the sensation received by the brain and the intensity refers to the amount of energy in the sound waves.
• the ear has a low sensitivity to low pitches such as the lowest note on a piano having a frequency of 27Hz and some organ notes as low as 15 Hz.
• a sound with an intensity of 60 dB sounds louder at a frequency of 1,000 Hz than at 500 Hz so that a greater intensity is required at the lower frequencies to produce a loudness equivalent to that at the higher frequencies;
• the low frequencies from such instruments as the tympani and the bass guitar may be lost by the average listener because the intensities of the low frequencies either from recordings or even live performances maybe be ⁇ low the range at which these vibrations may be heard.
• Phonograph recordings are made with the use of micro ⁇ phones which change the sound waves into electric currents while the loudspeaker changes the electric currents back into sound waves.
• the loudspeaker must not only reproduce the sounds from the electric currents but must also provide means for in some way increasing the intensity of low frequency sounds to which the ear has relatively low sensitivity.
• the low intensities may be caused by losses occurring because of the sound reproducing process including the recording studio. the record processing, the turntable, and the speakers as well as the associated amplifiers, wiring, connectors, and the like.
• Sound waves will expand outwardly from the source of the sound similar to ripples in a pool of water which are created when a pebble is dropped into it.
• an interference such as a wall which forms a reflecting surface
• the wave will be reflected and again expand but in a new di ⁇ rection depending on the orientation of the reflecting sur ⁇ face.
• the sound wave will be reflected by each of the walls it encounters and the reflected waves will also encounter the walls to be again reflected while new waves are created by the vibrations of the speaker diaphragm.
• Each time there are new vibrations the process is repeated until the various elements of the composite sound in effect become turbulent, set up standing waves, resonance effects, and other phenomena which are exceedingly difficult to analyze and predict.
• the causes can usually only be hypo ⁇ thesized because of the difficulty of examining the complexity of the sound waves within the cabinet under the influence of the vibrating diaphragms.
• Various formulae and concepts have been suggested to predict the performance of speaker enclo ⁇ sures, however, in the final analysis, the human ear is the determining factor as to whether a particular speaker enclo ⁇ sure is producing sounds at the proper intensities; over the listening range.
• Speaker enclosures fqr enhancing the low frequency sounds are well known in the art and are usually referred to as bass- reflex or ported boxes; the ports are sometimes referred to as ducted ports which is a combination of a sound duct and its associated port opening. They contain one or more woofers or low-frequency range speakers, tweeters or high-frequency speakers, and probably one or ' ore mid-range speakers, and are tuned with ducted ports. As described by David Weems in "Building Speaker Enclosures", published'by TAB Books, Inc., Catalogue No. 62-2309 of Radio Shack, the design and construe- tion of several types of ported boxes are developed from math ⁇ ematical formulae and curves.
• Patent No. 3,037,081 discloses an acoustic resonator with a woofer and a ducted port wherein there is a combination of a low value of the volume parameter and various combinations specified in order to increase the equivalent mechanical .resistance in series with the diaphragm of the loud ⁇ speaker.
• Patent No. 3,952,159 discloses a bass-reflex repro ⁇ ducing system employing a woofer, a tweeter, a ducted port and exhibiting a predetermined compliance in order to achieve the low frequency response.
• An object of the present invention is to provide a small, relatively inexpensive ducted port speaker enclosure.
• Another object of the present invention is to provide a ducted port speaker enclosure which extends the low-frequency range of the reproduced sound and increases the intensity of the low-frequency sound vibrations.
• a further object of the present invention is to provide a ducted port speaker enclosure wherein its geometry including the size of the enclosure, the locations of the speakers, and the sizes and locations of the .speakers, and the sizes and lo ⁇ cations of the ducted ports are based solely on the dimensions of said speakers.
• FIG. 1A is a fragmentary front view of a 2-woofer ducted port speaker enclosure.
• FIG. IB is a fragmentary side view of a 2-woofer ducted port speaker enclosure including hypothesized flow paths of the air within the enclosure.
• FIG. 2A is a fragmentary rear view of the top speaker of 2-woofer ducted port speaker enclosure illustrating the loca ⁇ tion of a damping material on the top-facing and the bottom- facing sectors of the ' speaker frame.
• FIG. 2B is a rear view of the bottom speaker of the 2- woofer ducted port speaker ' enclosure illustrating the location of the four sectors of the speaker frame.
• FIG. 3A is a fragmentary front view of a 1-woofer ducted port speaker enclosure.
• FIG. 3B is a fragmentary side view of a 1-woofer ducted port speaker enclosure including the hypothesized flow paths of the air mass within the enclosure.
• FIG. 4A is a fragmentary front perspective of the left hand port of a 2-woofer ducted port speaker enclosure.
• FIS. 4B is a fragmentary front perspective of the right hand port of a 2-woofer ducted port speaker enclosure.
• FIG. 5A is a fragmentary front perspective of the left hand port of a 1-woofer ducted port speaker enclosure.
• FIG. 5B is a fragmentary front perspective of the right hand port of a 1-woofer ducted port speaker .enclosure.
• FIG. 6A shows the curves of loudness vs. frequency of a 2-woofer ducted port speaker enclosure as measured at the bot ⁇ tom 8-inch speaker and a port respectively.
• FIG. 6B shows the curve of loudness vs. frequency of a 2-wo ⁇ fer speaker enclosure which shows the summation of the curves of FIG. 6A.
• FIG. 7A shows the curves of loudness vs. frequency of a 1-woofer ducted port speaker enclosure as measured at the 8-inch speaker and at a port respectively.
• FIG. 7B shows the curve of loudness vs-. frequency of a 1-woofer ducted port speaker enclosure which shows the summa ⁇ tion of the curves of FIG. 7A.
• FIG. 8A shows the curves of loudness vs. frequency of a 1-woofer ducted port speaker enclosure as measured at the 6 - inch speaker and at a port respectively.
• FIG. 8B shows the curve of loudness vs. frequency of a 1-woofer ducted port speaker enclosure which shows the summa ⁇ tion of the curves of FIG. 8A.
• TWO-WOOFER SPEAKER SYSTEM Referring to FIGS. 1A and IB, the size of the ported cabinet 10, the locations of a ⁇ ass- range woofer speaker 12 and a bass-range woofer speaker 14,and the sizes and locations of a sound duct 16 and a sound duct 18 have been determined experimentally by the inventor for the purpose of extending the low-bass range of the reproduced sound from cabinet 10. All measurements can be determined from relatively simple relationships based solely on speaker dimensions as derived from experimental determinations by the inventor.
• Speaker 12 is conventionally mounted in vertical align ⁇ ment with and below speaker 14 on front panel 20 and both speakers are centered between panels 22 and 24 of the 2- woof- er cabinet 10 with cones 26 and 28 of speakers 12 and 14 re ⁇ spectively projecting within cabinet 10 through openings 30 and 32 respectively in panel 20.
• Speaker 12 is located so that its center 34 is at a distance of twice its cone radius r.., or 2r 1 , above the inside wall 35 of bottom panel 36 and at a dis ⁇ tance from the inside wall 37 of panel 22 that is the sum of cone radius r. plus 1.3/1.6 of cone radius r ⁇ , or 1.81'r..
• the size relationship of speakers 12 and 14 is such that cone rad ⁇ ius r. of speaker 12 may be equal to or greater than the cone radius r ⁇ of speaker 14.
• the inventor has determined experi ⁇ mentally that it is preferred that r- should be on the order of 4/5 of r ⁇
• cabinet 10 and of sound ducts 16 and 18 are inside dimensions unless other ⁇ wise noted.
• Speaker 14 is located so that its center 38 is at a dis ⁇ tance from center 34 of speaker 12 which is equal to the sum of r_ + 1.8/2.9 r 2 + r. or (1.62r 2 + r.) .
• Line ⁇ is parallel to bottom panel 36 and line ir bi ⁇ sects panel 22 between bottom panel 36 and top panel 39.
• To locate line m. extend a line 40 from center 38 at an angle of -45 from a horizontal axis -42 at center 38, said line 40 in ⁇ tersecting cone 28 at point 44, and extend a line 46 from cen ⁇ ter 38 at an angle of +225 from said axis 42, said line 46 intersecting cone 28 at a point 48.
• Line m. is a straight line passing through points 44 and 48 respectively and intersecting panels 22 and 24 at a point 50 and a point 52 respectively.
• Line n. passes through center 34 of speaker 12 and is parallel to line m. .
• Line n ⁇ intersects panels 22 and 24 at a point 54 and a point 56 respectively.
• Distance E.. between lines m. and n* is (r. + 1.8/2.9 r 2 ) of E. - r, + 0.914 r,.
• Width W. of cabinet 10 is twice (r. + 1.3/1.6 r.) or W 1 - 3.625 r ⁇ .
• line 1. along wall 57, extend a line 58 from center 38 at an angle of +135° from axis 42, said line 58 intersec ⁇ ting cone 28 at point 60; line 1. extends from point 60 to the intersection of panels 20, 22, and 39 at point 62.
• line 64 from center 38 at an angle of +45° from axis 42, said line 64 intersecting cone 28 at point 66; line 1- extends from point 66 at the in ⁇ tersection of panels 20, 24, and 39.
• Line q. is the center axis of sound ducts 16 and 18 and is parallel to line ⁇ t ⁇ . .
• Line q ⁇ ⁇ is located at a distance E- from line ⁇ where distance E, is equal to distance E..
• sound duct 16 is affixed to wall 37 and to wall 70 at port opening 76 in panel 20, and is com ⁇ prised of a top 78, a side 80, and a bottom 82 all orthogon ⁇ ally and sealingly joined together and with wall 37 to form a sound duct of which wall 37 between top 78 and bottom 82 forms a fourth side of said sound duct.
• sound duct 18 is affixed to wall 84 and to wall 70 at.
• a port opening 77 in panel 20 is comprised of a top 86, a side 88, and a bottom all orthogonally and sealingly joined together with wall 84 to form a sound duct of which wall 84, between top 86 and bottom 90 forms a fourth side of said sound duct.
• Thickness J of the respective top, side, and bottom of sound ducts 16 and 18 is on the order of 1/8 to 3/16 inch.
• the thickness T of front panel 20 depends on the .mounting re ⁇ quirements of the speaker employed; a thickness of % inch is usually desired for a 6 inch speaker while 5/8 to 3/4 inch thickness is desired for an 8 inch speaker.
• the thickness T of panel 20 is uniform and in . accordance with the maximum re ⁇ quired ordinarily if different sized speakers are employed.
• the thickness of the other, panels of cabinet 10 is similar to that of the front panel 20. All said panels are ortho ⁇ gonally joined together with sealed joints to form cabinet 10. The panels must have sufficient rigidity to withstand the vi ⁇ bratory forces of the reproduced sounds without flexing.
• Height F,, width K ⁇ , and depth R 1 of sound duct 16 are determined as follows, referring to FIG. 4A: a. Line q. bisects height F. which extends from inside wall 92 of top 78 to the inside wall 94 of bottom 82. Height F. measured along the outside wall 96 of side 80 + the thick ⁇ ness J of top 78 will coincide with line 1. a t point 98 w h en when line 1 1 is projected onto the inside surface of panel 20. Note that height F. is the same dimension as the depth F of cone 26 in FIG. IB. b. Width K * extends from the inside wall 37 of panel 22 to the inside wall 100 of side 80.
• Width K measured along the outside wall 102 of top 78 + the thickness J of side 80 will coincide with line at point 98 also when line r. is projected onto surface 70 of panel 20.
• Depth R. extends from said point 98 on the inside wall 70 of panel 20 orthogonally for a distance equal to F l + ⁇ F l " T * Note that the total depth of sound duct 16 will be the sum of depth R ⁇ ⁇ + the thickness T of the front panel 20.
• the height F 2 , K 2 , and depth R 2 of sound port 18 are de ⁇ termined as follows, referring to FIG. 4B: a. Line q. bisects F 2 which extends from inside wall 104 of top 86 to the inside wall 106 of bottom 90. Height F 2 measured along outside wall 108 of side 88 + the thickness J of top 86 will coincide with line 1- at point 110 when line l 2 is projected onto the inside surface 70 of panel 20. Note that height F 2 is the same dimension as the depth of cone 26 in FIG IB; F ⁇ » F-.
• Damping material I having a thickness on the order of 1 inch, is affixed along the inside walls 37 and 84 of side panels 22 and 24 respectively, extending from the in- - side wall 35 of bottom panel 36 to the outside wall 116 of of sound port 16 and the outside wall 118 of sound duct 18 respectively.
• the inventor has determined experimentally that the section of material I opposite speaker 12 may be hollowed out to a thickness on the order of k inch to further enhance the bass; the exact height of said hollowed out section is not critical and may be on the order of half the diameter of said speaker, centered about line n ⁇ , and extending the full depth of cabinet 10.
• Speaker 14 has an overall depth Y which conventionally is slightly less than twice the depth F of speaker con ⁇ ' 26 when r 2 is on the order of 4/5 of r..
• speaker 14 has a frame 120 with a plurality of open sectors of substantially similar dimensions spaced substantially sym ⁇ metrically about said frame such as, for example.
• Radio Shack Speaker Model No. 40-1006 wherein speaker 14 is shown as hav ⁇ ing a top-facing sector 122 and a bottom-facing sector 124 which are respectively covered with a sound damping material 126 for damping the sounds from said sectors but not inter- ferring with the vibratory movements of cone 28.
• Material 126 such as, for example, metal or hard plastic, is on the order of 1/16 inch thick.
• a conventional mid-range speaker (not shown) and a tweeter (not shown) may be installed in appropriate openings (not shown) in front panel 20 within the area bounded by line q., line 1., the bottom side 128 of top panel 39, and line 1 2 .
• a conventional crossover network (not shown) may be mounted on the inside wall 70 of front panel 20 in either the area bound ⁇ ed by line 1 ⁇ top 102 of sound duct 16, and inside wall 37 of panel 22 slightly above sound duct 16 or in the area bound ⁇ ed by line l 2 ,top 114 -of sound duct 18, and inside wall 84 of panel 24 slightly above sound duct 18.
• FIG. IB The side view of cabinet 10 in FIG. IB illustrates a hy ⁇ pothesized flow of air mass within cabinet 10 caused by the impact of the sounds generated by speakers 12 and 14 and the presence of sound ducts 16 and 18. It is hypothesized that the air mass will become turbulent and vibrational causing a pro ⁇ nounced flow of air mass in two directions from speaker 12. A first direction 69 will be downward along wall 70, across wall 35, and upward along wall 72, then curving upward towards sound ducts 16 and 18.
• a second direction is hypothesized to to be upward along wall 70, over speaker 14 and also by ⁇ passing speaker 14, across wall 128, downwardly part way along wall 72, then curving towards sound ducts 16 and 18, meeting the flow of air mass from the first direction 69 at the sound ducts 16 and 18 as in FIG. IB.
• the bass-range vibrations gen ⁇ erated by bass speaker 14 are hypothesized to reinforce the bass-range vibrations generated by speaker 12 at said sound ducts.
• the sound vibrations from the uncovered sectors 130 and 132 respectively of frame 120 are hypothesized to reinforce the movement of air mass generated by speaker 12 by exercizing more pressure to the air mass within cabinet 10 and producing a deeper bass because of the increased pressure and resultant increased intensity as disclosed by the test results as here ⁇ inafter described.
• frame 120A of speaker 12 has open s.ectors substantially similar to frame 120 of speaker 14 and having a top-facing sector 122A, a bottom-facing sector 124A, a left-side facing sector 130A, and right-side facing sector 132A.
• frame 120A it is not necessary that frame 120A be similar to frame 120 or that it be oriented in any particular direc ⁇ tion although it is preferred that its orientation be the same as for speaker frame 120 if a four-sector frame is used.
• ONE-WOOFER SPEAKER SYSTEM The procedures for developing the design of the one-woofer speaker system are substantially similar to those described for the two-woofer speaker system hereinbefore. ;
• the size of the one-woofer ported cabinet 134, the position of the bass-range woofer speaker 136, the sizes and locations of a sound duct 138 and ; - sound duct 140, have been determined experimentally by the in ⁇ ventor for the purpose of extending the bass-range of the re ⁇ produced sound from cabinet 134. All measurements can be deter ⁇ mined from relatively simple relationships based solely on speaker dimensions.
• Speaker 136 is mounted on panel 142 and centered between panels 144 and 146 of cabinet 134 with cone 148 of speaker 136 projecting within cabinet 134 through opening 150 in panel 142. Speaker 136 is located where its center 152 is at a dis ⁇ tance of twice the radius r of its cone 148 above the inside wall 154 of the bottom panel 156 and at a distance from the inside wall 158 of panel 144 which is the sum.of cone radius r + 2/3.5 r or 1.57r.
• Line ⁇ is parallel to bottom panel 156 and it bisects panel 144 between bottom panel 156 and top panel 160.
• cate line m 2 extend a line 162 from center 152 at an angle of +45° from a horizontal axis 2 passing through center 152, said line 162 intersecting cone 148 at point 164, and extend a line 166 from center 152 at an angle of +135° from said line n 2 , said line 166 intersecting cone 138 at point 168.
• Line m 2 is a straight line passing through points 164 and 168 respect ⁇ ively and intersecting panels 144 and 146 at points 170 and 172 respectively.
• Line 1- extends from point 168 along wall 174 of front panel 142 to point 176 at the intersection of panels 142, 144, and 160.
• Line 1. extends from point 164 along outside wall 174 of front panel 144.to point 170 at the intersection of panels 142, 146, and 160.
• Line q- is the center axis of sound ducts 138 and 140 and is parallel to line ir .
• Line q 2 is located at a distance E. from line m 2 where distance E. is equal to distance E, or
• sound duct 138 is affixed to the inside wall 158 of panel 144 and to the inside wall 180 of front panel 142 at a port opening 181 in said panel 142 and is comprised of a top 182, side 184, and bottom 186 all ortho- gonally and sealingly joined together with wall 158 to form a sound duct of which wall 158 between top 182 and bottom 186 forms a fourth side of said sound duct.
• Sound duct 140 is af ⁇ fixed to the inside wall 188 of panel 146 and to the inside wall 180 of front panel 142 at port opening 1.89 in front panel 142 and is comprised of a top 190, side 192, and bottom 194 all orthogonally and sealingly joined together with wall 188 to form a sound duct of which wall 188 between top 190 and bottom 194 forms a fourth side of said sound duct.
• the thickness J of the respective top, side, and bottom of sound ducts 138 and 140 respectively is on the order of 1/8 to 3/16 inch.
• the considerations related to thickness T of the panels of cabinet 134 are similar to those for the panels of cabinet 10 hereinbefore described. All said panels are ortho ⁇ gonally joined together in sealed joints to form cabinet 134. The panels must be rigid in order to withstand the vibratory forces of the reproduced sounds without flexing.
• Height F 3 together with inside width K 3 and depth R 3 of sound duct 138 are determined as follows, referring to FIG. 5A: a. Line q 2 bisects height F, which extends from the inside wall 198 of top 182 to the inside wall 200 of bottom 186. Height F, measured along the outside wall 202 of side 184 + thickness J of top 182 will coincide with line 1. at point 204 when line 1- is projected onto the inside surface 180 of panel 142. Note that height F 3 is the same dimension as the depth F of cone 148 in FIG..3B. b. Inside width K 3 extends from the inside wall 158 of panel 144 to the inside wall 206 of side 184.
• Width K 3 measured along the outside wall 208*' of top 182 + thickness J of side . 184 will also coincide with line 1, at point 204 when line 1 3 is projected onto the inside surface 180 of panel 142.
• Inside depth R extends from point 204 on the inside wall 180 of front panel 142 orthogonally for a distance equal to 4/3 F 3 - T.
• the total depth of sound duct 138 will be the sum of depth R 3 + thickness of the front panel 142 or 4/3 F 3>
• Damping material I having a thickness on the order of 1 inch, is affixed along the inside wall 158 of panel 144 and inside wall 188 of panel 146, extending from inside wall 154 of bottom panel 156 to outside wall 222 of sound duct 138, and from inside wall 154 of bottom panel 156 to outside wall 224 of sound duct 140.
• the inventor has determined experimentally that the material I opposite speaker 136 should be hollowed out to a thickness on the order of inch; the exact height of said hollowed out section is not critical and may be on the order of h the diameter of said speaker 136 centered about line n_ and extending the depth D- of cabinet 134.
• a conventional mid-range speaker (not shown) and a tweet ⁇ er (not shown) may be installed in appropriate openings (not shown) in front panel 142 » within the area bounded by line q 2 , line 1 3 , inside wall 226 of top 160, and line 1..
• a convention ⁇ al crossover network (not shown) may be mounted on the inside wall 180 of front panel 142 either in the area bounded by line
• FIG. 3B the side view of cabinet 134 illu ⁇ strates a hypothesized flow of air mass within cabinet 134 14 caused by the impact of sound vibrations from speaker 136 and the presence of sound ducts 138 and 140.
• the air mass within cabinet 134 will become turbu ⁇ lent and vibrational by the sounds from speaker 136 causing a pronounced flow of air mass in two directions from speaker 136.
• a first direction will be downward along wall 180, across wall 154, and upward along wall 228, then towards sound ducts 138 and 140.
• a second direction 232 is upward along wall 180, a- cross wall 226, downward along wall 228, then towards sound ducts 138 and 140 effectively joining the air mass of the first direction 230 to reinforce the movement of the air mass of the first direction 230 and produce a deeper bass as shown by said test results.
• either the two-woofer speaker cabinet " 10 or of the one-woofer speaker cabinet 134 is relatively straightforward for a do-it-yourselfer or for a manufacturer. All the dimensions are based on dimensions of the speakers utilized. It is commonly known among handymen as to how to in ⁇ stall the sound insulation material on the inside walls of the cabinets and the sound damping material sealingly covering the top and bottom facing sectors of the top woofer in the two- woofer speaker cabinet 10. A convenient opening at the back of the cabinets can readily be provided for having a sealing ⁇ ly fitted door (not shown) for reaching into the cabinets when installing the components.
• the dimensions E 1 must be sub ⁇ stantially similar to dimension E 2 within ten (10%) percent for cabinet 10 and the dimensions E, must be substantially similar to dimension E. within ten (10%) percent for cabinet 134.
• the remaining measurements could be within ten (10%) per- cent of the respective dimensions as determined from the var ⁇ ious relationships without a serious degradation of the bass- range of sounds from said cabinets.
• All inner joints of said cabinets and respective sound ducts should be sealed with a conventional sealer such as, for example, caulking. It is pre ⁇ ferred that the respective speakers in said cabinets fit into the openings which have been routed to provide a close fit be ⁇ tween the respective front panels and said speakers.
• the cabin ⁇ ets constructed according to the present invention will be smaller and less expensive and provide a deeper bass-range than other speakers on the market today except possibly for the larger and more expensive speaker enclosures.
• FIGS. 6A, 6B, 7A, 7B, 8A, and 8B illustrate the relation ⁇ ship between loudness measured in decibels or dB along the vertical or ordinate axis and frequency measured in Hertz or Hz along the horizontal axis or abscissa
• FIGS. 6A and 6B are for cabinet 10
• FIGS. 7A and 7B are for cabinet 134 with an 8-inch speaker
• FIGS. 8A and 8B are for cabinet 134 with a 6 -inch speaker.
• the measurements were made in an aver ⁇ age size room with the microphone held vertically approximate ⁇ ly one inch from the center of the speakers and ports measured.
• the measurements for the sound ducts were made at a single duct opening so that the measurement for sound ducts 16 and 18 were made only at sound duct 16 and the measurement for sound ducts 138 and 140 were made only at sound duct 138.
• the com ⁇ bined loudness-frequency relationships of the sound ducts and speakers as shown in FIGS. 6B, 7B, and 8B were obtained by summing the respective points on the curves in FIGS. 6A, 7A, and 8A.
• Real Time Analyzer No. 3347 manufactured by Bruen and Kjaer, Inc., of Denmark was employed for generating the sound frequencies and for measuring the loudness of the sound out ⁇ puts.
• FIGS. 7A and 8A are for the loudness-frequency relationships at the respective sound ducts.
• the solid curve in Fig. 6A is the loudness-frequency relation ⁇ ship at the lower woofer in cabinet 10.
• the solid curves in FIGS. 7A and 8A are the loudness-frequency " relationships of the speakers in cabinet 134 respectively.
• speaker 14 acts to reinforce and enhance the bass-range sounds from speaker 12 as measured at sound ducts 16 and 18. It is to be noted in FIG. 6A that at 20 Hz the bass output for sound ducts 16 and 18 was on the order of -19 dB while the bass output from speaker 12 was on the order of -28 dB. The following were included in the measurements: speaker 12: 8 inches. Radio Shack model #40-1006; speaker 14: 6k inches. Radio Shack model #40-1009. Cabinet 10 had an in ⁇ side volume of 1.72 cubic feet and was 12 inches wide, 9 inches deep, and 26 inches in height. The sound ducts 16 and 18 were 2k inches wide, 1% inch deep, and Ik inch high.
• FIG. 7A it is to be noted that at 20 Hz the bass-range output for sound ducts 138 and 140 was on the order of -23 dB while the bass-range output from speaker 136 was below -30 dB. The folowing were included in these measure ⁇ ments: speaker 136 ' : 8 inches. Radio Shack model #40-1006. Cab ⁇ inet 134 had an inside volume of 1.07 cubic feet and was 11 inches wide, 9 inches deep, and 18-3/4 inches high. The sound ducts 138 and 140 were ' Ik inch in width, depth, and height re ⁇ spectively. In FIG.

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• 1985
  • 1985-02-14 EP EP19850901220 patent/EP0214130A4/de not_active Withdrawn
  • 1985-02-14 WO PCT/US1985/000228 patent/WO1986005060A1/en not_active Application Discontinuation
  • 1985-02-14 JP JP50094485A patent/JPS61502718A/ja active Pending

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