An incinerator for combustible waste materials including a combustion chamber having a side charging entrance with a base no lower than the mid-plane of the combustion chamber. A ram moves waste materials in an elongated hopper connected to the side charging door into the combustion chamber. A fire door is raised to open the charging entrance and lowered to seal the charging entrance. An elevator positioned under the hopper is charged with waste materials and raised to the level of the hopper until the platform of the elevator becomes the bottom of the hopper on a horizontal level with the base of the charging entrance. An after burner unit can be positioned over the combustion chamber. A heat recovery unit is positioned over the after burner to recover heat from the combustion for use in an outside heating unit.

BACKGROUND OF THE INVENTION 
This application relates to incinerators for burning combustible rubbish 
and garbage, and particularly to medium-speed incinerators. 
One of the problems encountered in such incinerators is in the loading 
process. Incinerators of the type discussed here are loaded in two ways. 
One method is to stuff the waste materials into the bottom of the 
combustion chamber. Another method is to gravity top load the combustion 
chamber, which necessitates raising the waste material completely over the 
combustion chamber from where it is passed into the chamber. The top 
loading process is described in my U.S. Pat. No. 3,881,431. 
The problem with top loading is that a great deal of energy is expended in 
raising the waste materials completely over the combustion chamber. 
The problem with bottom loading is that the waste materials must be stuffed 
into the incinerator. This expends energy. Also, the waste materials are 
not in a condition for full combustion. 
One invention that attempts to deal with these problems is described in 
U.S. Pat. No. 4,074,638 issued to Miller. There, a hydraulically operated 
ram is mounted for reciprocating movement in the lower portion of the 
primary combustion chamber. Located opposite the ram is a discharge door. 
The ram enters the combustion chamber and agitates highly compacted waste 
and also fully extends to push the ash and non-combustible materials to a 
collection site. 
The problem with the Miller invention is that it does not solve the 
problems of stuffing in the waste materials at the lower portion of the 
combustion chamber. The energy expended in raising and stuffing the waste 
materials in the combustion chamber results in the waste materials so 
tightly packed that they are not readily combustible. Also, two rams are 
needed, one for stuffing and one for agitation and removal. 
Other prior art patents in the field of the art of incinerators being 
discussed here besides my previous patent are as follows: U.S. Pat. Nos. 
3,855,950 issued to Hughes Dec. 24, 1974; and U.S. Pat. No. 3,749,031 
issued to Burden, Jr. July 31, 1973. Patents discussed in my U.S. Pat. No. 
3,881,431 include U.S. Pat. Nos. 3,215,101; 3,248,178; and 3,355,254 
issued to Hoskinson; also U.S. Pat. Nos. 3,610,179; 3,631,823; 3,651,771; 
and U.S. Pat. No. 3,567,399. Patents cited in my prior patent are U.S. 
Pat. Nos. 3,552,332; 3,651,771; 3,664,277; 3,749,031; and 3,782,301. 
It is also noted that a large amount of energy is lost to the atmosphere 
during incinerator burning operations. During the winter months this lost 
energy results in a low efficiency operation even when the burning of the 
rubbish is 100 percent efficient since the energy input is entirely lost. 
It is noted here that many incinerators of the type being discussed here 
includes an after burner unit over the combustion chamber. This type of 
unit is set forth in my prior U.S. Pat. No. 3,881,431 and in Miller, U.S. 
Pat. No. 4,074,638. Starved air combustion systems as well-known in the 
art of incinerators are described in both patents. 
SUMMARY OF THE INVENTION 
Accordingly, it is an object of the present invention to provide an 
incinerator that includes a side loader system for waste materials that is 
aligned no lower than the center line of the cylindrical primary 
combustion chamber. 
It is another object of the present invention to provide an incinerator 
that injects the air into the combustion chamber through apertures at the 
bottom of the primary chamber, and also includes a side charging entrance 
located at or above the horizontal mid-plane of the incinerator. 
It is yet another object of the present invention to provide an incinerator 
that includes a combination of a side loader system at or above the center 
line of the combustion chamber with the injection of air into the bottom 
of the primary combustion chamber in opposed jet streams. 
It is yet a further object of the present invention to provide an 
incinerator that includes a charging elevator that lifts the waste 
material to a feed hopper having its bottom wall aligned with the center 
line of the combustion chamber which is aligned with the bottom side of a 
side charging door to the chamber. 
It is still another object of the present invention to provide an 
incinerator that has a horizontal ram that forces the waste material 
through a feed hopper into the side of a cylindrical primary combustion 
chamber at or slightly above the horizontal midplane of the combustion 
chamber. 
The incinerator system provided in accordance with the present invention 
includes a combustion chamber for burning combustible waste materials that 
has a horizontal midplane. The chamber has a side charging entrance having 
a bottom side disposed no lower, and preferably at, the horizontal 
midplane. A side charging apparatus co-extensive with the side charging 
entrance is adapted to load waste materials into the combustion chamber. 
Air is forced into the lower portion of the combustion chamber in opposed 
directions along a bottom outlet of the chamber. 
The side charging apparatus includes an elongated, horizontal feed hopper 
box adapted to hold waste materials. The hopper box has an outlet 
co-extensive with the side charging entrance and opposed end wall. An 
elevator with a platform forms the bottom wall of the hopper box when the 
platform is in a raised position. When the elevator is in a lowered 
position it is below the midplane of the combustion chamber. The platform 
is enclosed by a housing that has a charging doorway covered by a hinged 
charging door so that waste materials can be loaded into the platform 
easily at the lowered essentially ground level position. A hydraulically 
operated ram is adapted to push waste materials in the hopper box through 
the side charging entrance into the combustion chamber. A fire door is 
raised by a hydraulic cylinder to uncover the side charging door prior to 
charging the chamber. A microswitch on the frameway of the firedoor is 
tripped when the fire door reaches its top position so as to activate 
movement of the elevator platform and, after a preset interval, movement 
of the ram to charge the combustion chamber. 
The system includes an after burner over the primary combustion chamber, 
which can be of the starved air type. A heat recovery unit is preferably 
positioned downstream of the after burner. 
Opposed rows of fire bricks are set at generally tangential angles on 
opposite sides of a longitudinal bottom outlet of the combustion chamber. 
The fire bricks form a plurality of air channels having downstream outlets 
on opposite sides of the bottom outlet and upstream inlets connected to 
the blower and duct system of the incinerator. The combustion chamber has 
an imaginary vertical longitudinal center plane with the bottom outlet 
being aligned along the centerplane with the air outlets of the fire 
bricks being set directly as to form jet air streams at approximate right 
angles to the center plane. 
The present invention will be better understood and the objects and 
important features, other than those specifically enumerated above, will 
become apparent when consideration is given to the following details and 
description, which when taken in conjunction with the annexed drawings, 
describes, discloses, illustrates, and shows a preferred embodiment of the 
present invention and what is presently considered to be the best mode of 
practice in the principles thereof. Other embodiments or modifications may 
be suggested to these having the benefit of the teachings herein. Such 
other embodiments or modifications are intended to be reserved especially 
as they fall within the scope and spirit of the subjoined claims.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Reference is now made in detail to the drawings, wherein like reference 
numerals denote corresponding parts. 
The incinerator system described hereinabove is based upon a starved air 
type incinerator with an after-burner unit of the type described in my 
prior U.S. Pat. No. 4,117,931 for purposes of illustration only. The 
inventive features described below can be applied to any type of starved 
air incinerator. 
FIGS. 1, 2 and 3 illustrate an incinerator system 10 for burning 
combustible waste materials that includes an elongated cylindrical casing 
12 mounted on a base platform 14. Casing 12 forms a primary combustion 
chamber 16 having an inner surface and having a height. Primary combustion 
chamber is cylindrical having a horizontal elongated longitudinal axis 17 
(FIG. 2) and circular in cross-section with a horizontal centerline, or 
mirror axis, which is aligned with an imaginary horizontal midplane 18 of 
primary combustion chamber 16 and which will be referred to herein as 
midplane 18. As seen in FIGS. 3 and 4, refractory materials 20 are mounted 
over the inner wall of casing 12 over an insulation in a manner known in 
the art. Fire bricks 24 are secured to the top surfaces of flat steel 
supports 26 angularly positioned in a general "V" configuration along 
approximately one-third of the inner surface of casing 12 with a 
longitudinal open portion adapted to pass ash from primary combustion 
chamber 16 through a plurality of passages 28 extending from an open area 
between fire bricks 24 to a collection tray 30 (FIG. 3). 
Incinerator system 10 further includes an afterburner unit, or secondary 
combustion chamber, 32 mounted over in operative connection with primary 
combustion chamber 16, a stack assembly 34 mounted over and in operative 
connection with secondary combustion chamber 32, a fan, or blower, 38 for 
pressuring air via upper and lower ducts 40 and 42 to an aspirator ring 44 
above after-burner unit 36 and to the lower portion of primary combustion 
chamber 16 respectively, the latter in a manner to be discussed in detail 
below. An air control system 46 maintains a negative air pressure in 
primary combustion chamber 16 to insure a slow, smouldering, smokey 
non-turbulent fire therein through adjustments of an automatic primary air 
damper (not shown). The benefits of creating a negative air pressure in 
primary combustion chamber 16 measured at the base of after-burner unit 36 
combined with a very hot, tangentially fired after-burner for reburning 
rising ash and gases are discussed and set forth in greater detail in my 
U.S. Pat. No. 3,881,431, which is made a part of the disclosure herein by 
reference thereto. 
Incinerator system 10 further includes casing 12 forming a side charging 
doorway, or entrance 48 to primary combustion chamber 16 having a bottom 
side 50 that is aligned with midplane 18 of primary combustion chamber 16. 
A rectangular, elongated, horizontal feed hopper box 52 forms a hopper 
chamber 54 adapted to hold waste materials (not shown). Hopper box 52 has 
a long dimension generally perpendicular to the longitudinal axis 17. 
Hopper box 52 has an outlet passage coextensive with side charging 
entrance 48 of casing 12 and an opposed end wall 58. Hopper box 54 has a 
horizontal bottom plane that is aligned with bottom side 50 of charging 
entrance 48 and midplane 18 of primary combustion chamber 14. 
An elongated horizontal outer hydraulic ram tube 60 of cylindrical 
configuration is aligned perpendicular to the longitudinal of hopper box 
52 at one end and a blind flange 62 at the opposite end. A cylindrical 
inner ram tube 64 concentrically positioned inside outer ram tube 62 is 
likewise connected to end wall 58 at one end and is spaced from flange 62 
at the other end. A cylindrical ram piston 66 concentrically mounted and 
movable within inner ram tube 64 extends through end wall 58 into hopper 
chamber 54. Ram piston 66 is generally perpendicular to the vertical plane 
extending through longitudinal axis 17 of combustion chamber 16. A 
rectangular, vertically oriented ram blade 68 attached to the inner end of 
ram piston 66 is positioned in hopper chamber 54. A hydraulic power unit 
70 (FIG. 2) operatively connected to inner and outer ram tubes 60 and 62 
by way of hydraulic piping 72 is capable of driving ram piston back and 
forth in inner ram tube 62. A main control panel 74 includes hydraulic 
controls operatively connected to hydraulic power unit 70. Ram piston 66 
is capable of moving ram blade 68 in hopper chamber 54 between first and 
second positions. In the first position, ram blade 68 is positioned 
proximate to end wall 58 of hopper 52 as shown in dotted lines in FIG. 1 
and in phantom lines in FIG. 3. In the second position, ram blade 68 is 
positioned at side charging entrance 48 of first combustion chamber 14 as 
shown in solid lines in FIG. 3 and indicated as ram blade 58A. As seen in 
FIG. 3, ram piston 66 has been pushed into hopper chamber 54 by hydraulic 
force where it is indicated as ram piston 66A. Waste materials positioned 
in hopper chamber 54 are moved from the hopper chamber into first 
combustion chamber 14 when the hydraulic unit is activated at control 
panel 74 to move ram piston and ram blade from their first positions 66 
and 68 to their second positions 66A and 68A. 
Waste materials are loaded into hopper chamber 54 by an elevator 76 mounted 
in a housing 78 positioned directly below hopper box 52. Housing 78 is 
supported by legs 80 at one side and connected to base 14 at the other 
side. As seen in FIG. 2, a door 82 rotates on hinges secured to housing 78 
parallel to ram piston 66 between a vertical position wherein door 82 
closes a charging doorway 84 formed by housing 78 to a horizontal position 
as seen in FIG. 2 wherein charging doorway 84 is open to be charged with 
waste materials. Elevator 76 further includes a generally horizontal 
elevator platform shown in the lowered position in FIGS. 2 and 3 as 
platform 86 and in FIGS. 1 and 3 in the raised position as platform 86A. 
In the raised position as platform 86A, the platform becomes the bottom 
wall of hopper box 52, which, as described previously, has a bottom plane 
aligned with midplane 18 of prlmary combustion chamber 14. Elevator 76 is 
electrically operated in a conventional manner and is connected to an 
outside power source. 
A fire door 88 adapted to seal off charging entrance 48 of casing 12 is 
vertically slidably mounted transverse to midplane 18 and hopper box 52 in 
a vertical frame 90. A hydraulic cylinder 92 set in frame 90 over fire 
door 88 is connected via piping (not shown) to hydraulic power unit 70. 
Fire door 88 is shown in its normally lowered position covering entrance 
48 as shown in FIG. 1 and in its raised position as fire door 88A in FIG. 
3 in preparation for charging of waste materials from hopper chamber 54. 
A miscroswitch 94 is positioned at the end of the upward ram of fire door 
88 to its raised position 88A so that fire door 88 trips microswitch 94 at 
the upper portion of frame 90 so as to activate an electical signal via an 
electric circuit (not shown) that causes hydraulic cylinder to deactivate 
the raising process of fire door 88. Microswitch 94 also simultaneously 
activates an electrical signal via an electric circuit (not shown) to the 
power unit for elevator 76 to activate raising loaded platform 86 to 
position 88A. Activation of microswitch 94 by fire door 88 also activates 
an electrical signal via an electric circuit (not shown) to activate 
hydraulic power unit 70 after a preset time delay to move ram piston 66 in 
hopper box 52 so as to force the waste materials just raised by elevator 
76 to hopper chamber 54 and from the hopper chamber through charging 
entrance 48 into first combustion chamber 14. Ram blade 68 is then 
positioned over bottom side 50 of charging entrance 48 so as to cover the 
entire area of charging entrance 48 and act as a temporary fire door as 
shown in FIG. 3 with the ram blade shown as 68A. At this time the operator 
activates a reverse movement of the sequences described by causing a 
signal to be sent from main control panel 74. Automatic timing devices can 
trigger a reverse movement upon the ram blade reaching its position 68A. 
The reverse movement of first ram piston being activated to pull ram blade 
68 back to its position adjacent to end wall 58; second, fire door 88 
being dropped to from its open position at 88A to its closed position 88 
wherein it operates as a fire door; and third, the power unit of the 
elevator platform is activated to move the platform from its raised 
position 88A to its lowered position 86. 
Air pressured from blower 38 is directed via upper ducts 40 to secondary 
combustion chamber 32 and lower ducts 42 to both sides of the Vee of 
firebricks 24 at the bottom of primary combustion chamber 14, and in 
particular to air channels positioned in each of the firebricks 24. As 
seen in the schematic view of FIG. 4, the pressurized air is delivered to 
a pair of headers 96 positioned under steel support plates 26 from where 
individual air ducts 98 for each fire brick 24 conduct the air to a 
stepped portion of each fire bricks 24 to an outlet 100 that directs the 
air in a general cross-wise direction perpendicular to the vertical plane 
102 of primary combustion chamber 14, that is, the air is directed in a 
line of movement spaced above the bottom of the chamber. This flow of 
pressurized air acts to fluff the pushed falling waste materials during 
the combustion process. This bottom movement of the air combined with the 
falling waste materials results in 100 percent combustion of the waste 
materials leaving only a fire ash. 
FIG. 3 in particular illustrates exhaust smoke duct 104 which carries any 
smoke that has entered hopper box 52 during the charging process back to 
primary combustion chamber 14. 
A heat recovery unit 106 shown in FIG. 5 draws the heat of the combustion 
into secondary combustion chamber 32 to an area for building or water 
heating. Heat recovery unit 106 includes a by-pass duct 108 that extends 
at right angles from main exhaust duct from an area immediately above 
secondary combustion chamber 32 to initiate a "U" bend to return again to 
a position immediately below stack assembly 34 and aspirator ring 44. Hot 
gases from primary combustion area 32 are passed straight up in main duct 
108 in direction "A" or are passed to by-pass duct 108 at right angles to 
direction A in direction B through by-pass duct 108 to return to main duct 
108. A by-pass duct control damper 114 is positioned in by-pass duct 108. 
By-pass control damper 114 is shown in a fully opened position in solid 
lines and a fully closed position 114A in phantom lines. Directly 
downstream of by-pass control valve is a suction fan 116 adapted to draw 
hot gases from main exhaust duct 110 into and through by-pass duct 108. 
Directly downstream of fan 116 is a heat exchanger unit 118 having inlet 
and outlet pipes 120 and 112 respectively that are connected to a heating 
unit (not shown). Heat exchanger unit 18 is shown schematically and can be 
of any of a number of heat exchanger type units known in the art. By-pass 
damper 114 can be controlled and suction fan 116 regulated so as to direct 
the flow of hot gases relatively more in one direction or another. In 
winter months, for example, the damper and fan may be so controlled as to 
make the B flow greater than the A flow; and in summer months the A flow 
can be made greater than the B flow. 
A self-activating harmonic action damper as known in the art can be used in 
place of aspirator 44 as shown in FIG. 6. 
Other features shown on the drawings include small hinged door 124 at the 
center of a end cover 126 bolted to casing 12. An inspection opening 125 
is located at the center of small door 124. Door 124 is opened for manual 
ignition of waste materials in primary combustion chamber 16 and for 
visual inspection of chamber 16. 
Details of after-burner, or secondary combustion chamber, 32 are set forth 
in my U.S. Pat. No. 3,881,431. As shown in functional schematic FIG. 4, 
tangential gas jets 128 are located around the base of secondary 
combustion chamber 32 which supply fuel via gas line 130. Ignition for 
this gas is supplied by an electrical control system (not shown). 
Additional oxygen for combustion in secondary combustion chamber 32 is 
supplied through a number of tangential air jets 132 supplied by upper air 
ducts 40 from blower 38. 
Flow of air to primary combustion chamber 16 via lower air ducts 42 and air 
jet outlets 100 is regulated by a photo-helix switch (not shown). The 
exact negative air pressure at the top of primary combustion chamber 16 is 
determined by the type of refuse being burned. A desirable negative air 
pressure is preset in a pressure regulator (not shown) in main control box 
74. If the air pressure in primary chamber 16 becomes too negative for the 
desired combustion, the photohelix switch trips to a margal valve (not 
shown) to activate the automatic primary air damper (discussed previously 
with respect to blower 38) to open and permit a greater volume of air to 
move through the base area to primary combustion chamber 16. 
The embodiment of the invention particulary disclosed and described herein 
above is presented merely as an example of the invention. Other 
embodiments, forms, and modifications of the invention coming within the 
proper scope and spirit of the appended claims will, of course, readily 
suggest themselves to those skilled in the art.