Ultraviolet curing oven with rotable lamp assembly

An oven for curing ultraviolet curable ink on cylindrical objects consists of an assembly of two pairs of elongated ultraviolet lamps with respective reflectors for directing the radiation of the respective pairs of lamps toward the path taken by the objects to be cooled. The assembly is rotatable to move either of the pair of lamps into operative curing position and to enable maintenance on the other two lamps or the lamp power supplies at a convenient time as when other maintenance is required rather than force immediate shutdown of the decorating/printing and curing line. Air flow paths are provided to cool the lamps and reflectors during high power operation and to enable the lamp to stay hot during low power operation. A plurality of spindles which carry the cans to be cured are fixed on the pins of a pin chain and move over a wire brush type rack to cause the spindles and then the cans on the spindles to rotate as they move under and along the length of the lamps.

BACKGROUND OF THE INVENTION 
Ultraviolet curing ovens for curing ultraviolet curable inks on cylindrical 
objects are well known. One such oven is shown in U.S. Pat. No. Re. 29,590 
in the name of Whelan and assigned to the assignee of the present 
invention. The oven of that patent contains an elongated ultraviolet lamp 
disposed above a pin chain which carries coated cans beneath the lamp on a 
path which is at a slight angle to the lamp. The cans are caused to rotate 
on their axis as they move under the lamp and the axis of the cans is 
generally perpendicular to the lamp axis. A reflector above the lamp then 
produces a focused line of ultraviolet radiation which, in effect, spirals 
around the full length of the cans as they move through the oven. 
Ovens of this type have been used successfully. However, like most 
presently available ultraviolet ovens, the amount of radiation available 
per square inch is limited, and the oven must be taken out of service to 
perform maintenance on the lamp. 
BRIEF DESCRIPTION OF THE PRESENT INVENTION 
In accordance with the present invention, a novel ultraviolet oven is 
provided wherein two pairs of parallel elongated lamps with respective 
reflectors are provided on a common rotatably mounted support. The 
reflector and lamps of each pair are rotatable to respective positions 
above the path taken by rotating spindles of a pin chain which moves 
through the oven with ultraviolet decorated cans suspended from and 
rotating on the pin chain. The oven is about 7 feet long and the cans 
rotate through about two full rotations as they pass through the oven. The 
reflectors are preferably parabolic and direct parallel light rays toward 
the cans, rather than a skewed focused line of radiation. The cans are 
exposed to about 300 watts per square inch within the oven so that the 
ultraviolet decoration is completely cured when the cans leave the oven. 
The oven can cure decorated cans moving through the oven at rates up to 
and possibly in excess of 900 cans per minute. 
A novel air control system is provided in combination with a lamp power 
control system such that a strong air flow moves past the lamps and 
reflectors to cool the reflectors and remove ozone when the lamps are 
operated at full power. When, however, the line stops the lamp power is 
reduced to standby power, sufficient to keep the lamps ignited, and 
cooling air is diverted from the lamps to prevent their cooling and 
possible turning off during standby conditions. 
In order to rotate the pin chain spindles as they move through the oven, 
and thus rotate the cans, a novel stationary metal brush rack is provided 
to ensure contact with the spindles, even though the spindles may be 
slightly out of line in a way that they or any of them would not contact a 
rigid rack structure. 
An important feature of the invention is that either pair of lamps and 
reflectors can be quickly rotated into position relative to the can path. 
Thus, if there is a failure of one of the lamps, or some malfunction in 
connection with the lamp and reflector structure in use, the assembly can 
be easily rotated to bring a new set of lamps and reflectors in place. The 
former pair of lamps and reflectors can then be repaired or replaced at 
leisure and without shutdown of the can line. 
The entire oven assembly is simple in construction and can be easily 
maintained and all parts are easily accessible. Included in the assembly 
is a novel reflector carried on the front panel which reflects radiation 
from the lamp assembly toward the bottom of the can. In addition, two 
spaced air conduits extend along the length of the can path adjacent the 
opposite ends of the cans in the path. One of these conduits applies an 
air jet against the closed bottom of the can to hold the can on its 
spindle. The other conduit acts as a sliding stop for the open can end and 
keeps the can bottom from hitting the free end of the spindle. Air jets 
from this latter conduit cool the spindle and stationary wire rack which 
rotates the spindles. An air slot between reflectors performs multiple 
functions. Air is blown against cans to ensure contact between cans and 
rotating pins and to cool the cans in standby. This air also cools the 
reflectors.

DETAILED DESCRIPTION OF THE DRAWINGS 
Referring first to FIGS. 1 and 1a, there is illustrated therein in 
elevation and perspective view, respectively, the novel oven of the 
present invention. 
As schematically illustrated in FIG. 1, the oven receives a chain 40 which 
carries pins in the manner disclosed in above U.S. Pat. No. Re. 29,590, 
which pins in turn carry a plurality of cans which have been decorated by 
a suitable printing and/or coating mechanism, which decoration must be 
cured by exposure to ultraviolet radiation. The cans are schematically 
illustrated in FIG. 1 as cans 41. The cans are introduced to the oven 
through an input shroud or sleeve 42 which prevents leakage of ultraviolet 
radiation from the interior of the oven and they exit through a similar 
sleeve or shroud 43. The oven structure contains, as shown in FIG. 1, a 
side wall 44 which is hinged at its bottom and can be opened to the open 
position shown in FIG. 1a. As will later be described in detail, cooling 
air and exhaust air are controlled within the body of the oven with the 
assistance of the upper plenum chamber 45 and bottom plenum chamber 46. 
The entire oven assembly is mounted on a suitable structural steel frame 47 
shown in FIG. 1a which tilts the oven assembly at an angle of about 
10.degree. to the horizontal so that the pins traveling through the oven 
will be at a slight pitch to prevent cans from walking off the pins. This 
angle is matched to the angle of the pins on the conventional pin chain. 
The main oven chamber is formed of sheet metal walls which are carried on a 
suitable structural steel frame. Thus, as shown in FIGS. 2 and 3 a 
rectangular frame is formed of structural steel members 50 to 53 (FIG. 2) 
with suitable cross members such as the cross members 54 and 55 shown in 
FIG. 3 and similar cross members at the opposite end of the oven. Suitable 
upright cross members such as the member 56 (FIG. 3) are also provided. 
The oven chamber is enclosed by the two side members 44 and 60 (FIG. 2), 
the top and bottom members 61 and 62 (FIGS. 2 and 3) and end members 
including the end member 64 shown in FIG. 3. 
Side cover 44 is shown in detail in FIGS. 12 and 13 and consists of a sheet 
metal main body section 70 which is hinged at its bottom by the hinge 71 
(FIG. 2) to the frame member 52 and to the bottom plenum 46. The upper 
portion of member 70 is provided with thumb screw latching members such as 
the latching member 72 in FIG. 2 which enable the cover to be latched in 
the raised position shown in FIG. 2 by latching into the angle latch plate 
73 which is fixed to the frame support member 50. FIG. 12 illustrates four 
locations 73 to 76 for receiving these latching members. 
The inside surface of member 70 then supports metal sheet 77 by a suitable 
spacer bolt arrangement including the spacer bolts 78 and 79 shown in FIG. 
2. Sheet 77 defines an air channel with cover 44 and helps keep a cool 
outer surface for the oven. An elongated sheet 80 of reflecting material, 
such as Alzac with its bright side facing outwardly, is then supported 
from sheet 77 by any desired bolt arrangement or the like. As will be 
later seen, member 80 assists in reflecting radiation toward the bottom of 
a can which moves through the oven. 
The upper portion of member 77 is fitted with an angle member 81 to help 
enclose the oven chamber and its bottom has an inwardly turned section 82. 
As will be later seen there are several air passages defined by the member 
77 which help to control the movement of cooling air through the oven. 
Side wall member 60 shown in FIG. 2 has a construction generally similar to 
that shown for side wall 44 except that the wall is fixed. If desired, 
side wall 60 can be opened like wall 44. The wall 60 consists of a main 
sheet metal member 90 which has an internal sheet member 91 spaced 
therefrom and secured thereto by the spacer bolts 93 and 94. Member 91, 
like member 77, helps define a cooling air path adjacent wall member 60 
and helps to keep the outer surface of the oven cool. The upper portion of 
member 91 has the angle member 95 connected thereto to complete the 
definition of an air channel which will be later described. 
A fixed reflector section 96 extends from and is supported by member 91 to 
assist in deflecting radiation toward cans which move through the oven as 
will be later described. This also reduces radiation and heating of the 
chain, brush and spindle assembly. 
The top cover 61 shown in FIGS. 2 and 3 is also shown in detail in FIG. 6. 
As shown in FIG. 6, the top cover contains a plurality of air openings 100 
to 105 with opening 103 visible in FIG. 2. These openings define the main 
air flow channel through the oven body. The outer edges of member 61 also 
contain smaller openings or aligned slots which may be covered with a 
mesh, if desired, such as the openings 106 to 115 and 116 to 125. Note in 
FIG. 2 that the opening 111 (as well as all of the other openings 106 to 
115) are aligned with the top of the air channel 130 formed between cover 
members 70 and 77 while the slots 116 to 125 will be aligned with the air 
flow channel 131 formed between members 90 and 91. The top cover 61 is 
held in place by suitable screws or the like which fix the cover to the 
frame members 50 and 51 and the cross members associated therewith at the 
ends of the oven. 
A top plenum 45 is then fixed atop the cover 61 where the plenum 45 is 
shown in more detail in FIGS. 4 and 5. The plenum consists simply of an 
elongated chamber 140 of suitable sheet metal which has a lower flange 141 
which is bolted or otherwise fixed to the top cover 61. 
A baffle 142 of relatively short length extends across the short length of 
the interior of chamber 140 and disposed beneath the cylindrical outlet 
144 of the plenum and causes relatively even air flow upwardly through the 
oven along the length of the oven. 
The bottom cover 62 is shown in detail in FIG. 7 and consists of a simple 
flat plate which contains a plurality of openings 150 to 155 which extend 
across and along the bottom of the oven chamber. Cover 62 is fixed to the 
oven as by bolting or otherwise securing the member to the frame members 
52 and 53 and the cross frame elements at the opposite ends of the oven. 
A bottom plenum assembly is then fixed to the bottom cover 62 and consists 
of the assembly 46 which is shown in detail in FIGS. 8 and 9. As shown in 
FIGS. 8 and 9 the plenum chamber 46 consists simply of an enclosed volume 
formed of sheet metal members. Chamber 46 has a side outlet 160 which 
leads to the air control system. 
The ends of the oven are enclosed by end sheet metal cover members. The end 
cover member 64 shown in FIG. 3 is also shown in detail in FIGS. 10 and 
11. 
As shown in FIG. 10, the end wall member 64 contains a slot 170 having 
dimensions suitable for accepting the pin chain and cans supported thereby 
which are to move through the oven. End wall 64 also contains a 
cylindrical air inlet connection 171 and an opening 172 which receives the 
control shaft for rotating the reflector assembly which is contained 
within the oven as will be later described. 
The opposite end wall (not shown) may be a simple flat sheet metal 
enclosure member which is secured across the end of the oven which is 
opposite to the end shown in FIG. 3. An exit slot will be formed in the 
opposite end wall to permit exit of the pin chain and cans carried 
thereby. The end walls will each have appropriate means for pivotally 
mounting the opposite end of the reflector assembly which will be later 
described. 
The rotatable reflector assembly of the invention is generally illustrated 
in FIGS. 2 and 3 as the rotatable reflector assembly 180. The reflector 
assembly is mounted between two mounting plates at the opposite ends of 
the assembly. One of the mounting plates is shown as mounting plate 181 in 
FIG. 3 and an identical mounting plate will be formed at the opposite end 
of the assembly. Mounting plate 181 is shown in detail in FIG. 19 and 
contains four cutouts 182 to 185 which will receive the necks of 
respective ultraviolet tubes associated with the mounting plate. Thus, 
FIG. 3 shows the narrow neck 186 of a typical ultraviolet lamp 187 
disposed within the notch 182 in the mounting plate 181. 
Mounting plate 181 also contains a central opening 188 which receives the 
flush end of a mounting shaft 189 (FIGS. 2 and 3) which is rotatably 
mounted in a suitable mounting bearing 190 (FIG. 3) fixed to end wall 
member 64. 
Mounting plate 181 also contains two openings 191 and 192 which are 
disposed in communication with the tube 193 (FIG. 3) which is in turn in 
communication with the air inlet 171. A tube having air outlets along its 
length extends from tube 193 and along the length of the two reflectors on 
opposite sides of tube 193. 
A mounting block 200 shown in FIGS. 20 and 21 as well as FIGS. 2 and 3 is 
bolted to the mounting plate 181 and is also securely fixed, as by set 
screws, to the shaft 189. The mounting plate 200 then receives tube 
mounting assembles such as the tube mounting assembly 210 for mounting the 
ultraviolet lamps such as lamp 183. Note that a similar identical 
subassembly is contained at the opposite end of the oven (not shown). 
Mounting assembly 210 may be any conventional type of mounting bracket for 
permitting electrical connection to the terminal end of an ultraviolet 
lamp. 
The interior surface of the mounting plate 181 is then fixed to reflector 
support brackets 220 and 221 which are identically constructed and which 
serve to receive the reflector assembles which will be later described in 
connection with FIGS. 17, 18 and 18a. Reflector brackets are elongated 
members where the bracket 220 is shown in detail in FIGS. 14, 15 and 16. 
These are made of steel and have end flanges 223 and 224 at their opposite 
ends for connection to the support or mounting bracket 181 and the other 
identical bracket at the opposite end of the oven. These brackets also 
serve as air channels, connected to an air inlet supply through tube 193 
and inlet 171 (FIG. 3) for forcing air through the longitudinal slot 
between the active pair of reflectors. The air through this bracket is 
also useful for cooling the reflector. 
Four reflectors which are each identical in construction are then connected 
to the reflector brackets in the manner shown best in FIGS. 2 and 3 for 
the four identical reflectors 230, 231, 232 and 233. The construction of 
the reflectors is shown typically in FIGS. 17, 18 and 18a for the 
reflector 230. Thus, the reflector consists of a generally parabolically 
curved bracket member which may have fixed to the interior thereof a 
reflector member 235 which may be of an Alzac type reflection material or 
the like. If desired, the reflector 235 can be replaced by polishing the 
interior surface of the reflector bracket. The ultraviolet lamp associated 
with each of reflectors 230 to 233 are located generally along the focus 
of their respective reflector. 
Alzac reflector inserts, such as section 236, define an air slot between 
adjacent reflectors. The slot formed between adjacent sections 236 
receives an air stream from the conduit connected to air inlet 171 and 
tube 193 (FIG. 2). 
The back surfaces of the reflector supports 230 to 233 may contain 
projections or fins such as fins 237 and 238 increasing the available 
surface area of the reflectors for cooling. 
The reflector bodies 230 to 233 are provided with air passage slots such as 
the slots 240 and 241 best seen in FIGS. 17 and 18a and these slots allow 
air passage to prevent heat buildup on the lamp side of the reflector. 
From the above, the solid reflector assembly consisting of the four 
reflectors 230 to 233; the support brackets 220, 221; the mounting plate 
181 and a similar mounting plate at the other end of the assembly; the 
mounting bracket 200 and a similar mounting bracket at the other end of 
the assembly; and the shaft 189 and a similar shaft at the other end of 
the assembly, are rotatably mounted on the side walls of the oven so that 
the entire assembly can assume either the position shown or a position 
which is rotated 180.degree. from the position shown. The adjustment of 
the angular position of the rotating assembly is obtained through a 
rotating handle 250a having a knob 251 which is fixed to the end of the 
shaft 189 which extends through the rotatable mounting bearing 190. The 
adjusted position of the operating handle 250a is fixed by detents such as 
the detent 252 in the side wall 64 (FIG. 3) which detent receives a 
plunger 253 fixed to the handle 250a. A similar detent is located in other 
positions to which the handle 250a rotates in order to rotate the lamp 
assembly 180 to maintenance or inspection positions. 
As pointed out previously, a pin chain 40 carrying cans to be cured enters 
into the oven through the opening 170 in side wall 64 and exits from the 
oven through a similar opening in the opposite side wall. The pin chain 40 
and cans 41 are shown in FIGS. 2 and 3 where the cans 41 are disposed on 
the rotatable pins 250. One pin 250 is shown in detail in FIG. 2 and 
consists of an outer rotating shell 251 which is rotatably mounted on a 
central support pin 252 by the bearing surfaces 253 and 254. An outer 
collar 255 on the rotating sleeve 251 bears against a wire brush 260 of 
steel or other suitable material carried in a brush holder 261. The brush 
260 and the brush holder 261 extend along the full length of the oven. 
Thus, as the pins pass through the oven their bushings 255 roll on the 
wire brush 260 causing the pins to rotate thereby causing the cans 
supported by the pins to rotate. Note that the use of the wire brush 260 
permits independent pressure contact between the wire brush 260 and the 
bushing 255 of each pin of the pin chain. 
The wire brush support 261 is fixed to an elongated bracket 270 (FIG. 2) 
which is fixed to the main support bracket 53 as by bolts 271 and 272. 
This bracket also supports the upper chain guide 280 and the lower chain 
guide 281 which define between them a narrow slot which receives the chain 
40 and guides its motion through the oven and thus guides the 
translational movement of the rotating pins of the pin chain 40. 
The axial position of the cans 41 within the oven is controlled by the 
elongated guide tube 290 (FIG. 2) which is supported from a bracket 291 
fixed to the wire support member 261. If desired, air can be introduced 
into the interior of conduit 290 to be directed through spaced openings 
toward the wire brush 260 and chain 40 for cooling. 
A second elongated air conduit 293 is located as shown in FIG. 2, along the 
length of the oven and supported by a bracket 294. The conduit 293 will 
have spaced openings along its length to direct an air curtain toward the 
bottom of the cans 41 in order to provide a force to maintain the cans 
against the stop member 290 in their movement through the oven. 
In operation it will be seen that the cans 41 to be cured move directly 
under the two lamps 300 and 301 in FIG. 2 which have their output 
radiation focused by reflector assemblies 232 and 233, respectively toward 
the surface of can 41 which is to be cured. 
If there is a failure of a lamp or power supply, the handle 250a is quickly 
operated to cause the entire assembly 180 to rotate about the axis of the 
shaft 189 (and its companion shaft at the other end of the oven) in order 
to bring the lamps 302 and 187 into the position occupied in FIG. 2 by the 
lamps 300 and 301. The system can then be immediately restarted and the 
lamps 300 and 301 can be removed at a later time. Thus, the entire can 
line does not have to come to a stop to replace lamps or the like. Note 
that the lamps can be easily reached since the entire side wall 44 can be 
opened and the operator need only manipulate the handle 250 to present the 
lamps to be replaced for easy access. 
During the operation of the system the air flow through the oven will be 
different depending on whether the lamps are operating at full power or at 
standby power. Thus, at full power, it is desired to cool the lamps and 
reflectors, but during standby when power to the lamps is reduced, 
over-cooling of the lamps might cause them to extinguish. Therefore, 
different cooling conditions must apply during the two different 
conditions. 
An exhaust fan system is connected both to the plenum 140 at the top of the 
oven and to the bottom plenum connection 160 at the bottom of the oven. 
In the preferred embodiment of the invention, air will be exhausted from 
only one or the other of these plenums at any one time depending on 
whether the lamp system is operated at full power or at low power and 
standby power. 
When the lamps are operating at full power, the damper which permits air 
exhaust from the lower plenum 46 is closed so that air exhaust takes place 
only through the upper plenum 140. In this mode of operation, air is 
brought into the side chambers 130 and 131 defined between the outer walls 
70 and 90 and the inner walls 77 and 91, respectively, and then generally 
follows the path taken by the arrows 310 to 316 with the air moving down 
along the outer walls of the oven and then up through the center of the 
oven and around the lamp regions. This air then removes ozone and produces 
the desired cooling of the outer oven walls and of the lamps and 
reflectors. In addition, air flow is produced through the slot between 
reflector sections 236-236 of the reflectors 232 and 233 to produce a 
positive air pressure down on the cans 41 moving beneath the reflector. 
This air also returns upwardly through the upper plenum 140. 
During a reduced power, standby condition, it is desired that the air flow 
across the lamps be reduced to prevent extinguishing the lamp by undue 
cooling, but it is still necessary to remove ozone from the oven volume. 
Accordingly, during standby conditions, air exhaust through the upper 
plenum 140 is discontinued by closing its damper and the damper in plenum 
46 is opened to permit air exhaust through the lower plenum 46 and its 
outlet 160. Under this condition, air flow coming down the channels 130 
and 131 will simply continue into the lower plenum 46 and then out the 
exhaust section 160. This removes air flow from the lamps and thus 
prevents the undue cooling of the lamps. Note, however, that air flow 
stills comes through the slot produced between members 236 of the 
reflectors 232 and 233 to mainly supply cooling for the cans on the pin 
chain. Clearly over configurations can be used. 
Although the present invention has been described in connection with a 
preferred embodiment thereof, many variations and modifications will now 
become apparent to those skilled in the art. It is preferred, therefore, 
that the present invention be limited not by the specific disclosure 
herein, but only by the appended claims.