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EP 0 223 534 B1 |
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EUROPEAN PATENT SPECIFICATION |
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Mention of the grant of the patent: |
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06.11.1991 Bulletin 1991/45 |
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Date of filing: 11.11.1986 |
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Heat Exchangers
Wärmetauscher
Echangeurs de chaleur
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Designated Contracting States: |
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DE ES FR GB IT NL SE |
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Priority: |
22.11.1985 GB 8528806
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Date of publication of application: |
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27.05.1987 Bulletin 1987/22 |
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Proprietor: PENTAGON RADIATOR (STAFFORD) LIMITED |
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Hixon
Staffordshire (GB) |
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Inventor: |
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- Smith, Eric
Uttoxeter
Staffordshire (GB)
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Representative: Hands, Horace Geoffrey et al |
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Withers & Rogers
4 Dyer's Buildings
Holborn London EC1N 2 JT London EC1N 2 JT (GB) |
(56) |
References cited: :
CH-A- 309 256 US-A- 3 474 513 US-A- 4 163 474
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US-A- 3 158 122 US-A- 3 831 247 US-A- 4 419 802
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Note: Within nine months from the publication of the mention of the grant of the European
patent, any person may give notice to the European Patent Office of opposition to
the European patent
granted. Notice of opposition shall be filed in a written reasoned statement. It shall
not be deemed to
have been filed until the opposition fee has been paid. (Art. 99(1) European Patent
Convention).
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[0001] This invention relates to heat exchangers in which tubes, intended for the flow of
a first fluid of a heat exchange pair, are provided with an internal fin of somewhat
star shape to provide an extended surface for heat exchange. U.S.-A-3831247 discloses
such an arrangement.
[0002] US-A-3158122 discloses a method according to the precharacterising part of claim
1.
[0003] In this disclosure, a strip of sheet metal is first corrugated, then rolled into
a cylinder and moved parallel to the axis of the corrugations into the tube.
[0004] The problem with these arrangements is to provide good contact between the insert
and the tube.
[0005] The invention aims to solve this problem: according to the features of claims 1 and
5. The corrugated strip has the flanks of the corrugations modified by being bulged
outwardly. The corrugations become radially resilient and this assists in obtaining
good contact with the tube into which they are inserted.
[0006] A preferred embodiment of the invention is more particularly described with reference
to the accompanying drawings wherein:-
Figure 1 is a somewhat diagrammatic plan view of an apparatus for these purposes:
Figure 2 is a side elevation of the same;
Figure 3 and Figure 4 are enlarged fragmentary views of the apparatus;
Figure 5 shows the corrugated strip;
Figure 6 shows the modified shape corrugated strip;
Figures 7 to 9 shows successive stages in the conversion of the flat strip to the
circular shape for posting into a tube; and
Figure 10 shows a modification.
[0007] Referring to the drawings and particularly Figures 1 and 2, metal foil in strip form
is fed from a spool head through tensioning rolls 12. A motor 14 via an angle gear
set 16 drives primary forming rolls 18 which are generally in the form of a pair of
meshed gears. The strip is transversely corrugated at 22 as it leaves the gears 18,
and a stop and cutter device 24 is used to separate the strip into short sections
26 here shown as fed forwardly on conveyor 28 to rolling and insertion means. These
comprises a guide 30, further explained hereinafter, a ram 32 for displacing the sections
in the length of the corrugations into and along the guide 30, and heat exchange tube
34 into which the sections are inserted.
[0008] The primary form of the corrugation produced by the meshed gears 18 is shown in Figure
5 and comprises planar flanks connected by arcuate portions. Such formation can be
rolled to star shape, somewhat as later described herein, but is found to be unsatisfactory
because the shape so produced is (relatively) fixed in diameter. It is a feature of
the invention that the shape is modified so as to make the flanks non-planar, and
so that as the rolling step proceeds, each "petal" of the somewhat daisy shape is
outwardly bulged, as seen for example in Figure 8. This has the advantage that each
"petal" becomes slightly resilient in a radial direction and this helps to ensure
good contact between the strip and the tube which is essential for heat transfer.
[0009] The corrugation modifying or perfecting mechanism comprises a die in the form of
a blade which is located below a strip guide or bed and the latter is reciprocated
in the direction of the arrows A Figure 2 to lift the strip clear of the die 40 or
lower the strip via lever 42 pivoted at 44 and having a cam follower 46 at its opposite
end, to engage a corrugation with the die.
[0010] The perfecting mechanism further comprises a former 48 here shown as comprising a
grooved roller or wheel, journalled on a carriage 50 which is crank 52 driven from
the motor 14 and extends across the upper surface of the corrugated strip 22.
[0011] The strip is supported by the bed 41, having a suitable gap through which die 40
can project. When the carriage 50 moves to the left in Figure 3, cam surface 54 displaces
the bed and vice versa. The onward progress of the strip at that point is halted because
the movement of the carriage is synchronised with the forming gears 18. When strip
is being bent into a new corrugation by the gears 18 the roll 48 is perfecting a corrugation,
and as the formed corrugation leaves the gears the perfected corrugation leaves the
roller and die. However a slight closing together or opening of the corrugations longitudinally
can provide tolerance. At the same time as the die enters the corrugation, the roller
48 moves across the corrugation and the foil trapped between the roller and die is
modified in shape according to the profiles of the die and roller. The chain dot line
56 Figure 3 shows the final position of the roller before the carriage is withdrawn
by the crank 52, allowing the bed to return and the strip to be fed onwardly in the
arrow B direction.
[0012] The bed may comprise an upper plate 41 slotted to allow the die 40 project through
when the part 41 is in a lower plane, but located above the upper edge of die 40 at
other times, i.e. when the strip is to be fed forwardly. Plate 41 may be connected
to plate 43 by interposed springs 45, as plate 45 is contacted by the lever 42 via
a further roller 47.
[0013] The illustrated mechanism for cutting the formed and perfected strip into sections
comprises a stop bar 60 and a cutter blade 62 fixed in angular relation to one another
and also to an operating member 64 (see particularly Figure 4). The stop 60 may be
temporarily located in the path of the corrugated strip 22 as shown in Figure 2, and
when contacted by the strip (as illustrated) member 64 may be actuated to displace
the stop bar out of the plane of movement of the strip 22 and at the same time move
the cutter 62 through that plane hence severing a portion of strip. As the parts 24
are returned to the Figure 2 position, the severed length of strip is fed onwardly
and the remaining portion of strip continues to travel until stop 64 is again contacted
when a repeat cycle can be initiated.
[0014] The stop and cutter mechanism 24 can be operated manually, or if the apparatus is
to be made completely automatic, the stop bar 64 can incorporate a microswitch or
can be associated with a proximity switch or counting mechanism causing the automatic
operation at appropriate points in the feed of the strip 22.
[0015] The guide 30 tapers along its length from a maximum width at the end 70 which is
sufficient to allow a severed but generally planar length of the strip to be inserted
therein by movement of the ram 32 in the direction of the arrow C Figure 1. At the
opposite end 72 the guide is generally circular in cross section and approximately
equal or slightly smaller in internal diameter to the heat exchange tube 34 into which
the insert is to be posted. Between the ends 70 and 72 the guide tapers in width and
preferably increases in dimension transverse to the width being of generally elliptical
cross section at all points for example as illustrated in Figures 7 and 8. As the
strip is displaced along the guide it acts on the strip to take it out of a generally
planar shape into a rolled configuration. The effect is to cause the corrugated strip
to roll transverse from the Figure 7 position via the Figure 8 position to the Figure
9 position.
[0016] The actual displacement in the direction of the arrow C can continue to displace
the insert into the heat exchange tube 34. Such displacement can continue until an
insert contacts a previously entered insert, by using carefully adjusted pressure
applied to the ram. However it is preferred to use a system of proximity switches
indicated generally by the reference numerals 80 which detect the presence of an insert
in the heat exchange tube 34 and cause termination of ram movement, or alternatively,
a microprocessor programme connected to the valves controlling the supply of fluid
to the ram and causing its displacement with proximity switches 82 sensing ram position,
so that each successive ram stroke is shorter that the previous one by a length approximately
equal to one insert or less than one insert until a new exchange tube is positioned,
when the cycle starts again with a full ram stroke followed again by successively
shorter ram strokes.
[0017] Figures 9 and 10 illustrate the variation which is possible in the same size of heat
exchange tube 34 using different lengths of the corrugated and perfected strip rolled
into respectively 8 and 14 pointed stars which provide different amounts of additional
heat exchange surface with minimal difference in pressure drop or flow restriction
within the tube, and possibly both formed in one and the same apparatus or at least
generally similar apparatus merely programmed so that the strip is cut off into greater
lengths, for example by making the spacing along the length of the strip between the
stop bar and the cutter blade adjustable: but a slightly different guide might be
necessary, having a suitably larger inlet end, and it may be found useful to modify
the perfecting step to crimp the corrugations more closely.
[0018] Metal foil of suitable thinness forthe purposes of the present invention is likely
to have an inherent resilience when formed into the shape illustrated particularly
in Figures 8 to 10, and this results in the star or daisy shape of Figure 9 attempting
to unroll to the Figure 8 configuration and itself inherently creating good metal-to-metal
contact for heat flow between the insert and tube wall but the bulged petal shape
makes each petal radially resilient additionally to or instead of relying on any uncurling
action. Nevertheless it is preferred to employ a solder dipping, brazing or other
fixing step subsequently since efficiency for heat exchange depends upon heat conduction
between the insert and tube wall.
[0019] It is found that apparatus according to Figure 1 can operate substantially automatically
without supervision and run continuously providing a high output of inserts; the apparatus
can if desired be duplicated and driven from a single motor 14. The restriction on
output rate is largely due to the time taken to post the inserts into the heat exchange
tube. For this purpose it may be desirable in some circumstances to omit the cutting
step and to take the formed and perfected strip in continuous lengths and recoil it,
so that a single forming and perfecting machine can supply a series of separate cutting,
rolling and inserting machines.
[0020] It can be expected that when a series of inserts is posted into the same tube one
after the other, they will be slightly out of line (angularly) with one another. This
creates a slight degree of turbulence and edge effects which improve the heat exchange.
Gaps between successive inserts are useful for the same reason.
[0021] If desired, the strip may be one which has been perforated along its length which
will provide edge effects and modify the flow of the fluid in the heat exchange tube
in use.
1. A method of making a heat exchange tube (34) comprising the steps of taking an elongated
strip of metal foil, corrugating the foil transversely (22), cutting the strip into
lengths, rolling each corrugated strip into a cylinder by bending it about an axis
parallel to the length of the corrugations and moving the strip along an axis parallel
to the corrugations into the tube (54) characterised in that the corrugation shape produced by passing the foil between a pair of continuously
running meshed gears (18) is then modified so that the flanks of the corrugations
are, in the cylinder form, outwardly bulged so as to be slightly resilient in a radial
direction.
2. A method as claimed in Claim 1 wherein a series of like inserts are displaced axially
into the tube bore into generally or near end to end contact.
3. A method as claimed in any preceding claim wherein the strip is perforated prior to
forming.
4. A method as claimed in any preceding claim wherein the assembly of tube and inserts
is soldered or brazed to secure the inserts in position.
5. Apparatus for carrying out the method claimed in Claim 1 comprising means (12) for
feeding strip between a pair of rotating meshed gear-like formers (18), means (62)
for cutting the strip into separate pieces located before or after the forming gears,
secondary forming means comprising a former (48) arranged to be reciprocated transversely
of the strip and a die (40) to cooperate with the former, the profile of the former
and die being such as to form outward bulges on the flanks of the corrugations, and
means (32) displaceable transversely of the length of the strip for displacing the
pieces into a tube bore.
6. Apparatus as claimed in claim 5 wherein corrugated strip rolling means is provided
in the form of a guide tube having a tapering shape with an internal mandrel so as
to receive a generally planar strip at one end, and conform it into a rolled strip
at the other end when the strip is displaced along the length of the guide.
7. Apparatus as claimed in Claim 6 wherein a ram is provided for displacing the section
along the guide and into and along the heat exchange tube, the ram being provided
with means for terminating the ram stroke at a position such that each successive
insert is displaced towards or into contact with the previous located insert.
1. Procédé de fabrication d'un tube échangeur de chaleur (34) comprenant les opérations
qui consistent à prendre une bande allongée en feuille de métal, à former sur la feuille
(22) des ondulations transversales, à tronçonner la bande, à enrouler en forme de
cylindre chaque bande ondulée en la repliant autour d'un axe parallèle à la longueur
des ondulations, et à déplacer la bande dans le tube (34) le long d'un axe parallèle
aux ondulations, caractérisé en ce que la forme d'ondulation produite en faisant passer
la feuille entre deux pignons tournant de façon continue en engrènement (18) est alors
modifiée de manière que les flancs des ondulations soient, dans la forme de cylindre,
bombés vers l'extérieur pour présenter une légère élasticité en direction radiale.
2. Procédé selon la revendication 1, dans lequel une série de pièces rapportées semblables
sont déplacées axialement dans l'ouverture du tube pour être mises pratiquement en
contact bout à bout ou presque.
3. Procédé selon l 'une quelconque des revendications précédentes, dans lequel on perfore
la bande avant son formage.
4. Procédé selon l'une quelconque des revendications précédentes, dans lequel l'assemblage
du tube et des pièces rapportées est effectué par soudage ou brasage pour fixer en
position les pièces rapportées.
5. Appareil pour la mise en oeuvre du procédé selon la revendication 1, comprenant des
moyens (12) d'alimentation de la bande entre deux organes de formage (18) tournants
du genre de pignons en engrènement, des moyens (62) de tronçonnage de la bande en
tronçons séparés qui sont disposés avant ou après les pignons de formage, des moyens
de formage secondaires comprenant un organe de formage (48) disposé de façon à subir
un mouvement de va et vient transversalement à la bande, et une matrice (40) destinée
à coopérer avec l'organe de formage, le profil de l'organe de formage et de la matrice
étant conçu pour produire des bombages vers l'extérieur sur les flancs des ondulations,
et des moyens (32) mobiles transversalement à la longueur de la bande pour déplacer
les tronçons dans une ouverture du tube.
6. Appareil selon la revendication 5, dans lequel un moyen d'enroulement de la bande
ondulée est prévu, sous la forme d'un tube de guidage ayant une forme effilée avec
un mandrin intérieur, de façon à recevoir à une extrémité une bande pratiquement plane
et à lui donner la forme d'une bande enroulée à l'autre extrémité lorsque la bande
se déplace dans le sens de la longueur du guide.
7. Appareil selon la revendication 6, dans lequel est prévu un piston pour déplacer le
tronçon le long du guide ainsi qu'à l'intérieur et le long du tube échangeur de chaleur,
le piston étant pourvu de moyens pour arrêter la course du piston dans une position
telle que chaque pièce rapportée successive soit déplacée vers la pièce rapportée
précédemment mise en place, ou soit mise en contact avec celle-ci.
1. Verfahren zur Herstellung eines Wärmetauscherrohrs (34), enthaltend folgende Verfahrensschritte:
- es findet ein länglicher Streifen einer Metallfolie Verwendung,
- es wird die Folie in Querrichtung (22) gewellt,
- es wird der Streifen in Längsstücke geschnitten,
- es wird jeder gewellte Streifen in einen Zylinder durch Biegung um eine parallel
zur Längsrichtung der Wellungen verlaufenden Achse gerollt,
- der Streifen wird längs einer parallel zu den Wellungen verlaufenden Achse in ein
Rohr (34) bewegt,
dadurch gekennzeichnet, daß die Wellung, die dadurch erzeugt wird, daß die Folie zwischen
zwei kontinuierlich laufenden, ineinandergreifenden Zahnrädern (18) hindurchläuft,
dann so abgeändert wird, daß die Flanken der Wellungen in der zylindrischen Form nach
außen gewölbt werden, so daß sie geringfügig in radialer Richtung federn.
2. Verfahren nach Anspruch 1, wobei eine Mehrzahl von ähnlichen Einschüben in den Innenraum
des Rohres bis in ungefähren oder angenäherten stirnseitigen Kontakt axial eingeführt
wird.
3. Verfahren nach einem der vorhergehenden Ansprüche, wobei der Streifen vor der Verformung
perforiert wird.
4. Verfahren nach einem der vorhergehenden Ansprüche, wobei die aus dem Rohr und den
Einschüben bestehende Anordnung verlötet oder verschweißt ist, um die Einschübe in
ihrer Position zu sichern.
5. Vorrichtung zur Durchführung des Verfahrens nach Anspruch 1, enthaltend
- eine Einrichtung (12) zur Führung des Streifens zwischen ein Paar rotierender, ineinandergreifender
zahnradartiger Formstücke (18),
- eine vor oder nach den Formstücken angeordnete Einrichtung (62) zum Schneiden des
Streifens in einzelne Teile,
- eine zweite Formeinrichtung, die ein in Querrichtung des Streifens hin- und herbewegliches
Formstück (48) sowie eine mit dem Formstück zusammenwirkende Backe (40) enthält, wobei
das Profil des Formlings und der Backe derart ausgebildet sind, daß nach außen gerichtete
Wölbungen auf den Flanken der Wellungen erzeugt werden,
- und eine Einrichtung (32), die quer zur Längsrichtung des Streifens beweglich ist,
um die Stücke in einen Innenraum des Rohrs zu schieben.
6. Vorrichtung nach Anspruch 5, wobei eine Einrichtung zum Rollen von gewellten Streifen
in der Form eines Führungsrohrs vorgesehen ist, das eine sich verjüngende Form mit
einem inneren Dorn zur Aufnahme eines im wesentlichen planaren Streifens an einem
Ende und zur Verformung in einen gerollten Streifen am anderen Ende, wenn der Streifen
in Längsrichtung der Führung bewegt wird.
7. Vorrichtung nach Anspruch 6, wobei ein Stempel vorgesehen ist, um den Abschnitt längs
der Führung sowie in und längs des Wärmetauscherrohrs zu verschieben, wobei der Stempel
mit Einrichtungen versehen ist, die den Stempelhub in einer solchen Position beenden,
daß jeder folgende Einschub in Richtung auf oder in Kontakt mit dem vorangehend eingesetzten
Einschub verschoben wird.