FI110703B - Method and cylinder for heating or cooling a fibrous web - Google Patents

Description

HEATING OR COOLING PROCEDURES AND CYLINDER

OF A FIBER MATERIAL COVER

-atoms

MENETELMÄ JA SYLINTERI KUITURAINAN KUUMENTAMISEKSI TAI JÄÄHDHDTTMISEKSI

The present invention relates to a method and cylinder for heating or cooling a fibrous web, as defined in the preamble of the following independent claims.

In a conventional paper machine or other equivalent machine, for making fibrous webs, the fibrous web is dried in the dryer portion of the machine by passing the web over one or more heated dryer cylinders, usually in direct heat transfer contact with the cylindrical surface of the cylinders. In the drying portion, the fibrous web is then dried by heat being applied to the web from the dryer cylinder (s), so that the desired amount of water evaporates from the web and the web achieves the desired dry content.

• Tissue paper, such as tissue paper or other hygiene paper, is usually manufactured in • t .: machines with a single large drying cylinder, e.g. and sk. Yankee cylinders, or in machines with both conventional drying cylinders and one or more larger drying cylinders. The large / drying cylinders have a diameter of> 2 m, usually 3 - 6 m. The Large drying cylinders may have sealed surface, e.g. for making creped paper, or .., .. patterned mantle surface, e.g. for fabricating textured tissue.

The drying cylinders are normally meadow heated, with the meadow delivering the heat to the • * · • ;; <: the web, which is needed to evaporate the desired amount of water from the web as it is passed over the casing surface of the cylinder. When designing the Yankee cylinders, a • is used. *. Optimum ratio between meadow pressure and cylinder wall thickness, to obtain maximum heat transfer. A meadow pressure of 5 - 10 bar e gives maximum heat transfer for the cylinder sizes in question.

However, one disadvantage of the Big Dry Cylinders, especially the Yankee Cylinders, is their size. The manufacturing problems today make it almost impossible to increase the drying capacity by further increasing the diameter of the Yankee cylinder. Also, the transport arrangements when moving very large cylinders can be an obstacle to further increase the cylinder size.

Another problem is the large material thickness of the cylinders, which reduces the heat transfer from the interior of the cylinder to its casing surface. A Yankee cylinder for 10 tissue machines is generally provided with internal latches or grooves in the circumferential direction of the cylinder. Men can have a thickness of approx. 100 mm before the catch has been turned on the inner surface of the jacket. A new barreled cylinder has this thickness between the barbs. After a number of rounds of the cylinder, this thickness decreases to something between 50 - 70 mm. Also, the thickness of the pawl bottom decreases and can usually be allowed down to slightly below 25 mm. An MG cylinder, which is smooth inside, can, as new, have a thickness of approx. 40 to 60 mm. By sanding, the jacket thickness can be allowed to decrease to less than 25 mm, to maintain the internal meadow pressure in the cylinder.

• '* A Yankee cylinder therefore has a considerable mass, which must be heated with the meadow, due to the thickness of the mantle surface and the large diameter of the cylinder. The large thickness reduces the heat transfer to the cylinder surface of the cylinder. This makes it difficult to obtain a ....: for the drying sufficiently high heat flow through the Yankee cylinder's casing surface and therefore the temperature of the casing surface is usually at most 95 - 100 ° C.

Another problem that arises if the diameter of the Yankee cylinder is enlarged is the difficulty of keeping the same temperature on the cylinder sheath and the ends, such that '. the shape of the cylinder is kept constant in the transverse direction of the machine. Where the surface of the envelope and the gables cannot expand freely and independently of one another, temperature differences can lead to large stresses between them.

In today's tissue machines, the inner surface of the Yankee cylinder is usually provided with spades. Each locking needs its own condensed outlet. The system for discharging condensate from the cylinder can therefore be very complicated.

The present invention aims to provide a method and a cylinder for heating or cooling a fibrous web in which the aforementioned disadvantages have been minimized.

It is also intended that in a machine, for the heating or cooling of a ίο fiber material web with a cylinder, increase the heat transfer capacity without substantially increasing the space requirement for the heat transfer.

It is also intended to provide a means of increasing the heat transfer capacity of the drying cylinders without necessarily increasing the size of the cylinder or using additional energy to heat the casing surface of the cylinder.

. The above objects are achieved by a method and a cylinder, which are characterized by what is stated in the characterizing part of the following claims: independent claims.

In a typical method of heating, drying or cooling a J: fibrous web, in the manufacture or treatment of a fibrous web of the invention, in a machine having at least one fibrous web heating or cooling cylinder, in which the cylinder wall is of metal or other suitable heat conducting material, the fiber material web is passed over the heating or cooling cylinder in heat transfer contact with at least part of the cylinder surface of the cylinder, the heating surface of the cylinder surface being the cooling or cooling medium. of a heat transfer fluid, such as heat transfer oil or the like, whose 110703.

4 meadow pressure is lower than 50 kPa within the temperature range relevant for carrying out the process. The initial boiling point is then typically above the upper limit of this temperature range.

The envelope surface heating or cooling medium of the cylinder is passed through the cylinder 5 in ducts in direct or indirect heat transfer contact with the cylinder wall.

A typical cylinder, for heating or cooling a fibrous web in a machine for fabricating or treating the fibrous web, comprises a metal wall or other suitable heat conducting material, end walls, and ducts for passing heat-emitting or heat-receiving medium through the cylinder. The channels, for conducting heat-emitting or heat-receiving medium through the cylinder, typically consist of channels formed in the cylinder wall material or channels arranged at or in the cylinder wall, for conducting the envelope surface heating or cooling medium through the cylinder in direct or indirect heat transfer contact. The heat-emitting or heat-receiving heat transfer medium consists of a heat transfer fluid, such as heat transfer oil or the equivalent, whose meadow pressure is less than 50 t "kPa within the temperature range applicable for conducting the heat transfer heat transfer heat." The initial boiling point of the guide fluid is typically above the upper limit .... for this temperature range.

In tissue machines, advantageously, heat transfer fluids are used, whose initial boiling point is higher than 250 ° C, preferably higher than 300 ° C, preferably higher than 350 ° C, and whose steam pressure at 300 ° C is preferably lower than 10 kPa.

In one embodiment of the invention, preferably, heat transfer oils having a temperature of> 100 ° C, typically 150-300 ° C, can be used as heat transfer medium in drying cylinders.

»· 5 110703

However, in most cases the use of heat transfer oils as heat transfer medium in drying cylinders requires some minor changes in the cylinder structure itself. Different conceivable constructions may be considered.

Heat transfer oil could be sprayed onto the inner surface of the cylinder and removed from the cylinder in any suitable manner, e.g. with siphon, in a similar manner as water meadow condensate is removed from conventional drying cylinders, by means of pressure difference. The heat exchanger oil could be removed from the cylinder by constructing the cylinder as a pressure vessel or with pump and suction pipe. The inner surface of the cylinder may be provided with radial or axial or orbital directions in the direction of the mantle periphery, in order to enhance the heat transfer.

A more efficient heat transfer is provided if the heat transfer oil is passed through pipes, heat exchanger pipes, which are in contact with the inner surface of the cylinder wall. This method requires a good heat transfer contact between the heat exchanger tubes and the cylinder wall. A good contact can be achieved by filling the gap between the heat exchanger tubes and the cylinder wall with some material with good thermal conductivity. One could, for example, hot-dip galvanize with zinc, so that zinc fills the gaps' · * * between the pipes and the wall. Other metals or fillers, such as good heat transfer contact between pipe and cylinder wall, may also be considered.

•> · t 20 Instead of separate heat exchanger pipes, axial hazards formed in the inner wall of the cylinder can be channels for the heat transfer oil. The gaps can be covered with an extra inner, cylindrical disc or inner wall, so that separate channels are formed in the wall of the cylinder. It is also possible to form separate channels within the wall material itself, e.g. through ; attborrakanalerdäri.

t. »'1' Those formed in the cylinder wall or those arranged at or in the cylinder wall>» '. ·. according to a typical embodiment of the invention, the channels are substantially parallel to the axis of the cylinder and all individually or in groups arranged at an equal distance from the cylinder axis. The diameter of the channels formed in the cylinder wall or the channels arranged at or in the cylinder wall can be substantially constant in the direction of the cylinder shaft, but can on the other hand, if desired, be e.g. increasing in the flow direction, in order to maintain the heat transfer from the heat transfer oil or correspondingly to the casing surface of the cylinder despite the temperature change in the flow direction. On the other hand, a constant heat transfer from the heat transfer medium to the mantle surface can also be maintained by having constant diameter channels arranged at a distance from the mantle surface, which decreases in the direction of flow of the channels. Equal or heat transfer in the axis direction of the cylinder may also be phase where each of the ducts is arranged to conduct the heat transfer oil or the equivalent from the driver's side to its drive side and each other from its drive side to its driver side.

According to a typical embodiment of the present invention, heat transfer oil or other suitable heat transfer material is passed into a drying cylinder through an inlet of one of the shaft pins and is distributed therefrom, via a distributor arranged on the inner wall of the cylinder, e.g. on the drive side of the cylinder, to ducts formed in or heat exchanger tubes arranged at or in the cylinder wall. In a corresponding manner:. the inner wall of the cylinder on the driver's side be provided with a collector, which collects: the heat transfer oil or electricity. like. from the heat exchanger tubes or ducts, to be discharged through an outlet provided in the second shaft.

In order to achieve a uniform heat transfer along the entire cylinder surface in its axial direction in a cylinder according to the invention, the heat transfer medium should not be cooled or heated too much when flowing through the cylinder.

• ·:. In a drying cylinder according to the invention, the heat transfer medium can conveniently be cooled to approx. 10 ° C when flowing through the cylinder. The cooling of the heat transfer medium can be compensated by making the cylinder wall slightly; '. j conical, so that the walls at the inlet side are e.g. 10% thicker than at the outlet side, which offsets the temperature change between the inlet and outlet side. Another alternative approach to compensating for temperature changes is to allow the heat transfer medium to flow in a first direction in every other heat exchanger tube and in the opposite direction in the other tubes.

The invention will now be described in more detail with reference to the following drawings: FIG. 1 is a schematic cross-section through a portion of a cylinder's cylinder wall according to the invention; FIG. 2 shows a schematic cross-section through part of another cylinder's cylinder wall according to the invention; FIG. 3 schematically shows an axial cross-section of a cylinder according to the invention and FIG. 4 shows a schematic flow diagram for heat transfer medium between a drying cylinder and a device for heating the heat transfer medium.

15 .; | In FIG. 1 shows a cross section of a sector of the cylinder wall of a dryer cylinder 10.1. The cylinder wall has a number of heat exchanger pipes 14 arranged on its inner side.

:. The tubes 14 are arranged parallel to the cylinder shaft and at an equal distance from the shaft. The tubes 14 are attached to the inner side of the cylinder wall 12 by hot galvanizing with zinc 16, which partially surrounds the tubes and fills the space between the tubes and the inside of the cylinder wall. The zinc galvanization provides good heat transfer contact between the tubes and the inside of the cylinder wall.

'Hot': Hot heat transfer oil is arranged to flow through the tubes, heat being transferred from the oil via the tube wall, the zinc layer and the cylinder wall to the cylinder surface 25 of the cylinder, for heating the fiber material web to be dried with the drying cylinder.

. In FIG. 1, an advantageous embodiment of the invention is shown in the heating and drying of a fibrous web, such as tissue paper, in which the heat-giving, heating and drying medium is passed through the dryer cylinder in the heat transfer contact with the cylinder wall through the inner wall of the cylinder wall or in the cylinder wall. Good heat transfer contact between the heat exchanger pipes and the cylinder wall is achieved by the addition of material with good heat transfer capability between the cylinder wall and the pipes arranged at its inner surface. The heat exchanger tubes can e.g. are attached to the cylinder wall by hot galvanizing with zinc.

In FIG. 2 shows an alternative embodiment of the heating of the casing surface 18 of a dryer cylinder according to the invention. In FIG. 2, the inner side 12 of the cylinder wall 10 has channels 14 formed in the cylinder wall material itself. The ducts 14 are covered by a thin inner cylinder 20 which forms a sealing wall of the ducts, so that separate tube-like ducts are formed at the inner wall of the drying cylinder, partially embedded in the wall material.

FIG. 2 shows an advantageous embodiment of the invention in heating and drying a fibrous web, such as tissue paper, according to which the heat-releasing, heating and drying medium is passed through the drying cylinder in direct or indirect heat transfer contact with the cylinder wall through in the cylinder wall. , ..: 20 material shaped channels.

In FIG. 3 shows an axial cross section of a dryer cylinder 22 according to the invention.

..: The drying cylinder has in its first end 24 a first shaft pin 26 through which is provided: an inlet 28 for heat transfer medium m and in its second end 30 a second:. ·. shaft pin 32 through which is provided an outlet 34 for heat transfer medium.

The inlet 28 is connected to a distributor 36 disposed on the inner side of the first end face.

'. ·; The outlet 34 is correspondingly connected to a collector 38 arranged on the other. the inner side of the gable. The distributor 36 and collector 38 are connected to heat exchanger tubes or ducts 14, e.g. of the type shown in FIG. 1 and FIG. 2. Heat transfer fluid, such as heat transfer oil, is arranged at a> 100 ° C, advantageously 150-300 ° C, temperature to flow from the inlet 28 via distributors 36, pipes or ducts 14, collector 38 and outlet 34 through the drying cylinder 22 for heating its casing surface 18.

5 FIG. 4 shows a system for heating the casing surface 18. of the drying cylinder 22. The heat transfer medium is in this case heat transfer oil. 230 kg / s of oil is passed through an inlet 28 at a temperature of 220 ° C into the drying cylinder 22.1 The drying cylinder flows the oil through pipes or ducts 14 and exits heat via the cylinder wall to the cylinder surface 18, after which the oil flows out of the cylinder via the outlet 34 at 10 a temperature of approx. 210 ° C. The major portion of the extracted oil, 197 kg / s, is passed through a circulation line 38, valve 40 and inlet line 42 with pump 44 back to the inlet 28 of the drying cylinder 22. A partial flow, 33 kg / s, of the extracted oil is passed through a line 46 to a heating device 48, wherein the oil is heated to a temperature of 280 ° C. The heated oil is passed through a conduit 50 to the valve 40 so that, together with the main portion of the oil, it is introduced into the inlet conduit 42.1 the inlet conduit, the partial stream of heated oil is mixed with the main portion of oil so that a stream of 230 kg / s of oil at a temperature of 220 ° C are attached to the inlet line. According to this system, only a portion of the oil needs to circulate through the heater. The temperature of the oil fed into the oil. The drying cylinder can be quickly controlled by regulating in a known manner the relationship between the two oil streams, the main stream and the sub-stream.

EXAMPLE

. · *. The following examples are intended to show that the same or significantly larger, e.g. 50% greater, the degree of heat transfer can be achieved with a dryer cylinder according to the invention as: with a conventional meadow heated dryer cylinder.

The following conditions apply to the comparison: - the diameter of the cylinder 4572 mm and the width of the web 5000 mm; - the k value, meadow / cylinder casing surface, for the meadow heated cylinder is assumed to be 0.7 kW / m2 / ° C since the meadow temperature is 170 ° C (7 bar e); The k value of the oil heated cylinder is assumed to be equal; - the oil-heated cylinder is assumed to be designed to provide 50% more heat than the meadow heated; - the temperature of the mantle surface of the meadow heated cylinder is 100 ° C; - the temperature of the casing surface of the oil-heated cylinder is 110 ° C.

io The temperature of the heat transfer oil should be 110 ° C + 1.5 x (170 - 100) ° C = 215 ° C to obtain a 110 ° C temperature on the casing surface. Therefore, the oil temperature before the cylinder should be 220 ° C and after the cylinder 210 ° C, which gives an average temperature of 215 ° C.

The entire cylinder then emits heat as follows:

15 π x 4.572 m x 5.00 m x 0.7 kW / m2 / ° C x (215 -110) ° C = 5279 kW

• ·

The specific heat for oil is 2.3 kJ / kg / ° C. In this case, at 10 ° C ΔΤ one requires: “*: oil volume of 230 kg / s, which has a volume flow of 2521 / s (density 910 kg / m3).

i in k Mill ....: The outer / inner diameter of the heat exchanger pipes is assumed to be 21/17 mm and the pipe spacing at the cylinder wall is 28 mm. Thus, a total of 504 pipes are included in the wall. The oil flow in the tubes is thus 2.2 m / s. ,

• * I

• ·. ''. The heat transfer coefficient from oil to the inner wall of the pipe is 1.55 kW / m2 / ° C at ...,: this flow rate. The thermal conductivity of the wall is assumed to be 50 W / m / ° C. A wall thickness from the bottom of the rail to the outside of the cylinder, with which said k value 0.7 * -n | '*': kW / m / ° C is obtained, is 39 mm, which shows that it is possible to a corresponding k- * · »value with oil heating as with meadow heating of a cylinder.

The present invention proposes that drying cylinders be heated with heat transfer oil or other equivalent medium which does not extend at the temperature and pressure in place of water vapor. A variety of heat transfer oils which can be used at temperatures up to 300 ° C and which are suitable for heating purposes in various embodiments of the invention are available.

Examples of commonly available suitable heat transfer oils include, for example, Thermia B and Thermia E from Shell. The initial boiling point for Thermia B is approx. 355 ° C and for Thermia E approx. 410 ° C. When using these oils, the temperature of the surface giving off heat should not exceed 340 ° C. The steam pressure for Thermia B is less than 10 kPa at 300 ° C and lower than 1 kPa at 220 ° C. For Thermia E, meadow pressure is lower.

With a method according to the invention, The following advantages are obtained when drying fibrous webs: * »: - The drying cylinder must not be dimensioned as a pressure vessel.

· - The temperature level of the heat emitting medium can be raised from the current 160 ° C: 180 ° C (for water vapor) to close to 300 ° C (for heat transfer oil).

>:: - Temperature level can be raised from the current tile to a higher temperature level without enlargement of the dryer cylinder structure itself.

: The invention can be used to increase the drying capacity, in Large drying cylinders, ....: e.g. of Yankee cylinder type, having a large diameter,> 2m, usually 3 - 6m.

The invention may be utilized e.g. at Yankee cylinders in tissue machines. Cylindrical: v. Drying capacity can easily be regulated by regulating the temperature of the oil. The invention can also be utilized in large cylinders with a filtered surface, for the manufacture of e.g. creped 12 110703 paper, as in Large cylinders with patterned surface, for making textured tissue.

The invention can also be applied to conventional drying portions in paper machines. Existing dryer sections can be increased by replacing conventional meadow heated cylinders to oil heated cylinders of the same size.

The invention can also advantageously be used in fiber-material webs for cooling cylinders, with the potassium water as heat transfer, in this case cooling, medium. The cylinder provides better heat transfer power or lower water consumption.

The drying cylinders are typically made of metal, such as steel or cast iron.

The present invention should not be limited to only the preferred embodiments described above, but is intended to apply also various modifications within the scope of the scope of protection defined by the patent claims.

a a I »* a

Claims (26)

A method of heating or cooling a fibrous web in the manufacture or treatment of the fibrous web of a machine having at least one fibrous web heating or cooling cylinder, in which the cylinder wall is of metal or other suitable heat conducting material, wherein - the fibrous web is passed over the heating or the cooling cylinder in heat transfer contact with at least a portion of the cylinder surface of the cylinder; and the medium consists of a heat transfer fluid, such as heat transfer oil, whose meadow pressure, within the temperature range relevant for carrying out the process, is less than 50 * 15 kPa. • i A method of heating a fibrous web according to claim 1,. . characterized in that the initial boiling point of the heat transfer fluid is • ·, · · ·. above the upper limit of the temperature range applicable for the execution of the procedure. , ··. 20 A method for heating a fibrous web according to claim 2, *. characterized in that the initial boiling point of the heat transfer fluid is higher than 250 ° C, preferably higher than 300 ° C, preferably higher than 350 ° C. Method for heating a fibrous web according to claim 1, characterized in that the vapor pressure of the heat transfer fluid at 300 ° C is lower than 25 °Pa. 110703 5. A method of heating a fibrous web according to claim 1, characterized in that the casing surface heating medium of the cylinder is constituted by heat transfer oil having a temperature of> 100 ° C, advantageously between 150-300 ° C. 5 Method for heating a fibrous web according to claim 1, characterized in that the fibrous web is passed in heat transfer contact over the casing surface of a drying cylinder, such as Yankee cylinders or other drying cylinders, preferably having a large> 2m diameter and having a smooth or patterned casing surface. 7. A method according to claim 1, characterized in that the fiber material web, whether to be heated or cooled, is a textured or unstructured tissue web, tissue web or other corresponding web of paper. 8. A method according to claim 1, characterized in that the heat-dissipating or heat-receiving medium is conducted in direct or indirect heat transfer contact with the cylinder wall through channels formed in the cylinder wall material. 15 9. A method according to claim 1, characterized in that. that it gives off heat; or the heat-receiving medium is conducted in heat transfer contact with the cylinder wall '· through heat exchanger tubes arranged at the inner surface of the cylinder wall. Method according to claim 9, characterized in that. that good. . heat transfer contact between the heat exchanger tubes and the cylinder wall is achieved by the addition of material with good heat transfer capacity between the cylinder wall and the tubes arranged at its inner surface. 11. A method according to claim 10, characterized in that the heat exchanger tubes are attached to the cylinder wall by hot galvanizing with zinc. • V Method for heating a fibrous web according to claim 1, characterized in that. the 110703 fiber material web is passed in heat transfer contact across the casing surface of a dryer cylinder, such as a Yankee cylinder or other dryer cylinder, preferably having a large> 2m diameter, and with a slat or patterned casing surface, and that - the heat-transferring or heat-receiving medium is fed directly or indirectly into the heat transfer medium. through channels formed in the cylinder wall material or through heat exchanger tubes arranged at the inner surface of the cylinder wall, which channels or tubes are in good heat transfer contact with the cylinder wall and its casing surface. A cylinder for heating or cooling a fibrous web in a two machine for fabricating or treating the fibrous web, the cylinder comprising: - a cylinder wall of metal or other suitable thermally conductive material, - end walls, and - ducts for conducting heat-emitting or heat-receiving medium. '. Characterized by the cylinder, characterized in that the * # '·· [channels, for conducting heat-dissipating or heat-receiving medium through the cylinder, are formed by channels formed in the cylinder wall material or by channels arranged in the cylinder wall for conducting heating or cooling medium of the cylinder surface of the cylinder through the cylinder in direct or indirect: · 20 heat transfer contact with the cylinder wall, and that: «- the heat-dissipating or heat-receiving heat transfer medium. · · · Of a liquid, such as heat transfer oil or the equivalent, whose meadow pressure, within .. '. the temperature range relevant for carrying out the process is lower than! ·· '·. 50 kPa. • · 110703 14. A cylinder for heating a fibrous web according to claim 13, characterized in that the initial boiling point of the heat transfer fluid is above the upper limit of the temperature range which is relevant for carrying out the process. 15. A cylinder for heating a fibrous web according to claim 14, characterized in that the initial boiling point of the heat transfer fluid is higher than 250 ° C, preferably higher than 300 ° C, preferably higher than 350 ° C. 16. A cylinder for heating a fibrous web according to Claim 13, characterized in that the steam pressure of the heat transfer liquid at 300 ° C is lower than 10 10kPa. Cylinder according to claim 13, characterized in that. the heat-transferring or heat-receiving medium consists of heat transfer oil having a temperature> 100 ° C, advantageously 150-300 ° C. Cylinder according to claim 13, characterized in that. that the cylinder is a: · drying cylinder, such as a Yankee cylinder or other large cylinder of at least 2 m '_' diameter, in a Yankee machine, tissue machine or other similar machine for ''. manufacture of tissue or the like. 19. A cylinder according to claim 13, characterized in that the casing surface of the cylinder is smooth or patterned. 20. Cylinder according to claim 13, characterized in that they in the cylinder wall * ·; The shaped or the channels arranged at or in the cylinder wall are substantially '' parallel to the axis of the cylinder and arranged at an equal distance from the cylinder axis. Cylinder according to claim 13, characterized in that the channels arranged at the cylinder wall 25 are heat exchanger tubes arranged at the inner surface of the cylinder wall. ,, 110703 22. A cylinder according to claim 13, characterized in that. that the diameter of the channels formed in the cylinder wall or the channels arranged at or in the cylinder wall is substantially constant in the direction of the cylinder shaft. 23. A cylinder according to claim 13, characterized in that. that the diameter of the channels formed in the cylinder wall 5 or the channels arranged at or in the cylinder wall grow in the direction of flow, in order to maintain the heat transfer from the heat transfer oil or corresponding to the casing surface of the cylinder despite the temperature change in the flow direction. 24. A cylinder according to claim 13, characterized in that. that the cylinders in the cylinder wall of the cylinder wall material or the channels arranged at or in the cylinder wall have a constant diameter and are arranged at a distance from the casing surface, which decreases in the direction of flow of the channels, in order to maintain the heat transfer from the heat transfer oil in the cylindrical end of the cylindrical end or the corresponding constant flow. 25. A cylinder according to claim 13, characterized in that. that every other channel • »!. is arranged to conduct the heat transfer oil or equivalent from the machine's • M. · · ·. driver's side to its driver's side and every other from its driver's side to its driver's side. • 1 26. A cylinder according to claim 13, characterized in that. that good ***** t · heat transfer contact between ducts provided at the inner wall of the cylinder and the cylinder wall is achieved by the addition of material with good •: heat transfer capability between the cylinder wall and the ducts, e.g. by hot galvanizing with zinc. · • · 110703