FI66070C - INSULATION ROUND LIGHTING FOR FOUNDATION FRAMSTAELLNING - Google Patents

Description

U5r <n [Bl mx * ANNOUNCEMENT PUBLICATION

jöÄ W UTLÄCCNINCSSKRIFT 6 6070 · £ & 5 C (4¾ Patent granted 10 OS 19S4 y ^ Q ^ / Patent oeddelat "(SI) Vol.lc.WcL3 F 16 L 59/14 ENGLISH — FINLAND (2.1) PW * rtöWwraiii-- IN ** ii «« «eiii» lnf 752690 (22) H «kMni * pM« t — AMeknlnp4ae 26.09.75 '' (23) AlknptM — GUtlgtaicadag 26.09.75

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Pktnttl · k Registry Board nn ^ tyr ^ r <«> i2 £% ToS, 30.0 /,. 8-, (32) (33) (31) Requested« cuoikaus-e «finf prlorket 09-10.7 ^ USA (US) 513 ^ 81 (71) Ameron, Inc., ^ 00 South Atlantic Boulevard, Monterey Park,

Cal ifornia 91751 *, USA (US) (72) Hugh Thomas McLaughlin, Santa Ana, California, USA (US) (7 * 0 Leitzinger Oy (5 * 0 Insulated pipeline and method of its manufacture -Isolated rorledhing and farfarande för dess framstäl1 Ning

The invention relates to an insulated pipeline comprising a rigid body tube and an outer shell arranged concentrically around and spaced from the body tube, and to a partially compressed, variable volume insulating layer arranged in the space between the body tube and the outer shell. The invention further relates to a method of manufacturing such a pipe, wherein the insulating material is placed and wrapped around a rigid body pipe and sealed in an outer shell.

Piping systems for conducting high and low temperature liquids generally include an inner conveyor tube for conveying the liquid, an insulating layer surrounding the outer periphery of the conveyor tube, and a tubular outer jacket or shell around the insulating layer. The insulation forms a layer with low thermal conductivity around the conveyor tube to maintain uniform temperatures in the fluid being transported. The outer sheath or shell protects the secretion against water absorption.

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In a previously known method for producing an insulated pipe, an outer shell of polyvinyl chloride is extruded around a conveyor tube and a foam insulation layer is injected into the annular space between the extruded shell and the conveyor tube as a continuous process. This method is time consuming and requires expensive equipment to perform the continuous process. In addition, the extrusion process limits the pipe so that only thermoplastics with a limited duration of temperature fluctuations can be used as the outer shell.

In another previously known method for producing an insulated pipe, the insulating layer is made of fiberglass felt. The density of the glass fiber felt is usually increased by impregnating the glass fibers with a resin and then pressing the felt into a heated mold to cure the resin. Thus, a rigid fiberglass layer of the desired shape and high density is obtained. The increased density is necessary due to the increased total heat resistance to the heat flux required for a certain strength of insulation. The rigid fiberglass layer is usually cast in semicircular half-shell pieces attached to the outer circumference of the conveyor tube. The outer sheath or shell is then placed around the fiberglass pieces. It is difficult to cause the rigid tubular outer shell to slide longitudinally along the outer circumference of the rigid fiberglass bodies and to make the insulating layer completely fill the annular space between the conveyor tube and the shell. This problem can be avoided by extruding the outer shell around the insulating layer, but this in turn results in the disadvantages that the method is expensive, time consuming and temperature limiting, as mentioned above.

FI patent 59 660 discloses a method of insulating a pipe, in which the pipe is surrounded by a jacket of carpet-like secretion material, which is temporarily compressed, for example using a strip, after which the pipe thus coated is inserted into the tubular outer jacket. A cutting device is then pulled between the outer sheath and the insulation, which cuts the strips, allowing the insulation to expand and press against the outer sheath. The disadvantage of this method is the numerous execution steps involved in its implementation, as well as the uncertainties.

3,66070 In order to overcome these drawbacks, the insulated pipeline of the present invention is characterized in that a flexible, non-perforated air-impermeable pipe having an inner diameter usually larger than the outer shell encloses the insulating layer and is enclosed in the outer shell and partially compressed characterized in that a layer of compressible insulating material is placed around the rigid body tube, that a flexible tube is arranged around the insulating layer, that the interior of the flexible tube is evacuated so that the insulating layer is compressed around the body tube and that the flexible tube is compressed then the vacuum is removed so that the insulating layer can expand radially and fill the space between the body tube and the outer shell.

These and other aspects of the invention will become more apparent with reference to the following detailed description and the accompanying drawings, in which:

Fig. 1 is a schematic cross-sectional view showing a method according to the present invention for pressing an insulating layer arranged on the outer circumference of a conveyor tube.

Fig. 2 is a partial cross-sectional view showing an outer tube placed around a compressed insulating layer.

Fig. 3 is a cross-sectional view showing a finished insulated pipe according to the invention.

Referring first to Figure 1, the layer 10 of volumetric compressible insulating material is initially wrapped around the outer surface of the elongate conveyor tube 12. The conveyor tube 12 is preferably the type of tube generally used to conduct pressurized, low or high temperature liquids. Such a pipe can be made of extruded thermoplastic, for example polyvinyl chloride, although a tape-wrapped plastic pipe made of heat-curable resin materials is now preferred. The pipe is shown to have a straight end 14 and an expanded end 16 to join several parts of the pipes 12 together to form a suitable high pressure pipe system.

The release layer 10 preferably comprises a layer of volumetric compressible fiberglass insulation felt wrapped around the outer circumference of the conveyor tube and then held against the tube to hold the insulation together, although a banding tape (not shown) may be used or the insulation layer may be glued to the outer circumference of the conveyor tube. Other types of insulating materials may also be used, for example polyurethane foam or other porous, flexible foam materials, as long as the insulating layer only provides the desired low thermal conductivity and is volumetric compressible.

The entire conveyor tube and insulating layer are arranged inside the hollow interior of the flexible, intact tube 18, whereby the tube 18 may also be some other suitable flexible film or film capable of surrounding the conveyor tube and the insulating layer to draw a vacuum around them. In a preferred embodiment, the tube 18 is a flexible polyethylene bag having at least one end connected to a vacuum pump 20. Although the drawing shows both ends of the polyethylene bag connected to separate vacuum pumps, in the presently preferred method vacuum is drawn from only one end of the bag. to provide an airtight space around the conveyor tube and the insulating layer.

As shown in Figure 2, one or both vacuum pumps draw a partial vacuum into the interior of the bag 18 so that air pressure compresses the volumetric compressible insulation layer. The vacuum compresses the layer in a sufficient amount to allow the rigid outer tube or shell 22 to slide longitudinally over the plastic bag and the insulating layer. A large vacuum pump is not required, as only a vacuum of about 12.7 cm (with a total vacuum of 76.2 cm) is required to provide the required compression. Commercially suitable pipe sections of conventional length can be provided with a suitable compression simply by using a vacuum pump taken from a conventional vacuum cleaner.

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The outer tube 22 is preferably a strip-wrapped plastic tube made of a thermosetting resin material, although the plastic tube may be any other rigid tube type that is light in construction and capable of protecting the insulating layer 12 from water absorption and other damage, e.g., wear. When the outer tube and the inner conveyor tube are properly aligned, the vacuum is preferably broken by cutting off the two ends of the plastic bag 18 to allow the compressed insulating layer to expand and fill the annular gap between the two tubes. The strength of the separating layer is preferably chosen so that it can only partially return to its normal uncompressed state when the vacuum is broken, whereby the insulating layer remains in a partially compressed state. In this case, means are provided for adjusting the desired density of the annular intermediate insulating layer.

Once the insulating layer is in place, the ends of the plastic bag can be properly flattened and the end seals 24 can be added to the ends of the tube to provide the required protection against water absorption.

Thus, the method of the invention provides an insulated pipe without the need for the previously known expensive and time consuming steps of extruding the outer shell and injecting the foam insulation as a continuous process. In addition, since the outer tube 22 can be manufactured as a separate process, the outer tube can be a strip-wrapped plastic tube made of thermosetting quartz materials that do not have temperature restrictions on thermoplastics. In addition, the previous casting step of the insulating layer in the form of rigid hemispherical pieces can be eliminated. Therefore, it is no longer necessary to add resins to the fiberglass felt and then heat the resin in a mold to cure the resin. The insulated tube provided by the invention also has the advantage of forming an insulating layer between the inner and outer tubes, which allows vacuum to be easily drawn into the insulating layer in case such measures are necessary to reduce heat transfer for specific low thermal conductivity applications.

Claims (8)

66070 --- - Γ " An insulated pipeline comprising a rigid body tube (12) and an outer shell (22) arranged concentrically around and spaced from the body tube, and a partially compressed, variable volume insulating layer arranged in the space between the body tube (12) and the outer shell (22). , characterized in that a flexible, non-perforated air-impermeable membrane tube (18), the inner diameter of which is usually larger than the outer shell (22), encloses the insulating layer (10) and encloses the outer shell (22) and the partially compressed secretory layer (10) between. Pipeline according to claim 1, characterized in that the insulating layer (10) comprises a flexible, fibrous insulating felt. Pipeline according to Claim 1 or 2, characterized in that the insulating layer (10) is made of a porous, elastic foam material. Pipeline according to one of Claims 1 to 3, characterized in that the impermeable pipe (18) consists essentially of an air-impermeable flexible plastic film from which air can be removed in bag form to compress the outer diameter of the compressible insulation layer (10) radially inwards. A method of manufacturing an insulated pipe according to any one of the preceding claims 1 to 4, wherein the insulating material (10) is placed and wrapped around the rigid body tube (12) and enclosed in an outer shell (22), characterized in that a layer is placed around the rigid body tube (12). (10) a volume of compressible insulating material, that a flexible tube (18) is arranged around the insulating layer (10), that the interior of the flexible tube is sucked under vacuum so that the insulating layer (10) is compressed around the body tube (12), that the flexible tube (18) an outer shell 7 60070 (22) is placed around the insulating layer (10) and that the vacuum is then removed so that the insulating layer (10) can expand radially and fill the space between the body tube (12) and the outer shell (22). Method according to claim 5, characterized in that the body tube (12) and the insulating layer (10) surrounding the body tube are completely enclosed in the flexible tube (18) before deaeration takes place. Method according to Claim 5 or 6, characterized in that the outer shell (22) is pushed onto the flexible tube (18) before the vacuum is removed. Method according to one of Claims 5 to 7, characterized in that the thickness of the insulating layer (10) is selected relative to the inner diameter of the outer shell (22) so that the insulating layer only partially returns to its original thickness when the vacuum is removed so that it remains partially compressed. space between the body tube (12) and the outer shell (22). 8,66070 Patentkrav *