NL2010833C2 - METHOD FOR SUPPORTING AN OBJECT AGAINST A SUPPORT AND A SLIDERY SECTION. - Google Patents

Description

Method for supporting an object against a support, as well as a slide bearing section

The present invention relates to a method for supporting an object against a support using a slide bearing, which slide bearing - a vibration-insulating first slide bearing section which has a first slide surface, and - a second slide bearing section which has a second slide surface for contact with the first sliding surface of the first slide bearing section insulating against vibration; wherein an element selected from the object and the support is provided with the first slide bearing section which is insulating against vibration and the other element is provided with the second slide bearing section whereby the object is supported against the support via the slide bearing.

Such a method is known in the art. The method is used to support conduits for transporting a fluid, such as conduits that are under use during atmospheric pressure, such as 400 Bar. This could include natural gas pipelines. They can also be liquid pipes, such as for petroleum. Such pipes are heavy. With changes in, for example, the operating pressure and the fluid temperature, the pipes tend to bend, stretch or move in some other way. The method of supporting the pipes must allow this. Devices such as pumps and compressors cause vibrations in the pipes. To prevent noise nuisance, the pipes are usually provided with sound insulation. However, vibrations from the pipes are transmitted via the supports, so that they can also become a source of noise. The first plain bearing section must isolate the vibrations from the support, reducing noise pollution. The first slide bearing section is referred to in the art as an acoustic slide plate.

For the known method, anti-vibration first plain bearing sections from Fabreeka (Stoughton, United States) for plain bearings are known. These slide bearing sections consist of a sandwich of - a PTFE plate for providing the first glide surface, - a layer of elastic polyurethane for providing a barrier for transmitting vibrations, which layer is glued to the PTFE plate, and - a steel mounting plate which is connected to the support, wherein the steel mounting plate is glued to the layer of elastic polyurethane. The steel mounting plate is usually welded to the support. It is also possible to fix the mounting plate with bolts.

A problem is that the degree of vibration isolation that can be achieved is limited, so that the support can produce noise. The slide bearings must be able to withstand large loads since the objects are very heavy in practice. A support carries a mass of usually more than 500 kg. The mass can also be 100 tons or more. This limits the choice of material, in particular that of the intermediate layer insulating against vibrations. The thickness of the intermediate layer insulating against vibrations is also limited.

The object of the present invention is to provide a method of the type mentioned in the preamble with which the transmission of vibration energy can be reduced.

To this end, a method according to the preamble is characterized in that a vibration-insulating first slide bearing section is provided at the location of the support, which vibration-isolating first slide bearing section comprises a plate-shaped frame with a first side and a second side, the first sliding surface being on the first side and an elastomer-containing body on the second side; wherein the freedom of movement of the elastomer-containing body in a plane parallel to the plate-shaped frame with respect to both the plate-shaped frame and with respect to the element is limited by stops enclosing the elastomeric body.

The invention makes it possible to use an elastomer-containing body with better vibration-insulating properties since shear release of an adhesive connection between the first sliding surface and the elastomer-comprising body - or are absent from such an adhesive connection - with a heavy load does not mean that the first sleeve bearing section insulating against vibration is broken. The elastomer-comprising body according to the invention is compressible, for example in that it is provided with recesses, for example in the form of slots or holes, other interruptions in the elastomer-containing body; - it has a foam structure, such as with an open (sponge) or closed cell structure; and / or - the inclusion of compressible particles or bodies.

The elastomer-comprising body is, for example, a body comprising closed-cell polymer. The closed cell polymer is advantageously polyurethane. The plate-shaped frame will usually be a steel frame. The method according to the invention is not only suitable for supporting pipes. Other objects, such as valves and heat exchangers, are conceivable. To limit the freedom of movement of the elastomer-containing body relative to the element, the element can be provided with one or more stops. This can easily be done using a steel mounting plate which comprises one or more stops. The mounting plate can be welded to the element, such as the support. An important advantage of the invention is that, in contrast to the known method in which the mounting plate is welded, the elastomer-containing body will not be present at that moment and thus cannot be damaged by heat during welding. After welding, the elastomer-containing body is only brought into contact with the mounting plate. If this is required due to aging, wear or damage to the first gill surface or the elastomer-containing body, it is not necessary to remove the mounting plate. This means a reduction in maintenance costs. The installation where the slide bearing is used can also be put into operation faster again, which also offers a significant cost advantage.

Restriction of freedom of movement is understood to mean that the relative displacement of the elastomer-containing body is less than 5 mm in any direction parallel to the plate-shaped frame. Preferably the relative displacement is less than 2 mm, and most preferably at least substantially zero. If the elastomer-comprising body is a rectangular body, the number of stops is, for example, 4 or more, with a stop being provided near each side of the rectangular elastomer-containing body. When an attack engages more than one side, the number of attacks can also be less than four. In the case of a raised edge which surrounds the elastomer-comprising body, a single stop will suffice. The stop can also protrude into the elastomer-comprising body. In that case, the assessment if only one is preferably unfounded.

In the context of the present application, the term "support against a support" means support against a support that may be below, above or next to the object, such as for limiting lateral displacement. The support is, for example, of concrete or a steel beam, such as an I-beam. The first gill surface and the second gill surface will usually be provided by different materials. They will be chosen to have a relatively low coefficient of friction. They are provided, for example, by polished stainless steel (stainless steel) and a fluoropolymer such as PTFE.

US2006 / 0186279 describes a method for clamping a pipe, for example that in a car, wherein a vibration-damping material is arranged between a section in which the pipe is clamped and a receiving part in which that section is included. This is not a jigger bearing configuration as in the present invention, since said section is not in contact with the receiving member. The freedom of movement of the pipe is minimal.

DE2801472U1 also does not include a slide bearing and describes a vibration-isolating foot for equipment, the aim being to prevent the equipment from sliding. This is in contrast to the method according to the invention.

AT505861A1 relates to supporting a pipeline, wherein an elastic buffer is provided between two plate parts and the movement of the pipeline is damped. The device does not include a second gill surface for contact with the first gill surface, with an elastomer-containing body on the second side of a plate-shaped frame of the first slide bearing section.

GB2377479A describes elastic fixation of a conduit by means of pouches filled with elastomer arranged in the space between the support and the conduit. The surface of the bags can be coated with PTFE. A plain bearing configuration according to the invention is not described.

A preferred embodiment is characterized in that the stops extend over the outer circumference of the elastomer-comprising body.

The stops make it possible to enclose the elastomer-containing body in contact with the stops, whereby the elastomeric body retains its shape and changes substantially only in thickness when loaded. Thus, the occurrence of shear forces in the elastomer-containing body during operation is substantially limited. This ensures excellent vibration isolation combined with maintaining the elastomeric body. The thickness of the elastomer-containing material can be chosen large in this preferred embodiment, so that a considerably improved vibration isolation can be achieved. The stops are usually over at least 60% of the circumference of the elastomer-comprising body, preferably at least 80%, more preferably over at least 90%, and most preferably over at least 96% with the elastomer-containing body in contact. About 100% of the circumference is the best. The stops are provided, for example, by upright walls of a recess milled in the plate-shaped frame, or the upright walls of a collar welded to the plate-shaped frame.

A particularly preferred embodiment is characterized in that the elastomer-comprising body is a compressible elastomer-comprising body.

Compressible in the context of the present application means that in the absence of an opportunity to deviate transversely to the applied force, it can be pressed in at least 1% of the length in the direction of the applied force. Suitable compressible material is preferably compressible over at least 5% of its length to the maximum load (with the body collapsing). Compressible material is preferably material that contains gaps such as bubbles or compressible particles. The elastomer-comprising body is, for example, a body comprising closed-cell elastomer. The closed cell elastomer is advantageously polyurethane.

A favorable embodiment is characterized in that a stop is present for limiting the distance over which the plate-shaped frame can move in a direction transverse to the main surface of the plate-shaped frame relative to a side of the elastomer-comprising body remote from the second side .

The elastomer-containing body can thus be protected against excessive loads (an object that is too heavy, or which can occur during the placement of the object), as a result of which the elastomer-containing body can collapse. The stop for limiting can advantageously form part of, or be formed by, the stops which limit the freedom of movement of the elastomer-containing body in a plane parallel to the plate-shaped frame relative to both the plate-shaped frame and to the element .

Upon further compression of the elastomer-containing body - in the preferred embodiment where that body is limited to its circumference - the opposite stops come closer to each other, the material thus having less and less opportunity to yield sideways. As a result, local overloads in the material are thus increasingly avoided as the load on the slide bearing increases, until the moment that the stops touch each other and the forces on the elastomer-containing body do not increase further.

A favorable embodiment is characterized in that the elastomeric material is a composite of a compressible particulate material in an elastomeric matrix.

With such a composite, the transmission of vibrations can be better prevented and thus, indirectly, noise nuisance limited. In combination with a stop of the type described above, the composite can be protected against overloading. The compressible material is, for example, cork.

A favorable embodiment is characterized in that the composite comprises cork particles embedded in silicone rubber.

Thus it becomes possible for the first time to effectively insulate hot pipes, as known in the petrochemical industry, against transmission of vibrations.

A favorable embodiment is characterized in that the first sliding surface on the first side is provided by a plate-shaped body, the plate-shaped body and the plate-shaped frame being mechanically coupled.

A mechanical coupling is understood to mean a glue connection, a connection to a connecting member such as a bolt, or the engagement of at least one of the plate-shaped body and the plate-shaped frame on the other of the plate-shaped body and the plate-shaped frame. The plate-shaped frame can for instance have a rectangular recess for receiving the plate-shaped body such that the latter protrudes outside the recess of the plate-shaped frame. The plate-shaped body is, for example, a fluoropolymer plate such as PTFE.

A favorable embodiment is characterized in that the freedom of movement of the plate-shaped body in a plane parallel to the plate-shaped frame is limited by at least one stop that encloses the plate-shaped body.

The stops are usually in contact with the plate-shaped body over at least 60% of the circumference of the plate-shaped body, preferably at least 80%, more preferably over at least 90% and most preferably over at least 96%. Large local taxes are thus avoided. In the case of gluing the plate-shaped body to the plate-shaped frame, the glue connection is loaded to a lesser extent. This allows heavier loads to be carried. Furthermore, creep of the material of the plate-shaped body can be prevented and a long service life can be achieved.

A favorable embodiment is characterized in that the object is a conduit for transporting a fluid under pressure.

This is an important application of the method according to the invention. The pipe is usually thermally and / or acoustically insulated with insulation material. The fluid is, for example, a petrochemical liquid, cryogenic liquid, CO2, air or natural gas.

A favorable embodiment is characterized in that the vibration-insulating first plain bearing section comprises a mounting plate which is attached to the element before the elastomer-containing body is placed against the mounting plate.

The mounting plate is preferably welded. This is possible in the method according to the invention without the welding being able to damage the elastomer-containing body (by heat), since this is provided separately. The mounting plate encloses the elastomer-comprising body by means of at least one stop.

A favorable embodiment is characterized in that the mounting plate is connected to the plate-shaped frame using an element.

Thus, the first plain bearing section can also be used in a non-lying position. The organ is, for example, a leaf spring.

Finally, the present invention relates to a sliding bearing section that has a sliding surface, which sliding bearing section is a vibration-insulating sliding bearing section, the first sliding bearing section insulating against vibration comprising a plate-shaped frame with a first side and a second side, the sliding surface on the first side and an elastomer-containing body on the second side; wherein the freedom of movement of the elastomer-containing body in a plane parallel to the plate-shaped frame with respect to the plate-shaped frame is limited by at least one stop enclosing the elastomer-containing body.

Such a first slide bearing section, which is insulating against vibration, is suitable for use in the method according to the invention. The invention also relates to all variants of the first plain bearing section as described in the method claim described above and preferred embodiments thereof, wherein repetition thereof has been omitted only to be brief.

The present invention will now be explained with reference to the drawing, in which

FIG. 1a-1c show a first sleeve bearing section which is insulating against vibration in top view, cross section and side view, respectively; and

FIG. 2 shows a section through a line which is supported on a support via a slide bearing.

Figures 1a-1c show a vibration-insulating first plain bearing section 100 in top view, cross section and side view, respectively. The main components are formed by a PTFE plate 110, a plate-shaped frame 120 and an elastomer-containing body 130.

The plate-shaped frame 120 is made of solid stainless steel (e.g., stainless steel 316) and has a first side 121 and a second side 122. A first sliding surface is provided on the first side 121, here provided by the PTFE plate 110. Alternative materials are PCTFE, PVDF or Tufnol®. The materials may contain fillers or the like, such as graphite or reinforcement fibers such as fiberglass.

The PTFE plate 110 is received in a recess 125 which is milled on the first side 121 in the plate-shaped frame 120 and has a depth of 1 mm. The PTFE plate 110 has a thickness of 2 mm and therefore protrudes on the first side 121 outside the plate-shaped frame 120. The peripheral edges of the milled recess 125 can function as a stop for limiting and preferably preventing the relative movement parallel to the main surface. of the plate-shaped frame 120. Alternatively or additionally, the PTFE plate 110 may be glued to the plate-shaped frame 120 on the first side, for example with Allyl cyanoacrylate type 920 or 922 from Permabond LLC (Pottstown, United States). The PTFE plate is etched on the side to be glued and provided with a Polyolefine primer, also available from Permabond.

In the embodiment discussed here, the plate-shaped frame 120 has a thickness of 4 mm. The plate-shaped frame 120 has upstanding walls on the second side 122 that act as a stop 123 for the elastomer-comprising body 130.

The elastomer-comprising body 130 is advantageously a composite, such as a composite of silicone rubber and cork granulate, type VC-7000 from Amorim (Mozelos, Portugal). This material can be used at an operating temperature of -65 to + 175 ° C. A continuous load (pressure) of 1.5-6 MPa (N / mm) is permitted at room temperature. The maximum short-term load of the material is 8 MPa (at 20 ° C). This composite can, if desired, for example with glue of type 106 from the company Momentive Performance Materials Ine. (Columbus, United States) are glued to the plate-shaped frame 120, but this is not necessary.

For applications up to 60 "C, alternatively a (compressible) polyurethane elastomer with a closed cell structure can be used, such as Sylodyn® from Getzner Werkstoffe (Bürs, Austria). This elastomer can be used, for example, with Sikaflex type 552 from Sika Corporation (Lyndhurst, United States) are glued to the plate-shaped frame 120, but this is not necessary.

The thickness of the elastomeric body 130 in this embodiment is 2 cm, but can also be e.g. 10 cm. This is much thicker than is possible with known slide bearing insulating bearings.

In the embodiment discussed here, the plate-shaped frame 120 performs various functions: • providing a stable form-retaining base for the attachment (gluing) of the low-friction layer (PTFE plate 110).

• providing a frame enclosing the low-friction layer (PTFE plate 110) to prevent the low-friction layer from shifting, for example when releasing the (glue) connection.

• providing a frame enclosing a low-friction layer (PTFE plate 110) to limit deformation of the low-friction layer due to creep under particularly long-term high loads and high temperatures.

Providing a frame enclosing the elastomer-comprising body 130 to prevent shifting of the elastomer-containing body 130, for example, when releasing the adhesive connection between the elastomer-comprising body 130 and the plate-shaped frame 120.

• Providing a frame enclosing the elastomer-containing body 130 to prevent lateral displacement (bulging of the side faces) of the elastomer-containing body 130 under load, thereby reducing the material stress in the elastomer-containing body 130 and the material can therefore be loaded more heavily.

The first vibration bearing section 100 described above for vibration isolation could be placed as such on a support, the support being provided with stops for limiting the freedom of movement by enclosing the elastomer-comprising body 130.

The in FIG. However, the first slide bearing section shown against vibration isolating 1 also comprises a mounting plate 140 with upright walls 143 which act as a stop 143 for enclosing the elastomer-comprising body 130. Between the stops 123, 143 which extend over the entire circumference of the elastomer-comprising body 130, there is a gap 145 which becomes smaller as the load increases, until the allowable design load for the elastomer-comprising body 130 is reached. At that time, the opposite stops 123, 143 touch each other. Although vibration isolation is no longer available at that time, as soon as the overload is released, the plain bearing can continue to function; it didn't break. The slide bearing will be designed in such a way that in the loaded state the gap is very small, for example 2 mm. This then results in the material of the elastomer-comprising body 130 having hardly any opportunity to give way and thus local overloading is avoided.

When using glue, it will be avoided that the elastomer-containing body 130 is glued against the stops 123, 143 in order to move the elastomer-containing body 130 along the stops 123, 143 with which the elastomer-containing body 130 extends over its entire circumference. is to allow contact in the direction transverse to the plate-shaped frame 120.

The mounting plate 140 is mounted on a support, for example by welding. Since the mounting plate 140, unlike a first slide bearing section which is known against vibration in the prior art, is not rigidly connected to the elastomer-comprising body 130, the latter is not damaged by high welding temperatures. For the flexible connection of the mounting plate 140 and the plate-shaped frame 120, which is necessary for non-horizontal use of the vibration-isolating first slide bearing section 100, wire springs 150 are provided which are mounted on cams 151 (for example socket-head screws) on the mounting plate 140 respectively and engage the plate-shaped frame 120. Instead of wire springs, tension springs, magnets or other means for holding the mounting plate 140 and the plate-shaped frame 120 together can be used. The advantage of magnets is that a direct connection between the mounting plate 140 and the plate-shaped frame 120 can be avoided. The magnets may be mounted on the mounting plate 140 and the plate-shaped frame 120, and / or included in the elastomeric body 130.

FIG. 2 shows a pipe 200 as an object 200 which is supported against a support 210. The pipe 200 comprises an insulating shell (202), for example mineral wool, and an insulating jacket (203), made of thin steel or aluminum sheet. In the embodiment shown here, the support 210 is an I-beam 210 which is provided on its upper side with two noses 211.

The inner tube 201, in which a fluid is transported during use, is provided with a shoe 220 which is provided with three second slide bearing sections 230 of slide bearings 240. The three second slide bearing sections 230 have second slide surfaces 232 which are to the first sides 121 of first slide bearing sections 100. turned.

These second sliding surfaces 232 are advantageously made of polished stainless steel. For this purpose, polished stainless steel can be welded onto the shoe 220, as is known per se in the art.

The first jigger bearing section 100 'is part of a slide bearing that rests on the support 210. Wire springs or the like for holding the mounting plate 140 and the plate-shaped frame 120 together are not necessary in such a case.

The arrangement shown in FIG. 2 permits displacement of conduit 200 relative to support 210 in the axial direction of conduit 200.

Claims (12)

A method of supporting an object (200) against a support (210) using a slide bearing (240), which slide bearing (240) - a first vibration bearing insulating section (100) which has a first slide surface, and - a second jig bearing section (230) having a second jig surface for contacting the first jig surface of the first jib bearing section (100) which is insulating against vibration; wherein an element selected from the object (200) and the support (210) are provided with the first vibration bearing section (100) which is insulating against vibration and the other element is provided with the second jib bearing section (230) through which the object (200) the slide bearing (240) is supported against the support (210), characterized in that a vibration-insulating first jib bearing section (100) is provided at the location of the support (210), which first vibration jib-bearing section (100) is insulating against vibration (120) comprising with a first side (121) and a second side (122), the first side surface (121) having the first gill surface and on the second side (122) an elastomer-comprising body (130); wherein the freedom of movement of the elastomer-comprising body (130) in a plane parallel to the plate-shaped frame (120) with respect to both the plate-shaped frame (120) and with respect to the element is limited by stops including the elastomeric body (130) (123, 143). The method of claim 1, wherein the abutments (123, 143) extend over said outer circumference against the outer circumference of the elastomer-comprising body (130). The method of claim 1 or 2, wherein the elastomer-comprising body (130) is a compressible elastomer-comprising body (130). Method according to one of the preceding claims, wherein a stop is present for limiting the distance over which the plate-shaped frame (120) in a direction transverse to the main surface of the plate-shaped frame (120) with respect to one of the second side ( 122) can move away from the side of the elastomer-comprising body (130). A method according to any preceding claim, wherein the elastomeric material is a composite of a compressible particulate material in an elastomeric matrix. The method of claim 5, wherein the composite comprises cork particles embedded in silicone rubber. The method of any preceding claim, wherein the first sliding surface on the first side (121) is provided by a plate-shaped body (110), the plate-shaped body (110) and the plate-shaped frame (120) being mechanically coupled. The method of claim 7, wherein the freedom of movement of the plate-shaped body (110) in a plane parallel to the plate-shaped frame (120) is limited by at least one stop enclosing the plate-shaped body (110). A method according to any one of the preceding claims, wherein the object (200) is a conduit (200) for transporting a fluid under pressure. The method of any one of the preceding claims, wherein the vibration-insulating first plain bearing section (100) comprises a mounting plate (140) that is attached to the element before the elastomer-comprising body (130) is placed against the mounting plate (140). The method of any one of the preceding claims, wherein the mounting plate (140) is connected to the plate-shaped frame (120) using a member (150). A slide bearing section (100) having a sliding surface, which slide bearing section (100) is a vibration-isolating slide bearing section (100), characterized in that the vibration-isolating first slide bearing section (100) comprises a plate-shaped frame (120) with a first side (121) and a second side (122), the sliding surface being present on the first side (121) and an elastomer-comprising body (130) on the second side (122); wherein the freedom of movement of the elastomer-comprising body (130) in a plane parallel to the plate-shaped frame (120) relative to the plate-shaped frame (120) is limited by at least one stop that encloses the elastomer-containing body (130).