FI83984B - TRYCKLEDNING. - Google Patents

Description

1 83984

The present invention relates to a pressure line, in particular to a ground or water pressure drain line, consisting of successive pipes and fittings, such as branch connections, which pipes and fittings are connected to each other by sleeve joints, the sleeve having members and grooves on the outer surface of the pipe. for a locking member for locking the pipes and / or fittings together in their longitudinal direction, the pipes being ribbed flange tubes and the seal being located in the groove between the ribbed flanges.

In some sewer lines, such as pressure sewer lines, the medium to be transported is under pressure. The pressurization is achieved, for example, by feeding the medium into the pipeline by means of pumps. Typical pressures in pressure sewer pipes are 3-4 bar. In certain situations, such as when the pumps are stopped, a considerable vacuum may also be created in the pipeline.

20 At points in the pipeline where the walls of the pipeline are subjected to high forces due to pressure or water movement, such as bends, valves and branch connections, the pipeline pipes and fittings shall be locked together to keep the relative position of the parts constant during pressure shocks. Also, since the sections of the pipeline must not move relative to the surrounding ground, the sections must be locked together so far that the friction between the pipes and the ground is large enough to anchor the bend.

An arrangement is known for locking the pipes to each other and to the connecting pieces, which consists of grooves located on the inner surface of the sleeve and on the outer surface of the plug end, in which a locking strip extending into each groove is arranged. This arrangement locks the parts together in the direction of the length of the tube-35 axis.

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One of the disadvantages of the known pressure lines described above is the high need for locked joints, because the friction of smooth plastic pipes and the surrounding ground is relatively low. In addition, the manufacture of locking points is laborious.

5 When the pipe has to be cut, the groove of the pipe must be grooved for the locking strip or a sleeve with said groove must be inserted over the pipe.

It is an object of the present invention to provide a pressure line in which less than 10 locking points between parts are required than in known lines and in which the manufacture of locking points is considerably simpler than in known lines. The pressure line according to the invention is characterized in that the locking members are located in the grooves between the rib flanges.

By constructing a pressure line from the rib flange tubes, a much higher frictional force is provided between the line and the surrounding soil, which allows the number of interlocking conductor parts to be significantly reduced, i.e. the number of interlocking points is smaller than in known conductors. In addition, cutting the pipe does not make it difficult to lock the parts together, because the outer surface of the rib flange pipe has circumferential grooves along the entire length of the pipe, so that it is never necessary to make a groove in the plug end for the locking strip or seal. The number of locking rings and 25 seals is also easy to optimize during installation.

In addition to the above considerations, the use of rib flange pipes in a pressure drain is also advantageous in that the rib flanges give the pipe high ring stiffness, which prevents the pipe from buckling inwards under vacuum inside the pipe, allowing the pipe walls to be dimensioned according to internal pressure requirements. Namely, the wall thickness of smooth pipes of known pressure drains has had to be oversized due to the risk of buckling.

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A surprising advantage of the finned tube construction is also that the axial stiffness of the tube does not increase too much due to the oversizing of the wall, as is the case with smooth tubes. Namely, it has been found that the vaulting of the earth around the line, which increases the strength of the pipeline, is enhanced if the pipe is also suitably flexible in the axial direction. However, since the inner wall of the rib flange tube is typically dimensioned to 6 bar, the axial stiffness is formed high enough so that the tubes are easy to install. However, small obstacles such as stones or the like can be circumvented by bending the pipe, which is not possible in the case of smooth pipes oversized in terms of wall thickness.

Another reason for the oversizing of the wall thickness is that since the temperature of the pipe increases due to the heat given off by the wastewater, the elastic modulus of the pipe and thus also the stiffness of the ring decreases. In a fin flange pipe, the temperature of the fins does not rise much, so the decrease in ring stiffness does not have to be taken into account when dimensioning the pipe. Because similar smooth pipes have been used in emotional-20 pressure sewers and fresh water pipes, faulty connections have occurred. Building pressure drains from ribbed flange pipes eliminates this possibility of error.

In addition, it should be noted that the pumping pressure of the drains is usually 2 to 4 bar. A sufficient design pressure for pressure shocks is 6 bar. However, the smooth 6 bar PVC pipe buckles because the ring stiffness is only about 9 kN / m2. A smooth PVC pipe with a ring stiffness of about 16 kN / m2, i.e. sufficient, weighs about 13.4 30 kg / m with a diameter of NS 200. The corresponding fin flange pipe (same rigidity) and sufficient pressure resistance (6 bar) weigh only 10 ... 11 kg / m, so the fin flange pipe is also more economical to manufacture.

The use of a fin flange tube is particularly advantageous in situations where reasonable pressure resistance, good buckling strength and interlocking joints are required at the same time.

According to a preferred embodiment of the invention, the locking member is a flexible strip or rod with a diameter exceeding the height of the rib flanges. In this case, the locking member 5-5 extends from the groove between the rib flanges, extending into the groove in the inner wall of the sleeve, whereby the parts are locked together in the longitudinal direction of the cable.

The rib flange pipes are known per se, for example from patent application FI 860135. A typical embodiment is a 10-walled earth sewer drain line with high narrow ribs. A thin wall is possible because there is no pressure in the guide lines and the high ribs provide sufficient ring stiffness against ground pressure. Typically, such a pipe has a volume ratio between the inner wall and ri-15 of about 1 ... 1.5 / 1. The straight shape of the ribs is due to the optimization of material use. In this case, the emission angle of the fins is typically about 4 degrees or less.

A preferred embodiment of the invention is characterized in that the volume of the wall of the rib flange tube is more than twice the volume of the material of the rib flanges, that the rib flanges of the rib flange are trapezoidal in cross section and that their side angle is 45 ° to the longitudinal plane 45 ° , preferably about 35 °.

The ribs shaped in this way also improve the pressure resistance of the pipe. The strongly wedge-shaped groove between the ribs causes the pressure inside the pipe to effectively push the sealing ring against the sleeve, whereby the tightness 30 improves as the pressure increases.

One preferred embodiment of the pressure line according to the invention will now be described in more detail with reference to the accompanying drawing, in which Figure 1 shows a sleeve connection 35 between a pipe and a connecting piece in longitudinal section, and

II

Fig. 2 83984 shows a cross-section along the line II ... II in Fig. 1, and Fig. 3 shows a second embodiment of the invention in longitudinal section.

5 The drawing shows a part of a pressure line consisting of a plug end 1 of a pipe and a sleeve 2 of a connecting piece such as a branch one or a double sleeve 2. The parts 1,2 are preferably made of plastic and are connected to each other by means of a sleeve connection 2 in. The pipeline of the invention is intended to carry a pressurized fluid, such as wastewater, at a pressure of typically about 2-5 bar. Occasionally there may be vacuum in the line. The line is immersed in the ground or water and can also act as a water suction-15 and outlet pipeline, e.g. carrying cooling water.

With straight and easy sections of the cable, the plug heads and sleeves do not necessarily have to be locked together, but a sealing ring 3 between the outer surface of the plug head and the inner surface of the sleeve is sufficient. If necessary, two sealing rings of different material placed in adjacent grooves can be used, one resistant to oil and the other to microbiological attack. At points where additional pressure from fluid flows to the line walls, such as line bends, vent-25 bricks, and branches, the plug head and sleeve must be locked together to prevent the connection from opening.

According to the invention, the number of locked joints between these pipes can be considerably reduced and their making simplified by using the rib-flange tubes of the line put-30 and placing the locking means between the plug head and the sleeve in the grooves between the rib flanges of the rib flange tubes. The grooves are also used as a sealing groove.

The outer surface of the plug end 1 of the tube shown in the drawing has circumferential ribs 4 with grooves 35 5 between them. The inner surface of the sleeve 2 also has a number of circumferential grooves 6 corresponding to the number of locking members 6 83984 which align with the groove grooves 5. The locking members of the connection are located in the aligned grooves of the plug head and sleeve 5.6. In the embodiment shown, the locking members 5 are formed of flexible rods 7, for example of relatively rigid plastic, the diameter of which exceeds the height of the rib flanges 4, the rods extending from the grooves 5 of the plug head to the grooves 6 of the sleeve. the whole plug head.

The ribs 4 are trapezoidal with the sides straight or, as in the figure, curved. The ribs are compact and their side angle to a plane perpendicular to the longitudinal direction of the tube is 5 ° to 45 °, preferably about 35 °. The volume of the wall of the tube 15 is more than twice the volume of the material of the rib flanges.

The fin flange tube can be easily optimized for pressure line applications. This is not the case with conventional smooth pipes. Since the pressure causes a circumferential tensile stress 20, it is preferable to reinforce the inner tube with long fibers, the majority of which are circumferentially oriented, whereby the breaking strength in this direction increases. Since the function of the ribs is to increase the tire stiffness, there is another load situation prevailing in the ribs. They prevent the tube from nearly twisting the sea buckthorn in the circumferential direction, whereby the design stress is bending stress and compression. In this case, the strength of the ribs can best be increased by using fillers. A surprising advantage is achieved by selecting the filler so that it reacts with the metal detector, etc. In this case, the plastic pipes-30 ken location can be easily located after installation. The use of these types of fillers is not possible with ordinary pressure pipes, as the fillers reduce the tensile strength.

The connection shown in the figures is formed by inserting, if necessary, the plug end 1, 7 83984 of a cut-off flange tube into the sleeve 2 of the cut-off ring 3, in which a at least one rod 7 is then inserted

5 Contrary to the above, the grooves 6 of the sleeve can be omitted, in which case only the locking effect of the holes 8 is relied upon. The bars 7 can be replaced by another corresponding locking member, such as a strap. This method of locking has the advantage that it is easy to see from the straps whether the lii-10 is locked or not.

The above-mentioned locking arrangement between the pipe and the sleeve can be replaced by projections located on the inner surface of the sleeve, which protrude into the grooves 5 of the pipe, locking the parts together, the so-called snap on lock.

15 The locking arrangement can also be replaced by a piston ring type plastic ring mounted on the sleeve with a locking pin or pins which protrude through a hole in the wall of the sleeve between the ribs of the plug head. Alternatively, a collar 20 9 according to Fig. 3 can be used, which extends in width to the side of the plug head and also sits between the ribs of the plug head. In this case, a sleeve with lowered ribs is used.

The sleeve 2 can extend over at least four grooves 5, thus enabling the use of two sealing rings 3 and two locking bars 7.

Claims (8)

A pressure line, in particular a pressure sewer line for installation on land or water, consisting of successive pipes and fittings, such as branch connections, which pipes and fittings are connected to each other by sleeve connections, the sleeve (2) having members (6, 8) and a pipe (1) the outer surface has grooves (5) for the seal (3) and the locking member (7) for locking the pipes and / or fittings together in their longitudinal direction, the pipes being ribbed flange tubes and the seal (3) being located in the rib flanges (4) in the groove (5), characterized in that the locking members (7) are located in the grooves (5) between the rib flanges (4). Pressure line according to Claim 1, characterized in that the members of the sleeve (2) for the locking element are formed by a circumferential groove (6) in the inner surface of the sleeve and / or by a hole (8) in the wall of the sleeve. Pressure line according to Claim 2, characterized in that the locking element is a flexible strip or rod (7) whose diameter exceeds the height of the rib flanges (4). Pressure line according to Claim 3, characterized in that the sleeve (2) extends over at least four grooves (5), enabling the use of two sealing rings (3) and two locking rods (7). Pressure line according to Claim 1, characterized in that the volume of the wall of the rib flange tube is more than twice the material volume of the rib flanges (4). Pressure line according to Claim 5, characterized in that the rib flanges (4) of the rib flange tube have a trapezoidal cross-section and that the angle of their sides 35 perpendicular to the longitudinal direction of the tube is 5 ° to 45 °, preferably about 35 °. Pressure line according to Claim 1, characterized in that the ribs (4) of the rib flange tube contain fillers, such as metal particles. Pressure line according to Claim 1, characterized in that the wall of the rib flange tube (1) has long fibers in order to increase the pressure resistance. 10 83984