DE3210254C2 - Plastic pipe section that can be used as a pipe bend - Google Patents

Abstract

A pipe section made of thermoplastic material that can be used as a pipe bend with two end connection sections and a flexible bend section. All sections are formed from a single tube. The arch section is provided with a corrugated profile of constant wavelength and amplitude. It has a wall thickness that is around a quarter to a third less than the static wall thickness. The corrugated profiling is provided with an amplitude which, in conjunction with the reduced wall thickness, leads to an average polar area moment of inertia related to the wavelength, which corresponds approximately to or is greater than the polar area moment of inertia of the pipes to be connected.

Description

The invention relates to a pipe section made of thermoplastic material that can be used as a pipe bend, with two end connection sections and a flexible arch section, all sections from one uniform tube are formed and the arch section with a corrugation profile of constant wavelength and Amplitude - viewed in a longitudinal section - is provided with wave crests, wave troughs and wave flanks and further wherein the connecting sections have a wall thickness that is the wall thickness of the to be connected Corresponds to pipes with a given polar area moment of inertia.

Such pipe sections are customary in particular in connection with pipelines made of plastic pipes, the Record cables in the form of telephone cables and the like. They should be flexible enough to be used as pipe bends of up to 90 ° or even more. The polar area moment of inertia of the pipes is determined the behavior in terms of strength and stability and thus the loads that can be absorbed. The main material used is polyvinyl chloride - which is known from practice Pipe sections have not only the connection sections, but also the flexible elbow section the wall thickness of the pipes to be connected. This has been considered necessary for reasons of strength and stability. On the other hand, these pipe sections are not very flexible. Especially when used as cable ducts are that have a diameter of 10 cm and more

ίο have very large elastic ones when they are bent Restoring forces. That bothers when laying.

In order to improve the flexibility of generic pipe bends, it has been proposed (FR-PS 13 85 986), the wall thickness in the area of the selected arch section to reduce compared to the wall thickness of the connecting piece as well as cracking in the To prevent transition area, the amplitude in the corrugation in the transition area to the connecting section decrease as well as increase the wall thickness.

Such a design can hardly be achieved in practice when it comes to pipe sections that relate to of the connecting sections and with respect to the selected arc section from an originally smooth extruded one Tube to be shaped. This is why this version has no entry, at least in the case of cable ducts found in practice, especially since they are mass-produced items, such as the pipe sections that can be used as pipe bends in the case of cable ducts, cannot be manufactured with reasonable effort.

The invention is based on the object of a generic To further develop the pipe section so that it meets all the requirements from a static point of view, which the pipes to be connected also suffice, but that it is much more flexible and with considerable reduced springback, bending of up to 90 ° and more, is bendable.

This object is achieved in that for the purpose of use as a cable pipe of z. B. 10 cm diameter the arch section has a wall thickness which is about a quarter to a third ^ thinner than that static wall thickness of the connecting sections, and that the corrugated profile has an amplitude that in Connection with the reduced wall thickness to a mean polar area moment of inertia related to the wavelength leads, which is about the polar area moment of inertia of the pipes to be connected equals or is greater.

The invention has recognized that the flexibility of generic pipe sections without loss of static

in this way and in terms of stability can, if the wall thickness in the area of the arch section is reduced as specified but at the same time that mean polar area moment of inertia of the arc segment is set up so that it is the polar area moment of inertia corresponds to or is larger than the pipes to be connected. The result is an as Elbow pipe that can be used, which at least absorbs all stresses, including the one to be connected Receives pipeline, which is, however, much more flexible than known embodiments. Such a Pipe section can also be easily produced if you work with a corresponding two-shell mold which is closed around the pipe section, which is to experience the design according to the invention. These Form has a special design for the curved section with the corrugated profile and for the connecting sections. If the pipe section made of thermoplastic material is then heated and

offset by pressure, the arch section is pressed into the corrugated profile of the form, and surprisingly away from the expansion up to the specified polar area moment of inertia also the specified Adjusts the wall thickness. The pipe section according to the invention is also particularly suitable for mass production.

In particular, there are several possibilities for further training and within the scope of the invention Layout. An advantageous embodiment of the invention is characterized in that the wave crests, the waves are smaller and the wave flanks have the same reduced wall thickness everywhere. With usual Cable ducts of the specified diameter, the wall thickness of the connecting sections z. B. make about 3 mm, that of the arched piece about 2 mm. In the context of the invention, the amplitude of the wave profile is to match the reduced wall thickness of the Boger section. With the usual plastics, in particular in the case of polyvinyl chloride, this means that the amplitude of the corrugated profile is about a fifth to a quarter from the inner tube radius of the connecting sections. The wavelength should expediently be approximately one fifth to one third of the inner pipe radius of the connecting sections be. It goes without saying that in the area of the corrugated profiling of the "inner" wave crests measured inside diameter compared to the inside diameter of the connecting sections regularly unchanged is

In the following the invention is illustrated by means of a drawing which shows only one exemplary embodiment explained in more detail It shows in a schematic representation

F i g. 1 shows a longitudinal section through a pipe section according to the invention,

F i g. 2 in opposite to FIG. 1, on a much larger scale, the section A from the object according to Fig. 1. And

F i g. 3 on the scale of FIG. 2 shows section B from the object according to FIG. 1.

The pipe section 1 shown in the figures consists of thermoplastic material, for example polyvinyl chloride. It can be used as a pipe bend and can therefore be bent up to 90 ° or even more. The basic structure includes two end connection sections 2 and a flexible bend section 3. All sections 2, 3 are made from a single tube

ίο shaped. The curved section 3 is provided with a corrugated profile with corrugation peaks 4, corrugation troughs 5 and corrugation flanks 6 - viewed in a longitudinal section. The terminal portions 2 have a wall thickness D, which corresponds to the wall thickness of the connecting portions 2, and thus for the connected pipes with a predetermined polar moment of inertia, the arc portion 3 has other hand, a wall thickness d which is less by one-quarter to one-third D. than the static wall thickness This gives can be seen in particular from a comparative consideration of FIG. 2 and 3. In addition, the arrangement is such that the corrugated profiling 4, 5, 6 has an amplitude A upc '., T, which in connection with the reduced wall thicknessc d leads to a mean, polar area moment of inertia related to the wavelength L, which corresponds approximately to the polar area moment of inertia of the pipes to be connected or is greater. In the exemplary embodiment, an even more preferred embodiment of the invention, the wave crests 4, the wave troughs 5 and the wave flanks 6 have the same, reduced wall thickness d everywhere. The wall thickness D of the connecting sections 2 may be about 3 mm, that of the curved section 3 about 2 mm. The amplitude A of the corrugated profiling 4, 5, 6 makes up about a fifth to a quarter of the inner tube radius R of the connecting sections 2. The wavelength L is in the range from about a fifth to a third of the inner tube radius R of the connecting sections 2.

1 sheet of drawings

Claims (5)

Patent claims: 1. A pipe section made of thermoplastic material that can be used as a pipe bend - with two end-side end sections and a flexible bend section, all sections are formed from a single tube and the bend section with a corrugated profile of constant wavelength and amplitude viewed in longitudinal section - provided wave crests, wave troughs and wave flanks is and wherein the connection sections also have a wall thickness which corresponds to the wall thickness of the pipes to be connected with a predetermined polar area moment of inertia, characterized in that for the purpose of use as a cable pipe of z. B. 10 cm diameter, the arch section (3) has a wall thickness (d) which is about a quarter to a third less than the static wall thickness (D) of the connecting sections (2), and that the corrugated profile (4,5,6 ) has an amplitude (A) which, in conjunction with the reduced wall thickness (d), leads to a mean polar area moment of inertia related to the wavelength (L) , which corresponds approximately to the polar area moment of inertia of the pipes to be connected or is greater 2. pipe section according to claim 1, characterized in that the wave crests (4), the wave troughs (5) and the wave flanks (6) have the same reduced wall thickness f <# everywhere. 3. pipe section laughs one of claims 1 or 2, characterized in that the wall thickness (D) of the connecting sections (2) is about 3 u / m and that of the arc section (3) efwa 2 n, m. 4. Pipe section according to one of the claims 1 to 3, characterized in that the amplitude (A) of the corrugated profile (4, 5, 6) is about a fifth to a quarter of the inner pipe radius (R) of the connecting sections (2). 5. Pipe section according to one of claims I to 4, characterized in that the wavelength (L) makes up about one fifth to one third of the inner pipe radius (R) of the connecting sections (2).