DE202015003257U1 - Inline lighting device - Google Patents

Abstract

Inline lighting device (10) for radiation curing of an inliner plastic lining in a pipe and / or a channel, wherein the inline lighting device (10) has at least one support device (11) on which at least one electromagnetic beam source (23) is arranged characterized in that at least two support devices (11) are provided, which are arranged in the direction of a longitudinal axis (A) of the inline lighting device (10) at a mutual distance (a) behind one another, wherein this distance (a) is variable.

Description

The invention relates to an inline lighting device for radiation curing of an inliner plastic lining in a pipe and / or a channel, wherein the inliner lighting device has at least one support device on which at least one electromagnetic beam source is arranged.

From the prior art, it is known, for example, in a pipe to be rehabilitated a pipe or a water pipe impregnated with a thermosetting plastic resin hose, d. H. a so-called inliner, introduce radially expand and thereby tension against the inner wall of the pipe or the channel. In this position, the inliner is cured and fixed by means of electromagnetic radiation, for example by UV light. For this purpose, inline lighting devices are known, which are moved or moved along the extension direction of the pipe and / or the channel, so that the inliner or the entire plastic lining of the pipe and / or the channel by the radiation of the electromagnetic radiation source, for example UV light, is cured.

The common inline lighting devices have the disadvantage that the radiation distributions of the electromagnetic radiation sources within the tube and / or the channel, in particular along the extension direction of the tube, are always the same, so that the time for radiation curing can not be optimized by tuning the radiation distribution. In addition, the known inline lighting devices can be cumbersome introduced into the pipe and / or the channel.

It is therefore the object of the invention to eliminate the above-mentioned disadvantages and to develop an in-line lighting device with the aid of which the time for radiation curing of a plastic lining in a pipe and / or a channel can be changed by changing the radiation distribution. In addition, the inliner lighting device according to the invention should be introduced into the pipe and / or the channel in a simple manner.

The invention is achieved with an inline lighting device, which is characterized in that at least two support devices are provided, which are arranged in the direction of a longitudinal axis of the inline lighting device in a mutual distance one behind the other, wherein this distance is variable.

In the context of the invention, the longitudinal axis of the inline lighting device coincide with the extension direction of the pipe and / or the channel, but it is in any case parallel to this. A radial direction is perpendicular to the longitudinal axis in the direction of the tube and / or the channel.

Due to the variable distance of the support devices, the axial distance of the electromagnetic radiation sources mounted on the support devices along the longitudinal axis is variable, so that the radiation distribution of the electromagnetic radiation sources at least in the axial direction along the longitudinal axis of the inline lighting device with respect to the dimensioning of the liner or the plastic lining is tunable. By a small axial distance of the support devices, for example, a high local illumination density can be achieved, with a larger illumination range can be obtained by a large axial distance of the support devices. The illumination density can therefore be matched to the inliner or the plastic lining, so that the time for radiation curing can be optimized. Another advantage of the in-line lighting device according to the invention relates to its variable axial dimensions. Thus, the lighting device can be introduced in axially collapsed state in a simple manner in the pipe and / or the channel and be extended to the desired size only at the site. Likewise, removal of the inline lighting device from the pipe and / or the channel is facilitated.

Preferably, the support devices are connected to each other via at least one axially adjustable connecting element, which may for example preferably be a telescopic linkage. This type of design requires a small amount of material, so that a shadow through the axially adjustable connecting element is as small as possible. In addition, a telescopic linkage is a structurally reliable structure to connect the support devices with a variable axial distance.

In addition, a control unit may be provided by means of which a drive for the axially adjustable connecting element can be activated and the axial distance between the supporting devices can be changed in this way. About the control unit and its associated drive a defined change in the axial distance of the support devices can be achieved in a simple manner, in particular, the control unit can be controlled remotely by a user from the outside.

An advantageous embodiment provides that at least one of the support devices and preferably all support devices have at least one and preferably a plurality of support devices, each with one held on the lighting device arm and an extendable telescopic member. The support device may extend with a radially outward direction component outwardly toward the inside of the liner, preferably, the extension direction of the support device is perpendicular to the longitudinal axis of the inline lighting device. The arm of the support device is preferably connected directly to the inline lighting device and held by this. The extendable telescopic member may be indirectly or directly connected to the arm and preferably guided in the inside hollow arm, so that it can be extended and retracted linearly and radially. As a result, the supporting device can be brought into contact with the inner wall of the inliner. In this case, a braking or locking element may be provided that fixes the position of the telescopic member relative to the arm, such as by positive and / or non-positive action. By the supporting device, a defined position of the lighting device is achieved in the pipe and / or the channel, wherein each support device may have at least three distributed over the circumference arranged, in particular evenly distributed arranged supporting devices. With little design effort, the lighting device can assume a defined position within the tube and / or the channel, so that it is always radially centered in particular.

The support devices may have a chassis with at least one roller. Preferably, the chassis is arranged on the radially outer and the inliner facing end of the support device, in particular on the radially outer, the inliner end facing the telescopic member, so that the chassis, in particular its roles, are in contact with the inliner. If the lighting device is moved along the extension direction of the pipe and / or the channel, not only is a support against the inner wall of the pipe and / or the channel, it also reduces the resistance to movement within the pipe and / or the channel by the Roll on the inner wall of the tube and / or the channel rest and roll.

At least one of the beam sources can be attached to one of the telescopic links and be adjustable together with this. In particular, this at least one beam source at the radially inner and the inliner opposite end of the telescopic member may be attached. Preferably, the beam source is aligned parallel to the longitudinal axis of the inline illuminator and extends to one or both sides perpendicular to the telescoping member in the axial direction. As a result, the radial distance of the beam sources to the inliner in the tube and / or the channel is variable, so that a further coordination of the illumination distribution on the inliner or the plastic lining can be made. For example, for a higher local illumination intensity of the radial distance of the beam source relative to the liner or the plastic lining can be reduced or increased for a broadly distributed illumination intensity of the radial distance of the steel source to the liner or the plastic lining. In addition, the compact design of the inline lighting device facilitates the introduction into and the removal from the pipe and / or the channel substantially.

A further development provides that at least one of the support devices has a spring element, by means of which the associated telescopic member is acted upon by a radially outward force, so that the support devices always with the liner or the plastic lining of the pipe and / or the channel in contact stand. As a result, a dynamic adaptation of the supporting devices to the inliner or the plastic lining of the pipe and / or the channel is possible.

The axial distance between the support devices and / or the length of the support device may be variable over a range of 100 mm to 800 mm, preferably from 300 mm to 600 mm, in particular from 400 mm to 500 mm. In this way, an adjustment of the illumination distribution and the illumination intensity in the manner described above over a wide range, both along the axial and the radial direction. As a result, the radiation hardening process can be adapted to the boundary conditions and in particular the inliner or the plastic lining of the pipe and / or the channel. In addition, in this way, the radial dimension of the inline lighting device can be reduced, so that the inline lighting device can be easily inserted into and removed from the pipe and / or the channel. Only after the introduction of the axially and / or the radially movable components can then be extended and thereby the inline lighting device can be adapted to the application.

In an advantageous embodiment, a control unit is provided on at least one of the support devices, by means of which a drive for at least one of the telescopic members of the support device can be controlled. The control unit and / or the drive can directly with the be associated with associated telescopic member. The control unit and the drive can be integrally formed and arranged on the support device. The control unit as well as the drive can be controlled externally by a user remotely. As a result, the telescopic members can be controlled comfortably and mechanically reliably.

In a further development of the invention, a control unit is provided on at least one of the support devices, by means of which a drive for at least one of the telescopic members of the support device can be controlled. The control unit and / or the drive can be connected directly to the associated telescopic member. It may be advantageous to form the control unit and the drive in one piece and to arrange on the support device. The control unit as well as the drive can be controlled externally by a user remotely. As a result, the telescopic members can be controlled comfortably and mechanically reliably.

Further advantages and features of the invention will become apparent from the claims and from the following description in which an embodiment of the invention with reference to the drawings is carried out in detail. Showing:

1 A perspective view of an inline lighting device according to the invention;

2 a front view of the inline lighting device;

3 the inline lighting device according to 2 in the extended state;

4 a side view of the inline lighting device according to 2 and

5 a side view of the inline lighting device according to 3 ,

1 shows an inliner lighting device according to the invention 10 in a perspective view. The inline lighting device 10 has two axially adjustable connecting elements 12 extending parallel to a longitudinal axis A of the inline lighting device 10 extend.

The longitudinal axis A of the inline lighting device 10 extends parallel to the extension direction of a surrounding pipe and / or a channel (both not shown), whose inner wall is provided with a plastic lining, also called inliner, which in the application by the inline lighting device 10 is to cure by means of electromagnetic radiation.

It is assumed that an "axial" direction parallel to the longitudinal axis A of the inline lighting device 10 runs and a "radial" direction perpendicular thereto.

The two axially adjustable connecting elements 12 are in 1 as well as in 4 and 5 formed as a telescopic linkage, each having two telescoping axial telescopic arms 25 exhibit.

The axially adjustable connecting elements 12 connect two carrying devices 11 the in-line lighting device 10 each with the following components: Four circumferentially equally distributed support devices 13 , a control unit 14 with assigned drive 15 and another control unit 19 with assigned drive 20 ,

The two carrying devices 11 are arranged one behind the other along the longitudinal axis A of the inline lighting device at an axial distance a. About a change in length of the axially adjustable connecting element 12 the distance a is variably adjustable. Accordingly shows 4 a merged inline lighting device 10 with a small axial distance a and 5 an extended in-line lighting device 10 with increased axial distance a.

The control unit 14 with assigned drive 15 is on the axial connecting elements 12 facing away from the in 1 shown rear support device 11 appropriate. According to 4 and 5 are both the control unit 14 as well as the drive 15 centered on this front. The control unit is used 14 for controlling the drive 15 over which the axial telescopic arms 25 can be moved.

The four on each one of the support devices 11 uniformly distributed over the circumference arranged supporting devices 13 each have one on the support device 11 held arm 16 one in the arm 16 engaging and extendable from this telescopic member 17 , an electromagnetic radiation source 23 with a socket 24 as well as a chassis 21 with two rolls each 22 on.

The arm 16 the support device 13 is with the carrying device 11 rigidly connected and hollow inside, so that the telescopic telescopic member 17 inside the arm 16 is stored and guided. Alternatively, also the telescopic member 17 hollow and around the arm 16 be feasible. The arm 16 extends radially outward in the direction of the inliner (not shown). The telescopic link 17 is radially extendable and has at its radially outer end a chassis 21 with two rolls each 22 on. Both roles 22 each of a chassis 21 are connected by a common axis and are in the application on the inner surface of the liner. This allows the entire inline lighting device 10 be moved in the longitudinal direction.

At the telescope links 17 is laterally each a spring element 18 attached, which is the associated telescopic member 17 acted upon by a radially outward force, so that the telescopic member 17 always with a force biased in the direction of the inliner and thus always contact with the inliner on the rollers 22 is guaranteed.

On both facing each end faces of the support devices 11 is each a control unit 19 with an associated drive 20 appropriate. The control unit 19 serves to control the drive 20 , By means of which the length b of the associated supporting device 13 by a movement of one or more telescopic members 17 can be adjusted.

Out 1 . 4 and 5 shows that an electromagnetic radiation source 23 in each case an associated socket 24 on the extendable telescopic member 17 is arranged. The electromagnetic radiation source 23 is designed as a UV lamp, but can also emit radiation in any other wave range. The electromagnetic radiation sources 23 are cylindrical, so that their cylinder axis substantially parallel to the longitudinal axis A of the lighting device 10 lies. The electromagnetic radiation sources 23 are with protective elements 26 covered at its radial outside, so that the beam sources 23 are protected from external mechanical impact.

2 and 4 show the inline lighting device 10 in a state in which the adjustable components, in particular the axially adjustable connecting elements 12 and the extendable telescopic links 17 have moved together, so that the inline lighting device 10 has minimal dimensions. In this condition, the inline lighting device 10 for example, introduced into the tube and / or the channel or removed therefrom. Within the pipe at the job site, the adjustable components can be extended, for example by a user, so that the inline lighting device 10 in the 3 and 5 shown extended position occupies. To do this, the user controls the control units 14 . 19 on, for example via wired and / or wireless data communication, and thus causes a corresponding change in the adjustable components.

Here, a denotes the axial distance of the support devices 11 along the longitudinal axis A of the inline lighting device 10 and b the length of the support devices 13 , Both the axial distance a as well as the length b of the support devices 13 can be changed in a range of 100 mm to 800 mm.

LIST OF REFERENCE NUMBERS

10

Inline lighting device

11

carrying device

12

axially adjustable connecting element

13

Support device

14

control unit

15

drive

16

poor

17

telescoping member

18

spring element

19

control unit

20

drive

21

landing gear

22

role

23

beam source

24

Rifle

25

axial telescopic arms

26

protection element

A

longitudinal axis

a

distance

b

length

Claims (11)

Inline lighting device ( 10 ) for radiation curing of an inliner plastic lining in a pipe and / or a channel, wherein the inline lighting device ( 10 ) at least one carrying device ( 11 ), at the at least one electromagnetic radiation source ( 23 ), characterized in that at least two supporting devices ( 11 ) are provided, which in the direction of a longitudinal axis (A) of the inline lighting device ( 10 ) are arranged one behind the other at a mutual distance (a), this distance (a) being variable. Device according to claim 1, characterized in that the supporting devices ( 11 ) via at least one axially adjustable connecting element ( 12 ) are interconnected. Apparatus according to claim 2, characterized in that the axially adjustable connecting element ( 12 ) is a telescopic linkage. Device according to one of claims 2 or 3, characterized in that a control unit ( 14 ) is provided, by means of a drive ( 15 ) for the axially adjustable connecting element ( 12 ) and the distance (a) is changeable. Device according to one of the preceding claims, characterized in that at least one of the carrying devices ( 11 ) at least one supporting device ( 13 ) with one on the lighting device ( 11 held arm ( 16 ) and an extendable telescopic member ( 17 ) having. Device according to claim 5, characterized in that each supporting device ( 11 ) at least three distributed over its circumference arranged, in particular uniformly distributed support devices ( 13 ) having. Device according to one of claims 5 or 6, characterized in that the supporting devices ( 13 ) a chassis ( 21 ) with at least one roll ( 22 ) exhibit. Device according to one of claims 5 to 7, characterized in that at least one of the beam sources ( 23 ) on one of the telescopic links ( 17 ) and is adjustable together with this. Device according to one of claims 5 to 8, characterized in that at least one of the support devices ( 13 ) a spring element ( 18 ), by means of which the associated telescopic member ( 17 ) is acted upon by a radially outwardly acting force. Device according to one of the preceding claims, characterized in that the axial distance (a) between the support devices ( 11 ) and / or a radial length (b) of the supporting devices ( 13 ) is variable over a range of 100 mm to 800 mm, preferably from 300 mm to 600 mm, in particular from 400 mm to 500 mm. Device according to one of claims 5 to 10, characterized in that on at least one of the support devices ( 11 ) a control unit ( 19 ) is provided, by means of a drive ( 20 ) for at least one of the telescopic links ( 17 ) of the supporting device ( 13 ) is controllable.

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