DE102006047049A1 - Shatterproof fluorescent tube has transparent shatterproof protective film applied on glass tube, and made of elastomer material that can steadily withstand temperatures above 150 degrees Celsius - Google Patents

Abstract

The fluorescent tube (1) includes a glass tube (2), and electrical contacts (4) provided on the fluorescent tube's support socket (3). A transparent shatterproof protective film (5) is applied on the glass tube. The shatterproof protective film is made of elastomer material which can steadily withstand temperatures above 150 degrees Celsius. The shatterproof film is made of silicon rubber, and may be provided in the form of a hose. A coupling agent (6) is used for fixing the shatterproof protective film at the end of the fluorescent tube. Independent claims are also included for the following: (1) Shatterproof protective film; and (2) Fluorescent tube manufacture method.

Description

The The invention relates to a fluorescent tube according to the preamble of Claim 1. Furthermore, the invention relates to a splinter protection coating for such Fluorescent tube and a manufacturing method for a shatterproof Fluorescent tube.

A generic fluorescent tube is known from the DE 200 13 429 U1 , There, a shrink tube is proposed as splinter protection coating.

Fluorescent tubes of newer Design, especially compact fluorescent tubes are known for Splitter protective coating not suitable. The shrink tube ages quickly and starts also to discolor.

It It is therefore an object of the present invention to provide a shatter-resistant coating create that too for fluorescent tubes More recent stages of development is suitable, and a manufacturing method for a corresponding equipped Specify fluorescent tube.

These The object is achieved by a fluorescent tube with the features specified in the characterizing case of claim 1.

According to the invention was recognized that it is not mandatory to use the anti-shatter coating as To perform heat shrink tubing. By the omission of the boundary condition "heat shrink tubing" becomes apparent for the Material of the shatter-proof coating other, not necessarily shrinkable material classes. It got on recognized that for the too rapid aging and discoloration of the known shrink tubing materials for the Splitter protective coating their low resistance across from higher Temperatures is responsible. The material of the invention is also opposite higher Temperatures resistant, so that aging and discoloration problems do not occur. The elasticity of for the shatter-proof coating elastomeric material to be used ensures an application of the splinter protection coating on the glass tube with mass production techniques. The elasticity creates also the possibility an axial securing of the splinter protection coating on the glass tube. Also a colored, e.g. yellow, transition is possible.

silicone rubber according to claim 2 has been found to be particularly suitable material for the splinter protection coating. Because the silicone rubber does not have heat shrink tubing quality he can, in a for visible wavelengths transparent and clear quality be used. The silicone rubber can also to achieve desired Transmission properties equipped, in particular colored.

One Hose according to claim 3 allows a cost-effective Shatter protection coating.

A in particular axial fixation of the splinter protection coating according to claim 4 prevents unwanted displacement of the splinter protection coating relative to the glass tube the fluorescent tube.

One Adhesive according to claim 5 provides a secure fixation.

A shrink sleeve according to claim 6 allows an unobtrusive Fixation.

transmission properties of the splinter protection coating allow according to claim 7 filtering away unwanted Light components, in particular of UV light.

The Advantages of a splinter protection coating after Claim 8 correspond to those already described above with reference discussed on the fluorescent tube according to the invention were.

One The manufacturing method according to claim 9 allows the use of mass production manufacturing techniques.

This especially applies to applying the anti-shatter coating by shooting up Claim 10. Alternatively, an application of the splinter protection coating by swelling, rolling or mechanical stretching possible.

Diameter ratios according to claim 11 have for the application of the splinter protection coating on the one hand and for an axial Securing the splinter protection coating on the glass tube due to the elasticity of the splinter protection coating as particularly suitable.

embodiments The invention will be explained in more detail with reference to the drawing. In show this:

1 schematically in a longitudinal section a fluorescent tube with splinter protection coating enveloping it and a portion of the splinter protection coating before being pushed onto the fluorescent tube;

2 an excerpt from 1 in the area of the installation of the splinter protection coating on a lamp base of the Fluorescent tubes;

3 in one too 1 similar representation of a variant of attachment of a splinter protection coating on a fluorescent tube.

One in the 1 schematically illustrated first variant of a splinter-protected fluorescent tube 1 has a glass tube 2 and a lamp base 3 on the one hand the glass tube 2 carries and on the other hand supply and connection components for the luminous operation of the fluorescent tube 1 includes. About electrical contacts in the 1 schematically as plug contacts 4 are indicated, a voltage supply of the fluorescent tube 1 ,

On the glass tube 2 is a transparent anti-shatter coating 5 applied. This is a durable material at temperatures above 150 ° C. In the illustrated embodiments, it is the splinter protection coating 5 around a tube of silicone rubber, the outside of the glass tube 2 is raised. This material is also known under the abbreviation MVQ according to DIN / ISO. The shatter-proof coating 5 is a clear, almost non-scattering coating. In the relaxed state, the splinter protection coating has an inner diameter D ₁ . When mounting on the glass tube 2 This inner diameter is at least on the outer diameter D _{2 of} the glass tube 2 flared so that the on the glass tube 2 mounted splinter protection cover 5 flat on the outside of the glass tube 2 fully applied.

On the lamp base 3 fixed axially is the splinter protection coating 5 by means of a primer layer 6 between the lamp base 3 and the shatter-proof coating 5 , The primer layer 6 prevents the shatter-proof coating 5 undesirable relative to the glass tube 2 after applying the shatter-proof coating 5 relocated.

The fluorescent tube 1 can be made with different diameters. For a fluorescent tube with an outer diameter D ₂ of 16 mm, for example, a splinter protection coating 5 be provided with an inner diameter D ₁ in the range between 12 and 14 mm and a wall thickness d in the range between 0.5 and 0.8 mm, in particular of 0.5 mm.

With a fluorescent tube 1 with outer diameter D ₂ of 26 mm is preferably a splinter protection coating 5 with an inner diameter D ₁ in the range between 22 and 24 mm and a wall thickness d in the range between 0.5 and 0.8 mm, preferably of 0.5 mm.

With a fluorescent tube 1 with an outer diameter D ₂ of 38 mm is preferably a splinter protection coating 5 provided with an inner diameter D ₁ in the range between 34 and 36 mm and a wall thickness d in the range between 0.5 and 0.8 mm, preferably of 0.5 mm.

The inner diameter D _{1 of} the splinter protection coating 5 is therefore in each case absolutely between 2 and 4 mm and relatively between 8% and 15% smaller than the outer diameter D _{2 of} the glass tube 2 ,

Preferred is the splinter protection coating 5 equipped so that it no longer transmits wavelengths that are less than a lower limit wavelength. Such an embodiment is also called "UV stop", whereby also visible wavelengths (VIS) can be blocked, the lower limit wavelength can be in the range between 380 nm and 510 nm, also other cut-off wavelengths or also colorations of the splinter protection coating are possible ,

The shatterproof fluorescent tube 1 after the 1 and 2 is made as follows: first, a raw fluorescent tube with the glass tube 2 and the lamp base 3 provided. Subsequently, the shatter-proof coating 5 on the glass tube 2 applied. This application is done by shooting. Other application methods in which the relaxed inner diameter D _{1 of} the splinter protection coating 5 briefly over the outer diameter D _{2 of} the glass tube 2 Be stretched elastically, are possible. This elastic elongation can be achieved by introducing an overpressure into the interior of the tubular splinter protection cover 5 or by applying a negative pressure to the exterior of the tubular splinter shield coating 5 respectively. Also a mechanical stretching is possible. Finally, the inner diameter D _{1 of} the splinter protection coating 5 also be augmented by sources or roles.

Before applying the splinter protection coating 5 is on the outer circumference of the lamp base 3 still the primer layer 6 applied.

3 shows a further embodiment of a splinter-protected fluorescent tube 1 , Components which correspond to those described above with reference to the 1 and 2 The same reference numerals have been explained and will not be discussed again in detail.

The fluorescent tube after 3 is different from the one after the 1 and 2 by the type of axial securing of the splinter protection coating 5 on the lamp base 3 , this happens in the variant 3 through a shrink sleeve 7 , This may be a short tube section of cross-linked polyethylene or a fluoropolymer (FEP).

Additionally, in the execution after 3 even the adhesive layer 6 be provided. However, this is not mandatory.

In the production of the fluorescent tube 1 to 3 is after applying the shatter-proof coating 5 on the raw fluorescent tube or the shrink sleeve 7 over the splinter protection coating 5 in the area of the lamp socket 3 pushed. Subsequently, the shrink sleeve 7 on the shatter-proof coating 5 in the area of the lamp socket 3 Shrunk, for example, by heating the shrink sleeve 7 ,

Claims (11)

Fluorescent tube ( 1 ) - with a glass tube ( 2 ), - with at least one electrical contact element ( 4 ) for supplying the fluorescent tube supporting base ( 3 ), - with one on the glass tube ( 2 ) applied, transparent splinter protection coating ( 5 ), characterized in that the splinter protection coating ( 5 ) consists of a durable at temperatures above 150 ° C elastomer material. Fluorescent tube according to claim 1, characterized in that the splinter protection coating ( 5 ) is made of silicone rubber. Fluorescent tube according to claim 1 or 2, characterized by a shatter-proof coating ( 5 ) in the form of a hose. Fluorescent tube according to one of claims 1 to 3, characterized in that the splinter protection coating ( 5 ) is fixed at least at one end of the fluorescent tube. Fluorescent tube according to claim 4, characterized by a bonding agent ( 6 ) as a fixing agent. Fluorescent tube according to one of claims 1 to 5, characterized by at least one shrink sleeve ( 7 ), as a fixative. Fluorescent tube according to one of claims 1 to 6, characterized in that the splinter protection coating ( 5 ) is opaque below a predetermined optical cut-off wavelength. Shatter-proof coating ( 5 ) for a fluorescent tube ( 1 ) according to one of claims 1 to 7. Method for producing a splinter-protected fluorescent tube ( 1 ) according to one of claims 1 to 7, comprising the following steps: - providing a raw fluorescent tube with the glass tube ( 2 ) and the base ( 3 ), - applying and axially securing the splinter protection coating ( 5 ) on the glass tube ( 2 ). A method according to claim 9, characterized in that the splinter protection coating ( 5 ) on the glass tube ( 2 ) is applied by firing. A method according to claim 9 or 10, characterized in that the splinter protection coating ( 5 ) before application as a tube with an inner diameter (D ₁ ) which is absolutely between 2 and 4 mm and / or relatively between 8% and 15% smaller than the outer diameter (D ₂ ) of the glass tube ( 2 ).