DE19730006A1 - Compact energy-saving lamp with improved colour reproducibility - Google Patents

Abstract

A compact energy-saving lamp, having improved colour reproducibility with an Ra(8) value of \- 90 at a colour temperature of 2300-3500 K, comprises a mercury and inert gas filled discharge vessel with an interior luminescent material layer and has an output power of preferably greater than 500 W/m<2> of luminescent layer and UV radiation energies of greater than 3.5 eV. The novelty is that the luminescent layer consists of at least seven different phosphors, at least three of which have a visible emission band with a mid-height width of more than 30 nm and at least one of which has, in addition to a main emission band or main line group with 460-680 nm emission maximum, a second weaker blue region emission band or line group with 390-500 nm emission maximum.

Description

The invention relates to a compact energy-saving lamp with improved color rendering properties with an Ra (8) value greater than or equal to 90 with a most similar color temperature between 2300 K and 3500 K and is used in lighting and lighting technology.

Warm-tone energy-saving lamps with a most similar color temperature of 2700 K are included usually made on the inside of the vacuum-tight, with mercury and rare gas filled discharge tube a fluorescent layer consisting of a green and a red emittie renden component, the luminescence together with the mercury radiation the discharge leads to a three-band lamp spectrum, which also has a color rendering Ra (8) value greater than 80. The color rendering of such more conventional However, lamps do not exceed the Ra (8) value equal to 85 and are therefore color-matched classified IB.

To improve the color rendering properties with the achievement of Ra (8) values same or greater than 90, corresponding to the color rendering level IA, are different tech African solutions for rod-shaped fluorescent lamps of different diameters in the case of fluorescent lamps of small diameter only for Color temperatures greater than or equal to 3000 K.

EP 0 550 937 A2 has disclosed a low-pressure discharge lamp with very good color rendering properties, lamps with a higher wall load of E (UV) <500 W / m ^{2 being} included. The color point (x, y) lies on or near the Planck curve, and the effectiveness of the luminescence is relatively high. The phosphor layer used contains three phosphors, the first being a blue-emitting phosphor activated with divalent europium. The second phosphor is activated with divalent manganese and has at least one emission band in the red spectral range. The third phosphor, which has its main emission in the yellow spectral range, is an activated with divalent europium (strontium, barium, calcium) orthosilicate.

Low-pressure discharge lamps are also described in EP-A 0 114 441 and EP-A 0 124 175 called white light with very good color rendering. As the third phosphor in antimony and / or manganese activated calcium halophosphate is used in the mixture.  

Five lumines are found in the low-pressure mercury discharge lamp according to EP 0 596 548 A1 decorative materials as fluorescent application to achieve very good color rendering at the same time to preserve early aging of the lamp.

The first material emitting in the blue spectral range is activated by divalent Europi um and has an emission band between 470 and 500 nm. The material contains at least one of the systems SAE, which is described in detail in NL-A 8201943, with an emission maximum at 485 -495 nm and a half width of 55 to 75 nm, a barium aluminate: Eu ²⁺ (BAE) with an emission band at 485-495 nm and a half width of 70-90 nm and a strontium borophosphate: Eu ²⁺ (SBP ) with an emission maximum at 470-485 nm and a half width of 80-90 nm.

The second luminescent material is a red-emitting component that consists of a trivalent cerium and divalent manganese activated pentaborate (CBM) with one Emission maximum at approximately 630 nm and a half-value width of approximately 80 nm is formed.

The third luminescent material includes one or more two-person systems Europium activated substances like barium aluminate magnesium (BAM) after the NL-A 73214862 and strontium chlorophosphate (SCAP) according to US 4,038,204. BAM has an emission maximum at about 450 nm and a half-width of about 50 nm. SCAP shows an effective emission band with a maximum at 450 nm with a half value width of about 85 nm.

Substances that can be used for the fourth luminescent material are trivalent Terbium activated cerium magnesium aluminate (CAT) according to NL-A 7214862 and with trivalent terbium activated cerium magnesium pentaborate (CBT) according to NL-A 7905680. Both CAT and CBT show a very effective line emission in the green Spectral range at 520-565 nm. Also that with trivalent cerium, divalent manganese and trivalent terbium activated pentaborate (CBTM) can act as a fourth luminescent Material are used, as is known from NL-A 7905680.

Trivalent is found to be a suitable substance for the fifth luminescent material Europium activated yttrium oxide (YOX) application.

Through the use of yttrium aluminum garnet (YAG), which is not only short-wave ul traviolet radiation, but also absorbs visible deep blue radiation, becomes another broad fifth emission band with an emission maximum at 560 nm and a half value range of 110 nm obtained.  

According to EP 0 594 424 A1, good color rendering can be achieved at a color temperature of 2700 to 5500 K on or near the Planck curve by means of a quadruple phosphor mixture and combination of the phosphors in the fluorescent lamp. This four-component phosphor mixture is used in the lamp as a top layer in addition to the base layer, which consists of an inexpensive halophosphate phosphor. The second layer contains a green, a blue and a red emitting phosphor and additionally a phosphor with a Gauss peak in the range of 460-510 nm and / or 610-650 nm, which is responsible for an increase in the color rendering value. With the phosphor mixture of (Ce, Tb) -Mg aluminate with an emission band at 500-570 nm, yttrium oxide: Eu ³⁺ with an emission band at 590-630 nm, (Ba, Mg) aluminate: Eu ²⁺ with an emission band at 430-490 nm and Mn-activated Mg gallate with an emission band at 460-510 nm, Ra values between 83.1 and 89.1 are achieved in these fluorescent lamps.

DE 25 09 931 and EP 0 239 923 is a lamp with a two-layer version with one first layer of halophosphate: Sb, Mn and a second layer of YOX, CAT or BAM known, whereby here the improved color rendering mainly through the first alkaline earth halo phosphate layer is reached.

Fluorescent lamps according to US 4,623,816 also have a double layer, the first Layer made of the conventional calcium halophosphate phosphor. The second layer as top phosphor layer consists of a mixture of a green emitter end, cerium orthophosphate phosphor activated with terbium and a red emit the yttrium oxide phosphor activated with europium.

For an improved color rendering of the lamps according to US 4,751,426 and US 5,309,069 the first layer of halophosphate and the second layer of a mixture of BAM, CAT or LAP and YOX manufactured.

EP 0 595 627 A1 describes the four-component mixture in fluorescent lamps, in which the first layer contains a halogenated alkaline earth metal phosphate activated with lead, antimony, manganese or tin or a mixture thereof, and the second layer contains a mixture of the red-emitting phosphors YVO ₄ : Eu ³⁺ , Gd ₂ O ₃ : Eu ³⁺ and Y ₂ O ₃ : Eu ³⁺ , the green-emitting phosphors Mg gallate: Mn, Mg aluminate: Mn and Zn orthosilicate: Mn and the blue-emitting phosphors BAM, SCAP , (Sr, Ba, Ca) - Chlorophosphate: Eu ²⁺ contains.

The rod-shaped fluorescent lamp according to EP 0 124 175 with a color temperature between 2300 and 3300 K contains the compounds of halophosphate as phosphor mixture Alkaline earth halophosphate, Eu-activated phosphor with an emission band at 470- 500 nm and a half-width of max. 90 nm, rare earth metal metaborate (CBM), Tb activated phosphor with characteristic Tb emission, rare earth metal (CBT) and Ce-activated aluminate with a garnet structure.

According to US 5,049,779, high color rendering greater than 90 is achieved by mixing the red component with an emission band at 600-660 nm and half-width less than 10 nm using the phosphors YOX, Y-phosphate-vanadate: Eu ³⁺ ; Y-Vanadat: Eu ³⁺ and Mg-Fluorogermanat: Mn, the green component with emission band at 530-550 and half-width less than 10 nm from the phosphors LAP and / or CAT and the blue component with the emission band at 460-510 nm and Half-width greater than 50 nm from at least one of the phosphors Ca malophosphate: Sb, Mg tungstate, Ba pyrophosphate: Ti and Ba-Mg silicate: Eu ²⁺ achieved.

Equivalent technical solutions for the generation of high-quality color restoration properties are not yet known for compact warm-tone energy-saving lamps.

The invention is therefore based on the object, a compact energy-saving lamp with ver create better color rendering properties.

According to the invention the object is achieved in that the compact energy-saving lamp with a vacuum-tight and filled with mercury and inert gas discharge vessel and means for maintaining the discharge on the inside of its discharge vessel has only a single luminescent layer, which consists of a combination of at least seven Phosphors exist which, together with the visible mercury radiation, lead to the superimposition of eight emission spectra of different types and whose emission band with the associated half-value width has a color rendering with an Ra (8) value greater than or equal to 90 with simultaneous luminous fluxes with a column power of 500 W / m ² and a most similar color temperature between 2300 K and 3500 K.

According to the invention, at least three of the seven phosphors have a band-shaped one Emission in the visible spectral range with half-widths greater than 30 nm, and min at least one phosphor has a main emission band or a main line group a second weaker with an emission maximum between 460 and 680 nm Emission band or line group in the blue spectral range with an emission maximum between 390 and 500 nm.  

In this luminescent layer of the energy-saving lamp, in addition to commercial, he come fluorescent systems such as the orange-emitting phosphor strontium ortho phosphate: Sn; the turquoise emitting phosphors alkaline earth borophosphate: Eu or Erdal potash chlorophosphate: Eu; the red-emitting phosphor yttrium oxide: Eu, the green with fluorescent CAT or LAP, the blue-emitting phosphor BAM invented phosphors according to the invention cerium-magnesium-borate-silicate: Mn (BSCM) as red emitter render phosphor, strontium aluminate phosphate: Eu (SAPE) as a cyan emitting Fluorescent, barium strontium silicate: Eu (BSOSE) as a green-emitting phosphor and Strontium barium silicate: Eu (SBOSE) is used as a yellow-emitting phosphor.

The phosphors according to the invention are produced as follows:

1.) Borate: BSCM
with the composition

(Y, La) _1-xy Ce _x Gd _y (Mg, Zn) _1-p Mn _p B _5-qs (Al, Ga) _q (X) _s O ₁₀ ,

wherein
X = Si, Ge, P, Zr
p ≠ 0,
0.01 ≦ x ≦ 1 - y
0 ≦ y ≦ 0.99
0.01 ≦ p ≦ 0.30
0 ≦ q ≦ 1.0
0 <s ≦ 1.0.

Preparation: The stoichiometric amounts of the selected starting substances Y ₂ O ₃ and / La ₂ O ₃ , Gd ₂ O ₃ , ZnO and / or MgO, Al ₂ O ₃ and / or Ga ₂ O ₃ , CeO ₂ , ZrO ₂ , MnCO ₃ and / or GeO ₂ and / or SiO ₂ and / or MnNH ₄ PO ₄ and H ₃ BO ₃ with a defined excess of boric acid of 40% are mixed intensively for 30 minutes. Depending on the composition, the mixture is annealed both under an inert gas atmosphere and in a weakly reducing gas stream at temperatures between 950 and 1030 ° C. The annealing time is between 4 and 10 hours, an intermediate mortar proving to be advantageous.

The borates obtained luminesce in the red spectral range at maximum wavelengths between 625 and 635 nm. Their half-value widths are 73-80 nm. When gadolinium is partially replaced by terbium, which is added to the mixture in the form of Tb ₄ O ₇ , the emission range can be even wider be expanded, whereby in addition to the red manganese emission the characteristic green terbium emission occurs at 542 nm (BSCTM).

2.) Alkaline earth orthosilicate: SBOSE
with the composition:

(2-xy) SrO.x (Ba, Ca) O. (1-abc) SiO ₄ .aP ₂ O ₅ .bAl ₂ O ₃ .cB ₂ O ₃ : yEu ²⁺
0.11 <x <0.4
0.005 <y <0.5
0 <a, b, c <0.3

Alkaline earth orthosilicate: BSOSE
with the composition:

(2-xy) BaO.x (Sr, Ca) O. (1-abc) .SiO ₄ .aP ₂ O ₅ .bAl ₂ O ₃ .cB ₂ O ₃ : yEu ²⁺
0.4 <x <1.6
0.005 <y <0.5
0 <a, b, c <0.1.

Preparation of the silicates:
The stoichiometric amounts of the starting substances SrBO ₃ , BaBO ₃ , SiO ₂ , Eu ₂ O ₃ and smaller defined additions of (NH ₄ ) ₂ HPO ₄ and / or AlPO ₄ and / or H ₃ BO ₃ and / or M ₂ O ₃ are mixed together with NH ₄ Cl as a flux and then glowing under a reducing atmosphere for 2 to 8 h at a temperature between 1100 ° C and 1350 ° C ge. The yellow or greenish-looking product obtained is then washed with water to remove the flux.

The silicates obtained emit at wavelengths between 510 nm and 590 nm and besit zen a half width up to 110 nm.

3.) Aluminate: SAPE
with the composition:

4 (Sr, Ba) _1-a O. (7-xyz) Al ₂ O ₃ .xB ₂ O ₃ .yP ₂ O ₅ .zSiO ₄ : aEu ²⁺
0.0001 <a <0.8
0.001 <x, y, z <0.1.

Preparation of the aluminates:
After the stoichiometric amounts of the starting substances Al ₂ O ₃ , SrBO ₃ , BaBO ₃ and small defined additions of H ₃ BO ₃ and Al ₂ O ₃ and / or (NH ₄ ) ₂ HPO ₄ and / or SiO ₂ have been weighed out, the substances become intense mixed. The batch is then annealed under a reducing atmosphere for 1 to 6 h at temperatures between 1100 and 1500 ° C. The blue-turquoise product obtained is subjected to the same temperature process again after intermediate mortar. The aluminates SAPE produced in this way emit at wavelengths of 480-500 nm and have a half width of 70-90 nm.

With the phosphors used according to the invention, in combination with com commercial products in compact energy-saving lamps Ra values up to 96 at color temperature between 2300 K and 3500 K.

The size of the inner diameter of the discharge tube of the compact energy saving lamp is advantageous to dimension between 3 mm and 13 mm.

The invention will be explained in more detail using an exemplary embodiment. Examples of necessary phosphor mixing ratios for warm-tone lamps in comparison to conventional energy-saving lamps and the spectra of some example mixtures are shown in the corresponding figures in FIGS . 1 to 2 in Table 1.

In addition to the percentage by mass of the mixtures according to the invention of seven phosphors of the luminescent layer for compact energy-saving lamps with improved Ra (8) values, Table 1 shows the associated most similar color temperatures T _C in Kelvin, the color rendering values Ra (8) and the relative luminous fluxes V ( λ).

In the first column of Table 1, number 1 means fluorescent CAT, number 2 means fluorescent Yttrium oxide: Eu, number 3 phosphor BSCM, number 4 phosphor SAPE, number 5 Fluorescent BSOSE, number 6 Fluorescent SBOSE, number 7 Fluorescent alkaline earthenware phosphate: Eu and number 8 phosphor strontium orthophosphate: Sn.

For example, in Fig. 1 and Fig. 2, the spectrum of one of the phosphor mixtures according to the invention is shown in Table 1 for compact energy-saving lamps with the associated lighting specifications, in Fig. 1 the phosphor mixture the color temperature T _C = 2700 K and the color rendering value Ra = 92 and in Fig. 2 the phosphor mixture has the color temperature T _C = 2800 K and color rendering value Ra = 94.

Tab. 1

Claims (8)

1.Compact energy-saving lamp with improved color rendering properties with an Ra (8) value greater than or equal to 90 at a most similar color temperature between 2300 K and 3500 K, consisting of a vacuum-sealed discharge vessel filled with mercury and inert gas, with a luminescent layer arranged on the inside and means for maintaining the discharge, the column power based on the luminescent layer preferably being greater than 500 W / m ² and the UV radiation predominantly having energies greater than 3.5 eV, characterized in that the luminescent layer is at least seven contains various phosphors, of which at least three have a band-shaped emission in the visible spectral range with half-widths greater than 30 nm and at least one phosphor in addition to a main emission band or a main line group with an emission maximum between 460 nm and 680 nm e has a weaker second emission band or line group in the blue spectral range with an emission maximum between 390 nm and 500 nm. 2. Compact energy saving lamp with improved color rendering properties after Claim 1, characterized in that as a blue component one with a divalent Europium activated phosphor or a mixture of such phosphors used is, preferably alkaline earth aluminates and / or alkaline earth metal phosphate borates and / or alkaline earth halophosphates are used. 3. Compact energy-saving lamp with improved color rendering properties according to claim 1 and 2, characterized in that as phosphors which emit in the green region of the visible spectrum, CAT and / or LAP and / or alkaline earth metal silicates, activated with divalent europium with the composition
(2-xy) BaO.x (Sr, Ca) O. (1-abc) .SiO ₄ .aP ₂ O ₅ .bAl ₂ O ₃ .cB ₂ O ₃ : yEu ²⁺
0.4 <x <1.6
0.005 <y <0.5
0.001 <a, b, c <0.1
and / or zinc silicate: Mn are used. 4. Compact energy-saving lamp with improved color rendering properties according to claims 1-3, characterized in that an alkaline earth metal silicate activated with europium is used as the yellow-orange emitting phosphor
(2-xy) SrO.x (Ba, Ca) O. (1-abc) .SiO ₄ .aP ₂ O ₅ .bAl ₂ O ₃ .cB ₂ O ₃ : yEu ²⁺
0.11 <x <0.4
0.005 <y <0.5
0.0001 <a, b, c <0.3
and / or an alkaline earth orthophosphate activated with tin is used. 5. Compact energy-saving lamp with improved color rendering properties according to claims 1-4, characterized in that as phosphor with an emission in the red spectral range yttrium oxide: Eu and / or manganese-activated borate silicate BSCM with the composition
(Y, La) _1-xy Ce _x Gd _y (Mg, Zn) _1-p Mn _p B _5-qs (Al, Ga) _q (X) _s O ₁₀
wherein
X = Si, Ge, P, Zr
p ≠ 0,
0.01 ≦ x ≦ 1 - y
0 ≦ y ≦ 0.99
0.01 ≦ p ≦ 0.30
0 ≦ q ≦ 1.0
0 ≦ s ≦ 1.0,
wherein the gadolinium can be partially replaced by terbium, whereby, in addition to the magnane emission, the characteristic terbium emission occurs with an emission maximum at 542 nm, and / or yttrium vanadate phosphate is used. 6. Compact energy-saving lamp with improved color rendering properties according to claims 1-5, characterized in that as a phosphor with a second emission band or line group in the blue spectral range SAPE with the composition
4 (Sr, Ba) _(1-a) O. (7-xyz) Al ₂ O ₃ .xB ₂ O ₃ .yP ₂ O ₅ .zSiO ₄ : aEu ²⁺
0.0001 <a <0.8
0.001 <x, y, z <0.1
and / or CAT and / or LAP and / or an alkaline earth orthophosphate activated with tin is used. 7. Compact energy saving lamp with improved color rendering properties after Claims 1-6, characterized in that the luminescent layer consists of a Mixture of CAT and / or LAP, yttrium oxide: Eu, manganese activated Metaborate Silicate (BSCM), Eu-activated strontium aluminate phosphate (SAPE) and / or Eu-activated Erdaikali halophosphate borate, one or more different alkaline earth metal silicates activated with divalent europium and a tin activated alkaline earth orthophosphate. 8. Compact energy saving lamp with improved color rendering properties Claims 1-7, characterized in that the inner diameter of the Discharge tube is variable from 3 mm to 13 mm.