Illumination – Light source and modifier – Ionized gas or vapor light source
Reexamination Certificate
2001-02-12
2003-04-01
O'Shea, Sandra (Department: 2875)
Illumination
Light source and modifier
Ionized gas or vapor light source
C362S267000, C362S296040, C362S350000
Reexamination Certificate
active
06540379
ABSTRACT:
FIELD OF THE INVENTION
The invention relates to an electric lamp/reflector unit comprising:
a molded reflector body provided with a reflector portion with a focus, with an optical axis, and with a concave reflecting inner surface between a neck-shaped portion and a light emission window which is transverse to the optical axis;
an electric lamp provided with a light-transmitting lamp vessel which is closed in a vacuumtight manner and which has a cavity in which an electric element is arranged, and which has a first and a second end portion which are mutually opposed and have respective seals through which a respective first and second current conductor connected to the electric element issue from the lamp vessel to the exterior,
the electric lamp being fixed in the reflector body with its first end portion in the neck-shaped portion, the cavity within the reflecting portion, and the electric element in the focus and on the optical axis.
BACKGROUND OF THE INVENTION
Such an electric lamp/reflector unit is known from EP 595412. Units of this kind may be used for projection purposes, for example film or slide projection, but they may also be used in projection TV equipment. Users of such projection equipment continuously strive for an improved safety and miniaturization of the equipment. There is also a wish for this miniaturization to take place without an accompanying loss of screen lumens. Such a loss of screen lumens may occur, for example, owing to a decrease in the size of the reflecting surface. Such a loss of screen lumens may also result from a comparatively inaccurate positioning of the electric element in the reflector body, whereby the light generated by the lamp is less well aimed and concentrated into a beam by the reflector body. It is a disadvantage of the known lamp/reflector unit that the positioning of the electric element is comparatively inaccurate. A further disadvantage of the known lamp/reflector unit is that a possible explosion of the lamp involves the risk of the reflector body cracking and/or fracturing owing to this explosion.
SUMMARY OF THE INVENTION
It is an object of the invention to provide an electric lamp/reflector unit of the kind described in the opening paragraph which can be manufactured comparatively inexpensively and easily, in which a comparatively accurate positioning of the electric element in the reflector body is obtained, and which is comparatively well resistant to a possible explosion of the lamp.
According to the invention, this object is achieved in that the electric lamp/reflector unit of the kind described in the opening paragraph is characterized in that the reflector body is manufactured from a glass-ceramic material with a coefficient of thermal expansion of between −2×10
−6
K
−1
and 3×10
−6
K
−1
. Such a coefficient of thermal expansion represents an average coefficient of thermal expansion over a temperature range of 0 to 500° C. The reflector body has a better thermal shock resistance when the reflector body manufactured from a glass-ceramic material with such a coefficient of expansion is used. The term “coefficient of expansion” used in this specification is the linear coefficient of expansion.
The glass-ceramic material is obtained by a comparatively simple and inexpensive process comprising a partial crystallization of a glass suitable for this purpose. Known multi-phase systems from which such glass-ceramic materials are known are, for example, Li
2
O—SiO
2
—Al
2
O
3
, Li
2
O—SiO
2
—Al
2
O
3
—P
2
O
5
, Na
2
O—ZrO
2
—SiO
2
—P
2
O
5
, and Li
2
O—SiO
2
—Al
2
O
3
—MO, with M being, for example, Mg, Zn, Ca, and/or Ba. Known glass-ceramic materials are, for example, LiAlSiO
4
—LiAlSi
2
O
6
, and Mg
2
Al
4
Si
5
O
18
. To obtain a reflector body made from glass-ceramic material, a reflector body of glass is first manufactured. Then the reflector body is brought to a temperature at which a crystallization of the glass commences. The reflector body is subsequently kept at this temperature for some time, for example a few hours, until a glass-ceramic material with a sufficient degree of crystallization has been obtained, whereupon it is cooled down. The reflector body of glass-ceramic material is thus obtained in a comparatively simple and inexpensive manner, and has a bulk composition of a mixture of a crystalline phase and a glass phase.
The quantity of screen lumens obtained from the lamp/reflector unit is strongly dependent on the positioning of the electric element of the lamp with respect to the focus of the reflector body. During assembly of the lamp/reflector unit, the lamp is placed in an aligned position in the reflector body, such that the electric element is positioned in the focus. Usually this positioning takes place while the lamp/reflector unit is not being operated, i.e. the lamp/reflector unit is comparatively cold. When switched on, the lamp/reflector unit will heat up, and respective components of the lamp/reflector unit, such as the reflector body and the lamp, will expand, thus causing changes in the relative positions of the components. The change in position of the electric element relative to the focus depends on the difference in coefficient of thermal expansion between the lamp and the reflector body. If there is a comparatively great difference in expansion, because the lamp/reflector unit becomes comparatively hot while the coefficients of thermal expansion differ comparatively much from one another, for example at differences of more than 2.5×10
−6
K
−1
over a temperature range of at least 400° C., there will be a too great change in the position of the electric element with respect to the focus of the reflector body. The lamp is manufactured from quartz glass, i.e. glass having an SiO
2
content of at least 95% by weight, which has a coefficient of thermal expansion of approximately 0.6×10
−6
K
−1
. Since the reflector body is manufactured from a glass-ceramic material with a coefficient of expansion which corresponds roughly to the coefficient of thermal expansion of quartz glass, i.e. between −2×10
−6
K
−1
and 3×10
−6
K
−1
, an acceptably small change in the mutual positioning of the electric element and the focus will occur. A comparatively large quantity of screen lumens is thus obtained from the lamp/reflector unit according to the invention.
Said change is also dependent on the temperature difference between the lamp and the reflector body arising during operation of the lamp/reflector unit. The lamp then becomes comparatively hot as compared with the reflector body. It is favorable when the coefficient of expansion of the reflector body is somewhat greater than that of the lamp so as to obtain an expansion of both components such that the electric element at least substantially does not become shifted with respect to the focus. Preferably, the glass-ceramic material has a coefficient of expansion of between 1×10
−6
K
−1
and 2×10
−6
K
−1
. Such a coefficient of thermal expansion represents an average coefficient of thermal expansion over a temperature range of 0 to 500° C. Given such values for the coefficient of expansion of the glass-ceramic material, the electric element will remain at least substantially positioned in the focus. A larger quantity of screen lumens can thus be obtained from the lamp/reflector unit according to the invention.
Experiments have also shown that the reflector body has an improved temperature resistance and is better resistant to a possible explosion of the lamp. Since the coefficients of thermal expansion of the glass-ceramic material of the reflector body and the quartz glass of the lamp differ comparatively little from one another, the temporary mechanical stresses arising during operation of the lamp/reflector unit are comparatively small. On the other hand, this renders possible the use of the reflector body at a comparatively high temperature, for example of up to approximately 700° C. instead
Ooms Leo Frans Maria
Van Opstal Marcus Petrus Anna Jozef
Keegan Frank J.
Koninklijke Philips Electronics , N.V.
Negron Ismael
O'Shea Sandra
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