JPS6111401B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Application of the Invention] The present invention relates to a xenon light source device, and more particularly to a light source device equipped with a xenon lamp having a bulb and a metal portion.

[Background of the invention]

Spectrophotometers, especially spectrofluorophotometers, use a xenon lamp as a light source. FIG. 1 shows an example of the prior art. In this example, a normal lamp house 1
The entire xenon lamp 2 is placed inside. Apart from the lamp house 1, there is an ozone decomposition device 4, which has a blower 5 and a heater section 6 as main components. The upper part of the lamp house 1 is connected to an ozone eliminating device 4 through a hose 3 that is airtightly attached, and the gas inside the lamp chamber flows through the hose 3, the blower 5, and the heater section 6 in this order, and is discharged to the outside. The gas that has just flowed into the lamp house from the lower part of the lamp house 1 contains almost no ozone, but while it remains in the lamp house, the ozone concentration increases due to the discharge of the lamp, and it passes through the hose to the heater section. guided by. The heater section 6 has a structure in which gas flows between high-heat nichrome wires, and the temperature of the gas increases. As a result, ozone is thermally dissociated, and gas with extremely low ozone concentration is discharged to the outside. Although this example is very effective as a method for removing ozone generated by xenon lamps, it requires the provision of an ozone removal device as a separate unit, which poses the problem of increasing the size of the structure.

FIG. 2 shows another conventional example. lamp house 7
is completely sealed, with air circulating only inside. Both electrodes of the xenon lamp 2 are connected to metal parts, and cooling is achieved to some extent by the internal circulation of this air and by the effect of heat sinks 8, 9 attached to both metal parts. The blower 11 air-cools the lamp house 7 and the fins 10 attached thereto, thereby cooling the air inside to some extent. In this method, ozone inside the lamp house 7 does not leak to the outside, and ozone is repeatedly generated and dissociated inside. The biggest drawback of this method is that the cooling effect is limited and the temperature of the electrodes of the xenon lamp and the molybdenum foil connected to the electrodes increases, shortening the lamp life.

[Purpose of the invention]

An object of the present invention is to provide a xenon light source device that does not require a special ozone elimination device and can prevent lamp electrode deterioration.

[Summary of the invention]

In the present invention, the bulb serving as the light emitting part of the xenon lamp is placed substantially inside the lamp house, the lamp house is provided with an air inlet at the bottom, and the upper metal part of the xenon lamp is made to protrude outside the lamp house. The above object is achieved by forming a gas outflow gap between the xenon lamp and the lamp house forming material near the joint between the metal part above the xenon lamp and the bulb.

[Embodiments of the invention]

In a preferred embodiment of the invention, a conventional xenon lamp is used which has a bulb serving as a light emitting part and metal parts formed at both ends of the bulb. Since ozone is generated by lamp discharge, the area around the ozone generating area is covered by the lamp house. However, instead of housing the entire lamp inside the lamp house, at least one metal part, especially the upper metal part, is placed outside the lamp house, and the gas inside the lamp house is gradually moved along the lamp wall. The shape of the lamp house has been devised so that it can escape upwards. The gas outflow gap formed in the middle of the lamp prevents the generated ozone from immediately escaping to the outside, and the inside of the lamp house is kept in an appropriate condition that promotes thermal decomposition of ozone and prevents significant deterioration of the electrode material. It has the role of maintaining a certain temperature.

FIG. 3 shows an embodiment of the present invention. The lamp house 12 houses the bulb portion of the xenon lamp 2 and one metal portion 16 therein. The upper anode side metal part 13 is located outside the lamp house 12 and is fixed to the heat sink 15 with fixing screws 14. The plate 15 serves not only to hold the xenon lamp 2 but also to dissipate the heat of the anode-side metal portion 13 into the atmosphere. Near the joint between the anode side metal part 13 and the bulb, the xenon lamp 2 is in a state close to the upper member of the lamp house 12, that is, the lid part, but a gas outflow gap 20 exists in this close part. ,
The gas that has moved along the wall near the upper end of the valve and the lower end of the anode side metal part 13 flows out.

A blower 19 is disposed below the lamp house 12 to cool the lamp house 12 from the outside and send a small amount of air into the lamp house through an air inflow hole 21 at the bottom of the lamp house. Immediately inside the air inlet hole 21 is a heat dissipating piece 17.
There is a cathode-side metal part 16 having a diameter of 160 mm, and is cooled by the inflowing air. Inside the lamp house 12, the generation and thermal dissociation of ozone by ultraviolet rays are repeated, but the amount of ultraviolet rays is small near the gas outflow gap. On the other hand, the temperature of the upper end of the bulb and the anode side metal part 13 is about 170°C to 300°C. Since the dissociation rate of ozone increases rapidly above 100℃, by maintaining the temperature between 170℃ and 300℃, it is easy to reduce the ozone in the gas passing through the gas outflow gap by thermal dissociation. .

When a xenon lamp is turned on, the amount of ozone produced is highest near the center of the bulb, and decreases as it gets closer to both ends of the bulb. On the other hand, in a configuration like the embodiment shown in FIG. 3, it takes several minutes for ozone generated near the center of the bulb in the lamp house to reach the gas outflow gap above the lamp house.
It is known that the rate of ozone elimination is a function of temperature, and the half-life of ozone is less than 1 minute at temperatures above 170°C. Xenon lamps dissipate a considerable amount of heat, so if the lamp house were to be sealed, the temperature inside the lamp house would rise to over 300°C, causing adverse effects. Therefore, in the above embodiment, the lamp house prevents the dissipation of generated ozone, and the temperature near the gas outflow gap is reduced.
By maintaining the temperature between 170°C and 300°C, a temperature suitable for thermal dissociation of ozone is obtained while preventing excessive temperature rise.

As described above, it is possible to obtain a xenon light source device that cools the metal part to such an extent that the electrode and molybdenum foil do not deteriorate while thermally dissociating the ozone generated.

In the above embodiment, only the anode side metal part was taken out of the lamp house, and the cathode side metal part was cooled by the inflowing air, but it is also effective to take both parts out of the lamp house.

According to an embodiment of the present invention, it is possible to suppress the amount of ozone generated in the lamp house while the xenon lamp is lit to below a harmful level without using a separate elimination device, and furthermore, By cooling the metal parts of the lamp, it is possible to prevent deterioration of the molybdenum foil and electrodes inside the lamp due to temperature rise.

〔Effect of the invention〕

As can be understood from the above explanation, according to the present invention, ozone can be properly eliminated without the need for a special ozone elimination device, and furthermore, it is possible to prevent the lamp temperature from rising too much, resulting in a long service life. You can get the effect of

[Brief explanation of the drawing]

FIG. 1 is a diagram showing one conventional example, FIG. 2 is a diagram showing another conventional example, and FIG. 3 is a diagram showing an embodiment of the present invention. 1, 7, 12... Lamp house, 2... Xenon lamp, 13... Anode side metal part, 16...
Cathode side metal part, 20...Gap for gas outflow, 2
1...Gas inflow hole.

Claims (1)

[Claims] 1. The above-mentioned bulb of a xenon lamp having a bulb serving as a light-emitting part and metal parts provided at both ends of this bulb is substantially arranged in a lamp house, and an air inlet is provided below in the above-mentioned lamp house, and the above-mentioned The upper metal part of the xenon lamp protrudes outside the lamp house, and a gas outflow gap is created between the xenon lamp and the lamp house forming material near the joint between the upper metal part of the xenon lamp and the bulb. A xenon light source device characterized by forming: