DD279073B5 - ROUNDGENDIFRACTOMETER WITH AUTOMATIC ADJUSTMENT OF THE HORIZONTAL DIVERSITY LICENSE - Google Patents

Description

For this 3 pages drawings

The invention relates to an X-ray diffractometer for carrying out diffraction analyzes of predominantly polycrystalline substances. The known X-ray diffractometer consist of an X-ray tube and a goniometer mi! a beam entry diaphragm system, a sample carrier rotatable about the goniometer axis, and a detector arm pivotable about twice the angular amount of the sample carrier about one and the same goniometer axis, on which the beam exit diaphragm system and the detector for registration of the X-ray radiation emanating from the X-ray tube and reflected at the sample are located.

In the known X-ray diffractometers different means and methods for X-ray adjustment of the X-ray diffractometer are used.

The purpose of the adjustment is to match the axis of the primary beam emanating from the focus of the X-ray tube with the direction through the beam entrance aperture system (in particular through the horizontal divergence diaphragm), the goniometer axis and the beam exit diaphragm system (in particular through the detector diaphragm) in the zero position of the angular scale the detector arm is determined.

In general, in the known X-ray diffractometers, this direction is determined by the beam entrance diaphragm system, goniometer axis and beam exit diaphragm system by alignment by means of optical means. As a consequence, the X-ray adjustment of the X-ray tube with respect to this direction is necessary.

X-ray diffractometers are known. in which this adjustment is achieved in that adjusting means are provided which allow the goniometer to be positioned separately from the stationary. X-ray tube. Furthermore, X-ray diffractometers are known in which the X-ray tube is mounted on a fixedly connected to the goniometer device, which allows to move the X-ray tube relative to the goniometer.

Also known is an X-ray diffractometer for routine examinations, which has been described in WP 262302, in which the X-ray adjustment is simplified by the fact that the primary beam direction through the focus of the fixed fixed to the goniometer X-ray tube and through the insertable into the sample holder slit diaphragm whose center in the Goniometerachse is set. The horizontal divergence diaphragm is adjusted by means of manual displacement perpendicular to the primary beam direction and the detector diaphragm by means of rotation of the detector arm in the goniometer axis in the primary beam direction defined by the focus of the x-ray tube and slit diaphragm. The zero point of the angular scale of the rotation of the detector arm is shifted by mechanical or electronic means to the adjusted position of the detector arm with the detector blende in the primary beam direction.

In the known X-ray diffractometers, there are radiation protection boxes which enclose the X-ray diffractometer, and safety devices which largely exclude the operator's exposure to X-rays during measurement operation. However, the X-ray adjustment can be performed by the operator only with open radiation protection box and temporarily shut down security devices by manipulation of the X-ray diffractometer in the vicinity of the primary beam and simultaneous observation of the beam path by means of light screens or registered and displayed in the detector pulse rate, with a threat to the operator by X-radiation may occur during adjustment.

This also applies to the above-mentioned X-ray diffractometer according to WP.No. 52 302, in which the displacement of the horizontal divergence diaphragm perpendicular to the primary beam direction takes place by means of an adjustment drive by hand.

Another disadvantage of the X-ray adjustment of this X-ray diffractometer is that for determining the optimum position of the Hoi izontaldivergenzblende the registered in the detector X-radiation must be observed during the adjustment process by the operator on a display for the pulse rate and thereby the Justiergenauigkeit is limited.

It is also necessary in the course of the X-ray adjustment to use different diaphragm slides for the horizontal divergence diaphragm in the X-ray diffractometer by hand.

The invention is intended to automate the X-ray adjustment of an X-ray diffractometer for routine examinations and to eliminate the endangerment of the operator by X-ray radiation during the adjustment.

The invention has for its object to form an X-ray diffractometer according to WP 262302 so that the X-ray diffraction of the X-ray diffractometer can be performed automatically with closed Strahlonschutzbox and thereby eliminates the risk of X-ray exposure to the operator. According to the invention, this object is achieved in that the mounted on the Strahloneintrittsblendensystem, perpendicular to the primary beam direction displaceable Horizontaldivergenzblende has an electric drive for the displacement of the diaphragm perpendicular to the beam direction and an electronic control for this drive, which is included in the control of the X-ray diffractometer. In this case, the horizontal divergence diaphragm can be designed so that an automatic diaphragm change is possible.

In the X-ray adjustment of the X-ray diffractometer, the horizontal divergence diaphragm must be adjusted by displacement perpendicular to the primary beam direction, which is determined by the focus of the X-ray tube and a Spaitblende in the sample carrier so that the beam passing through them passes through the slit diaphragm in the sample carrier.

According to the invention, the displacement of the horizontal divergence diaphragm is performed by means of the electric drive. With gradual or continuous displacement of the horizontal divergence diaphragm by means of the electronic control and simultaneous registration of the intensity of the Prin arstrahlenbündels in the detector, the position of the horizontal divergence diaphragm is determined, is present at the max ¹ nale intensity.

This horizontal divergence position is then adjusted by the electronic control of the X-ray diffractometer.

By this type of automatic X-ray adjustment, which runs when the radiation protection box is closed, all the adjustment of the horizontal divergence diaphragm by the operator by means of a Justierriehds Near the primary beam and the associated threat to the operator by X-rays.

The invention is explained below with reference to the schematic drawings of the horizontal divergence diaphragm (FIG. 1), the X-ray diffractometer (FIG. 2) and the horizontal divergence diaphragm with automatic diaphragm change (FIG. 3).

The Horiiontaldivergenzblende consists of the main body Fig. 1/1, the aperture holder Fig. 1/2, the shutter slide Fig. 1/3 and the electric drive Fig. 1/4.

The main body Fig. 1/1 is designed so that it can be fixed by means of the clamp Fig. 1/5 on the entrance panel system Fig. 2/5 of the X-ray diffractometer.

The main body Fig. 1/1 has a guide Fig. 1/6 and a drive Fig. 1/7 for the displacement of the aperture holder Fig. 1/2 relative to the fixed body Fig. 1/1. On the main body Fig. 1/1 an electric drive Fig. 1/4 (preferably a stepper drive) is fixed, whose axis is coupled to the spindle of the drive Fig. 1/7.

In the diaphragm holder Fig. 1/2 shutter slide Fig. 1/3 can be used with different opening to limit the horizontal divergence.

The drive Fig. 1/4 is connected to an electronic control, not shown, which is part of the microelectronic control of the X-ray diffractometer. With the aid of the drive Fig. 1/4 and the drive Fig. 1/7, the diaphragm holder Fig. 1/2 with the shutter slide Fig. 1/3 continuously or in steps of about 0.005mm relative to the main body Fig. 1/1 be moved perpendicular to the primary beam direction Fig.2 / 4.

In another embodiment, the horizontal divergence diaphragm has a diaphragm holder Fig. 3/2, in the same time two shutter slide Fig. 3/3 can be used. The diaphragm holder can be brought by rotation about the axis Fig. 3/4 by means of a drive in two positions, so that either one or the other shutter slide in the beam path Fig. 3/1 is. In this way, an automatic aperture change is enabled.

The X-ray diffractometer is constructed as follows (Figure 2): The X-ray tube Fig.2 / 2, which is located in a tube protective housing, is fixedly attached to the goniometer Fig.2 / 1. Fig. 2/5 contains the horizontal diverting diaphragm Fig. 2/6, which is perpendicular to the primary beam direction Fig. 2/4 displaced and which is provided according to the invention with an electric drive.

In the sample carrier Fig. 2/7, a slit diaphragm Fig. 2/8 (opening about 0.05 mm) can be used, the center of which lies in the goniometer axis Fig. 2/9.

On the detector arm Fig. 2/10, the beam exit diaphragm system Fig. 2/11, the detector diaphragm Fig. 2/12 and the detector Fig.2 / 13 are angebrac'.t to register the X-ray.

Horizontaldivergenzblende Fig.2 / 6 and detector aperture Fig. 2/12 have interchangeable shutter slide.

In the X-ray diffraction of the X-ray diffractometer, the slit diaphragm Fig. 2/8 is inserted into the sample carrier Fig. ' Dl. As Horizontaldivergenzblenife Fig. 2/6 is a shutter slide with an opening of about 1 mm, as a detector aperture

Fig. 2/12 uses a shutter slide with an opening of about 0.05mm.

The detector arm Fig. 2/10 is rotated about its axis until the focus of the Fig. 2/3 of the X-ray tube Fig. 2/2 outgoing and limited by the slit diaphragm Fig. 2/8 primary beam bundles Fig.2 / 4 by the detector diaphragm Fig .2 / 12 occurs and is registered in the detector Fig. 2/13.

The detector arm Fig.2 / 10 should be adjusted so that maximum intensity is registered in the detector Fig. 2/13. This ensures that the focus Fig. 2/3, the goniometer axis Fig. 2/9 and the detector aperture Fig. 2/12 lie on a straight line.

This adjustment of the detector arm Fig. 2/10 is carried out automatically by means of microelectronic control of the diffractometer by the primary beam Fig.2 / 4 scanned stepwise, determines the maximum of the registered in the detector Fig.2 / 13 intensity distribution by means of a computer program and then the the Maximum corresponding angle of rotation of the detector arm Fig. 2/10 is set automatically.

The angle value obtained during the adjustment of the detector arm, which may deviate from the zero point of the angle scale of the detector arm, is corrected by the diffractometer control so that the zero point of the angle scale is assigned to the radiographically adjusted position of the detector arm.

For adjusting the horizontal divergence diaphragm Fig. 2/6, a shutter slide with an opening of about 0.05mm is inserted into this or such a shutter slide Fig.3 / 3 in the shutter holder Fig.3 / 2 brought by the automatic Blcndenwechsel in the beam path.

In the detector Fig. 2/13 maximum intensity is registered when the horizontal diverging diaphragm Fig. 2/6 on the same line as the focus Fig.2 / 3, the slit diaphragm Fig. 2/8 and the detector diaphragm Fig.2 / 12 is located. This position of the horizontal divergence diaphragm Fig. 2/6 is set according to the invention as follows:

the horizontal diverging diaphragm is shifted by means of its electric drive stepwise perpendicular to the primary beam direction Fig. 2/4, at each step the intensity falling in the detector Fig. 2/13 is registered; the maximum of the intensity distribution is determined by a computer program (approximation of the measured values by a polynomial and extreme value determination) and then the position of the horizontal divergence diaphragm Fig. 2/6 automatically adjusted by means of the drive, in which the maximum of the intensity distribution is.

The entire procedure of the X-ray adjustment is carried out automatically by means of the microelectronic control of the diffractometer. The radiation protection box remains closed, so that a threat to the operator is excluded by X-rays.

By the described determination of the optimal position of the horizontal divergence diaphragm from the measured intensity distribution, a higher precision of the adjustment and a faster adjustment procedure are achieved than with manual adjustment.

Claims (3)

1. X-ray diffractometer with an X-ray tube, a beam entry diaphragm system, a sample carrier, a detector arm with beam exit diaphragm system, a detector, a radiation protection box and a horizontal beam divider perpendicular to the primary beam direction, characterized in that the horizontal divergence diaphragm coupled to the microelectronic control of the X-ray diffractometer electric drive for the realization of Displacement has perpendicular to the primary beam direction and allows automatic Blendenwechs6l, so that so that a differentiated radiographic adjustment of the X-ray diffractometer is feasible. 2. X-ray diffractometer according to item 1, characterized in that the horizontal divergence diaphragm is automatically positioned perpendicular to the primary beam direction by means of the electric drive and the microelectronic control of the X-ray diffractometer in the X-ray adjustment that they on the same line as the focus of the X-ray tube, the goniometer axis and the detector aperture is located. 3. X-ray diffractometer according to item 2, characterized in that the adjustment process and aperture change take place within the closed radiation protection box.