DE2501507A1 - Automatic analysis of fine powders - uses atomic absorption or fluorescent spectrometers and graphite cuvettes and measuring and collecting stores - Google Patents

Abstract

In the analysis of fine dusts by atomising the test samples contained in graphite cells in an incandescent graphite tube into the radiation path of an atom absorption - or fluorescence - spectrometer and excited for light absorption or fluorescence, an automatic sequence of process steps takes place whereby (a) a large number of graphite cells containing samples are stored in a first magazine (measuring magazine) (b) the graphite cells are subjected to a thermal pre-treatment, (c) the magazine is brought to a support or holding device present in the measuring chamber of an atom absorption - or fluorescence spectrometer (d) each graphite cell is advanced from the measuring magazine into the measuring chamber for analysis in an interval adapted to the measuring time (e) after the introduction of one graphite cell after another into the measuring chamber and at pre-determined intervals, the atomising, excitation and measuring process is initiated for the signal emitted by the excited sample and (f) the graphite cell after the analysis step is withdrawn from the measuring chamber and supplied to a second, or collecting, magazine.

Description

Method and device for the automatic analysis of fine dust The invention relates to a method for the analysis of fine stagnation in graphite cuvettes introduced measurement sample in the beam path of an atomic absorption spectrometer or atomic fluorescence spectrometer atomized in a glowing graphite tube and used for light absorption or fluorescence are excited, as well as a device for performing the method.

The analysis of fine dust is used, among other things, to determine Air pollution, which often requires a large number of individual measurements is.

It is known to analyze fine dusts in dissolved samples Bring the shape into a graphite cuvette and close in the beam path of a spectrometer evaporate. From the vaporized sample are made by atomic absorption or atomic fluorescence Receive signals that are characteristic of the elements contained in the sample (Spektro Chemica Acta 1968, Vol 23b, pages 215-226). It is also known to collect the gas to be examined directly through a sample container conduct, whereby the fine build-up contained in the gas in the test container is electrostatic is deposited, and then the same sample container into the beam path brought an atomic absorption or atomic fluorescence spectrometer and there on the the temperature required to atomize the dust particles is heated up (registration P 24 o4 873.5-52 of 1.2.1974). It was also suggested that to the to arrange several sample containers in a magazine belt for automatic sampling and to provide a Slaga7intrRger for receiving the magazine tape, which with a Inlet nozzle for supplying the gas to be examined and an inlet nozzle is provided for receiving the ion generator, a motor with automatic Control for the transport of the magazine belt and for the simultaneous forward and backward movement the inlet connection is provided (registration P 2 55 091.2 of July 22, 1974).

The present invention is based on the task of making sense Use of automatic sample collection a method for automatic analysis of the samples as well as a suitable device for this.

This object is achieved according to the invention in that an automatic A succession of procedural steps is carried out, each of which consists of since (3 a larger number of graphite cuvettes filled with samples in a first Magazine (measuring magazine) are stored so that these (reEwhit cuvettes of a thermal Are subjected to pretreatment that the measuring magazine to one at the measuring chamber one Atomic absorption or atomic fluorescence spectro; meters located support or holding device is brought that each one of the graphite cuvettes from the measuring magazine in one the measuring time adapted clock is conveyed for analysis in the measuring chamber that through the introduction of a graphite cuvette iff - -die-measuring chamber one after the other and in specified Time intervals of the atomization, the excitation and the measuring process for the from The signals emitted by the excited sample are switched on that the analyzed Graphite cuvette conveyed out of the measuring chamber after the analysis process and a second magazine (collection magazine) is supplied to collect new test samples.

A suitable device for carrying out the procedure is drawn up is characterized in that transport means for conveying the samples containing Graphite cuvettes in one of the thermal pretreatment serving Furnace and then in the measuring chamber are provided that a program circuit ensures that the individual procedural steps are initiated and carried out the measuring chamber is divided perpendicular to its longitudinal axis and consists of a stationary one and a movable chamber part, that the movable chamber part in the direction the longitudinal axis is displaceable and pivotable about) 60, with two locking points for Collection and delivery of the sample cuvettes are provided.

The furnace for thermal pretreatment is in the described embodiment designed to accommodate the entire Neßmagazin.

It would also be possible for the oven to accommodate only one at a time Lay out the cuvette.

In a suitable device for carrying out the method is the transport means for the measuring magazine is arranged above the measuring chamber, and it are also provided in the Transportprograrnm locks that the magazine to Bring to a stop when a filled sample cell is on the one above the measuring chamber arranged opening of the support device is located. The collecting magazine becomes both The embodiment shown below the measuring chamber is transported and moves in the same steps as the measuring magazine.

In the described embodiment, the longitudinal axis falls' the Measuring chamber and the optical axis of the atomic spectrometer together, which makes it easier contributes to the adjustment.

The advantages achieved with the invention are in particular: that the personnel and time expenditure for the analysis is considerably reduced.

An embodiment of a device for implementing the invention The method is shown in the drawing and is described in more detail below. Show it: 1 shows a schematic representation of the entire device in partial section in the starting position; FIG. 1 a is a partial view of the one shown in FIG Device in the direction of line Ia; Fig. 2 is a section through the thermal Pre-treatment furnace in the phase of thermal pre-treatment of the samples; 5 shows a detail from the device shown in FIG. 1 in the phase of Measuring chamber filling, FIG. 4 shows a section of the device shown in FIG in the phase of measuring chamber closure; 5 shows the part of the device shown in FIG with closed measuring chamber; 6 shows a part of the device shown in FIG in the phase of emptying the measuring chamber; FIG. 7 shows part of that shown in FIG Device after completion of a measuring program; Fig. 8 shows the circuit diagram for the automated steps of the process.

In Fig. 1, 1 denotes a transport chain from the engine 2 is driven via a shaft 3. The transport chain 1 moves this with cuvettes 40a - 40e filled measuring magazine 4 over the platform 6 and the collecting magazine 5 over the platform 7 to the measuring chamber and back. The furnace for thermal pretreatment is denoted by 8, it is provided with ttn electrical connections 9.

The measuring chamber with the motors 11 and 12 is mounted on the frame 10. The movable part of the measuring chamber is denoted by 16, the fixed part by 16a It is surrounded by the contact pieces 14 and 15 or 14a and 15a. In the contact pieces supply lines 17 and 17a for protective gas and 18 and 18a for cooling water. Of the The motor 11 ensures the longitudinal movement of the chamber part 16, which for this purpose is in the slot 13 to be led. The drive for the longitudinal movement is supplied by the motor 11. For the implementation of the pivoting movement of the chamber part 16 is provided by the motor 12, the the chamber 16 is moved by means of the shaft 20. Subsequent to that shown in FIG The starting position of the process is the magazine equipped with filled jeß cuvettes transported to the furnace for thermal pretreatment. The measuring chamber is in the Starting position for receiving a cuvette swiveled 900 upwards.

Fig. 2 shows the phase of thermal pretreatment of the test samples in the drying oven 8.

In Fig. 5 is the phase of filling the measuring chamber 16 with a Samples? Uvette 40a shown. The locking of the Transportvor direction is in the position in which the first cuvette of the magazine is above the The opening 21 located in the platform 6 is above the measuring chamber 16, the cuvette 4Oa falls down through opening 21. This creates a contact in the measuring chamber triggered, which turns on the motor 12, causing the measuring chamber to 900 to the right is pivoted, as shown in FIG.

The attachment 19 prevents the cuvette from falling out during of panning.

In Fig. 5, the chamber part 16 is in the longitudinal direction to the right Chamber part 16a has been brought up so that the measuring chamber is closed and the Analysis process can take place. After the analysis has been carried out, the measuring chamber is through Longitudinal displacement of the movable part 16 after @@@ ks is then opened the moving part rotated another 900 to the right. In this situation can the measured sample cuvette 40a fall down into the collecting magazine. The end piece 25 prevents the sample cell from slipping sideways if it falls out. the The phase of the emptied measuring chamber is shown in FIG. Following this The measuring magazine and the collecting magazine are around a cuvette 40b transported further to the right, the measuring chamber refilled and the sample analyzed and the sample cuvette 40b is then emptied again into the collecting magazine.

These steps are repeated until all sample cells of the Measuring magazine are analyzed. Then the measuring magazine and the collecting magazine are in transported back to the starting position shown in FIG. 7 and the device can be equipped with the next full measuring magazine.

In Fig. 8 the program of the automatic method is schematically shown. When the start switch is closed, the motor 25 is started, which then closes the switches 27-57 via the shaft 26 at predetermined time intervals and thereby initiates the individual process steps.

Claims (4)

Claims 1. Procedure for the analysis of fine dusts, Tobei those in graphite cuvettes test samples introduced in the light path of an atomic absorption spectrometer or Atomic fluorescence spectrometer is atomized in a glowing graphite tube and used for light absorption or fluorescence are excited, characterized in that an automatic A succession of procedural steps is carried out, each of which consists of that a larger number of samples containing graphite cuvettes in a first Magazine (measuring magazine) are stored that the graphite cuvettes one possible thermal pretreatment that the magazine to one at the measuring chamber an atomic absorption or atomic fluorescence spectrometer located, support or Holding device is brought that each one of the graphite cuvettes from the measuring magazine is conveyed into the measuring chamber for analysis in a cycle adapted to the measuring time, that after inserting a graphite cuvette into the measuring chamber one after the other and in predetermined Time intervals of the atomization, the excitation and the measuring process for the from the excited sample emitted signals is switched on that the analyzed Graphite cuvette conveyed out of the measuring chamber after the analysis and a second magazine (collecting magazine) is fed. 2. Apparatus for performing the method according to claim l, at the one perpendicular to its longitudinal axis and divided from a fixed and a moving part is used, characterized in that, that transport means are provided for conveying the graphite cuvettes containing the samples are that the movable chamber part is displaceable in the direction of the longitudinal axis and is pivotable by 560 °, wherein two locking points for the swivel movement are provided for receiving and handing over the sample cells. 5. Device according to AniprucEI 2 for carrying out the process according to Claim 1, characterized in that the longitudinal axis of the measuring chamber and the optical Coincide with the axis of the atomic spectrometer, 4. Device according to claims 2 and 3 for carrying out the method according to claim 1, characterized in that the furnace takes up the entire filled measuring magazine for thermal pretreatment. 5. Device according to claims 2-4 for performing the method according to claim 1> characterized in that the furnace is a single cell for thermal pretreatment. 6. Device according to claims 2 - 5 for carrying out the process according to claim 1, characterized in that the transport means for the measuring magazine above the measuring chamber and the transport means for the collecting magazine below the Measuring chamber is arranged, and that locks are provided in the transport program are. L e r s e i t e