DE9212524U1 - Sample piece punching and transport device - Google Patents

Description

My file: H 73/18

Sample piece punching and transport device

The invention relates to a sample piece punching and transport device with which several sample pieces are punched out simultaneously from a prepared metallic material sample and brought to a receiving station.

In the devices known to date in practice, the punched-out sample pieces are transported to the receiving station via a transport route and there is no guarantee that the sample pieces will arrive properly at their respective analysis location due to possible mixing. Mixing and thus falsification of the sample analysis occurs in particular when individual sample pieces are not punched out as a whole sample piece due to blowholes or other material inclusions, but rather disintegrate.

In addition, the transport route from the punch to the receiving station is cumbersome, time-consuming and unsafe.

The object of the invention is to create a sample piece punching and transport device which, in a simple and automatic manner, conveys the punched sample pieces individually to the assigned place in the receiving station on a fast transport path and, in the process, sample pieces that have disintegrated during the punching process remain together, i.e., are sent to the evaluation station as a sample for flawless analysis

(Evaluation of the carbon content of one sample, evaluation of the nitrogen content of the other sample and evaluation of the sulfur content of the third sample).

This object is achieved according to the invention by the characterizing features of claim 1.

The subsequent sub-claims contain design features that represent advantageous and beneficial further developments in the solution of the task.

With the device according to the invention, several sample pieces are punched out of a material sample for later evaluation of the carbon, nitrogen and sulphur contents at the same time, these punched out sample pieces are separated and fed by means of blowing air in individual pipes to the receiving station, namely to a crucible in each case, so that the sample piece also reaches its predetermined place in the receiving station for its predetermined analysis and from there can be safely fed to the automatic analysis machine.

Since the material samples often contain cavities or other material inclusions, punching can result in a sample piece breaking up into two or more parts. However, since this sample piece is fed to its evaluation station in the receiving station in its own pipe even in its broken state, no adulteration, i.e. mixing with another sample, can occur and the sample that has thus broken down is conveyed as a unit in its own transport path.

The sample pieces are transported using blowing air, so that the sample pieces are moved along a fast transport path from the punch to the receiving station.

The device is simple and cost-effective, separates the samples automatically and requires little energy for the transport of the samples using the blowing air, whereby the blowing air ensures a safe transport of the samples in the pipeline and is additionally supported by injection air.

The sample pieces fall into an assigned crucible in the receiving station and these crucibles are linked to signal switches which register the arrival of the sample pieces in a crucible and thus ensure that a sample piece is present in each crucible for the subsequent analysis and if the desired number of sample pieces is not present, the fault is also reported.

The drawings show an embodiment of the invention, which is explained in more detail below. It shows:

Fig. 1 a schematic representation of the sample punching and transport device with punch, sample separator, pipes and receiving station,

Fig. 2 a cross-section through the punch with sample separator and connected pipes,

Fig. 3 is a front view of the receiving station consisting of several cyclones with associated crucibles for the sample pieces,

Fig. 4 is a top view of a material sample with three sample pieces to be punched out.

Using the sample piece punching and transport device, several sample pieces (Pl, P2, P3) are punched out simultaneously from a prepared metallic material sample (1) and conveyed to a receiving station (2), from which the sample pieces (Pl, P2, P3) are fed to an automatic analysis machine for a C-N-S analysis (testing for carbon, nitrogen and sulphur contents).

The device according to the invention has a sample piece separator (4) connected to its punch (B) with a receiving channel (7) leading from each punch hole (5) of the die (6) with an associated air blowing channel (8), and a pipe (9, 10, 11) is connected to each receiving channel (7), each of which is led to its own crucible (12, 13, 14) in the receiving station (2) for the individual transport of the sample pieces (P1, P2, P3) by means of blowing air.

The embodiment is designed for simultaneous punching and transporting of three sample pieces (P1, P2, P3) which are shown in Fig. 4.

In Fig. 1, the three pipes (9, 10, 11) are also shown, but in Fig. 2 only two punch holes (5), two receiving channels (7), two blowing channels (8) and two pipes (9, 11) are drawn, since the third of these components (5, 7, 8 and 10) are located behind them.

This device can be designed for two, three or more sample pieces (Pl, P2, P3) that are to be punched out simultaneously and transported separately.

The sample piece separator (4) is designed as a flat, rectangular housing block (15), on the top of which the punching die (6) with its punch holes (5) is attached. A vertical punch hole channel (5a) extends from each punch hole (5) in the die (6), to which a vertical and then horizontal channel part (7a, 7b) of each receiving channel (7) is connected, whereby these channel parts (7a, 7b) are recessed in the housing block (15) (Fig. 2).

A connecting channel (16) for the blowing air supply is introduced into the housing block (15), from which an air blowing channel (8) leads to each receiving channel (7) to its vertical channel part (7a) or to its horizontal channel part (7b), the air blowing channels (8) being smaller in cross section than the common connecting channel (16).

Each horizontal channel part (7b) of the receiving channels (7) is connected to a pipe (9, 10, 11) fixed in/on the housing block (15) and an injector pipe (17) introducing blowing air into the pipes (9, 10, 11) is connected to each pipe (9, 10, 11) so that

on the one hand, blowing air is introduced into the receiving channels (7) and on the other hand, blowing air is introduced into the pipes (9, 10, 11) for the transport of the sample pieces.

Each pipe (9, 10, 11) ends at a cyclone (18) of the receiving station (2) and under each cyclone (18) in the receiving station (2) there is a crucible (12, 13, 14) for the sample piece (P1, P2, P3) fed through the associated pipe (9, 10, 11) to the cyclone (18) and falling from there into the crucible (12, 13, 14).

Each crucible (12, 13, 14) is coupled to a detector (registration switch) (19) for detecting and registering the sample piece (P1, P2, P3) that has fallen into the crucible (12, 13, 14).

The material sample (1) is held in a fixed position by the die (6) and the height-adjustable male die (20) of the punch (3) simultaneously punches two, three or more sample pieces (Pl, P2, P3) out of the material sample (1) with its punching dies (21) and each sample piece (Pl, P2, P3) then falls downwards through the vertical punch hole channel (5a) which adjoins its punch hole (5) and has an enlarged cross-section into the channel part (7a) of the receiving channel (7) which adjoins it and has the same cross-section and then further into the horizontal channel part (7b).

The blowing air flowing through the blowing channels (8) into the receiving channels (7) conveys the sample pieces (Pl, P2, P3) out of the receiving channels (7) - channel parts (7b) - into the pipes (9, 10, 11) and further in the pipes (9, 10, 11) to the cyclones (18), whereby the injection pipes (17) introduce additional blowing air into the pipes (9, 10, 11) to support the conveyance of the sample pieces.

A sample piece (Pl, P2, P3) then falls from each pipe (9, 10, 11) into the cyclone (18) through which air flows from bottom to top and then into the crucible (12, 13, 14) and the detectors (19) register the sample pieces (Pl, P2, P3) that have arrived.

If there is a sample piece (Pl, P2, P3) in each crucible (12, 13, 14), the detectors (19) give a signal and the sample pieces (Pl, P2, P3) can be fed to the analysis machine with their crucibles (12, 13, 14) for evaluation.

If fewer than three sample pieces (Pl, P2, P3) have arrived at the receiving station (2), i.e. a crucible (12 or 13 or 14) has not received a sample piece (Pl, P2, P3), this is also registered by the detectors (19) and the fault is indicated by a signal.

Since voids or other material influences mean that when punching out the sample pieces (Pl, P2, P3), one-piece (full) sample pieces (Pl, P2, P3) are not always obtained, but one or the other sample piece (Pl or P2 or P3) breaks down into two or more individual pieces, these individual pieces of the sample piece are then fed together in the assigned transport path (7, 9/10/11, 18) to the corresponding crucible (12/13/14); the broken sample piece (Pl or P2 or P3) thus remains together and is not falsified.

Claims (6)

Protection claims 1. Sample piece punching and transport device with which several sample pieces are punched out of a prepared metallic material sample at the same time and fed to a receiving station, characterized by a sample piece separator (4) connected to the punch (3) with a receiving channel (7) leading from each punch hole (5) of the die (6) with an associated air blowing channel (8) and with a pipe (9, 10, 11) connected to each receiving channel (7), each of which is led to a separate crucible (12, 13, 14) in the receiving station (2) for the individual transport of the sample pieces (P1, P2, P3) by means of blowing air. 2. Device according to claim 1, characterized in that the sample piece separator (4) is designed as a flat, rectangular housing block (15), on the top of which the punching die (6) with its punch holes (5) and adjoining vertical punch hole channels (5a) is attached, and in which the receiving channels (7) adjoining each punch hole channel (5a) are recessed. 3. Device according to claim 1 or 2, characterized in that each receiving channel (7) has a vertical channel part (7a) adjoining the associated punch hole channel (5a) and a horizontal channel part (7b) adjoining thereto. 4. Device according to one of claims 1 to 3, characterized in that a connecting channel (16) for the blowing air supply is led into the housing block (15) of the sample piece separator (4), from which an air blowing channel (8) leads to each receiving channel (7), the air blowing channels (8) being smaller in cross section than the common connecting channel (16). 5. Device according to one of claims 1 to 4, characterized in that each horizontal channel part (7b) of the receiving channels (7) is connected to a pipe (9, 10, 11) fixed in/on the housing block (15) of the sample piece separator (4) and an injector pipe (17) is connected to each pipe (9, 10, 11) which introduces blowing air into the pipes (9, 10, 11) in addition to the blowing air introduced into the receiving channels (7). 6. Device according to one of claims 1 to 5, characterized in that each pipe (9, 10, 11) is connected to a cyclone (18) of the receiving station (2), under which in the receiving station (2) a crucible (12, 13, 14) is arranged for the sample piece (Pl, P2, P3) fed through the associated pipe (9, 10, 11) to the cyclone (18) and falling from there into the crucible (12, 13, 14), each crucible (12, 13, 14) being coupled to a detector (registration switch) (19) for detecting and registering the sample piece (Pl, P2, P3) that has fallen into the crucible (12, 13, 14).