DE930236C - Method and arrangement for sorting cartridge cases - Google Patents

Description

Method and arrangement for sorting cartridge cases The invention relates to the method and arrangement for sorting reloading Cartridge cases, in particular rifle cartridge cases.

In the manufacture of cartridges and cartridge chambers, certain Tolerances are taken into account. So that the cartridge fits into all cartridge chambers, their dimensions may not exceed the minimum dimensions of the cartridge chamber be. When fired, the case is under so high pressure that it hits the chamber fully filled. In doing so, it experiences a slight increase in diameter and moreover an extension. The dimensions of the case after the shot are therefore of the Size of the chamber determined. After the shooting, the case is sent to the ammunition plant returned for reloading. Before reloading, the case is first refurbished, d. H. the fired primer removed and the external shape of the case restored. The sleeve is inserted into a gauge that restores its outer diameter, at the same time the constricted case mouth is drawn in. This lengthens the narrowed part, which is then turned off to the correct length. The sleeve elongation reaches a size of about 1/2 to r mm. After that, the sleeve has the same exterior Dimensions as before the shot, so that they are measured by one not shot at Sleeve cannot be distinguished. After reloading, the case will come back shot at and the workup repeated.

The repeated bombardment weakens the case and gradually leads to Burst open. the The consequence of this is gas permeability Shot and change in the initial velocity of the projectile. Also cause the sleeve breaker ejector malfunctions. Personal injury can also occur. It is therefore of great importance when re-ammunitioning used cartridge cases to sort out those sleeves that are at risk of ripping open is. The only previously proposed method of such sorting out of individuals Sleeves is to label the sleeve with each reload, e.g. B. one Grain mark or the like, to be provided by the number of shots and reloads become apparent. This process is relatively cumbersome, and it does not take into account that different weapons, e.g. B. those with a very large chamber Compared to those with a very small chamber, the cases are very uneven claim. There is also the risk of two or more brands coinciding or that the marking is forgotten after reloading. The procedure is therefore has not been used to any significant extent in practice either.

Instead, you managed to close such sleeve sections cash, which have a relatively high frequency of tears. Here However, many relatively new pods can also be cashed in because it is in practice it is not possible to tell different games apart, because the games come off both with the senders, z. B: Rifle associations, as well as in the ammunition factories mixed up.

The present invention provides a method in which the aforementioned Disadvantages are avoided and with the ammunition companies have the opportunity to Regardless of the number of case shells that have taken place, there is a high degree of certainty To sort out cartridge cases where there is a significant risk of tearing is.

The new method is based on the finding that a significant Risk of tearing, at least with the new thickness tolerances that occur in practice Pods, only occurs when the strength of the pod is in a certain proportion, proportionate limited area, hereinafter referred to as "critical area", is less than is a certain critical value. The critical area is near the bottom of the case and has z. B. with cartridge cases for rifle ammunition of caliber 6.5 mm mainly a width of about 3 to 5 mm and is about 5 to i 5 mm from the case base. According to the invention, the wall thickness of the case is therefore critical when reloading Area measured and, such sleeves, for which the wall thickness in this area is less than is a certain critical value are sorted out. This value can e.g. B. for 6.5 mm rifle ammunition are within the limits of 0.65 to 0.45 mm. For other cases and calibres, of course, other values apply.

According to the invention, the wall thickness is best measured by that the critical area of the sleeve is x-rayed.

The wall thickness in the critical area of the sleeve to be tested is, preferably with the aid of a standard sleeve, i.e. H. a sleeve that is in the critical area that Beringst has admissible strength. This' standard sleeve is used to adjust a measuring device which is arranged so that sleeves, whose strength in the critical area is less than the Beringst permissible, sorted out while everyone else continues.

The invention also includes apparatus for practicing the aforesaid Procedure. Some embodiments of this device are exemplified below described with reference to the drawing. In the drawing, Fig. I is a schematic Side view of an embodiment of the invention and FIG. Z is a longitudinal section through part of another embodiment of the arrangement according to the invention.

The arrangement shown in Fig. Z consists in principle of four main parts, namely a radiation source i o, a sighting head i i, an amplifier I z and a sorting mechanism 13.

The radiation source io consists best of one with a relatively low anode voltage continuously working X-ray tube, its radiation divided into two beams by a suitable, not shown slit system will.

The sighting head i i comprises two sighting systems, one of which is a system 14, 15, 16 for the sleeve to be tested 17 and the other system 18, 19 for a standard sleeve 2o is determined, d. H. a sleeve that is the smallest permitted in the critical area Has strength. The 'systems are identical except that the first system is provided with a locking arrangement 14, which is mechanically by a cam is controlled while the channel of the standard sleeve is always open. 15 and 18 are tubes provided with columns, in which the sleeves 17 and - o are during the measurement are located. 16 and 19 are multiplier photocells with a fluorescent screen.

The amplifier 12 is a balanced DC amplifier, the is completed with a balancing relay. The amplifier unit also includes Not particularly shown arrangements of known design for regulation, for control and for signaling.

The sorting mechanism 13 exists in the exemplary embodiments shown from a magnetic device 21 with a sorting flap 22. The flap 22 can with Using the magnetic device 21 are brought into two different positions, whereby the entrance to two sorting compartments 23 and 24 for "good" and "reject" cases can be closed or opened. The mechanical connection between the sighting head and the sorting mechanism, d. H. the path of the sleeve 17 from the measuring position in the tube 15 to the sorting flap 22 has not been shown in the drawing. the Magnetic device 21 is, as illustrated schematically in the drawing, arranged such that it is actuated by the amplifier 12. How this is done is shown below explained in connection with the description of the mode of operation of the device.

The arrangement works as follows: In the tube 18 there is a standard sleeve 2o, e.g. B. a metal tube with exact wall thickness housed, which is continuously from the one beam of radiation source io is transilluminated. This will the photocell i9 is energized. In the tube 15, for. B. by means of a tube machine, Sleeves 17 introduced to be tested. At the moment of the working cycle, in which no sleeve 17 is in the measuring position, the cam is the lock 14 locked so that the photocell 16 is strorrilos. Right now is also the amplifier 12 automatically locked, so that the magnetic device 21 no Control impulse receives. When a sleeve 17 is inserted into the tube 15 in the measuring position, the closure 14 opens and the critical area of the sleeve 17 is x-rayed, so that the Fato cell 16 is also energized. At that moment the Amplifier 12 coupled so that the over the anode resistance of the photocells 16 and i9 resulting voltages are amplified and compared in the amplifier can. The latter actuates the balancing relay, which in turn actuates the magnetic device 21 with the sorter flap 22 controls. When the wall thickness is in the critical area of the test piece 17 greater than or equal to the corresponding thickness of the standard sleeve 2o, the sorting flap 22 is set to>: Good <<. On the other hand, is the sleeve thinner, the flap turns to "reject". With regard to possible sources of error in the amplifier and magnet device, the arrangement on the sorting flap expediently designed in such a way that the "good" side is normally closed remain.

The sorting flap 22 is so long in set position so that the case has time to run after 23 or -24, when it leaves the measuring position. Before this occurs, however, the shutter 14 is closed and the amplifier locked, after which a new working cycle can begin.

A standard sleeve is also inserted into the tube 15 to calibrate the arrangement introduced and the amplifier adjusted.

A radioactive substance can also be used as the radiation source without having to change the arrangement.

A radioactive substance can also be used as a radiation source, which is housed in a cylinder with very small dimensions, which is the Measurement into the sleeve to x-ray the sleeve wall in a number of directions is introduced, as shown for example in Fig. 2. The one shown in this figure Arrangement consists of a rod 25, which with a space 26 for a radioactive Fabric and a radiation window 27 is formed. Are around the pole a tube 28 and a spring 29 are arranged. 3o denotes the sleeve to be examined is and the z. B. is brought in the direction of arrow 3 z. 32 denotes the Radiation receiver, which either consists of a fluorescent screen Photocell or a Geiger-Müller tube.

The amplifier, not shown, can in principle be the same as the amplifier 12 in Fig. t, but it can also be designed as an unbalanced amplifier will.

The sorting arrangement can be similar to arrangement 13 in FIG.

The arrangement according to Fig.2 works as follows: At the moment of The working cycle in which there is no sleeve in the measuring position is located the arrangement 25 to 29 on the far left in FIG. 2 in that shown with dashed lines Position a, in which the radiation window 27 is closed by the spring 29 and the tube 28 is held so that no radiation escapes. The amplifier is right now blocked according to the procedure described above. When a sleeve 3o in the measuring position has been brought, the aforementioned arrangement comes into the solid line position indicated in Fig. 2, and immediately thereafter the fluoroscopy begins, in that in this position b the tube 28 strikes the sleeve mouth while the rod 25 continues its way to the right into the sleeve up to the dashed line Lines indicated position c continues, whereby the radiation window 27 is opened will. During the movement of the rod from position b to position c and back The sleeve is x-rayed for the required period of time. But there is the amplifier switched on. If, on the other hand, there is no sleeve in the measuring position, there will be none Radiation emitted because in this case the tube 28 in position b is not at the case mouth strikes, but assumes its normal position, in which it the radiation window during of the whole working cycle. After fluoroscopy is completed the arrangement 2 5 to 29 goes back to the position a, the sleeve being the measuring position and, as previously described, is sorted.

To calibrate the arrangement sketched in FIG. 2, it is best again a standard sleeve is used, according to which the sensitivity of the amplifier is based a suitable value is set.

It is clear that the invention is limited to the embodiments shown is not limited, but that various modifications within the scope of the invention are conceivable.

Claims (13)

PATENT CLAIMS: i. Process for sorting used, for reloading certain cartridge cases, characterized in that the wall thickness of the case measured in a limited area close to the bottom of the sleeve, the critical area is sorted out and .such pods for which the wall thickness is less than a certain critical value in this area. 2. Procedure according to Claim i, characterized in that the critical area of the sleeve for measurement the wall thickness is x-rayed. 3. The method according to claim i or 2, characterized in that the wall thickness is d. H. a sleeve that has the most permissible wall thickness in the critical area has, is determined. 4. The method according to claim 3, characterized in that the Standard sleeve is used to adjust a measuring arrangement which is so arranged is that the sleeves are sorted out, their wall thickness in the critical area is less than the Beringst allowable strength. 5. Procedure for sorting out Cartridge cases for 6.5 mm rifle ammunition according to one of the preceding claims, characterized in that the critical area is an area with a width of about 3 to 5 mm at a distance of about 5 to. 15 mm from the bottom of the case will. 6. The method according to claim 5, characterized in that the sleeves are sorted out whose wall thickness in the critical area is less than 0.65 to 0.45 mm eats. 7. Arrangement for sorting cartridge cases according to the method according to a of claims i to 6, characterized by a radiation source (io), which for Illumination of that sleeve area is arranged in which the sleeve at Bombardment is mainly deformed, and a standard element (20) in comparison to the test item is also x-rayed, as well as a sorting mechanism (13), by means of the radiation from the radiation source (i o) over the test object (17) and is operated via the standard element (2o). B. Arrangement according to claim 7, characterized by two visor systems, one for the test item (17) and the other for the standard element, z. B. a standard sleeve (2o), each of which consists of a visor system with a Gap for lighting from the radiation source (io) provided for the sleeves (17, 20) certain tube (15 or 18) as well as one each in relation to the radiation source A photocell with a fluorescent screen placed behind these tubes (16 or i g), which are followed by a compensation amplifier (12). 9. Arrangement according to claim 8, characterized in that the amplifier consists of a balanced DC amplifier. exists, which is terminated with a balancing relay is. i o. Arrangement according to one of Claims 7 to 9, characterized in that the radiation source consists of an X-ray tube. i i. Arrangement according to one of the Claims 7 to. 9, characterized in that the radiation source consists of a radioactive Substance is made. 12. The arrangement according to claim i i, characterized in that the radioactive material is housed in a cylinder (28) so small in size, that the cylinder can be inserted into the sleeve (30) for illuminating the sleeve walls is. 13. The arrangement according to claim 12, characterized in that the radioactive Cylinder (28) containing substance is provided with a radiation window (27) and so on is arranged that the radiation window is automatically released when the cylinder is in such a position relative to the test item (3o) that the Main deformation area of the test object is x-rayed.