NL1000769C2 - Hydraulic press removes percussion caps of ammunition shells - Google Patents

Abstract

The base (41) of the press is mounted on a bench. The lower end of the hydraulic tool is threaded into a platform (39). The thread is locked onto the platform (39) by two lock nuts (40). The platform is supported from the base by vertical legs (42, 43). The shell (32) is placed in a tray (46) on top of a pressure piston (45). The user pulls down on a handle (48). The handle pivots on a hinge (50) at the lower end of two arms (49). The upper ends of the arms pivot (51) on the base (41). A rod (47), welded to the end of the handle pushes upwards on the pressure piston (45). When the cartridge is pressed up against the end of the tool, the hydraulic cylinder assembly presses out the percussion cap.

Description

Press for naturalizing a percussion cap from a sleeve

The invention relates to the field of reloading cartridges as used in ammunition for personal weapons, for example small arms such as pistols and revolvers, or rifles and the like. Such a sleeve has a cylindrical body which is closed on one side by a bottom. This floor has a floor in which a so-called percussion cap is pressed. At the location of that recess, the bottom of the sleeve has one or more holes which provide a connection between the impact shaft in the percussion cap and the explosive agent in the sleeve. As is known, the open end of the sleeve is closed by means of a projectile such as a bullet.

When firing the projectile with a weapon, its firing pin strikes the percussion cap, causing the percussion to ignite and causing the explosive to ignite via the 15 holes. After the shot a sleeve remains with the percussion cap in the bottom of it.

However, since the sleeve is made of a copper alloy, it still represents a certain value. Often the sleeves are therefore collected in order to be reloaded. In that context, the old percussion cap must be replaced by a new percussion cap with percussion shaft. The sleeve must be recalibrated before the explosive and projectile can be applied.

For most of these operations tools have been developed, which also offer the amateur the opportunity to produce 25 ammunition from old cartridges themselves at a reasonable cost. Nevertheless, it turns out that removing the old percussion caps is still a difficult, labor-intensive task. Some sleeves (Boxer type) have a central hole in the sleeve bottom, which still provides some access to the percussion cap. Other sleeves (type Berdan), however, have two small holes, which barely allow access.

The percussion caps are firmly clamped in the sleeve bottom; in addition, the percussion caps must be engaged from the inside in order to be able to remove them from the recess in the sleeve bottom to the outside. However, the accessibility from the interior of the sleeve leaves much to be desired in view of the small dimensions. The result is that the sleeve can be damaged when the percussion cap is removed, which makes reuse difficult or sometimes impossible.

The object of the invention is therefore to provide a tool with which percussion caps can be removed from the sleeve bottom in a simple, inexpensive and safe manner. This is accomplished by means of a 1000769 2 hydraulic tool for removing a percussion cap from a sleeve, comprising a press nozzle fitted in the sleeve on the bottom thereof and around each ignition hole located therein, which tool further includes a fluid chamber which communicates with the press nozzle, wherein the press nozzle is movable relative to the chamber such that by pressing the bottom of the sleeve on the press nozzle, the pressure of the liquid in the chamber and the press nozzle can be increased.

In the tool according to the invention, the sleeve bottom is pressed against the pressing nozzle with its inner side. As a result, an overpressure is generated in the liquid contained in the liquid chamber and in the press nozzle. This overpressure results from the (small) movement of the press nozzle which is generated by pressing the sleeve against it.

The pressurized liquid also enters the percussion cap via the holes in the sleeve bottom, which is then pressed out at sufficiently high pressures.

Preferably, a hollow rod is provided which has a through bore which opens at one end into the press nozzle, and at the other end into the liquid chamber, which hollow rod is slidably sealed in the liquid chamber.

When successively removing a number of percussion caps, some liquid may leak out. In order to keep the liquid chamber always completely filled, it can be connectable via a first non-return valve to a liquid reservoir, which first non-return valve is forced into the closed position under the influence of an overpressure in the liquid chamber.

The discharge nozzle can also be connected via a second non-return valve to the liquid chamber, which second non-return valve is forced into the closed position under the influence of an underpressure in the liquid chamber. In this embodiment, after releasing the pressure in the liquid chamber, a possible shortage of liquid will be filled, whereby the first check valve opens and the second check valve closes, allowing liquid to flow from the reservoir into the liquid chamber.

According to a preferred embodiment, a housing is provided which comprises the liquid chamber, which housing is provided at one end with the first non-return valve and connecting means for a liquid reservoir, and at the other end an externally threaded apron through which the hollow rod extends. .

The tool according to the invention can be used in combination with a known mechanical press. Such a press is also already used for the tools with which the sleeves can be calibrated. On the one hand, this press has an internally threaded hole in which the apron of the tool can be fixed, and on the other hand it has displacing means on which a sleeve can be received and which are movable in the direction towards the tool mounted in the hole.

An exemplary embodiment of the tool according to the invention will be explained in more detail below with reference to the figures.

Figure 1 shows the tool according to the invention in cross section.

Figure 2 shows a press with the tool according to the invention, in rest position.

Figure 3 shows the device according to Figure 2, in working position.

The tool according to the invention shown in Figure 1 comprises a housing indicated in its entirety by 1, which comprises a liquid chamber 2 and an apron k provided with external screw thread 3. At the top side, the housing 1 is closed by screw piece 5. which is screwed into corresponding screw thread 6 of the housing 1. In the liquid chamber 2, the hollow rod, which is indicated in its entirety by 7, is provided with an internal bore 8. The hollow rod, at its area located in the liquid chamber 2, has a widened part 9 · This widened part has a circumferential groove 10, in which is included an O-ring 11 which seals with respect to the internal wall of the liquid chamber 2 The widened portion 9 of the hollow rod 7 rests on the constriction 12 which forms an end wall of the liquid chamber 2, which end wall 25 defines a passage 13 through which the rod 7 passes.

The widened portion 9 of the hollow rod 7 has a sleeve I at its upper end, through which compression spring 15 extends. Compression spring 15 rests on the one hand against bottom 16 of the hollow rod 7. and on the other hand against a ring 17 which is placed in the screw piece 5. Compression spring 15 30 keeps the hollow rod 7 with its widened part 9 pressed against the constriction 12.

The screw piece 5 further has a non-return valve 33 with a valve 18, which is held in the closed position by spring 19. By means of 0-ring 20, valve 18 is sealed with respect to the internal wall of the screw piece 5 · 0-ring 20 is held captive by the ring 17. By means of further 0-ring 21, the screw piece 5 is sealed with respect to of the house 1.

In the lower, slightly widened part 22 of the bore 8 in the hollow rod 7, a compression spring 23 is provided, which keeps the ball 2k pressed against the seat 25. Together, seat 25 and ball 2k form a second 1000769 4 non-return valve 37 ·

At its lower end, the spring rests against the inner surface 25 of pressing nozzle 26. At its outer end, the pressing nozzle carries an O-ring 27, which is held captive between the upright edge 28 of the pressing nozzle. The pressing nozzle itself is sealed to the hollow rod 7 by means of O-ring 29

Finally, the housing 1 has an O-ring 30 on its outer circumference near the screw piece 5, by means of which the schematically indicated liquid reservoir 55 can be placed on the housing 1.

The tool according to the invention works as follows. The bottom 31 of a used sleeve 32 is placed against the nozzle 26, in particular O-ring 27. The sleeve 32 is pressed with a certain force, whereby hollow rod 7 tries to move slightly upwards relative to the housing 1. Since check valve 33 is closed, the pressure of the liquid in chamber 2 and bore 8 increases as a result. This pressure propagates through the holes 34 in the bottom 31 of the sleeve 32, into the space 35 which is bounded by the percussion cap 36. As soon as the pressure of the liquid has become sufficiently high, the percussion cap 36 is removed from the sleeve 32 pressed.

When the pressure is released, the hollow rod 7 will try to move slightly downwards relative to the housing 1. The second non-return valve 37 closes thereby. The first non-return valve 33 opens. Then just as much liquid can flow from the reservoir 55 into the chamber 2, as necessary to ensure full filling. The tool is thus ready for the next operation of removing a percussion cap.

Although a sleeve 9 x 19 is shown in Figure 1, the tool is suitable for a wide variety of sleeves. Long sleeves can also be treated: these reach between hollow bar 7 and apron 4.

The device according to the invention is best used in combination with the mechanical press shown in figures 2 and 3. The housing 1 of the tool is screwed with the external screw thread 3 of the apron 4 into the internal screw thread 38 of platform 39. The housing 1 is set to the correct height by means of lock nut 40. A liquid reservoir 31 is also placed on the housing 1.

The mechanical press further has a base 41 on which the platform 39 is supported by two legs 42, 43. The base 2 can be clamped on a workbench by means of a suitable clamp or bolt connection (not shown).

The base 41 has a pipe piece 44, into which a pressing rod 45 is guided. A housing holder 1 + 6 is mounted on the top side of the pressing rod, in which sleeve 32 is held in a known manner.

Press rod 1 + 5 has an eye on its underside in which a hinge pin 46 is attached. The foot 47 is mounted rotatably on hinge pin 46. On the one hand this foot is rigidly fixed with lever 48, while on the other hand two arms 49 rotatable according to hinge pin 50 cooperates with foot 47.

On the other hand, the arms 49 are attached to base 41 by hinge pins 51.

As can be seen in Figures 2 and 3, when lever 48 is lowered, foot 47 is rotated with arms 49, whereby pressing rod 45 is moved upwards. The ratio of the dimensions of foot 47. arms 49 and the distance between hinge pins 46, 50 and 51 is chosen such that at the end of the stroke of the lever it makes a large displacement 15 while the corresponding displacement of press cylinder 45 is only is very small. Therefore, by exerting a small force on lever 48, a large pressing force can still be obtained on pressing cylinder 45.

The sleeve 32 received in the housing holder 46 is thereby firmly pressed against the mouthpiece 26 with its bottom 31 (see figure 1), whereby the percussion cap 36 can be reliably removed.

1000769

Claims (7)

A hydraulic tool for removing a percussion cap (36) from a sleeve (32), comprising a pressing nozzle (26) insertable in the sleeve (32) on the bottom (31) thereof and around each ignition hole contained therein (3 * 0, which tool further comprises a fluid chamber (2) communicating with the press nozzle (26), the press nozzle (26) being movable relative to the chamber (2) such that by pressing the bottom (31 ) of the sleeve (32) on the press nozzle 10 (26), the pressure of the liquid in the chamber (2) and the press nozzle (26) can be increased. 2. Tool according to claim 1, wherein a hollow rod (7) is provided which has a through bore (8) which opens at one end into the press nozzle (26), and at the other end into the liquid chamber (2 ), which hollow rod (7) is slidably sealingly received in the liquid chamber (2). 3. Tool according to claim 2, wherein the liquid chamber (2) 20 has an end wall (12) with a narrowed passage (13) through which the hollow rod (7) extends, which hollow rod (7) has an outer peripheral edge (9) in the extreme extended position of the rod (7) rests against the end wall (12) around the passage (13) Tool according to claim 2 or 3, wherein the liquid chamber (2) is connectable via a first non-return valve (33) to a liquid reservoir (40), which first non-return valve (33) is forced into the closed position under the influence of an overpressure in the fluid chamber (2). 30 Tool as claimed in claim 2, 3 or wherein the discharge nozzle piece (26) is connected via a second non-return valve (37) to the liquid chamber (2), which second non-return valve (37) is forced into the closed position under the influence of a negative pressure in the fluid chamber (2). Tool according to claim 2, 3, 4 or 5, wherein a housing (1) is provided which comprises the liquid chamber (2), which housing (1) is provided at one end with the first non-return valve (33) and connecting means (30 ) for a fluid reservoir (55), and at the other end an externally threaded apron (4) through which the hollow rod (7) extends. 1000769 Device for removing a percussion cap from a sleeve, comprising a hydraulic tool according to claim 6, as well as a press which has an internally threaded hole (38) on the one hand in which the apron (4) of the tool can be fixed, and on the other hand 5 has displacement means (47, 48, 49, 50, 51) on which a sleeve (32) can be received and which are displaceable in the direction to the tool mounted in the hole. 1000769