EP0731330A1 - Cooling system for the drum of a revolver type gun - Google Patents

Abstract

The drum (1) containing several round chambers (3) rotates on a spindle (2). There is a lengthwise feed passage (13) connected at one end (5) of the drum to radial inlet passages (12). Two cooling passages (4) for each chamber and parallel to the drum axis extend for the full length of the bullet-guide portion (3.1) of the chamber, and are connected together via an internal passage (7) in the drum. At the end of the latter, the first and second cooling passages are connected by first and second tangential pipes and respectively via the radial inlet pipe to the feed passage in the spindle, and via an outlet passage (16) parallel to the inlet one to a drain passage (17) in the spindle.

Description

The invention relates to a cooling device for revolver drums of revolver cannons, wherein the revolver drum has a plurality of cartridge bearings and is rotatably mounted on a drum axis, and an inflow channel is provided in the drum axis, which is connected to radial input channels arranged in the region of one end face of the revolver drum.

In the case of revolver cannons, for example from a publication OC 2059 e 94 from the company Oerlikon-Contraves, Zurich, the revolver drum heated during firing is generally cooled by the ambient air. In the case of longer bursts of fire and rapid projectile order, this type of cooling is insufficient, however, since the area of the drum in which the projectile is carried in the cartridge chamber can heat up considerably. This can lead to a critical condition when the heat is transferred to the area of the drum in which the sleeve is guided in the cartridge chamber, so that safety and reliability problems such as excess pressure shots, ignition failure, Cook OFF etc. can occur.

With the German patent DE-PS 31 45 764 a cooling device for gun barrels of firearms, in particular automatic firearms and high-performance machine guns, has become known. In high-performance firearms of this type, which fire highly-developed ammunition, the high level of wear on the weapon barrel is due to the fact that the surface heat is not dissipated quickly enough. The rapid succession of heat during the burst of fire causes surface tensions and material conversions. When the bullets flap in the weapon barrel, the trains are deformed and material is removed by the bullet's guide band. In order to increase the service life of the gun barrels, the patent cited above proposes to provide cooling channels in the region of the end part of the gun barrel axially adjacent to a barrel in the barrel, radially outward between the individual cartridges, with a main channel for the coolant supply running in the barrel axis are connected. The cooling channels are connected to nozzles running parallel to the drum axis, which open into the end of the drum facing the weapon barrel and are arranged at the same distance from the longitudinal axis of the drum as the central longitudinal axes of the cartridge chamber. Shut-off devices for the nozzles are provided in the cooling channels, which in the event of bombardment briefly release the nozzle in the area of the pipe opening. The shut-off devices are, for example, slides which can be moved by means of control pieces sliding along a control cam when the drum rotates. The coolant passes through the nozzles directly onto the inner wall of the barrel in the rear part. The nozzles are only open for the period when the nozzles slide past in the rear of the gun barrel and the coolant is only supplied when shooting.

Although the coolant is passed through the drum in the case of the above-described cooling device for a weapon barrel, it is only possible to achieve cooling in the region of the drum end wall, so that this device is not suitable for eliminating the problems mentioned at the beginning.

The invention has for its object to provide a cooling device for a revolver drum of the type mentioned, in which the heating is limited such that the above-mentioned disadvantages are avoided.

This object is achieved by the invention specified in claim 1 . Each cartridge chamber is assigned two cooling channels that run parallel to the drum axis and extend over the entire length of the bullet guide of the block chamber. The cooling channels assigned to a particular cartridge chamber are connected to one another at their ends inside the revolver drum. In the area of the one end face of the revolver drum, the first of two cooling channels assigned to a cartridge chamber is connected via first tangential connecting tubes and the radial input channels to the inflow channel provided in the drum axis. In each case the second of two cooling channels assigned to a cartridge chamber is also connected in the region of one end face of the revolver drum via second tangential connecting pipes and radial outlet channels running parallel to the input channels with a drainage channel provided in the drum axis.

The advantages achieved by the invention are, in particular, that the coolant is not passed through all the cooling channels of the revolver drum one after the other, but that everyone
Cartridge chamber is assigned its own cooling circuit, with which an effective, heat dissipating cooling is achieved. Another advantage can be seen in the fact that a substantial part of the heat is quickly dissipated in the most heated area, in which the projectile is guided in the cartridge chamber. As a result, the area of the revolver drum in which the sleeve is guided in the cartridge chamber can no longer heat up as much.
With these measures, the impairment of the cannon functions and strength problems are avoided and the tension curve in the drum is improved.
Further advantages can be seen in the low manufacturing and logistics costs as well as in the small change effort for existing cannons.

Fig. 1

einen Längsschnitt der erfindungsgemässen Revolvertrommel gemäss der Linie I-I in der Fig. 3,

Fig. 2

eine Draufsicht der Revolvertrommel,

Fig. 3

eine Ansicht der Revolvertrommel in Pfeilrichtung A der Fig. 1 mit einem Teilschnitt gemäss der Linie III-III in der Fig. 1, und

Fig. 4

einen Teilschnitt der Revolvertrommel gemäss der Linie IV-IV in der Fig. 2.

The invention is explained in more detail below using an exemplary embodiment in conjunction with the drawing. Show it:

Fig. 1

3 shows a longitudinal section of the revolver drum according to the invention along line II in FIG. 3,

Fig. 2

a plan view of the revolver drum,

Fig. 3

a view of the revolver drum in the direction of arrow A of FIG. 1 with a partial section along the line III-III in FIG. 1 , and

Fig. 4

a partial section of the revolver drum along the line IV-IV in Fig. 2nd

1 to 4 , 1 denotes a revolver drum which is rotatably mounted on a drum axis 2 . The revolver drum 1 has 4 cartridge chambers 3 , which are divided into a projectile guide 3.1 and a sleeve guide 3.2 . Each cartridge chamber 3 are associated with two extending parallel to the drum axis 2 cooling channels 4, which extend over the whole length of the floor guides 3.1 of the cartridge chamber 3 and are arranged in the region between the respective cartridge chamber 3 and the periphery of the revolving drum. 1 The cooling channels 4 are closed on one end face 5 of the revolver drum 1 by means of sealing plugs 6 . At their other ends inside the revolver drum 1 , the cooling channels 4 assigned to a specific cartridge chamber 3 are connected to one another via tangentially extending connecting channels 7 . The openings of the connecting channels 7 open into recesses 8 of the revolver drum 1 and are closed with further sealing plugs 9 . In the region of one end face 5 of the revolving drum 1 is respectively connected to deflecting parts 11 of the first of two a cartridge chamber 3 associated cooling channels 4 extending through first tangential connecting pipes 10th The deflecting parts 11 are connected to an inlet channel 13 provided in the drum axis 2 via radial inlet channels 12 which are offset by an angle of 90 ° to one another and arranged between the cartridge bearings 3 . At the end of the inflow channel 13 there are four radial bores 14 offset from one another by an angle of 90 ° in the drum axis 2 , the axes of which are in the same plane perpendicular to the drum axis 2 as the axes of the input channels 12 lie.

In the region of one end face 5 of the revolving drum 1 is respectively connected to the deflecting parts 11 of the second of two a cartridge chamber 3 associated cooling channels 4 extending via second tangential connecting pipes 15 °. The deflecting parts 11 are connected to an outlet channel 17 provided in the drum axis 2 via outlet channels 16 which run radially and parallel to the inlet channels 12 . The outflow channel 17 is separated from the inflow channel 13 by an intermediate piece 18 . At the beginning of the discharge channel 17 there are four radial bores 19 offset from one another by an angle of 90 ° in the drum axis 2 , the axes of which lie in the same plane directed perpendicular to the drum axis 2 as the axes of the output channels 16 . 20 denotes a sealing sleeve in which sealing rings 21 resting on the drum axis 2 are held so that a coolant located in the cooling channels cannot escape.

The cooling device described above works as follows:
The coolant is supplied via the inflow channel 13 , the four bores 14 , the four input channels 12 and the four first connecting pipes 10 to all the first cooling channels 4 ( 4 ', FIG. 3 ) of the cartridge chamber 3 and from all second cooling channels 4 ( 4 '' 3 ) the cartridge chamber 3 is simultaneously removed again via the four second connecting tubes 15 , the four outlet channels 16 , the four bores 19 and the drain channel 17 . In this way, each cartridge chamber 3 is cooled separately and simultaneously with the others, so that rapid and effective cooling is achieved.

The cooling can be operated by means of an open or closed circuit, water being used as the coolant, for example, and a pump provided for the coolant circulation being able to be switched on or off depending on the drum temperature.
It is also irrelevant whether the cooling channels 4 through which the coolant flows through the described input channels 12 to the output channels 16 or vice versa.

Reference list

1

Revolver drum

2nd

Drum axis

3rd

Cartridge chamber

3.1

Storey management

3.2

Sleeve guide

4th

Cooling channels

5

Face

6

Sealing plug

7

Connecting channels

8th

Recesses

9

More sealing plugs

10th

First connecting pipes

11

Deflecting part

12th

Input channels

13

Inflow channel

14

Holes

15

Second connecting pipes

16

Output channels

17th

Spillway

18th

Spacer

19th

Holes

20th

Sealing sleeve

21

Sealing rings

Claims (7)

Cooling device for revolver drums of revolver chambers, wherein the revolver drum ( 1 ) has a plurality of cartridge chambers ( 3 ) and is rotatably mounted on a drum axis ( 2 ), and wherein an inflow channel ( 13 ) is provided in the drum axis ( 2 ), which is also in the region of the an end face ( 5 ) of the turret drum ( 1 ) arranged radial input channels ( 12 ) is connected,
characterized in that - Each cartridge chamber ( 3 ) is assigned two cooling channels ( 4 ) running parallel to the drum axis ( 2 ), which extend over the entire length of the projectile guide ( 3.1 ) of the cartridge chamber ( 3 ), the respective cooling channels ( 4 ) assigned to a specific cartridge chamber ( 3 ) are connected to one another at their ends inside the revolver drum ( 1 ) via connecting channels ( 7 ), - In the area of one end face ( 5 ) of the revolver drum ( 1 ), the first of two cooling channels ( 4 ) assigned to a cartridge chamber ( 3 ) via first tangential connecting pipes ( 10 ) and the radial input channels ( 12 ) with the in the drum axis ( 2 ) provided inflow channel ( 13 ) are connected, and - In the area of one end face ( 5 ) of the revolver drum ( 1 ), the second of two cooling channels ( 4 ) assigned to a cartridge chamber ( 3 ) via second tangential connecting pipes ( 15 ) and radial output channels ( 16 ) running parallel to the input channels ( 12 ) ) are connected to a drain channel ( 17 ) provided in the drum axis ( 2 ). Cooling device according to claim 1 ,
characterized by
that the cooling channels ( 4 ) assigned to a cartridge chamber ( 3 ) are each arranged in the area between the relevant cartridge chamber ( 3 ) and the periphery of the revolver drum ( 1 ). Cooling device according to claim 1 ,
characterized by
that at the end of the inflow channel ( 13 ) there are four radial bores ( 14 ) offset from one another by an angle of 90 ° in the drum axis ( 2 ), the axes of which are in the same plane perpendicular to the drum axis ( 2 ) as the axes of the input channels ( 12) , and that at the beginning of the drain channel ( 17 ) four radial bores ( 19 ) offset from one another by 90 ° are provided in the drum axis ( 2 ), the axes of which are in the same plane as perpendicular to the drum axis ( 2 ) the axes of the output channels ( 16 ) lie. Cooling device according to claim 1 , wherein four cartridge chambers ( 3 ) are provided,
characterized by
that the input and output channels ( 12, 16 ) are arranged offset by an angle of 90 ° between the cartridge chambers ( 3 ). Cooling device according to claim 4 ,
characterized by
that the first and second tangential connecting pipes ( 10, 15) are connected to the input and output channels ( 12, 16 ) via deflecting parts ( 11 ). Cooling device according to claim 1 ,
characterized by
that an open or closed cooling circuit is provided. Cooling device according to claim 6 ,
characterized by
that a pump is provided for the coolant circulation, which can be switched on or off depending on the drum temperature.

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