ITBO20120375A1 - COOLED PLASMA TORCH DEVICE - Google Patents

Description

COOLED PLASMA TORCH DEVICE

DESCRIPTION OF THE INVENTION

The present invention is part of the sector concerning the generation of plasma for industrial and mechanical applications in general and refers to a plasma torch device equipped with a cooling system capable of dissipating large quantities of heat and particularly suitable for automated applications. and robotic.

Plasma torches equipped with cooling are known in which the water first passes through an internal duct, for example between a nozzle and a respective bush, and subsequently an outermost duct, for example between the bush and a protection screen where the water arrives already heated in the internal path. A disadvantage of these known torches consists in the fact that, particularly in the case of continued use at high powers, the water that reaches the external duct already heated, may be insufficient to ensure the necessary cooling; for example in the case of a torch installed in an automatic pantograph or robotic arm system, the heat and the reverberation radiation could heat the screen from the outside to bring the already hot water to boiling and evaporation temperature with the risk of overheating and damage to the torch.

An object of the present invention is to propose a torch device capable of effectively cooling and dissipating both the heat produced internally in the plasma generation chamber between electrode and nozzle, and the reverberation heat coming from the outside of the device and deriving from the dart. of plasma, from the material being processed and from any adjacent and additional torch devices.

The characteristics of the invention are highlighted below with particular reference to the accompanying drawings in which:

- figure 1 shows a sectional view from an axial plane of the cooled plasma torch device object of the present invention, some rear parts have been removed from here;

Figure 2 illustrates an axial and rear view of the device of Figure 1; Figures 3 to 5 show sectional views along the lines 11-11, IV-IV and V-V of Figure 1;

Figures 6 and 7 show sectional views along the lines VI-VI and VII-VII of Figure 2;

Figure 8 illustrates an axonometric view of a screen means of the device of Figure 1 consisting of an internal tubular wall and an external tubular wall which contains the internal ones;

Figure 9 illustrates a partially sectioned view of the screen means of Figure 8;

Figure 10 illustrates an axonometric view of the partially sectioned screen means of Figure 9;

Figure 11 illustrates a sectional view along the plane XI-XI of Figure 9; Figure 12 illustrates a sectional view along the line XII-XII of Figure 11;

Figure 13 illustrates an axonometric view of a first variant of the screen means of Figure 8;

Figure 14 is a partially sectioned view of the screen means of Figure 13;

Figure 15 illustrates an axonometric view of the partially sectioned screen means of Figure 14;

Figure 16 illustrates a sectional view along the plane XVI-XVI of Figure 14;

Figure 17 illustrates a sectional view along the line XVII-XVII of Figure 16;

Figure 18 illustrates an axonometric view of a further variant of the screen means of Figure 8;

Figure 19 shows a partially sectioned view of the screen means of Figure 18;

Figure 20 illustrates an axonometric view of the partially sectioned screen means of Figure 19;

figures 21 and 22 show sectioned views along the planes XXI-XXI and XXII-XXII of figure 19;

Figure 23 illustrates a sectional view along the line XXIII-XXIII of Figure 21.

With reference to Figures 1 to 23, 1 indicates the cooled plasma torch device object of the present invention.

In the preferred embodiment, the device 1, illustrated in Figures 1 to 12, comprises an electrode 3 arranged centrally and partially housed inside a nozzle 4 which extends beyond the free end of the electrode 3. The nozzle 4 and the electrode 3 delimit a plasma formation chamber 5 which is emitted through an axial hole present on the nozzle 4.

The nozzle 4 is partially surrounded by a bushing 7 externally of which there is a protective shield means 9, consisting of two interconnected first 10a and second 10b portions, to protect the electrode 3, the nozzle 4 and the bushing 7 .

The first 10a and second 10b parts of the protective shield means 9 are kept electrically insulated with respect to the bushing 7 by interposing insulating elements to ensure correct operation of the device 1. The second part 10b of the protective shield means 9 has an annular contact portion designed to keep in position the first part 10a of the protective shield means 9, placed to cover the nozzle 4 and the bushing 7, and to ensure the exchange between the screen and said first parts 10a and second parts 10b.

To allow plasma emission, the first part 10a of the protective shield means 9 is also equipped with a suitable coaxial hole with respect to the nozzle hole 4.

The device 1 also comprises a first interspace 11 between the nozzle 4 and the bushing 7 and a second interspace 12 obtained in the second part 10b of the screen means 9.

The first 11 and second 12 cavities are fed under pressure with at least one cooling fluid, for example water, through respective first 14 and second 15 supply ducts each equipped with a respective first 16 and second 17 inlet connectable to fluid supply means cooling systems, such as pumps, known and not illustrated.

The first 11 second 12 cavities are connected to a common outlet 19 through an outflow duct 20 for the outlet and recovery of the cooling fluid that has heated up passing through the first 1 1 and second 12 cavities.

The first supply duct 14 extends from the respective first inlet 16 to the first interspace 11 along an axial duct 22 leading into a longitudinal cavity 23 of the electrode 3.

This longitudinal cavity 23 opens into a first annular manifold 24 connected via a set of radial passages 25 to a second annular manifold 26 of eccentric or lobed shape which enters through a terminal passage 27 in the first interspace 11.

The second supply conduit 15 extends from the respective second inlet 17 to the second interspace 12 along a first decentralized conduit 29 leading into a first toroidal chamber 30 connected by means of a set of radial holes 31 to the second interspace 12.

The outflow duct 20 comprises a second decentralized duct 33 leading to the common outlet 19, connected by means of an extension 34 thereof to the first interspace 11 having an approximately frusto-conical shape and connected by means of its own lateral opening 37 to a second toroidal chamber 38 connected by means of a set of longitudinal ducts 39 and a third toroidal chamber 40 connected to the second interspace 12.

The second interspace 12 comprises two sets of first 47 and second 51 grooves which are arranged parallel to the longitudinal axis of the device 1 and mutually alternating.

The first 47 and second grooves 51 are formed on the external face of the internal tubular wall 43 and separated by portions of this external face in direct contact with the internal face of the external tubular wall 44 where each first groove 47 has a closed end 46 in which opens a corresponding radial hole 31.

The opposite end to the closed one 46 of each first groove 47 flows into a second annular manifold 50 of the second the interspace 12 and interposed between the external 43 and internal 44 tubular walls.

The second grooves 51 put the second annular manifold 50 in flow communication with the third toroidal chamber 40.

The operation of the device 1 typically involves the use of this torch for cutting metal objects of even very high thickness. A high potential difference is created between the electrode 3 and the metal object to be processed and an electric arc is triggered between the latter. There are different techniques for striking the electric arc, which being known will not be described below. The nozzle and electrode areas are therefore strongly heated by the electric arc which develops temperatures of several tens of thousands of degrees centigrade in the plasma formation chamber.

To cool the device 1, and in particular the area of the electrode 3 and of the nozzle 4, a pump introduces the cooling fluid through the first inlet 16 and pushes it along the entire path that passes through the first cavity to the common outlet. 19.

Similarly occurs for the cooling of the second part 10b of the screen means 9 by means of the cooling fluid through the second inlet 17 and pushed into the second interspace 12 and expelled through the common outlet 19.

The cooling of the first part 10a of the screen means 9 takes place through heat exchange by conduction with the second part 10b of the screen means 9.

In a first variant of the device 1, illustrated in Figures 13 to 17, the grooves are helical.

The operation of the first variant of the device is similar to that of the preferred embodiment.

In a second variant of the device, illustrated in Figures 18 to 23, the grooves 51 open directly to the outside of the device through a plurality of radial outlet holes 60. The first inlet 16 can be fed with a fluid consisting of water and the second inlet 17 can be fed with a second fluid preferably consisting of pressurized air, possibly also cooled and dehumidified.

The operation of the second variant of the device differs from that of the preferred embodiment in that the second cooling fluid is directly expelled and dispersed in the surrounding environment through the radial outlet holes 60.

An advantage of the present invention is to provide a torch device capable of effectively cooling and dissipating both the heat produced internally in the plasma generation chamber between electrode and nozzle, and the reverberation heat coming from the outside of the device and deriving from the dart. plasma, the material being processed and any adjacent and other torch devices.

Claims (10)

CLAIMS 1) Cooled plasma torch device comprising at least one electrode (3) at least partially housed in a nozzle (4) with which it defines a plasma formation chamber (5) intended to be emitted through an axial hole in the nozzle (4 ), the device (1) further comprises at least one bushing (7) containing at least partially the nozzle (4) and a screen means (9) at least partially containing the bushing (7); this device (1) also includes at least a first gap (11) placed between the nozzle (4) and the bushing (7) and a second gap (12) delimited at least by the screen means (9); said device (1) being characterized in that the first (11) second (12) air spaces are fed with at least one cooling fluid through respective first (14) and second (15) supply ducts each equipped with a respective first inlet ( 16) and second (17) connectable to feeding means for the at least one fluid. 2) Device according to claim 1 characterized by the fact that the first (11) and second (12) gaps are connected to a common outlet (19) for the at least one fluid through an outlet duct (20) and by the fact that the second interspace (12) is at least partially formed in the thickness of the screen means (9) which is preferably constituted by two first (10a) and second (10b) interconnected portions. 3) Device according to claim 1 characterized in that the first supply duct (14) extends from the respective first inlet (16) to the first interspace (11) along an axial duct (22) leading into a longitudinal cavity (23) of the electrode (3) which opens into a first annular manifold (24) connected through a set of radial passages (25) to a second annular manifold (26) of eccentric or lobed shape which enters through at least one terminal passage (27) in the first cavity (11). 4) Device according to any one of the preceding claims, characterized in that the second supply duct (15) extends from the respective second inlet (17) to the second interspace (12) along a first decentralized duct (29) leading into a first chamber toroidal (30) connected through a set of radial holes (31) to the second interspace (12). 5) Device according to claim 2 or according to claim 2 and at least any one of claims 3 and 4 characterized in that the outflow duct (20) comprises a second decentralized duct (33) leading to the common outlet (19), connected through its extension (34) to the first interspace (11) having an approximately truncated cone shape, said second decentralized duct (33) is connected through its own lateral opening (37) to a second toroidal chamber (38) connected through a set of ducts longitudinal (39) and through a third toroidal chamber (40) to the second interspace (12). 6) Device according to any one of the preceding claims, characterized in that the second screen means (10) comprises at least one internal tubular wall (43) and an external tubular wall (44) which at least partially contains the internal ones (43) in which they are obtained the radial holes (31) leading into the second interspace (12). 7) Device according to claim 6 characterized by the fact that the second interspace (12) is constituted by two sets of first (47) and second (51) grooves alternated and obtained on the external face of the internal tubular wall (43) and separated by portions of this external face in direct contact with the internal face of the external tubular wall (44) where each first groove (47) has a closed end (46) into which a corresponding radial hole (31) leads; the opposite end to the closed one (46) of each first groove (47) flows into a second annular manifold (50) of the second the interspace (12) and interposed between the external (43) and internal (44) tubular walls; the second grooves (51) place said second annular manifold (50) in flow communication with the third toroidal chamber (40). 8) Device according to claim 7 characterized by the fact that the first (47) and second (51) grooves are parallel to the longitudinal axis of the device (1). 9) Device according to claim 7 characterized in that the first (47) and second (51) grooves have a helical course. 10) Device according to claim 1 or any of claims 3 to 9 characterized in that the first interspace (11) is connected to an outlet (19) for the at least one fluid through an outlet duct (20) and that the second interspace (12) opens outwards through a plurality of radial outlet holes (60).