EP1785679A1 - Device for heating gas under high pressure - Google Patents

Abstract

The device comprises pressure vessel (1) from which gas flows and has heating element (3) and insulation (2). The insulation is arranged in the inner wall of pressure vessel. The insulation is available by means of heat dissipation of pressure vessel, so that the pressure vessel has lower temperature than the heated gas. An independent claim is included for coating device.

Description

The invention relates to a device for high pressure gas heating, wherein the gas is heated in a pressurized container. In particular, the invention relates to a device for high-pressure gas heating for a coating device for substrate materials with a gas-flowed pressure vessel, a heating element arranged in the pressure vessel and an insulation.

In cold gas spraying or kinetic spraying, powder particles from 1 .mu.m to 100 .mu.m are accelerated in a gas stream to speeds of 200 m / s to 1600 m / s, without melting or fusing, and sprayed onto the surface to be coated, the substrate. Only upon impact with the substrate does the temperature increase at the colliding interfaces due to plastic deformation under very high strain rates and leads to welding of the powder material to the substrate as well as to each other. For this, however, a minimum impact speed must be exceeded, the so-called critical speed. The mechanism and quality of welding is comparable to explosive welding. By heating the process gas, the sound velocity of the gas is increased, thereby increasing the flow velocity of the gas in the nozzle and thus also the particle velocity upon impact. In addition, the particle temperature increases upon impact with the process gas temperature. This leads to a thermal softening and ductilization of the spray material, which lowers the critical velocity of the impacting particles. Thus, raising the process gas temperature increases both particle velocity and particle temperature upon impact. Both have a positive effect on the order efficiency and coating quality. The process gas temperature always remains below the melting temperature of the spray material used. In the cold gas spraying method, therefore, a "colder" gas is used in comparison to other spraying methods in which the powder particles are melted by the gas. As with fuel injection methods, in which filler metals are melted by hot gas, the gas also has to be heated during cold gas spraying.

In order to be able to accelerate powder particles, in particular coarser particles between 25 and 100 μm, gas at high pressure is necessary. For heating, the gas can be passed through a pressure vessel in which a heating element takes place. The pressure vessel is thus subjected to high temperatures and pressures from the inside. If the temperature can directly affect the pressure vessel, expensive or difficult-to-process high-temperature materials have to be used, or the pressure vessel becomes relatively heavy due to its size and the required wall thicknesses. A heater with such a pressure vessel is difficult to handle because of the high weight and has a high thermal inertia. The heat dissipation via the pressure vessel leads to losses in the heat output.

From the DE 197 56 594 A1 a device for coating substrate materials by thermal spraying is known, can be sprayed with the powder particles. The device for coating substrate materials comprises a device for heating the gas, which in one embodiment comprises an electrical resistance heater. The device for heating the gas is arranged after a gas buffer container.

A disadvantage of this prior art, however, is that the device for heating the gas requires a pressure vessel, which is relatively heavy because of its temperature resistance and, when it is attached to a spray gun, prevents the operation of the spray gun. Due to the necessary large material thicknesses of the pressure vessel, this is also thermally inert.

It is also known from the document to isolate hot gas leading lines.

It is therefore an object of the invention to provide a device for high-pressure gas heating available that can work with high pressures and high temperatures while still being light. In particular, it is an object of the invention to provide a device for high-pressure gas heating for a coating device for substrate materials available.

This object is achieved by a device for high-pressure gas heating for a coating device with the features of the independent claim 1 as well a coating device according to claim 11 solved. Advantageous developments of the devices are specified by the subclaims.

This object is achieved by a device for high-pressure gas heating, which comprises a gas-flowed pressure vessel, a heating element arranged in the pressure vessel and an insulation, wherein the insulation is arranged on the inner wall of the pressure vessel and means for heat dissipation of the pressure vessel are present, so that Pressure vessel has a lower temperature than the heated gas.

The high-pressure gas-heating apparatus releases gas with gas outlet temperatures of 100 to 1100 ° C, preferably 700 to 900 ° C. Especially in the upper temperature range of the stated values, only selected steels can be used for a limited time or special high-temperature materials, since otherwise softening of the material and deformation due to creep occurs and only a very low creep rupture strength of most materials is given. Since the device for high-pressure gas heating gas heated from a pressure of 15 to 100 bar, in particular in the range of 25 to 60 bar, a large amount of energy is transferred from the high-tension gas to the wall of the pressure vessel. The inventive design of a device for high-pressure gas heating, the energy transfer is reduced to the wall of the pressure vessel by the internally arranged insulation. By the means for heat dissipation, the temperature of the pressure vessel is reduced compared to the hot gas to 60% of the hot gas temperature, preferably to less than 40% and with appropriate design less than 20% of the temperature of the hot gas, measured in ° C. In the latter case, temperatures of the pressure vessel of below 220 ° C, in which, for example steel still shows no significant reduction in its strength. The pressure vessel can therefore be designed with a significantly lower wall thickness and is lighter, so that the device for high-pressure gas heating can also be integrated into a spray gun. Due to the reduced heat transfer to the pressure vessel, the device for high-pressure gas heating is not thermally inert and reacts quickly when the temperature of the gas is to be changed. Next heat losses are avoided in continuous operation by the insulation on the inside of the pressure vessel.

Advantageously, the means for heat dissipation with the ambient air directly in contact outer surface areas of the pressure vessel. On the outer surfaces of cooling fins may be formed.

Due to the insulation from the inside, despite the high energy transfer by high-pressure gas, the losses are kept low by heat dissipation and already ensured by free areas of the outside of the pressure vessel, which are in direct contact with the ambient air, a low temperature of the pressure vessel. If, nevertheless, an excessively high pressure vessel temperature is set, cooling fins, gas or liquid flows or both can also be used in conjunction with the cooling of the pressure vessel.

Advantageously, the pressure vessel temperature is less than 600 ° C. The pressure vessel may for example consist of steel and / or titanium or a titanium alloy.

If the pressure vessel temperature is reduced to less than 600 ° C by insulation and external heat dissipation, a pressure vessel with significantly lower wall thickness can be used when using a high-temperature material. Also, pressure vessels made of steel, titanium or titanium alloy can be used. Lowering the tank temperature further below 400 ° C results in a significant reduction in weight.

In an advantageous embodiment, the pressure vessel temperature is less than 200 ° C. The pressure vessel may be made of aluminum or aluminum alloys.

This allows a construction of lightweight construction materials, in particular aluminum and aluminum alloys. Aluminum is a not only lightweight, but also inexpensive construction possible.

In a favorable embodiment, a flow distribution element is arranged in an inflow region of the pressure vessel, which distributes the inflowing gas over the entire width of the heating element. The flow distribution element may consist of a double cone or perforated disks, a grid, guide plates or a diverging inlet section.

Highly compressed gas has a high density and at the same flow cross section and same mass flow compared to non-compressed gas, a significantly lower flow velocity. Therefore, when using compressed gas under otherwise identical conditions, the flow resistance is significantly lower and the driving force for a uniform distribution of the gas over the entire flow cross section is missing. In order to ensure a uniform flow of the heating element, therefore, the gas flow through the flow distribution element is distributed evenly over the cross section of the pressure vessel.

In a favorable embodiment, the heating element consists of electrical heating wires.

Such a heating element in the form of a so-called filament heater is electrically heated and advantageously produces no combustion residues.

In a favorable embodiment, the heating wires on power supplies, which are resistant to heat and have heat-resistant passages through the wall of the pressure vessel.

As a result, already heated gas can be supplied to the device for high-pressure gas heating, since the power supply lines do not have to be in a cold gas flow.

In a favorable embodiment, the device forms a replaceable unit with easily detachable connections for the gas supply and gas discharge.

This makes it possible to connect several devices in series, in particular if the gas supply connection fits to the gas discharge connection. This allows a flexible adaptation to the required performance and the achievement of very high gas temperatures. Finally, a simple replacement in case of repair is possible.

The pressure vessel can be designed for pressures of 25 to 60 bar and the heating element can heat the gas to 700 ° C to 900 ° C.

Advantageously, the device for high-pressure gas heating then works in favorable for cold gas spraying temperature and pressure ranges. Higher gas temperatures increase the speed of sound of the gas and thus the flow rate in a nozzle e.g. a coating device. Particles are accelerated more and bounce at a higher speed on a substrate to be coated. Also, the particle temperature at impact is higher. The particle material is thermally softened and ductilised. Higher gas pressures lead to a higher gas density in the gas flow, and thus promote the acceleration of the particles, in particular the acceleration of coarser particles. Coarser particles (25 to 100 μm in diameter) are very important for producing high-quality coatings.

The object is also achieved by a coating device for substrate materials in which at least one device for high-pressure gas heating is present. One or more of the high-pressure gas-heating devices can be arranged in or on a spray gun and further can be arranged in a stationary part of the coating device, which are then connected in series via a hot gas hose to the spray gun.

As a result, a high gas temperature is achieved and still a low weight of the spray gun.

Fig. 1

schematisch eine erfindungsgemäße Vorrichtung als rotationssymmetrisches Bauteil im Längsschnitt und

Fig. 2

bis Fig. 6 schematisch weitere Ausführungen des Strömungsverteilungselements der erfindungsgemäßen Vorrichtung der Fig. 1 im Längsschnitt.

An advantageous embodiment of the device according to the invention for high-pressure gas heating is explained in more detail with reference to the accompanying drawings. Show

Fig. 1

schematically a device according to the invention as a rotationally symmetrical component in longitudinal section and

Fig. 2

to Fig. 6 schematically further embodiments of the flow distribution element of the device according to the invention of Fig. 1 in longitudinal section.

Fig. 1 shows schematically a device according to the invention as a rotationally symmetrical component in longitudinal section, which is used in the present example in a coating apparatus for cold gas spraying. The pressure vessel 1 has on its inside an insulation 2. Inside the pressure vessel 1, a heating element 3 is arranged, here in the form of a filament heater, which consists of a plurality of electrical heating wires. The gas to be heated is supplied to the pressure vessel 1 via a gas supply line 4. In the present example, the pressure vessel 1 is a rotationally symmetrical body, in which a double cone 5 lying in the gas stream indicated by the arrows ensures a uniform distribution of the gas over the cross section of the heating element 3. The heated gas is led out of the pressure vessel 1 via a gas outlet 6. Outside surface areas 7 are in direct contact with the ambient air. The inventive device for high-pressure gas heating forms a standardized unit that is easily replaceable, z. B. in case of repair, or to arrange several consecutively. Also, the heating element 3 can be configured as easily replaceable heating cartridge. As a result, the heating element 3 can be easily replaced in case of repair.

The gas flows through the pressure vessel 1, wherein it is distributed uniformly over the cross section of the heating element 3 by the double cone 5, as shown by the arrows. Due to the internal insulation 2 is achieved that only a small amount of heat energy reaches the wall of the pressure vessel 1. At the same time heat of the pressure vessel 1 is discharged to the environment via the outer surface regions 7, so that the pressure vessel 1 is cooled and has a considerably lower temperature than the heated gas. The pressure vessel 1 can therefore be relatively thin-walled and lightweight. When the temperature at which the gas is to be heated changes, the device according to the invention reacts quickly and without delays. The mass of the pressure vessel can not delay because of the internally mounted insulation.

The design of the device for high pressure gas heating, such as strength of the insulation, gas distribution, heating via heating wires allows for compact design and high power density reaching very high gas temperatures for a wide range of gas pressures.

FIGS. 2 to 6 schematically show further embodiments of the flow distribution element of the device according to the invention of FIG. 1 in longitudinal section. Schematically illustrated is the front part of the pressure vessel 1 with the gas supply line In FIG. 4, a perforated disc 10 is arranged so that it causes a uniform gas distribution, and in FIG Gas through a combination of double cone 5 and the perforated disc 10 distributed. Finally, Fig. 6 shows an embodiment in which the pressure vessel 1 in the region which adjoins directly to the gas supply line 4, is designed as a divergent inlet section 11.

The high pressure gas heating apparatus of the present invention may also be used in other areas where high pressure gases must be heated, such as atomizing melts with hot gases.

The inventive device for high-pressure gas heating allows a compact design with length to diameter ratios between 1 and 5 and high power densities of 1 to 8 kW / kg at a high power volume of eg 5 to 25 kW / l. The design of the device as a unit allows quick replacement of a defective high pressure gas heating device. With the device according to the invention particularly favorable impact temperatures of the sprayed cold spray particles between 200 and 600 ° C can be achieved with high impact speed by gas temperatures of 600 to 1100 ° C, in particular from 800 to 1100 ° C can be very flexibly selected.

LIST OF REFERENCE NUMBERS

1

pressure vessel

2

insulation

3

heating element

4

gas supply

5

double cone

6

gas discharge

7

Outside area

8th

grid

9

guide plate

10

perforated disc

Claims (18)

Apparatus for high-pressure gas heating with a pressure vessel (1) through which gas flows, a heating element (3) arranged in the pressure vessel (1) and an insulation (2), characterized in that the insulation (2) is arranged on the inner wall of the pressure vessel (1) and means for heat dissipation of the pressure vessel (1) are provided, so that the pressure vessel (1) has a lower temperature than the heated gas. Apparatus according to claim 1, characterized in that the means for heat dissipation with the ambient air directly in contact outer surface areas (7) of the pressure vessel (1). Apparatus according to claim 2, characterized in that on the outer surface areas cooling ribs are integrally formed. Device according to one of the preceding claims, characterized in that the heating element (3) heats the gas to 100 ° C to 1100 ° C, preferably to 700 ° C to 900 ° C. Device according to one of the preceding claims, characterized in that the pressure vessel temperature is less than 600 ° C. Apparatus according to claim 5, characterized in that the pressure vessel consists of steel and / or titanium and / or a titanium alloy. Apparatus according to claim 5, characterized in that the pressure vessel temperature is less than 200 ° C. Apparatus according to claim 7, characterized in that the pressure vessel consists of aluminum and / or an aluminum alloy. Device according to one of the preceding claims, characterized in that in an inflow region of the pressure vessel (1) a flow distribution element is arranged, which distributes the inflowing gas over the entire width of the heating element (3). Apparatus according to claim 9, characterized in that the flow distribution element consists of a double cone (5). Apparatus according to claim 10, characterized in that the flow distribution element of perforated discs (10), lattices (8), guide plates (9) and / or a diverging inlet section (11). Device according to one of the preceding claims, characterized in that the heating element (3) consists of electrical heating wires. Apparatus according to claim 12, characterized in that the heating wires have power supply lines which are heat-resistant and have heat-resistant passages through the wall of the pressure vessel. Device according to one of the preceding claims, characterized in that the device forms a replaceable unit with easily detachable connections for the gas supply and gas discharge, Device according to one of the preceding claims, characterized in that the pressure vessel (1) for pressures of 15 to 100 bar, preferably from 25 to 60 bar is designed. Coating device for substrate materials, characterized in that at least one device for high pressure gas heating according to one of the preceding claims is present. Coating device according to claim 16, characterized in that at least one device for high-pressure gas heating according to one of claims 1 to 15 is arranged in a spray gun. Coating device according to claim 17, characterized in that at least one further device for high-pressure gas heating according to one of claims 1 to 15 is arranged in a stationary part of the coating device and is arranged in a gas supply with the device for high-pressure gas heating in the spray gun in series.

Images