RU2660873C1 - Device for washing the sand-polymer mandrel out of the missile engine body - Google Patents

Abstract

FIELD: rocket engineering.

SUBSTANCE: invention relates to a device for washing a sand-polymer mandrel out of a missile engine body. Technical result is achieved by an adaptation for washing away the sand-polymer mandrel from the missile engine body after winding its power shell, which contains a lid mounted on the flange of the missile engine body, with holes through which the steam supply lines pass into the housing. Moreover, the lid is made in the form of a removable bottom placed in the shell of the rocket engine of the cup, equipped with a flange, connected to the flange of the casing.

EFFECT: technical result is a reduction in the temperature of the material massif of the thermal protective coating of the RDTT body in the vicinity of the flanges during the washing process of the forming part of the mandrel by means of steam.

1 cl, 6 dwg

Description

The invention relates to mechanical engineering and can be used in the manufacture of the housing of a rocket engine of solid fuel (solid propellant rocket engine).

A known stand (prototype) for leaching a sand-polymer mandrel from the body of a solid propellant rocket engine [Vorobei V.V., Markin V.B. / Fundamentals of technology and design of rocket engine housings. - Novosibirsk: Nauka, 2003. - 164 p., Pp. 61-62].

The stand works as follows: the RDTT case with a washable sand-polymer mandrel inside is mounted horizontally on the stand’s lifting frame, fixed on it. Then, a flat cover with a steam supply pipe is installed on one of its flanges, after which the lifting frame of the stand assembled with the solid propellant housing is turned over into a vertical position, fixed, steam is supplied through the cover, and the mandrel washing process begins. The mandrel material is softened and poured through the unclosed flange of the solid propellant rocket motor.

The disadvantage of this stand is that during washing, the material of the mandrel softens unevenly, unclean pieces of the mandrel when they fall inside the solid propellant rocket motor from a height equal to the length of the mandrel mechanically affect the inner surface of the heat-protective coating (TP) and flanges.

The second disadvantage of this stand is its high cost, complexity and large dimensions. Hydraulic cylinders or bridge cranes are used for tilting the frame. Hydraulic cylinders require an expensive and complicated hydraulic system. Overhead cranes must have a large lifting capacity and require a considerable height of the room. Both canting methods significantly increase the leaching process.

The third disadvantage of this stand is that when the forming part of the mandrel is washed out, the steam contacts the entire inner surface of the solid propellant rocket engine body - with the heat transfer element and flanges, and heats them. Outside, the solid propellant cooler is cooled by atmospheric air. In the region of the flanges, the thickness of the shell and the thermal current transformer is greater than in the middle part; therefore, the bulk material of the thermal current transformer in the region of the flanges has a higher temperature than in the middle part of the solid propellant rocket motor housing. The temperature effect worsens the properties of the polymeric materials from which the solid propellant body elements are made. A metal flange, which has a higher thermal conductivity than polymeric materials, conducts heat to the zone of contacting surfaces of the thermal protection layer and the shell, and the material of the thermal protection layer is subjected to a more intense temperature effect than in the contact zone of the surfaces of the thermal protection layer and the shell. When heated, a complex stress-strain state arises, caused by the difference in their thermophysical properties, which can lead to delamination of the material of the heat-transfer agent in the contact area of the surfaces of the flange, heat-transfer agent and the shell and delamination along the contacting surfaces of the flange, heat-transfer agent and the shell.

An object of the invention is to reduce the temperature of the mass of material of the thermal protection material of the solid propellant rocket motor housing in the region of the flanges in the process of washing the forming part of the mandrel with steam.

The technical result consists in the fact that a glass with a removable bottom is installed in the flange of the RDTT case, which insulates the inner surface of the flange and the end face of the heat exchanger from direct contact with steam and removes excess heat to the surrounding atmosphere.

The technical result is achieved by the fact that the device for washing the sand-polymer mandrel from the rocket engine housing after winding its power shell contains a lid mounted on the flange of the rocket engine housing with holes through which the steam supply pipelines pass into the housing, the cover is made in the form of a removable bottom, placed in the housing of the rocket engine of the glass, equipped with a flange connected to the flange of the housing.

The glass is mounted coaxially in the housing based on the cylindrical part along its flange. It separates the inner surface of the flange and the end face of the TZP from direct contact with steam and is made in such a way that the gap between the cylindrical part of the glass, the inner surface of the flange, and the end of the TZP is minimal. The heat transferred from the inner surface of the heat exchanger to the flanges is transferred to the cylindrical part of the glass, the inner surface of which is constantly washed by atmospheric air. The temperature of the flange is reduced, which reduces the thermal effect on the material TZP in this area.

The bottom is made in the form of a plate and has holes in which pipelines with shutoff valves are installed. This allows an adjustable steam supply inside the solid propellant rocket motor housing.

The bottom is removable. This allows you to carry out the necessary manipulations in the internal cavity of the housing, for example, visual control of the degree of erosion of the mandrel, without dismantling the glasses, which requires force on the threaded holes and the inner surfaces of the flanges and ends of the TZP.

Using the proposed design of the device allows to realize a decrease in the temperature of the mass of the material of the TZP of the solid propellant rocket motor in the area of the flanges in the process of washing the forming part of the mandrel with steam. The number of force impacts on the threaded holes and the inner surfaces of the flanges and ends of the heat exchanger is also reduced, it is possible to adjust the flow rate of steam supplied into the housing. When extracting the remnants of the blurry mandrel, the glass protects the inner surface of the flange and the end face of the TZP from mechanical stress. The undisturbed pieces of the mandrel fall inside the solid propellant rocket motor housing from a height equal to the diameter of the housing, and not its height. Drop occurs on the layer of softened material, and not on the heat-transfer layer, which reduces the level of mechanical stress on its inner surface.

The proposed construction is illustrated in FIG. 1-6.

In FIG. 1 shows a housing structure with a mandrel inside.

In FIG. 2 shows the extension element A of FIG. one.

In FIG. Figure 3 shows a general view of two devices in the process of washing out the mandrel with steam from the solid propellant body.

In FIG. 4 shows the remote element B of FIG. 3 - the design of the device.

In FIG. 5 shows the design of the glass.

In FIG. 6 shows the construction of the bottom of the glass.

The device is installed on the body of the solid propellant rocket motor 1, consisting of TZP 2, the power shell 3, front 4 and rear 5 flanges having threaded holes 6 and inner surfaces 7 that are aligned with the ends 8 of the heat-insulating slurry 2. Inside the body of the solid rocket motor 1 there is a mandrel 9 to be removed . The device consists of a cylindrical glass 10, the bottom 11, assembled through gaskets 12 with bolts 13, and through gaskets 14 it is installed on the front flange 4 coaxially to the inner surface of the TZP 7 using bolts 13.

The glass 10 is made of an external connecting flange 15 having smooth holes 16 located coaxially with the threaded holes of the flange 6, the shell 17 and the internal connecting flange 18, made in one piece with the shell 17 and having threaded holes 19, coaxially with the smooth holes 20 in day 11.

The bottom 11 has openings 21 in which pipelines for supplying steam 22 with atomizers 23 are installed, pipelines for removing steam 24 and shutoff valves 25.

The manufacture of the device can be carried out as follows.

As the material of the parts of the device, a material with good thermal conductivity, for example, aluminum alloy, can be used. Gaskets 12, 14 can be made, for example, of heat-resistant rubber.

The glass 10 is assembled in three parts by welding the connecting flanges 15 and 18 with the rim 17. Then the surface is machined and the holes 16 and 19 are opened.

The bottom 11 can be made by welding with pipelines 22 and 24, pre-installed in the holes 21 and with the nozzles 23. Then open the holes 20 and install shutoff valves 25.

The proposed design operates as follows.

The solid propellant housing 1 is set horizontally. Then, in turn, two devices are assembled on the front and rear flanges 4, 5.

Installing the device on the front flange 4: the glass 10 is installed in the flange 4, the holes 6 and 16 are aligned, after which the glass 10 is fixed with the flange 4 with bolts 13. The gap between the glass 10 and the flange 4 is monitored, which guarantees the installation of the glass 10 without distortion. Then, a gasket 12, a bottom 11 is installed in the glass 10 and fastened with bolts 13. The second device is mounted on the rear flange 5 in the same way.

After assembling the devices inside the housing 1 through two pipelines 22 and nozzles 23, steam is supplied, the leaching of the mandrel 9 begins. The steam consumption is regulated by the fittings 25 on the pipelines 22, 24.

If it is necessary to carry out manipulations in the internal cavity of the housing 1, the steam supply is stopped, its excess is discharged through pipelines 24. The bolts 13 are unscrewed, the bottom 11 is removed from the cup 10. After the manipulations are completed, the device is assembled in the reverse order, steam is supplied, and the process of washing out the mandrel 9 continues .

At the end of the leaching of the mandrel 9, the steam supply is stopped, its excess is discharged through the pipelines 24. The bolts 13 are unscrewed, the bottom 11 is removed from the cup 10. From the housing 1, the remnants of the washed mandrel 9 are removed. The bolts 13 are unscrewed and the cups 10 are removed from flanges 4 and 5.

Thus, the design of the proposed device allows to reduce the temperature of the array of material TZP housing RDTT in the flange region in the process of washing the forming part of the mandrel with steam. Reduces the number of effects on the flanges of the housing during the necessary manipulations in the internal cavity of the housing. When extracting the remnants of a blurred mandrel, the glasses protect the inner surfaces of the flanges and the ends of the TZP from mechanical influences.

Claims (1)

A device for washing a sand-polymer mandrel from a rocket engine housing after winding its power shell, comprising a cover mounted on a flange of a rocket engine housing with holes through which steam supply pipelines pass into the housing, characterized in that the cover is made in the form of a removable bottom located in the housing of the rocket engine of the glass, equipped with a flange connected to the flange of the housing.

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