RU2476808C1 - Ejection device - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: ejection device includes a receiver, a high pressure gas source with a start-up system, and valves. High pressure gas source is installed so that gas can enter the receiver cavity. Valves are installed in the receiver housing. A cylindrical shell is attached with its bottom surface in installation place of each valve on the outside to the receiver so that gas can flow through the valve to its cavity. Each valve is equipped with a stock and a piston, which are arranged inside cylindrical housing with a closed end face. One of the stock ends is made so that is goes tightly through a closed end face of the valve body so that it can be borne against the appropriate ejected object. Piston has the possibility of fixing the specified distance relative to the end face of the valve body and is equipped with symmetrically located through holes. In side wall of the valve body between end faces of the valve body and piston there are symmetrical through holes, the total area of which is larger than or equal to total area of holes in the piston. Distance from inner surface of end face of the valve body to its farthest surface of the hole in side wall of the valve body is smaller than the piston height.

EFFECT: achieving the possibility of group ejection of several objects at specified speeds.

3 cl, 3 dwg

Description

The invention relates to testing equipment and can be used for group discharge of several objects with different speeds.

Known ejection device containing an outer pipe made with the possibility of connection with the carrier, an inner pipe placed coaxially with the first with the possibility of longitudinal movement relative to the first and interact with the ejected object, and a source of high pressure gases (IHVD) located in the cavity formed by the outer and inner pipes. The ejected object is installed with the possibility of interaction with the guides (see S.M. Alekseev et al., "Modern means of emergency escape from an airplane", M., Oborongiz, 1961, p. 123).

Known ejection device containing the first and second elements in the form of glasses, the first element is made with the possibility of connection with the carrier of the ejected object, the second element is placed coaxially with the first with the possibility of longitudinal movement relative to it and interaction with the ejected object; IHVD located on the inner surface of the bottom of the first element in the cavity formed by the first and second elements. Elements with an ejected object are placed in a launch container with guides at the end of which are mounted controlled locks that exclude uncontrolled relative movement of them (see French application No. 2594219, IPC 4 F41F 7/00, 5/02, B64D 1/01, publ. 14.08 .87).

An ejection device containing a receiver made of two coaxially placed elements in the form of glasses with the possibility of longitudinal movement relative to each other, an IHVD with a launch system installed with the possibility of introducing gases into the cavity of the receiver, and a valve installed in the receiver’s body and designed to remove gases from the receiver in the direction of the ejected object. The first and second elements are connected to each other by a bond that is destroyed at a given pressure (see RF patent No. 60197, "Ejecting device", publ. 10.01.2007, Bull. No. 1).

The disadvantage of these devices is the inability to produce a group emission of two or more objects with given speeds. Consistent (after a certain time) conducting an object discharge leads to a decrease in the productivity and accuracy of tests due to experiments, as a rule, in changing meteorological conditions.

The task of the invention is to enable the group ejection of several objects with given speeds.

Effect: increase the productivity of testing and increase their accuracy.

The technical result is achieved by the fact that in the ejection device containing the receiver, the IHVD with a launch system installed with the possibility of introducing gases into the cavity of the receiver, a valve installed in the receiver’s body and designed to discharge gases from the receiver in the direction of the ejected object, unlike the prototype, at least one other valve is installed in the receiver’s body; in the place of installation of each valve, a cylindrical cup is attached to the receiver with the bottom surface so that gases can escape through the valve into its strips s, designed to accommodate the ejected object. Each valve is equipped with a stem and piston located inside a cylindrical body with a closed end. One of the ends of the rod is made passing through the closed end of the valve body with the possibility of abutment in the corresponding ejected object. The piston is made with the possibility of fixing a predetermined distance relative to the end of the valve body and is equipped with symmetrically located through holes. Symmetrically located through holes are made in the side wall of the valve body between the ends of the body and the piston, the total area of which is greater than or equal to the total area of the holes in the piston, and the distance from the inner surface of the end of the valve body to the farthest surface of the hole in the wall of the valve body is less than the height of the piston.

The holes in the walls of the valve body can be made rectangular, with the larger side of the hole parallel to the end face of the piston.

Through the walls of the glasses at given distances from their bottoms, through symmetrically located holes can be made.

Installing into the ejection device containing the receiver, an IHVD with a start-up system installed with the possibility of introducing gases into the cavity of the receiver, a valve installed in the receiver’s body and designed to exhaust gases from the receiver in the direction of the ejected object, at least one valve, the place of installation of each valve from the outside to the receiver with the bottom surface of cylindrical cups with the possibility of gas escape through the valve into their cavity, designed to accommodate the ejected objects, allows Draw a group discharge of objects.

Supply of each valve with a rod and piston placed inside a cylindrical body with a closed end, the execution of one of the ends of the rod passing hermetically through the closed end of the valve body with the possibility of abutment in the corresponding ejected object, the execution of the piston with the possibility of fixing a predetermined distance relative to the end of the valve body and supplying it symmetrically located through holes, the execution in the side wall of the valve body between the ends of the valve body and the piston are symmetrically located through-holes, so that the distance from the inner end surface of the valve body to its surface remote from the hole in the side wall of the valve housing less than the height of the piston, allows the ejected objects with different velocities. The time of arrival of gases acting on the object from the receiver corresponds to the size of the piston stroke (determined by the specified distance of the piston relative to the end face of the valve body) and the object until the valve closes. The larger the stroke, the greater the acceleration speed of the object.

The holes in the walls of the valve body with a total area greater than or equal to the total area of the holes in the piston, allows you to adjust the amount of passage of high pressure gases from the receiver into the glass cavity by selecting the cross-sectional area of the holes in the piston. This also allows, along with the piston stroke, to regulate the value of the ejection velocity of objects.

Making holes in the walls of the valve body rectangular so that the large side of the hole is parallel to the end of the piston, makes it possible to quickly (at a shorter stroke equal to the smaller side of the hole) block the flow of gases from the receiver, which allows to increase the accuracy of determining the value of the acceleration rate of the object.

The implementation in the walls of the glasses at specified distances from their bottoms through symmetrically arranged holes also allows you to increase the accuracy of determining the speed of acceleration of the object by bleeding gases from the cavity of the glasses into the atmosphere after stopping the supply of gas from the receiver (after closing the valve) and, accordingly, reducing difficult to predict overshooting an object.

The invention is illustrated by drawings:

- figure 1 shows a General view of the device (for example, a device for ejecting three objects);

- figure 2 shows the elements of the longitudinal section of the valves;

- figure 3 shows an element of the cross section of the valves.

The ejecting device comprises a receiver 1, IHVD 2 with a launch system (not shown in the figure) installed with the possibility of introducing gases into the cavity of the receiver. Three (in this example) hollow cylindrical cups 3, designed to accommodate the ejected objects 4, are attached to the receiver’s body 1 from the outside by the bottom surface. Valves 5 are installed between the cavities of the receiver 1 and the cups 3. They are designed to discharge gases from the receiver in the direction of the ejected objects 4. Each the valve 5 is equipped with a stem 6 and a piston 7 located inside the cylindrical body 8 with a closed end. One of the ends of the rod 6 is made hermetically passing through the closed end of the valve body 5 and can be abutted against the corresponding ejected object 4. The piston 7 is configured to fix a predetermined distance L relative to the internal end of the body 8 (for example, the piston 7 is connected to the stem 6 by a threaded connection) and equipped with symmetrically located through holes 9. In the side wall of the housing 8 between the ends of the housing 8 and the piston 7 are symmetrically located through holes 10, the total area of which is greater than or equal to the total area of the holes 9 in the piston 7. The distance from the inner surface of the end of the housing 8 of the valve 5 to the surface of the hole 10 farthest from it is made smaller than the height of the piston 7. The holes 10 in the walls of the housing 8 can be made rectangular, with the larger side of the hole parallel to the end piston 7. In the walls of the glasses 3 at predetermined distances from their bottoms can be made through symmetrically located holes 11.

The device works in the following order.

Pistons 7 are fixed at specified distances L ₁ , L ₂ and L ₃ relative to the inner end of the housing 8, in the walls of the glasses 3, respectively, at the same distances L ₁ , L ₂ and L ₃ from the end of the object 4, rectangular holes 11 can be made.

IHVD 2 starts, the cavity of the receiver 1 is filled with high-pressure gases. Gases from the receiver 1 through the openings 9 in the piston 7 and 10 in the wall of the housing 8 flow into the closed volume of the cups 3 and acts on the ends of the objects 4. Under the influence of gas pressure, objects 4 begin to move. Simultaneously with the movement of objects 4, under the influence of gas pressure, the pistons 7 move with the rods 6. When the first object 4 is moved to a distance L _{1, the} piston 7 of the first valve 5 blocks the access of gases to the cavity of the first glass 3 and openings 11 open in the wall of the glass 3 (if they are made ) through which the gases from the cavity of the first glass 3 are vented to the atmosphere. The acceleration process of the first object 4 is terminated. The remaining objects continue to accelerate at displacements L ₂ and L ₃ , respectively. Changing the length of the piston strokes 7 and the gas pressure in the receiver 1, select the necessary speed of the release of objects 4. After departure from the glasses, studies are carried out, for example, the interaction of objects with an obstacle.

Thus, the proposed invention allows the group emission of several objects with different speeds, which makes it possible to increase the productivity of research and increase their accuracy due to experiments in the same meteorological conditions.

Claims (3)

1. An ejection device comprising a receiver, a high-pressure gas source with a start system installed with the possibility of introducing gases into the cavity of the receiver, a valve installed in the receiver body and designed to discharge gases from the receiver in the direction of the ejected object, characterized in that in the receiver body at least one valve is installed, at the place of installation of each valve on the outside, a cylindrical cup is attached to the receiver with the bottom surface so that gases can escape through the valve into its cavity, before assigned to accommodate the ejected object, each valve is equipped with a stem and a piston located inside the cylindrical body with a closed end, one of the ends of the rod is made hermetically passing through the closed end of the valve body with the possibility of abutment in the corresponding ejected object, and the piston is made with the possibility of fixing a predetermined distance relative to the end of the valve body and is equipped with symmetrically located through holes in the side wall of the valve body between the ends of the valve body and the piston symmetrically arranged through holes are made, the total area of which is greater than or equal to the total area of the holes in the piston, and the distance from the inner surface of the end face of the valve body to the farthest surface of the hole in the side wall of the valve body is less than the height of the piston. 2. The ejection device according to claim 1, characterized in that the holes in the walls of the valve body are rectangular, with the larger side of the hole parallel to the end face of the piston. 3. The ejecting device according to claim 1, characterized in that through the symmetrically located holes are made in the walls of the glasses at predetermined distances from their bottoms.

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