RU2282839C2 - Mechanical impact test board for objects - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: stand has one or several cylindrical shafts, mounted horizontally and connected together. Explosion chamber with explosive are mounted for longitudinal movement inside channels of edges meeting the impact. Explosion chambers are provided at one end with output holes for removing products of explosion. Stand also has impact plate mounted for interaction with tested object. Impact plate is fastened to edge surface of one or several shafts. Shafts are made closed at both edges. Shafts are mounted for horizontal movement directed to tested object. Length of any shaft is made to exceed length of explosion chamber at least twice. Channels of shafts in middle part are provided with extension which has length to exceed length of explosion chamber. Output holes of explosion chambers are directed to impact plate. Outer diameter of explosion chambers and internal diameter of brake departments are made to provide movement of explosion chambers in brake departments to have space relatively channel of shaft.

EFFECT: simplified design; reduced cost of stand.

4 cl, 2 dwg

Description

The invention relates to testing equipment, and in particular to devices for testing objects for mechanical shock. The stand can be used to test packages of dangerous goods and vehicles for collision with obstacles.

A well-known stand for testing mechanical systems for impact (USSR author's certificate No. 1538079, IPC 5 G 01 M 7/00, publ. 23.01.90 in bull. No. 3). The stand contains a base, a flyover with guides, a hammer in the form of a cart on wheels, mounted in the guides with the possibility of free movement in them, a hammer that transfers the shock load from the hammer to the test object, a device for securing the test object and a hammer lifting mechanism. The test is performed by lifting the hammer in the rails to a predetermined height and then dumping it. A free-falling hammer dynamically loads the test object with a hammer.

The disadvantages of this stand are the low speed of impact and overall mass restrictions that do not allow to experience large-sized objects, such as vehicles.

Explosion energy is used in a number of booth designs to increase impact speed. Explosive-type shock stands are known, published, for example, in the review: S. A. Novikov, V. A. Petrov "Explosive-type installations for mechanical testing of materials and structures", Moscow, TsNIIatominform, 1989, 37 pp. In these stands, for the acceleration of the projectile and the dynamic loading of samples of materials and structures, the energy of explosive products of explosives localized in the explosive chamber is used. This allows you to create high-speed relatively simple in design and compact shock stands.

The closest in technical essence to the claimed technical solution is a small-sized multi-module impact stand selected as a prototype, shown in Figure 12, page 22 of this review.

The stand contains a package of several horizontally mounted cylindrical shafts, rigidly interconnected into a single assembly and playing the role of working cylinders, inside of which explosive chambers are placed with the possibility of their free movement in the direction of impact, playing the role of pistons. The package of trunks on the side opposite to the direction of impact is connected to an inert mass.

The cameras contain a working explosive charge and communicate through the bypass (output) holes with the working volume of the barrel. Explosion chambers on the side of the impact are connected to a massive impact plate, which, when the stand is in operation, accelerates to a predetermined speed and makes an impact on the test object.

The test object is located at a certain distance from the stand on the side of the impact and interacts with the shock plate by means of a porous damper, which serves to form a predetermined temporal profile of the shock load.

The stand also contains braking devices for mutual braking and stopping of inertial and shock masses after completion of the main phase of the loading process. The brake devices use disposable foam dampers. The stand also contains, if necessary, a braking device for stopping the test object.

Thus, in fact, the stand itself, with the exception of the test object, contains two moving parts: inert and shock masses, which, when the stand is in operation, move relative to each other in the opposite direction under the influence of internal forces. The mass of the test object is small in comparison with the mass of the parts of the stand, so its effect on their movement is small. In this case, the center of mass of the stand both during acceleration and during braking remains approximately stationary.

The stand works as follows. Explosive charges in all explosive chambers are simultaneously blown up, after which the products of the explosion, flowing from the blasting chambers into the barrels at the ends of the chambers, accelerate the inertial and shock masses in opposite directions, dynamically loading the test object. After completion of the main loading phase, brake devices are connected that mutually brake both masses relative to each other until the stand is completely stopped.

The advantages of this stand are compactness and isolation of the mechanical system of the stand, which eliminates the need for external stops, which greatly simplifies the installation and fixing of the stand.

The disadvantages of the stand that interfere with the solution of the task are:

- The presence of complex braking devices that use disposable dampers, the cost of which increases significantly with increasing size of the stand.

- The presence of a large inert mass, the necessary value of which increases in proportion to the second degree of the mass of the test object. This follows from the fact that for the adequacy of the test conditions on the bench to the full-scale conditions of impact with an obstacle, the shock mass of the test bench should be 5 ... 10 times the mass of the test object, and to reduce the energy of inert mass recoil, the latter, in turn, should be 5. ..10 times the impact mass. Thus, the total mass of the stand should be 25 ... 100 times the mass of the test object.

Due to these shortcomings, the stand adopted as a prototype does not allow increasing its size so that it would be possible to experience large-sized objects such as motor vehicles.

The claimed invention is aimed at solving the technical problem of expanding the field of application of explosive shock stands in the direction of a significant increase in the dimensions and mass of the tested objects.

Achievable technical result is to simplify the design and reduce the cost of the stand for impact testing of large objects.

To solve this problem, a stand for testing objects for mechanical shock is proposed, which contains one or more cylindrical trunks installed horizontally and connected to each other, in the channels of which explosive chambers with explosive charges are mounted with the possibility of longitudinal movement with the possibility of longitudinal movement, equipped with one of the ends of the outlet for explosion products, a shock plate mounted with the possibility of interaction with the test object, different from prototype of the following features:

1. The shock plate is mounted on the end surface of one or more barrels.

2. The trunks are made closed at both ends.

3. The trunks are installed with the possibility of horizontal movement in the direction of the test object.

4. The length of each barrel is made at least twice the length of the explosive chamber.

5. The barrel channels in the middle part are provided with an extension, the length of which is greater than the length of the blasting chamber.

6. The outlets of the blast chambers are directed towards the shock plate.

7. The outer diameter of the blast chambers and the inner diameter of the brake compartments of the barrel channels are made from the condition of ensuring the movement of the blast chambers in the brake compartments with a gap relative to the barrel channel.

8. The diameters of the channels of the trunks in the brake compartments can be made smoothly increasing in the direction of the rear ends of the trunks.

9. At the rear in the direction of impact the ends of the trunks can be made throttle holes.

10. Inert masses can be attached to the explosive chambers from the rear in the direction of impact of the ends.

These differences allow us to solve the problem as follows.

The horizontal movement of the trunks and the installation of the shock plate directly on the end surfaces of the trunks allows you to load the test object directly with a package of trunks with a shock plate, the mass of which is significantly higher than the shock mass of the prototype. In this case, the mass of the stand increases with the mass of the test object in direct proportion, and not in proportion to the second degree, as is the case in the prototype. This makes it possible to test large and massive objects with the mass of the stand exceeding the mass of the object by 5 ... 10 times, and not by 25 ... 100 times, as in the prototype.

The execution of the barrels closed at both ends allows you to form a closed two-mass mechanical system of the stand, where the first mass is the barrels with a shock plate mounted on their ends, and the blasting chambers together represent the second mass. At the same time, the center of gravity of the closed two-mass mechanical system of the stand during operation remains approximately stationary.

The execution of the barrels along the length of not less than twice the length of the blasting chambers provides the possibility of large movements of the blasting chambers inside the barrels during operation of the stand. The movements of the blast chambers inside the test bench are made up of the displacements of both masses of the system in all phases of the test bench work: mass acceleration, their free movement during the collision of the test bench with the test object and subsequent braking. The specific lengths of the barrels, explosive chambers, areas of acceleration, free movement and braking are determined by the calculation-experimental method. When trunks are executed along the length of less than twice the length of the blasting chambers, the bench parameters become non-optimal.

The location of the blast chambers in the initial position in the barrel channels at the front ends (facing the test object) and the outlet from them in the same direction is necessary so that the barrel package with the shock plate installed on it starts moving when the stand is started towards the test object. This determines the acceleration (front) and brake (rear) compartments of the trunks.

The supply of the internal channels of the trunks with expansion in their middle part over a length exceeding the length of the blast chambers allows the products of the explosion of working charges to freely flow around the blast chambers from the booster compartment in the brake chamber when the blast chamber is in the expanded part of the barrel bore in the phase of free mass movement.

When the stand is launched (undermining the working charges), the explosive chambers and barrels accelerate in opposite directions under the influence of the pressure of the explosion products. When the front (facing toward the impact to the test object) exit of the end of the blast chamber from the booster compartment to the expanded part of the barrel, acceleration ceases, and the explosion products flow around the blast chamber from the booster compartment into the brake compartment. The test object should be located in front of the bench at a distance where the package of trunks reaches maximum speed (approximately half the length of the booster compartment). Mutual braking of explosive chambers and barrels is carried out by compressing the explosion products in the brake compartments. In this case, the explosion products enter the brake compartments of the trunks during the movement of explosive chambers along their extended part. Since only part of the explosion products is used for braking, the braking distance (length of the brake compartment) must be significantly greater than the acceleration path (length of the acceleration compartment).

The implementation of the outer diameters of the blast chambers and the inner diameters of the brake compartments of the barrel channels from the condition of ensuring the movement of the blast chambers in the brake compartments with a gap relative to the barrel channels allows throttled compressed gases through it during braking. As a result, the bulk of the energy of motion is irreversibly consumed, and the energy of elastically compressed gases at the end of braking causes the explosion chambers to be reflected in the opposite direction at a much lower speed. The gap should be determined by calculation and experimentally, based on the conditions for minimizing the reflection speed of the blasting chambers and the guaranteed absence of collision of the blasting chamber with the barrel, which is unacceptable due to possible breakdown of the stand. After reflection from the rear end of the barrel, the explosive chambers move relative to the barrel in the opposite direction with much lower energy and are braked in the acceleration compartment in a similar way. The process, fading, can be repeated until it stops.

The diameter of the brake compartment of the barrel can be made gradually increasing towards the rear end. This allows you to gradually increase the gap between the blast chamber and the bore for some equalization of the braking force of the chambers as they move, which reduces the maximum pressure in the barrel.

At the ends of the trunks from the side opposite to the direction of impact, throttle openings can be made, communicating the internal volume of the trunks with the atmosphere. It can also help reduce the maximum gas pressure at the end of braking.

To increase the mass of the blast chambers, which is necessary to optimize the parameters of the stand, based on its specific purpose, inert masses can be attached to them from the side opposite to the direction of impact. In this case, the outer diameter of the inert masses must be equal to the outer diameter of the explosive chambers.

The design of the inventive stand in the initial position is shown in figure 1. Figure 2 shows a view of the shock end of the stand.

The stand contains trunks 1, rigidly connected in a single package, closed at both ends with plugs 2, mounted with the possibility of horizontal movement towards the test object 7 along guides 9, explosive chambers 3 with explosive charges 4 installed inside the trunks 1 at the front in the direction of impact ends (directed to the test object 7) with the possibility of longitudinal movement. At the blast chambers 3 in the end facing the test object 7, an outlet 5 was made for the explosion products to exit into the cavity of the barrel 1. In the middle part of the trunks 1, their internal channels expanded 8 over a length exceeding the length of the blast chambers 3. Barrel length 1 performed at least twice the length of the blasting chambers 3. Directly on the end surfaces of the shafts 1 mounted shock plate 6. In front of the shock plate 6 is the test object 7.

When the explosive charges 4 are triggered, the gaseous products of the high-pressure explosion flow out of the blasting chambers 3 through the outlet openings 5 into the internal cavity of the shafts 1. Under the influence of the pressure of the blasting products, the shafts 1 and the blasting chambers 3 accelerate to a certain speed in opposite directions. A package of trunks 1 with a shock plate 6, interacting with the test object 7, loads it. When the front ends in the direction of impact (facing the side of impact) of the ends of the explosive chambers 3 from the booster compartments into the extension of 8 trunks 1, acceleration ceases. The gaseous products of the explosion begin to flow along the expansion of the 8 internal channels of the trunks 1 from the booster compartments into the brake compartments. After the rear ends of the blast chambers 3 are displaced in the direction of impact, the brake compartments of the trunks 1 are compressed and the gaseous products of the explosion are compressed by the moving blast chambers 3, due to which the brakes 1 and chambers 3 are mutually braked.

In the case of the diameter of the brake compartments of the trunks 1 gradually increasing towards the end, or if the ends of the trunks 1 have throttle openings communicating the internal volume of the trunks 1 with the atmosphere, throttle of the explosion products occurs through a smoothly increasing gap or throttle openings, which reduces the maximum pressure in the barrel.

The attachment of inert masses to the explosive chambers allows to optimize the speed of the explosive chambers and barrels, as well as the mass of the entire stand.

The authors calculated the parameters of a bench consisting of four shafts, which allows mechanical impact testing of objects weighing up to 1000 kg at an impact speed of up to 28 m / s. Below are the received parameters of the stand.

Barrel length - 10660 mm. The diameter of the barrel bore in the booster compartment is 330 mm. The acceleration compartment is 800 mm long. The diameter of the expansion of the bore is 357 mm. The length of the extension of the bore is 7500 mm. The diameter of the barrel bore at the beginning of the brake compartment is 330 mm. The diameter of the bore at the end of the brake compartment is 335 mm. The length of the brake compartment is 1400 mm. The length of the blasting chamber is 4160 mm. The diameter of the explosive chamber is 328 mm. Length × width × thickness of the shock plate - 1000 × 1000 × 80 mm. The total mass of the trunks with a shock plate is 6200 kg. The total mass of explosive chambers is 6040 kg.

Thus, the proposed stand for testing objects for mechanical shock under equal test conditions has many times less mass than the prototype, which allows its use for testing large-scale objects. Due to the exclusion of braking devices with disposable foam dampers, and the exclusion of inert mass attached to the package of trunks, this stand is simpler and cheaper than the prototype.

Claims (4)

1. A test bench for testing objects for mechanical shock, containing one or more cylindrical shafts installed horizontally and connected to each other, in the channels of which explosive chambers with explosive charges are mounted with the possibility of longitudinal movement at the front in the direction of impact of the ends, equipped with an outlet on one of the ends a hole for explosion products, a shock plate installed with the possibility of interaction with the test object, characterized in that the shock plate is mounted on the end surface The spans of one or several barrels that are closed at both ends, the barrels are mounted with the possibility of horizontal movement towards the test object, the length of each barrel is made at least twice the length of the blast chamber, the barrel channels in the middle part are provided with an extension, the length of which is longer than the length the blast chamber, the outlet openings of the blast chambers are directed towards the shock plate, while the outer diameter of the blast chambers and the inner diameter of the brake compartments of the barrel channels s from the condition of ensuring the movement of explosive chambers in the brake compartments with a gap relative to the drip of the barrel. 2. The stand according to claim 1, characterized in that the diameters of the channels of the trunks in the brake compartments are made gradually increasing in the direction of the rear ends of the trunks. 3. The stand according to claim 1 or 2, characterized in that in the rear in the direction of impact the ends of the trunks made throttle holes. 4. The stand according to claim 1 or 2, characterized in that inert masses are attached to the explosive chambers from the rear in the direction of impact of the ends.

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