RU208664U1 - Impact indicator - Google Patents

Abstract

The utility model relates to measuring technology, namely to shock detection and indication devices, and can be used for visual control of the impact. The shock indicator contains a body element, an inertial mass, a spring holding the inertial mass in the initial state, and a spring fixing the inertial mass in the actuated state. The impact indicator additionally contains windows for monitoring the position of the inertial mass. The inertial mass is made in the form of a massive plate with through holes located opposite the windows for controlling the position of the inertial mass. EFFECT: expansion of the arsenal of technical means of impact indication. 1 ill.

Description

The utility model relates to measuring technology, namely to shock detection and indication devices, and can be used for visual control of the impact.

Known impact indicator for shooting training, containing a light beam module with a switch and a compression device containing a piston at the end remote from the light beam module, and a rod at the other end, which turns on the light beam module switch when air flows on the compression device. Utility model patent of the Russian Federation No. 84242, IPC A63F 9/00, 07/10/2009.

The need to fix the light source in the impact indicator, as well as the complexity of its design, narrows the scope of this technical solution.

A device for indicating the occurrence of pressure is known, comprising a housing, a membrane drive, a movable information link, made, for example, in the form of two parallel shutters with through windows fixed on the rigid center of the membrane drive, backlight elements and an indicator screen made in the form of a set of contour plates made of light-conducting material with an engraving on the front side, directed by their end surfaces to the illumination elements, installed relative to them with a gap in which two parallel curtains with through windows are located. Author's certificate of the USSR No. 393627, 08/10/1973. This technical solution is taken as a prototype.

The prototype relates to security systems, in particular to devices for indicating the fact that mechanical action reaches maximum values. So, when the membrane drive is displaced due to pressure, the curtains with through windows connected with the rigid center of the membrane drive move to the boundary position corresponding to the triggered state of the indicator. Due to the displacement of windows from the ends of one engraved plate to another, the corresponding sign engraved on its front side glows.

The executive element of the presented design is curtains with through windows connected to the rigid center of the membrane drive, which perceives external influences. However, the presence of a light source in the device complicates the design and requires careful positioning of all interacting display elements during the assembly process. In addition, the presence of volatile components, which include light sources, such devices have a limited scope, especially in explosive environments.

The objective of the utility model is to create a device for indicating impacts when they reach the maximum values specified by the physical and geometric properties of the actuating structural elements, made in the form of a simple non-volatile mechanical device with an actuating element in the form of an inertial mass, which does not require complex manufacturing technology, which allows expanding the area its application use, including in explosive environments.

The technical result is the expansion of the arsenal of technical means of impact indication.

The technical result is achieved by the fact that the shock indicator contains a body element, an inertial mass, a spring holding the inertial mass in its initial state and a spring fixing the inertial mass in the actuated state. The impact indicator additionally contains windows for monitoring the position of the inertial mass. The inertial mass is made in the form of a massive plate with through holes located opposite the windows for controlling the position of the inertial mass.

The essence of the utility model is illustrated by the drawing, which schematically shows the shock indicator in the initial (I) and actuated (II) state, where:

1 - body structural element;

2 - inertial mass;

3 - compression spring;

4 - flat crimp spring-clamp;

5 - holes of the inertial mass;

6 - border of the zone of control of the position of the inertial mass (windows of control of the position of the inertial mass).

The shock indicator is a structure containing a body element 1 (shown in the drawing in cross section), and an inertial mass 2, made in the form of a massive plate with through holes 5 located opposite the border of the zone for monitoring the position of the inertial mass 6 (conditionally shown in the drawing by a dotted line ). The inertial mass 2 is kept in the initial state of the impact indicator due to the stiffness of the compression spring 3 from being displaced in the direction opposite to the external impact (acceleration M).

In the initial state of the impact indicator, in the zone of control of the position of its inertial mass 6, only that hole of the inertial mass 2 is visually visible, which is located opposite the window for controlling the position of the inertial mass (in the drawing in the initial state (I), the alignment of one hole of the inertial mass with one window is conventionally shown position control of the inertial mass).

Windows for controlling the position of the inertial mass can be made in the form of simple holes in the body element, or in the form of transparent areas on an opaque plate made of impact-resistant material, such as impact-resistant glass. In order to exclude false indication and ambiguous perception during visual control of the position of the inertial mass, its holes and control windows can be structurally located in zones spaced apart from each other.

For strict orientation of the inertial mass 2 in the vertical plane and to ensure the required trajectory of its movement relative to the control windows 6 under impact, the inertial mass may contain guiding elements, for example, end slots and grooves. To fix the inertial mass in the actuated state of the shock indicator, flat crimp springs-clamps 4 are fixed in the body element 1, and corresponding recesses are made on the outer sides of the inertial mass.

The properties of the compression spring 3, its geometric and physical parameters, as well as the parameters of the inertial mass 2, are selected based on the design features of the shock indicator and its response threshold for the values of external influence (acceleration M) specified in each specific case.

The impact indicator works as follows.

When an external impact on the impact indicator structure exceeds the threshold value determined by the stiffness of the compression spring 3, the inertial mass 2 under the action of the inertial force (Fim) is shifted in the direction opposite to the impact of the external impact (acceleration M). This changes the visually visible number of holes in the zone of control of the position of the inertial mass 6 (in the drawing in the actuated state (II) conditionally shows the alignment of two holes of the inertial mass with two control windows). Fixation of the inertial mass in the actuated state of the impact indicator is ensured by the action of flat crimp springs-clamps 4, the bent ends of which enter the recesses on the outer sides of the inertial mass, which, in turn, provides subsequent visual control of the impact.

The total number of holes in the inertial mass, windows for controlling its position, as well as their relative position in the structure, is selected based on the required geometric shapes of the observed "pattern" (a combination of visible and non-visible holes) in the initial and actuated states of the impact indicator.

The absence of complex mechanical units for moving the moving elements of the impact indicator allows you to reduce the number of parts, thereby increasing the reliability of the device as a whole.

The absence of volatile components in the shock indicator (such as, for example, light sources) allows expanding the scope of its use, including in explosive environments.

The use of an inertial mass as an actuating element, made in the form of a massive plate with through holes, makes it possible to significantly simplify the design and expand the scope of the shock indicator in security systems with visual control of the fact of shock effects.

Claims (1)

Impact indicator containing a body element, an inertial mass, a spring holding the inertial mass in its original state, and a spring fixing the inertial mass in the actuated state, characterized in that the impact indicator additionally contains windows for monitoring the position of the inertial mass, the inertial mass is made in the form of a massive plate with through holes located opposite windows for controlling the position of the inertial mass.

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