RU190224U1 - SEIS-SOUND-RESISTANT GAS FIRE EXTINGUISHMENT MODULE - Google Patents

Abstract

The utility model relates to gas fire extinguishing equipment used in areas with seismic hazards, in fortifications or mobile special-purpose equipment, and for general use, where dynamic impacts on the mounting base are possible. In particular, the utility model relates to gas extinguishing modules based on the use of metal composite cylinders. The problem solved by the utility model is to create an earthquake-resistant gas extinguishing module in which the metal composite cylinder is protected from both the inertial dynamic forces of the seismic wave and mechanical damage from local impact the higher reliability of his work is achieved. The solution of this task is achieved by the fact that the seismic shock-resistant gas fire extinguishing module, including tallocomposite cylinder with a locking-starting device and a support shoe, the frame in the form of a rectangular frame, having vertical and horizontal rods, the lugs located on the rods of the frame, is provided with a cylindrical shell covering the side of the cylinder and located inside the frame starting device from the top and sides, inserted into the shell, the lower cradle, covering the cylinder shoe, inserted into the shell, the middle liner, covering the cylinder, also inserted into the shell, and shock absorbers in the form of two single-travel springs mounted along the vertical and horizontal rods of the frame between the shell and the stops, the shock absorbers being connected to the frame and the cylindrical shell by means of ball bearings. 6 Il.

Description

The utility model relates to gas fire extinguishing equipment used in areas with seismic hazards, in fortifications or mobile technical equipment for special purposes and general use, where dynamic impacts on the mounting base are possible. In particular, the utility model relates to gas extinguishing modules based on the use of metal composite cylinders.

In accordance with the current regulatory documentation, in addition to the above requirements, additional requirements are imposed such as maintaining its operability and reliability after falling in a filled form from a certain height or during a local impact with a given impact energy.

Seismic impact or displacement of the mounting base of the fire module with significant accelerations and large amplitudes leads to different inertial loads on the cylinder and the elements of the locking-starting device. These loads can lead to mechanical stresses in the structural elements of the module, to mutual displacements of parts and components, deformation of fasteners, carriers and other structural elements, and their collision.

In addition, under dynamic effects, it is not excluded that the splinters of building structures or parts of the destroyed equipment are contiguous with the subsequent violation of the integrity of the composite shell. The strength characteristics of the metal composite cylinder deteriorate sharply when the composite surface layer is disturbed. For this reason, during operation it is necessary to strictly monitor the integrity of the composite shell, to protect it from impacts and mechanical effects.

To protect against external influences for metal composite cylinders, devices and methods of protection known from the prior art should be used. Known cylinder using special layers of different materials (patent US 5476189, 1993), the implementation of which allows to partially solve the problem of the resistance of the cylinder to the local effects. As an element of construction used to absorb shocks, additional elastic layers made of a viscoelastic material, such as rubber, are used.

A disadvantage of the known solution is that when striking the shell of the cylinder in these structures, the impact is not extinguished from the position of reducing the local force acting on the power shell of the cylinder, and only the local contact area is converted, which allows to partially solve the problem. At the same time, the task of creating a metal-plastic balloon, the design of which ensures its operation at given levels of local dynamic effects that occur when it falls from a certain height or is hit by an object with a certain impact energy, is not solved.

Another well-known technical solution for the protection of a metal-composite cylinder from mechanical external influences (RF Patent No. 2432520 publ. 10/27/2011, Bull. No. 30) contains a thin-walled closed sealing metal liner, a power shell made of composite material formed by a combination of groups of layers of high-modulus reinforcing material, oriented in spiral and circumferential directions, and a protective sheath made of composite material formed by a group of layers of low-modulus filaments of a reinforcing material, while Part of the surface of at least one of the bottoms between the group of layers of high modulus reinforcing materials of the power shell and the group of layers of low modulus reinforcing material of the protective shell is an energy absorbing shock absorber consisting of a rigid profile frame fastened together by a protective shell and a damping device on the side of the power shell .

The layers of the ballistic soft substrate of the damping device can be made from a set of high-strength material damped tapes, fixed and fixed along the chord of the cross section of the ellipsoidal carcass shell, forming a multi-pointed star-shaped configuration, or layers of a soft fabric substrate made of dry high-strength (aramid) fibers fixed to a core frame on the petals of the crown by means of transverse slits in the forming layers of the fabric.

However, this technical solution does not have a combined protection against seismic effects in the form of accelerations and with different frequency and amplitude and local shocks.

This disadvantage is solved in another technical solution, adopted as the prototype of the proposed technical solution (patent No. 89965, publ. 12/27/2009). The basis for the development is the stand of the gas fire extinguishing module, which includes a frame with long and short rods and is designed to accommodate gas cylinders for extinguishing a fire, and sensors for recording the weight of the said cylinder. The principle of operation of the electronic weighing device is as follows: with a gas leak equal to 5% of the mass of the charged gas, the electronic device detects this state by switching the HL1 and HL2 LEDs on the front panel from green to red and generates a signal by closing the output contacts (XS 3) and opening the contacts ( XS 4). These signals are used to transmit information to the controller or board (depending on the wiring diagram).

Known stand can not ensure the preservation of the health of the module during operation with seismic vibrations of the frame, causing movement of each cylinder in the direction across and along the long rods of the frame. The developers have set the task of preserving the module's operability during operation with seismic vibrations by limiting the amount of movement of each cylinder both in the direction across and along the long core bars.

To solve the problem, a gas fire extinguishing module rack is proposed, which includes a frame with long and short rods and is designed to accommodate at least one gas cylinder for extinguishing a fire, and a sensor for an electronic device controlling the mass of the said balloon.

The known module of gas extinguishing using metal composite cylinder has significant drawbacks. When inertial-dynamic forces act on it from a seismic wave, its almost instantaneous impact on stops stops it, which keeps it inside the frame from moving. At the same time, local (concentrated) loads are transferred to the balloon, destroying the surface layer of the composite coating, disrupting the integrity of the shell and the explosion of the balloon. Splinters from the explosion of a module can affect other modules that withstand the effects of seismic waves, and also lead to their exit from working condition. These circumstances reduce the reliability of the module as a whole.

The problem solved by the utility model, and the technical result achieved is to create an earthquake-resistant gas extinguishing module in which the metal composite cylinder is protected from both inertial-dynamic forces of the seismic wave and mechanical damage from local impact, thereby improving its operational reliability.

To achieve the above technical result, a seismic shock-resistant gas extinguishing module comprising a metal composite cylinder with a starting-up device and a support shoe, a rectangular frame frame having vertical and horizontal rods, stops located on the frame rods is provided with a cylindrical shell covering the side surface of the balloon and placed inside the frame, the upper cradle, covering the locking-starting device at the top and sides, inserted into the shell, the lower cradle, cover the cylinder shoe inserted into the shell, the middle liner covering the cylinder also inserted into the shell, and the shock absorbers in the form of two spring springs mounted along the vertical and horizontal frame rods between the shell and the stops, and the shock absorbers are connected to the frame and the cylindrical shell by ball bearings .

Due to the presence of these signs, when the inertial-dynamic forces from the seismic waves are transmitted to the module (base, foundation), the impact force is smoothly extinguished due to the elasticity of the springs that hold the balloon inside the frame from movement. In this case, the load on the cylinder is transmitted through the cradle, which distributes the force on a large surface. Due to this, local (concentrated) loads that destroy the surface layer of the composite coating are practically eliminated, the integrity of the shell is preserved and its explosion is eliminated. In addition, a cylindrical shell made of durable steel or reinforced composite material protects the container from external fragments or objects. This preserves the operational state of the cylinder and the reliability of the module as a whole.

The essence of the utility model is illustrated by drawings, where in FIG. 1-6 shown:

FIG. 1. A longitudinal section of a seismic shock-resistant gas extinguishing module with a metal composite cylinder in the operating position.

FIG. 2. Cross-section of the module at the location of the theoretical center of mass of the balloon in its middle part (section A-A, Fig. 1).

FIG. 3. A longitudinal section of the module and the position of the spring clips at the attachment points of the upper and middle lodgements (view I, Fig. 1).

FIG. 4. A longitudinal section of the spring clip mounted on ball bearings (View B, Fig. 1).

FIG. 5. A longitudinal section of the actual design of the spring clip mounted on ball bearings (View B, Fig. 1).

FIG. 6. Compression diagram of the clip from two compression springs.

The earthquake-resistant gas extinguishing module includes a metal composite cylinder 1 with a shut-off device 2 and a support shoe 3, a frame in the form of a frame 4 (in Fig. 1 is highlighted with a gray background), having vertical rods 5 and horizontal rods 6, abutments 7 located on the rods 5 and 6. The module is also equipped with a cylindrical shell 8, which covers the side of the cylinder and is located inside the frame space 4. Cylinder 1 is installed in the shell 8 by means of three cradles:

- the upper lodgement 9, covering the locking-starting device 2 and the upper part of the cylinder 1 from the top and from the sides;

- the lower lodgement 10, covering the shoe 3 and part of the cylinder 1 from the bottom and from the sides;

- middle lodgement 11, covering the cylinder in the middle cylindrical part.

The shell 8 is provided with an upper power rim 12 and a lower power rim 13, and the stops 7 are mounted with shock absorbers in the form of spring holders 14, installed vertical and horizontal sections of the frame 4. The spring clips 14 are assembled from two springs of different stiffness and different stroke. The internal spring 15 has a working stroke in the zone of elasticity L _n , designed for the perception of nominal (calculated) load Fn, and the internal spring 16 has a stroke ΔL = L _max -L _n , designed for the perception of the maximum load before the shell 8 starts to collapse 7

). Обоймы пружин 14 снабжены шаровыми опорами 17, посредством которых они прикреплены к вертикальным стержням 5 и горизонтальным стержням 6 и шаровыми опорами 18, посредством которых они присоединены к обечайке 8, с возможностью качания относительно горизонтальной (для горизонтально установленных обойм 14) или вертикальной (для вертикально установленных обойм 14) оси.(in Fig. 3, the distance is shown by

). The spring sleeves 14 are provided with ball bearings 17, by means of which they are attached to vertical rods 5 and horizontal rods 6 and ball bearings 18 by which they are attached to the shell 8, with the possibility of swinging relative to the horizontal (for horizontally installed holders 14) or vertical (for vertically the installed yoke 14) axis.

Lodgements 9-11 are made of lightweight durable material suitable for molding, for example, polystyrene foam, foam rubber or polyurethane.

The module is delivered to the installation site assembled and installed in the design position by fixing the rectangular frame 4 on the base or a special stand using bolts or welding (not shown in the figures) for connection to the connecting manifold.

During normal operation in the standard duty mode, the cylinder 1 with the locking-starting device 2 and the support shoe 3 through the lower cradle 10 and the lower power rim 13 rests on the spring clips 14 mounted on the lower horizontal rods 6. The lateral holders of the springs 14 fix the neutral position cylinder 1 through the retaining shell 8.

When the seismic wave acts in the transverse direction, the dynamic load causes the frame 4 to move, the force from moving the frame 4 through the spring clips 14 is transmitted to the rims 12 and 13, and then through the cradle 9, 10 and 11 to the cylinder 1 and the starting and closing device 2. At the same time due to the compressive strength and the adherence to the balloon distributed over the area, the impact force is redistributed and the surface of the composite shell of the balloon 1 is not destroyed. The resulting inertia forces of the cylinder 1 and the locking-starting device 2 may be different, which will lead to uneven compression of the spring holders 14. However, the nature of the work of each spring clip will be the same. First, the inner spring 15 of the spring clip 14 is compressed within the working stroke in the zone of elasticity L _n (Figures 3 and 7), calculated for the perception of nominal (calculated) load F _n . Then, the external spring 16 begins to contract, which is designed to perceive the maximum load F _max , after which the shell 8 comes into contact with the stop 7 and the shell 8 begins to transform, rigid mechanical destruction of the lodgment, and then the composite shell of the cylinder 1.

Since in reality each holder 14 will be compressed according to its operation diagram (due to the shell skewing about a rectangular coordinate axis), the longitudinal axes of the holder 14 will be deflected due to rotation in the ball bearings 17 and 18, transferring the load to the vertical rods 5 and horizontal rods 6

Claims (1)

 Seismo shock-resistant gas fire extinguishing module, including a metal composite cylinder with a starting-up device and a support shoe, a frame in the form of a rectangular frame, having vertical and horizontal rods, stops located on the rods of the frame, characterized in that it is provided with a cylindrical shell covering the side surface of the cylinder and placed inside the frame, the upper cradle, covering the locking-starting device at the top and sides, inserted into the shell, the lower cradle, covering the cylinder shoe, sun An at least one middle liner enveloped in the shell enclosing the cylinder, also inserted into the shell, and shock absorbers in the form of two separate springs mounted along the vertical and horizontal frame rods between the shell and the stops, the shock absorbers being connected to the frame and the cylindrical shell by means of ball bearings supports

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