RU2512878C1 - Fire preventing barrier - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: fire preventing barrier comprises a direct-flow housing and a composite locking element mounted inside the housing, comprising a locking element itself and a fire damper mounted on the locking element and made wholly or partly of titanium nickelide with reversible effect of shape memory. The damper has a shape not overlapping the opening of the direct-flow housing at a temperature below the temperature of beginning of the reverse martensite transformation, and a shape overlapping the opening of the housing at a temperature above the temperature of end of the reverse martensite transformation. At that the fire damper is made with the ability of the reversible effect of shape memory by treating the damper prior to securing on the locking element, with the cyclic thermal heating and cooling in combination with the deformation.

EFFECT: invention enables to reuse the fire preventing barrier without repeating mounting and replacement of structural elements.

10 cl, 4 dwg

Description

The invention relates to fire fighting equipment, in particular, to devices for blocking fire and combustion products through the channels of ventilation, air conditioning and other ducts.

Various automatic fire blocking systems in channels are known, including devices using materials with a shape memory effect.

Patent RU 2195984 “Fire retardant valve” describes the design of a valve comprising a rotary damper that is prevented from being closed by a hook made of an alloy with a shape memory effect. In case of fire, the hook heats up, straightens and automatically releases the damper, which blocks the path to the fire.

JP 61295455 describes the design of a fire damper. The damper consists of two semicircular sectors that can block the ventilation channel under the influence of a spring. In the initial state, the shutters are brought together and held in this state by a trigger mechanism made of an alloy with a shape memory effect. Under the influence of temperature, the trigger mechanism changes its shape, releases the spring and it opens the shutter flaps that overlap the channel.

JP 11350619 describes a design of a shutter made of an alloy with a shape memory effect. Initially, the shutter installed in the ventilation shaft is attached to the shaft wall and has the shape of a bent plate. Under the influence of the temperature of the fire, the plate straightens and blocks the ventilation passage.

The described structures cannot provide complete blocking of the channel from fire and combustion products. In addition, these designs do not ensure the return of the damper to its original state, which was before the fire, when the fire ended and the damper cooled down.

The design of the patent DE 10157525, publication 5.06.2003, which describes the design of a fire barrier using an element with a direct and reversible (reversible) shape memory effect, is also known. This design contains the actual shutter, held above the hole of the pipeline using a two-layer flexible pipe made of flame retardant material. Between the layers of the pipe there is a spiral of wire made of a material with a shape memory effect. When a certain temperature is reached, the spiral is compressed and the pipe is also compressed and further does not keep the shutter from vertical movement. The hole overlaps. After cooling, the spiral recalls its original shape and the pipe is restored. However, to bring the boom back to its original state, it is first necessary to raise the damper to its original state. This design also does not provide tight closing of the pipeline opening in case of fire.

The closest analogue is the design of the fire barrier according to the patent RU 2470683, publication 12/27/2012, IPC A62C 2/00. This design of the fire barrier includes a direct-flow housing and a composite locking element fixed inside the housing, which includes the actual locking element and the fire damper mounted on the locking element and made in whole or in part of a temperature-resistant material with a shape memory effect. The damper has a shape and dimensions that do not overlap the opening of the direct-flow housing at a temperature below the temperature of the start of mold recovery, and a shape that completely closes the opening of the housing at a temperature above the temperature of complete mold recovery.

The design of the damper according to patent RU2470683 allows you to reliably block the path of the spread of fire and combustion products. However, after the end of the fire, significant costs are required to restore the construction of the fire barrier. It is required to dismantle the fire damper and restore its shape, or replace the damper with a new one.

The aim of this invention is to improve the operational characteristics of the structure that blocks the spread of fire in ventilation systems, by the possibility of reuse of the structure without re-installation and replacement of structural elements after a fire.

The fire barrier includes a direct-flow housing and a composite locking element fixed inside the housing, including the actual locking element and the fire damper mounted on the locking element and made completely or partially of titanium nickelide with a reversible shape memory effect. The damper has a shape that does not overlap the opening of the direct-flow housing at a temperature below the temperature of the beginning of the reverse martensitic transformation, and a shape that blocks the opening of the housing at a temperature above the temperature of the end of the reverse martensitic transformation. In this case, the fire damper is made with the possibility of a reversible shape memory effect by processing the damper before attaching it to the shut-off element, cyclic temperature heating and cooling in combination with deformation.

The fire barrier contains a composite locking element, which consists of a locking element and a fire damper fixed to it. The locking element locks or opens the direct-flow housing channel under normal operating conditions. In the event of a fire that can spread through the ventilation system through an opening in the housing, the shut-off element closes. But this will not be enough. The combustion products and the fire itself, acting on the shut-off element, will destroy its seal and the fire will pass through the ventilation system.

The presence of a fire damper attached to the locking element dramatically increases the reliability and durability of the structure. Under the influence of the temperature of the fire, when the temperature reaches above the temperature of the end of the reverse martensitic transformation, the damper “remembers” its original shape and completely blocks the channel, creating a barrier to fire and combustion products. Thus, the combination of the two elements in the composite damper provides the normal operation of the damper and emergency mode, which provides reliable closure of the fire path. Since the fire damper is fully or partially made of titanium nickelide with a reversible shape memory effect, after the fire has finished and the damper has cooled, it will “remember” the original shape that it has at a temperature below the temperature of the beginning of the reverse martensitic transformation, and the design of the fire damper will return to its state, former before the fire. Thanks to this design of the fence, it becomes possible to reuse the structure without re-mounting and replacing structural elements after a fire. The reversible shape memory effect for titanium nickelide is known, but there are no fire barrier designs in which such material would be used for simple and effective designs.

The fire damper of the boom is made with the possibility of processing it to achieve a reversible shape memory effect, which contains several successive cycles including:

- deformation at a temperature below the temperature of the beginning of the reverse martensitic transformation to a form that does not overlap the opening of the direct-flow housing;

- heating to a temperature above the temperature of the end of the reverse martensitic transformation;

- loading the heated element with an external force field in the direction of transition to a form that does not overlap the opening of the direct-flow housing, and cooling below the temperature of the end of the direct martensitic transformation;

- unloading from an external load;

- heating to a temperature above the temperature of the end of the reverse martensitic transformation. Such training achieves a reversible effect of the fire damper material - titanium nickelide.

In the particular case, the shutter is made in the form of a disk, the peripheral edge of which, at a temperature below the temperature of the onset of the reverse martensitic transformation, is bent, for example, by means of a flange. The peripheral part of the damper disk may be made of a material with a shape memory effect, and the inner part of a conventional structural material, for example, titanium. The disk is designed in such a way that titanium and a shape memory material in the form of titanium nickelide are rigidly interconnected by means of a welded joint.

The disc can also be made entirely of titanium nickelide.

As a rule, the shutter is rigidly fixed to the locking element.

For better fire resistance in the initial period of the fire, the locking element contains a heat-resistant seal.

The barrier is characterized in that it further comprises a drive for moving the composite locking element for opening and closing the direct-flow housing. In this case, the composite locking element is made rotatable and connected to the drive.

The invention is illustrated by drawings.

Figure 1 shows a section of a fire barrier when the ventilation hole is closed by a rotary barrier element in the usual, in the absence of fire, condition.

Figure 2 shows a cross-section of a fire barrier when the ventilation opening is open.

Figure 3 shows a part of the structure in the seal area when the ventilation hole is closed.

Figure 4 shows a part of the structure in the area of the seal after automatic fire protection.

The fire barrier (Fig. 1) includes a direct-flow housing 1 and a composite locking element 2 installed inside the housing 1, which contains the actual locking element 3 and the fire damper 4. The composite locking element is mounted on the rotary axis 9 (or axes 9) with the possibility of rotation inside the housing 1 for opening and closing the ventilation hole 11. The locking element contains a heat-resistant seal 7, which closes the channel in normal conditions of use. The fire damper 4, which is made of a material with a shape memory effect, in particular nickel-titanium alloy, is made in the form of a disk and is rigidly attached to the locking element from the outer side 6, for example by bolts. The damper 4 at normal operating temperature, that is, at a temperature below the temperature of the beginning of the reverse martensitic transformation, has bent edges 5 at the edge of the damper 4, as shown in FIG. 3. The rotary axis 9 of the composite locking element is connected to the control actuator 8. The drive 8 can be made mechanical, electromechanical or any other.

In Fig.1, the fire barrier is shown in the "closed" position, in Fig.2 in the "open" position during normal operation. The drawings show that in normal operation, the fire damper 4 does not interfere with the opening and closing of the locking element 2 due to the fact that the edge of the fire damper 4 is bent inward and does not touch the inner surface of the housing 1.

The fire damper can be completely made of titanium nickelide, but or partially, the edge of the disk 5 and the rest of the disk are made of titanium nickelide. The damper, consisting of various metals, can be made, in particular, by welding.

Initially, the shutter is made in the form of a flat disk, and then the edge of the disk is bent, undergoing plastic deformation, for example, by flanging.

The concept of “reversible shape memory” is associated with the following flap behavior.

When heated to the temperature of the end of the reverse martensitic transformation (until the martensite completely decomposes, when all the material goes into the austenitic state), the damper spontaneously takes the form corresponding to the high-temperature state. For a disk shutter, this is a flat shape in which the bore is blocked.

When cooled to the temperature of the end of the direct martensitic transformation (when all the material goes into the martensitic state), the damper also spontaneously takes the form corresponding to the low-temperature state, that is, the state with bent, flanged edges of the disk.

The reversible shape memory effect for the design of the fire damper involves preliminary thermomechanical processing before installing the damper on the fence, and includes several successive cycles including the following operations:

Deformation at a temperature below the temperature of the beginning of the reverse martensitic transformation to a form (bent, flanged edges of the disk) that does not overlap the opening of the direct-flow housing.

Heating to a temperature above the temperature of the end of the reverse martensitic transformation until the transition to the austenitic state (in our example, about 125 ° C).

Loading the heated element with an external force field in the direction of transition to the shape, flanged edges of the flap, and cooling below the temperature of the end of the direct martensitic transformation. At the same time, strain martensite accumulates in the structure of the material, oriented toward the transition from a flat shape to the shape of the bent edges of the disk.

Unloading from external load.

Heating to a temperature above the temperature of the end of the reverse martensitic transformation. Such training achieves a reversible effect of the fire damper material - titanium nickelide.

These operations are repeated a number of times. Moreover, the channel for the generation and degeneration of martensite strain, responsible for the transition from a flat state to the shape of the flanged edges, is “developed”, which leads to a decrease in the external loads required for this transition. The training process can be considered completed when these loads can be reduced to zero. Usually a few dozen cycles are enough.

In case of fire, the entire structure of the fence is closed and the fire damper heats up. Initially, the passage of fire and gas is prevented by a heat-resistant seal 7, which can be made of heat-resistant rubber that can withstand temperatures up to 110 ° -130 ° C. Upon reaching a temperature of approximately 125 ° C, the material of the fire damper 4, “recalls” its original shape, in the form of a flat sheet. The edge 5 of the shutter 4 straightens and blocks the passage of combustion products, preventing the spread of fire. Figure 4 shows that the sheet size of the fire damper at a temperature above the end of the reverse martensitic transformation (in our example, about 125 ° C) has a size equal to the size of the overlapped hole 11 of the housing 1. Due to this, the edge 5 of the damper 4 firmly holds the locking element 2, preventing its warping. This ensures reliable overlap of the ventilation hole.

At the end of the fire and cooling of the fire damper 4, its shape is restored to the original, and the fire barrier can be further operated without major repairs.

Claims (10)

1. Fire barrier comprising a direct-flow housing and a composite locking element fixed inside the housing, including the actual locking element and the fire damper mounted on the locking element and made in whole or in part of titanium nickelide with a reversible shape memory effect, while the damper has a shape that does not overlap a direct-flow housing opening at a temperature below the temperature of the beginning of the reverse martensitic transformation, and a shape overlapping the opening of the housing at a temperature above the temperature The temperature of the end of the reverse martensitic transformation, while the fire damper is made with the possibility of a reversible shape memory effect by processing the damper before attaching it to the shut-off element, cyclic temperature heating and cooling in combination with deformation. 2. The fence according to claim 1, characterized in that the fire damper is configured to process it to achieve a reversible shape memory effect, which contains several consecutive cycles including:
- deformation at a temperature below the temperature of the beginning of the reverse martensitic transformation to a form that does not overlap the opening of the direct-flow housing;
- heating to a temperature above the temperature of the end of the reverse martensitic transformation;
- loading the heated element with an external force field in the direction of transition to a form that does not overlap the opening of the direct-flow housing, and cooling below the temperature of the end of the direct martensitic transformation;
- unloading from an external load;
- heating to a temperature above the temperature of the end of the reverse martensitic transformation. 3. The fence according to claim 1, characterized in that the shutter is made in the form of a disk, the peripheral edge of which, at a temperature below the temperature of the beginning of the reverse martensitic transformation, is bent, for example, using a flange. 4. The fence according to claim 1, characterized in that the peripheral part of the damper disk is made of a material with a shape memory effect, and the inner part is made of titanium. 5. The fence according to claim 4, characterized in that the damper disk is made in such a way that titanium and titanium nickelide are rigidly interconnected by means of a welded joint. 6. The fence according to claim 1, characterized in that the disk is completely made of titanium nickelide. 7. The fence according to claim 1, characterized in that the fire damper is rigidly fixed to the locking element. 8. The fence according to claim 1, characterized in that the locking element contains a heat-resistant seal. 9. The fence according to claim 1, characterized in that it further comprises a drive for moving the composite locking element for opening and closing the direct-flow housing. 10. The fence according to claim 9, characterized in that the composite locking element is rotatable and connected to the drive.

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