RU2756440C1 - Self-locking ventilation unit, an element for a self-locking ventilation unit that increases in volume during heat exposure, and a fire-resistant cable box containing such a ventilation unit - Google Patents

Abstract

FIELD: ventilation units.

SUBSTANCE: invention relates to ventilation units, in particular to self-locking ventilation units, it can be used to provide passive fire protection of cable facilities and other building structures, including that at nuclear and thermal power plants. The self-locking ventilation unit is a ventilation channel with lattices on each side of the channel, the space between which is at least partially filled with an element that increases in volume during heat exposure, containing a hole for airflows to pass through it. An element that increases in volume, as well as a fire-resistant box, are also described.

EFFECT: technical problem solved in the implementation of the claimed invention is the creation of a device that ensures the retention of the material increasing in volume mainly within the ventilation unit, allowing for guaranteed sealing of the ventilation channel during the entire standard time of fire exposure, thereby protecting the cables laid in a fire-resistant cable box from the negative effects of an external fire, while providing more effective fire protection and at the same time ensuring the required efficiency of heat removal from the fire-resistant cable box during normal operation.

9 cl, 3 dwg

Description

[0001] TECHNICAL FIELD

[0002] The proposed technical solution relates to ventilation units, in particular to self-locking ventilation units, and can be used to provide passive fire protection of cable facilities and other building structures, including at nuclear and thermal power plants.

[0003] BACKGROUND

[0004] From the application of the Russian Federation No. 2014147704 (D1) an electrical device is known that has a metal body of the device and at least one electrical component, which is located in the metal body of the device, characterized in that the metal body of the device has an opening into which a ventilation element is inserted providing the possibility of convection ventilation of the device body through at least one ventilation duct of the ventilation element, wherein the ventilation element contains an element that increases its volume in case of heating when the activation temperature is reached and at the same time closes at least one ventilation duct.

[0005] The disadvantages of the closest analogue known from D1 are the impossibility of holding the volume-increasing element in the ventilation duct when it reaches a certain volume, as well as the need to use ventilation elements, while the efficiency of closing the ventilation duct also decreases due to the peculiarities of the execution of the element increasing in volume.

[0006] DISCLOSURE OF THE INVENTION

[0007] The technical problem solved in the implementation of the claimed invention is the creation of a device that does not have the disadvantages of its closest analogue, and thus ensures the retention of the expanding element mainly within the ventilation unit, allowing to ensure guaranteed sealing of the ventilation duct during the entire standard time of fire exposure , thereby protecting the cables laid in the fire-resistant cable box from the negative effects of external fire, while providing more effective fire protection and at the same time ensuring the required efficiency of heat removal from the fire-resistant cable box during normal operation. Another technical problem is the expansion of the arsenal of technical means for a specific purpose of self-locking ventilation units.

[0008] The technical result achieved during the implementation of the claimed invention, in addition to realizing its purpose, is to eliminate the shortcomings of the closest analogue and, as a result, to ensure the retention of the element increasing in volume within the ventilation unit, eliminating the need to use ventilation elements (fans) in the composition ventilation ducts for fire-resistant cable ducts, ensuring the possibility of fire protection of the fire-resistant cable duct, increasing the efficiency of closing the ventilation duct, increasing the efficiency of fire protection of the ventilation unit and the ventilation duct as a whole, as well as ensuring the required efficiency of heat removal from the fire-resistant cable duct.

[0009] The technical result is achieved due to the fact that a self-locking ventilation unit is provided, which is a ventilation duct with gratings on each side of the duct, the space between which is filled with an element that increases in volume when exposed to heat and contains an opening for air flows through it.

[0010] BRIEF DESCRIPTION OF THE DRAWINGS

[0011] Exemplary embodiments of the present invention are described in detail below with reference to the accompanying drawings, which are incorporated herein by reference and in which:

[0012] FIG. 1 shows an exemplary embodiment of a heat-expanding element inside a self-locking ventilation unit.

[0013] FIG. 2 shows an exemplary other embodiment of a heat-expanding element within a self-locking ventilation unit.

[0014] FIG. 3 shows a further exemplary embodiment of a heat-expanding element within a self-locking ventilation unit.

[0015] CARRYING OUT THE INVENTION

[0016] The exemplary embodiments of the present invention described in this section are presented by non-limiting examples in relation to specific embodiments of the present invention, which in all their aspects are intended to be illustrative and non-limiting. Alternative embodiments of the present invention, without departing from the scope of its legal protection, will be obvious to those skilled in the art with ordinary skill on which this invention is designed.

[0017] Preferably, but not limited to, the claimed self-locking ventilation unit (100) is a ventilation duct (101) with gratings (102) on each side of the duct, the space between which is filled with a heat-expanding element (103) containing an opening (104) for the passage of air flows through it. Preferably, but not limited to, the ventilation duct is made of metal, for example, but not limited to, steel and / or other suitable material. Preferably, but not limited to, a grill is attached to each side of the ventilation unit as a ventilation grill. Preferably, but not limited to, the grating is made of metal, for example, but not limited to, steel and / or other suitable material. Preferably, but not limited to, the space between the gratings is filled with a heat-expanding element. Preferably, but not limited to, the heat expandable element is a heat intumescent composition containing the following components in the following ratio, wt. h .:

versatic vinyl ester copolymer dispersion acids in water 30-70 thermally expandable oxidized graphite 10-25 basalt fiber 15-40

[0018] For example, but not limited to, the heat expandable element is a heat intumescent composition containing the following components at the following ratio, wt. h .:

versatic vinyl ester copolymer dispersion acids in water 55 thermally expandable oxidized graphite 15 basalt fiber thirty

[0019] For example, but not limited to, the heat expandable element is a heat intumescent composition containing the following components at the following ratio, wt. h .:

versatic vinyl ester copolymer dispersion acids in water 50 thermally expandable oxidized graphite 25 basalt fiber 25

[0020] For example, but not limited to, the heat expandable element is a heat intumescent composition containing the following components in the following ratio, wt. h .:

versatic vinyl ester copolymer dispersion acids in water 70 thermally expandable oxidized graphite 15 basalt fiber 15

[0021] Preferably, but not limited to, the heat expandable member is prepared as follows. Preferably, but not limited to, in the first step, a dispersion of a copolymer of vinyl ester of versatic acid in water, thermally expandable oxidized graphite, basalt fiber is mixed until a wetted mixture is obtained. Preferably, but not limited to, in a second step, the resulting wetted mixture obtained is laid out in molds and placed in an oven preheated to a temperature in the range of 180 to 220 degrees Celsius. Preferably, a microprocessor-controlled drying and polymerization oven known from the prior art is used as said oven. Preferably, in a third step, said wetted mixture is kept in said preheated oven until a dried mixture is obtained, with the resulting mixture having a relative humidity of not more than 1% under the dried mixture. Preferably, but not limited to, the moisture content of the mixture during drying in the oven is controlled according to GOST 14870-77 “Chemical products. Methods for the determination of water "(with Amendments No. 1, 2), which is thus incorporated into this description by reference.

[0022] Preferably, but not limited to, in the last step, the dried mixture is mechanically processed, for example, but not limited to, using a prior art band saw, to obtain a heat expandable member of the desired shape.

[0023] Preferably, but not limited to, the heat-expanding element is activated and begins to expand when exposed to heat of at least about 200 degrees Celsius. Preferably, but not limited to, the heat-expanding element may be provided with a through hole to allow air flow therethrough when the heat-expanding element is positioned between said grids. For example, but not limited to, the heat-expanding element may be provided with multiple through-holes to allow air flow therethrough when the heat-expanding element is positioned between the grids. For example, without limitation, the element that increases in volume under the influence of heat can be made in the form of a cylinder with a through longitudinal hole (through a longitudinal cavity), which ensures the passage of air flows through it when the element that increases in volume under the influence of heat is placed between the said gratings (Fig. 1 ). For example, without limitation, an element that increases in volume under the action of a body can be made in the form of a parallelepiped with a through longitudinal hole (through a longitudinal cavity), which ensures the passage of air flows through it when the element that increases in volume under the influence of heat is placed between the aforementioned gratings (Fig. 2 ). For example, but not limited to, the body-expanding element can be made in the form of a sheet with a through hole allowing air flow through it when the heat-expanding element is placed between said gratings, in which case the space between said gratings is filled a sufficient number of such sheets (Fig. 3). For example, but not limited to, the heat-expanding element can be made in the form of a cylinder with several longitudinal through holes (through longitudinal cavities) allowing air flows to pass through them when the heat-expanding element is placed between said gratings. For example, but not limited to, the expanding element under the influence of heat can be made in the form of a parallelepiped with several through longitudinal holes (through longitudinal cavities) allowing air flows to pass through them when the expanding element under the influence of heat is placed between the said grids. For example, but not limited to, a heat-expanding element can be made in the form of a sheet with several longitudinal through holes allowing air flow through them when the heat-expanding element is placed between said gratings, in which case the space between said gratings are filled with a sufficient number of such sheets (Fig. 3). For example, without limitation, the element that expands in volume when exposed to heat can be made in the form of a small-sized said cylinder, which itself occupies an insignificant place inside the volume of the claimed self-locking ventilation unit, and in this case, the space between the said grids is filled with a sufficient number of such cylinders (Fig. . 1). In this case, it is preferable that the said undersized cylinders are arranged in such a way that their through holes are located mainly coaxially with the holes of the said lattice (Fig. 1). For example, without limitation, the element expanding in volume when exposed to heat can be made in the form of a small-sized parallelepiped, which itself occupies an insignificant place inside the volume of the claimed self-locking ventilation unit, and in this case, the space between the said grids is filled with a sufficient number of such parallelepipeds (Fig. 2). In this case, it is preferable that the mentioned small parallelepipeds are arranged in such a way that their through holes are located mainly coaxially with the holes of the said lattice (Fig. 2). Preferably, when the heat-expanding element contains a plurality of openings, such openings, when placing such an element inside the self-locking ventilation unit according to the invention, were located mainly coaxially with the openings of the said grill. For example, but not limited to, the expanding element upon exposure to heat is made in the form of a lattice with a plurality of openings, which, when such an element is placed inside the self-locking ventilation unit according to the invention, are located predominantly coaxially with the openings of said lattice. A person skilled in the art, having the ordinary knowledge on which the present invention is designed, it should be obvious that from the resulting dried mass can be obtained expanding when exposed to heat, an element of any suitable for placement inside the claimed self-locking block of the form, providing the passage of air flows inside the claimed self-locking ventilation unit, for example, but not limited to, such a shape can be a polyhedron, a prism, a pyramid, a ball and the like. It should also be apparent to those skilled in the art, with ordinary knowledge on which the claimed invention is designed, that the choice of the shape of the expandable element between a parallelepiped (the like shape) and a cylinder or ball (the like shape) depends on the requirements for the declared self-locking ventilation unit of the requirements: for example, without limitation, if the space inside the declared self-locking ventilation unit is filled with many parallelepipeds (many independent elements of a similar shape that increase in volume when exposed to heat, for example, many polyhedrons, prisms, pyramids containing corners), then, in this way, the throughput of the ventilation unit in terms of the air flows passing through it is reduced, but at the same time the space filled with elements that increase in volume when exposed to heat is increased, that is, the rate of filling the spaces is increased the nature of the ventilation box as a refractory material formed as a result of the activation of the element, since the amount of non-activated elements and, accordingly, the composition that swells when exposed to heat inside the ventilation unit is greater; for example, without limitation, if the space inside the claimed self-locking ventilation unit is filled with a plurality of cylinders (a plurality of independent elements of a similar shape that increase in volume when exposed to heat, for example, a plurality of balls that do not contain corners), then the throughput of the ventilation unit in part of the air flows passing through it, but at the same time, the space filled with elements that increase in volume when exposed to heat is reduced, that is, the rate of filling the space of the ventilation duct with refractory material formed as a result of the activation of the element is reduced, since the number of non-activated elements and, accordingly, swelling when exposed to heat, the composition inside the ventilation unit is less. The claimed self-locking ventilation unit can also be an intermediate link of a longer ventilation duct, and the grill can be oriented at an angle to the main length of the ventilation duct, for example, but not limited to, perpendicularly. In this case, such an intermediate link preferably contains elements that increase in volume upon exposure to heat, placed between its grids, which are preferably sheets or grids or the like, that is, such elements, the openings of which can be placed not only predominantly coaxially with the openings of the said lattice, but also coaxially with similar elements located in the main ventilation duct located at an angle, moreover, such an intermediate link can have only one grate, and the other space of the ventilation duct, not necessarily completely, but sufficiently, can be filled with an element that increases in volume when exposed to heat, moreover, it should be obvious to a person skilled in the art, having ordinary knowledge on which the present invention is designed, that the amount of the element expanding in volume upon exposure to heat should be such that it provides a sufficient increase to the boundaries of the lower and the upper walls of the ventilation duct, as well as the grille.

[0024] The claimed device operates as follows. Preferably, the claimed self-locking ventilation unit (including, but not limited to, in the form of an intermediate link of the ventilation duct) is preferably located on the upper wall of the fire-resistant cable duct and provides convection heat removal from electrical cables located inside the duct during their operation. Preferably, but not limited to, said fire-resistant cable duct is one of or a combination of: a fire-resistant cable duct formed by joining fire-resistant plates, for example, of calcium silicate; fire-resistant cable duct, formed by quick-disconnect connection of heat-insulating screens based on mineral stone wool; fire-resistant cable box formed by a roll (flexible) heat-insulating screen based on mineral stone wool; a fire-resistant cable box formed by a metal frame, on which rigid fire-resistant elements in the form of plates and / or screens are fixed. It should be obvious to a person skilled in the art, having the ordinary knowledge on which the present invention is designed, that in this case, the placement of the claimed ventilation unit as part of said fire-resistant cable duct is not necessarily carried out on its upper wall, but can also be carried out on its other walls, which is due to the heat dissipation requirements imposed on the fire-resistant box, as well as the method of its placement in the room. In normal operation, the claimed ventilation unit, due to the previously described expanding element with holes, provides the necessary efficiency for removing excess heat from the fire-resistant cable duct, preventing overheating of the cable and thereby increasing the reliability and durability of its operation. In the event of an emergency situation associated with a fire in any room in which electrical cables are laid protected by fire-resistant boxes with installed self-locking ventilation units, heat begins to affect the element that increases in volume when exposed to heat, which, when the exposure temperature reaches about 200 degrees Celsius is activated and begins to increase in volume, filling the space of the self-locking ventilation unit, thus preventing further passage of air flows from the outside through it and thus stopping the supply of combustion products and increased temperature inside the fire-resistant box. In the event of an emergency situation associated with the fire of the cable itself, heat also begins to affect the element that increases in volume when exposed to heat, which, when the exposure temperature reaches about 200 degrees Celsius, is activated and begins to increase in volume, filling the space of the self-locking ventilation unit. thus preventing the access of oxygen to the interior of the fire-resistant cable duct and thereby preventing further development of the fire. Moreover, in both of the described cases of emergency situations, in contrast to the analogs known from the prior art, the element that increases in volume when exposed to heat remains inside the ventilation unit as its volume increases, which is also due to the composition of the composition from which it is made, since this ensures its characteristics in an activated state, namely elasticity, hardness and absence of crumbling.

[0025] The present description of the claimed invention demonstrates only particular embodiments and does not limit other embodiments of the claimed invention, since possible other alternative embodiments of the claimed invention that do not go beyond the scope of information set forth in this application should be obvious to a person skilled in the art technicians having the usual qualifications for which the claimed invention is designed.

Claims (11)

1. Self-locking ventilation unit, which is a ventilation duct with grilles on each side of the duct, the space between which is at least partially filled with an element that expands in volume when exposed to heat and contains an opening for air flows through it. 2. The ventilation unit according to claim 1, characterized in that the element that increases in volume when exposed to heat is a composition containing the following components in the following ratio, wt. h .: versatic vinyl ester copolymer dispersion acids in water 30-70 thermally expandable oxidized graphite 10-25 basalt fiber 15-40 3. Ventilation unit according to claim 1, characterized in that the element that increases in volume when exposed to heat begins to increase in volume when exposed to a warm temperature of about 200 degrees Celsius. 4. The ventilation unit according to claim 1, characterized in that the element expanding in volume when exposed to heat contains several through holes. 5. The ventilation unit according to claim 1, characterized in that the element expanding in volume when exposed to heat is made in the form of a cylinder with a through longitudinal hole. 6. The ventilation unit according to claim 1, characterized in that the element expanding in volume upon exposure to heat is made in the form of a parallelepiped with a through longitudinal hole. 7. The ventilation unit according to claim 1, characterized in that the element expanding in volume upon exposure to heat is made in the form of a sheet with a through hole. 8. Increasing in volume when exposed to heat, the element, which is a composition containing the following components at the following ratio, wt. h .: versatic vinyl ester copolymer dispersion acids in water 30-70 thermally expandable oxidized graphite 10-25 basalt fiber 15-40 9. Fire-resistant cable box containing a built-in self-locking ventilation unit according to any one of paragraphs. 1-7.

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