RU2269166C1 - Device for thermal and mechanical protection of object - Google Patents

Abstract

FIELD: engineering of equipment for protecting microelectronic information registers, can possibly be used for engineering of protected onboard flight information storage devices for airplanes and helicopters.

SUBSTANCE: device for thermal and mechanical protection of object allows to maintain safety of microelectronic register under effect from combined external destructive factors: mechanical impacts, overloads, vibration effects, static pressure, and also fire-based factors with time of effect up to one hour with all-around fire enveloping at temperature up to 1100°C. Aside from that, invention provides for safety of accumulated information after long, up to 10 hours, effect of smoldering burning at temperature up to 260°C. Protection of microelectronic equipment from effect of destructive factors, in accordance to invention, is realized by using multi-layer casing, containing serially positioned in depth direction protective layers: external, intermediate and internal, and also biomorphic heat-protection cover on the outside surface of external layer, while each layer and cover perform certain protective function. Biomorphic heat-protective cover, meant for passive heat protection of protected object, provides aforementioned protection due to significant increase of volume and porosity level of cover material under effect from flames, leading to substantial increase of thickness and heat resistance of cover. External layer is meant for providing impact and fire resistance of protective cover due to high mechanical and heat resistance of metals used to manufacture external layer. Intermediate layer meant for passive heat protection of preserved object, realizes functions of heat isolator due to low heat conductivity of fire-resistant dry porous material forming this layer. Internal layer realizes active heat protection of microelectronic register. To reach aforementioned goal it is formed of crystalline compositions, containing crystallization water - crystalline hydrates, under effect from external heat consuming external heat and thus during whole time of heat-caused dehydration upholding temperature inside protected volume to be below temperature of heat decomposition of crystalline hydrate. To increase efficiency of heat protection, internal layer on both sides is covered by metallic heat-reflective inserts and it is formed of no less than two crystalline hydrates with different dehydration temperatures.

EFFECT: increased efficiency.

1 dwg

Description

The present invention relates to the protection of microelectronic equipment from external destructive factors, such as high-temperature fire, shock loads, static pressures, and also from prolonged exposure to elevated temperature, and can be used, for example, to create protected on-board flight information storage devices for aircraft and helicopters, as well as secure storage devices for other vehicles: diesel locomotives, ships, cars, etc.

A device is known for protecting microelectronic equipment from high temperatures (see RF patent No. 2042294, H 05 K 7/20, 1995).

In the known device, the protected microelectronic object is placed in an airtight container connected to the supply and circulation system of a cooling dielectric fluid, the evaporation of which on the inner surfaces of the walls of the sealed container and the outer surfaces of the microelectronic object leads to cooling of the latter and protects it from overheating.

A disadvantage of the known device is the need to use an additional system for supplying and circulating coolant, which increases the size of the protective device, reduces its reliability and makes it difficult to use the vehicle as on-board equipment.

It is also known a device for mechanical and thermal protection of microelectronic equipment, which is a BNI information storage unit that is part of the SDK-8 diagnostic and control system designed to record helicopter flight information (see Technical Manual 6T1.412.001RE. Diagnostic and control SDK-8, p. 32. Publishing house of JSC "Techpribor", St. Petersburg, 2001).

The specified device is a protective layered shell surrounding the protected volume in which the stored microelectronic object is placed - a solid-state memory card designed to record the helicopter flight information.

The protective laminate consists of an outer casing of the block and two protective layers: outer and inner, each of which performs a specific protective function. The outer layer of the protective shell made of fire-resistant heat-insulating porous material is intended for passive heat protection of the stored object after a helicopter accident accompanied by a fire when an external one-way heat flow with a flame temperature of up to 1100 ° C is exposed to the unit.

The outer layer of the protective shell provides passive heat protection of the stored object by creating a temperature difference on the thickness of the layer of heat-insulating material, which allows maintaining for 30 minutes the temperature of the inner surface of the layer, not exceeding 150 ° C, at a temperature of the outer surface of the layer of 1100 ° C.

The inner layer of the protective shell is a massive metal case made of impact-resistant metal alloys and designed to protect the stored object at the time of the accident from external destructive mechanical factors.

The outer and inner layers of the protective laminate are placed inside the outer thin-walled metal casing, on the outer surface of which there are identification marks and warning signs that facilitate search work to detect the information storage unit (the so-called "black box") after an accident that is not accompanied by a fire.

The known device reliably protects a solid-state microelectronic memory card located in a protected volume from external mechanical destructive factors, as well as from one-sided, i.e. aimed at only one side of the outer casing, high-temperature exposure, but not able to provide thermal protection with comprehensive fire exposure to the casing with a temperature of 1100 ° C for 30 minutes.

This drawback does not allow the use of the known device on new and modernized helicopters, since, in accordance with the industry standard (see OST 1 01080-95. On-board recording devices with protected drives, clause 6.2.11, p.11), thermal effect flame to a secure storage device must be comprehensive, i.e. aimed at the block from all six sides.

This drawback is overcome in the closest to the claimed and adopted as a prototype device, based on the creation of a protective laminate around a microelectronic object that protects it from external thermal and mechanical destructive factors (see RF patent No. 2162189, F 16 L 59/02, G 12 B 17/06, B 64 C 1/38, B 64 G 1/58, 2001).

In this device, the protective shell of the stored object is formed of several successively arranged layers: an external shock-resistant layer made of heat-resistant metals, an intermediate heat-protective layer made of refractory dry porous fiber material, and an internal heat-protective layer formed of a porous water-containing material enclosed between heat-reflecting gaskets, made of metallized polymer film.

The outer layer of the protective shell protects the stored object from external destructive mechanical and fire effects due to the shock and heat resistance of the material of the layer. An intermediate heat-protective layer provides passive thermal protection of the stored object due to the low thermal conductivity of the dry porous fiber material of the layer. The inner heat-protective layer provides active thermal protection of the stored object due to the absorption of heat during boiling of water located in the pores of the water-containing material. Active thermal protection allows maintaining the temperature of the protected volume not higher than the boiling point of water 100 ° C during the whole boiling time. Heat-reflecting gaskets contribute to an additional decrease in the temperature of the protected volume due to the partial reflection of the external heat flux by the heat-reflecting surfaces of the gaskets.

The known device effectively solves the problem of protecting the stored object from destructive mechanical factors and high temperature influences, providing protection for microelectronic equipment with external comprehensive fire exposure with a temperature of up to 1100 ° C for 30 minutes, shock overloads up to 3400 g and static pressures up to 600 atm.

However, in accordance with the international requirements of TSO (see "Technical Standart Order", TSO-C124a, Washington, DC; 8/1/96) for on-board protected storage devices for flight information of aircraft and helicopters, a stored object, in addition to the above destructive mechanical factors and high-temperature effects, must also withstand long-term comprehensive exposure to elevated temperature 260 ° C for 10 hours. In addition, according to the requirements of TSO, the time of comprehensive high-temperature exposure to 1100 ° C should be at least 1 hour.

To fulfill the TSO requirements for a comprehensive high-temperature exposure for at least 1 hour, a significant increase in the thicknesses of the intermediate and inner layers, i.e. a significant increase in the volume of the protective shell, which leads to an increase in its overall dimensions that is unacceptable for on-board equipment.

To meet the TSO requirements for resistance to long-term, up to 10 hours, comprehensive exposure to elevated temperatures of 260 ° C, the known device is ineffective.

The basis of the invention is the task of protecting the stored microelectronic object when exposed to mechanical and thermal overloads, including the comprehensive exposure to high temperature 1100 ° C for 1 hour, as well as long-term comprehensive exposure to elevated temperature 260 ° C for 10 hours.

The following new technical solutions are proposed for the effective protection of the stored property.

Firstly, it is proposed to additionally form a heat-insulating bimorph heat-shielding coating on the outer surface of the outer shock-resistant layer. In the initial state, the bimorph heat-shielding coating is a fairly thin film with a thickness of about 1.5-2 mm made of a heat-insulating composite material; depending on the external temperature, the bimorph coating can be in one of two stable morphological modifications: a low-temperature modification with a monolithic macrostructure and a high-temperature modification with a porous macrostructure.

Modification with a monolithic structure, stable up to 220 ° C, passes at a temperature above 250 ° C into a state with a porous structure; in the temperature range 220-250 ° С, the heat-insulating composite material of the bimorph coating is in an intermediate state.

The low-temperature modification of the bimorph heat-shielding coating has adhesion to the surface of the outer shock-resistant layer and allows it to form a smooth, mechanically strong film coating on it that allows the outer surface to be painted.

The high-temperature modification formed after exposure to the film coating with an external temperature above 250 ° C is a highly foamed structure with a thickness many times greater than the thickness of the film coating in the initial state.

The thermal insulation properties of the high-temperature modification of the coating are very high, which allows reliable protection of the outer shock-resistant layer from external high-temperature influences.

Secondly, it is proposed to form an internal heat-protective water-containing layer from materials containing water not in a free state, in the pores of a porous fiber material, as is done in a known device, but in a crystalline bound state in the structure of the crystal lattice of crystalline hydrates - crystalline compounds containing bound, t .n. "crystallization" water. The use of crystalline hydrates to form the inner heat-shielding layer can significantly increase the efficiency of active heat shielding of the inner layer, since the evaporation of crystallization water, which is part of the crystalline hydrate, requires a significantly greater amount of heat than the evaporation of the equivalent mass of free water located in the pores of a porous fiber material.

In addition, in the proposed device to provide an effective cooling mode of the intermediate heat-shielding layer with water vapor formed during dehydration of crystalline hydrates, it is proposed to perforate drainage holes in the outer shock-resistant layer with a certain ratio of the length and diameter of each hole, which ensures effective cooling of the inner heat-shielding layer with water vapor by creating inside the protective laminate overpressure of water vapor.

In addition, the invention proposes to produce heat-reflecting gaskets not from a metallized polymer, as in the known device, but from a metal foil having a fundamentally higher heat resistance compared to a polymer material. To drain the water vapor generated by the thermal decomposition of crystalline hydrates, it is proposed to perforate drainage holes in the metal foil of the outer heat-reflecting pad. To increase the reflectivity of heat-reflecting gaskets, it is proposed to polish their heat-reflecting surfaces.

Thus, in order to fulfill the task, in the device for thermal and mechanical protection of the object, consisting of sequentially arranged layers: an external shock-resistant layer made of heat-resistant metals, an intermediate heat-protective layer made of refractory dry porous material, and an internal heat-protective layer formed of water-containing material enclosed between the outer and inner heat-reflecting gaskets, new according to the invention is that complement On the outer surface of the outer shock-resistant layer, a bimorph heat-insulating coating is formed of a heat-insulating composite material that has adhesion to the surface of the outer shock-resistant layer and is able to increase in volume by at least 10 times when heat is applied by a flame to it, while the outer shock-resistant layer is perforated with through-hole drainage holes the diameter of each of which does not exceed half the thickness of the outer shock-resistant layer, heat-reflective gaskets made They are made of metal foil, the outer heat-reflecting pad being perforated, and the inner heat-shielding layer formed using at least two crystalline hydrates, such that the dehydration temperature of one of them exceeds the dehydration temperature of the other by at least two times.

For a more complete disclosure of the invention, the drawing shows a section of the proposed device.

The stored object 1 is placed in a protected volume 2 located inside the protective laminate, including:

- bimorph heat-insulating coating 3, formed from a heat-insulating composite material deposited on the outer surface of the outer shock-resistant layer 4. Bimorph heat-insulating coating 3 has adhesion to the surface of the outer shock-resistant layer 4, and also has the property of foaming when exposed to heat at a temperature of no more than 260 ° C with a multiple increase in volume, and therefore, heat-insulating properties of the material;

- outer shock-resistant layer 4 made of heat-resistant metals and perforated by drainage holes 5, the diameter of each of which is chosen not exceeding half the thickness of the outer shock-resistant layer 4;

- an intermediate heat-protective layer 6, designed for passive heat protection of the stored object 1 and made of refractory dry porous material;

- the inner heat-protective layer 7, intended for active thermal protection of the stored object 1 and formed from a material that includes crystalline hydrates: crystalline compounds containing crystallization water;

- layer 7 is composed of at least two different crystalline hydrates with different dehydration temperatures: in one of the crystalline hydrates, this temperature exceeds the dehydration temperature of the other crystalline hydrate by at least two times. On the outer and inner surfaces of the inner heat-shielding layer 7 there are respectively outer 8 and inner 9 heat-reflecting pads made of metal, for example, aluminum, foil and designed to reflect the external heat flux, and the external heat-reflecting pad 8 is perforated to allow drainage through its openings of water vapor .

The geometric shape of the proposed device can be spherical, cylindrical, prismatic, etc. The device with spherical geometry shown in the drawing is the most compact and heat-shock resistant of these.

The outer shock-resistant layer 4 of the device can be composed of two hemispheres interconnected, for example, by means of a weld 10, which allows the hemispheres to be separated to access the stored object 1 after an accident, for example, by removing the seam 10.

The bimorph heat-shielding coating 3 is made of a monolithic and smooth material in the initial state, the outer surface of which allows coloring with the application of identification marks and warning signs provided for by the airworthiness standards and facilitating the search for the “black box” after an accident not accompanied by a fire.

Bimorph heat-shielding coating 3 can be in two stable morphological states: the initial state with a monolithic structure, stable to temperatures not exceeding 220 ° C, and the state with a porous structure, stable at temperatures above 250 ° C. In the temperature range of 220 ° C-250 ° C, the coating material is in a metastable intermediate state.

In the event that a fire occurs as a result of an accident, emergency situations provided for by TSO standards are possible: a situation with active comprehensive fire exposure to a stored flame object with a temperature of 1100 ° C for 1 hour and a situation with smoldering comprehensive fire exposure to a stored object at a smoldering temperature of 260 ° C for 10 hours.

In each of these two situations, the material of the bimorph heat-protective coating 3 of the protective shell, deposited on the outer surface of the outer shock-resistant layer 4, is subjected to direct fire exposure and, after heating above the heat resistance limit of 250 ° C, softens and foams.

To obtain the necessary heat-shielding and mechanical properties of the bimorph heat-shielding coating 3, it is formed from a composite containing at least three components: a foaming heat-resistant base, a foaming agent, and a modifier.

A foaming heat-resistant base is a substance having the ability to form a rigid heat-resistant high-foamed structure with interconnected pores, which arises as a result of thermal softening and foaming when the heat resistance limit is reached as a result of internal gas generation stimulated by the catalytic action of the foaming agent. The blowing agent is a catalyst that provides intense gas evolution in the foamable material when the latter reaches the heat resistance limit. The modifier is a binder additive that gives the bimorph heat-shielding coating material 3 the mechanical properties required in the initial state: solidity, smoothness, mechanical resistance to impact and abrasion, as well as adhesion to the material of the outer shock-resistant layer 4.

As components of the composite can be used, for example: a foaming heat-resistant base based on phenol-aldehyde resin with a heat resistance limit of at least 150 ° C, a foaming agent based on a surfactant (surfactant) and an epoxy-based modifier.

With external fire exposure with a temperature above 250 ° C, the structure of the bimorph heat-shielding coating 3 changes significantly: the previously monolithic composite coating material is transformed under the influence of the flame into porous, which leads to a sharp increase in its volume. As a result, the thickness of the bimorph heat-shielding coating 3 increases 15-20 times when smoldering comprehensive fire exposure at a temperature of 260 ° C, while the outer surface of the coating reaches the diameter indicated in the drawing, item 11 (near border 11) and 30-50 times at active comprehensive fire exposure with a temperature of 1100 ° C, while the outer surface of the coating reaches the diameter indicated in the drawing, item 12 (distant border 12).

An increase in thickness and a change in the structure of the bimorph heat-insulating coating 3 leads to a qualitative improvement in its heat-insulating properties.

As a result of this, when exposed to a comprehensive external heat flux with a temperature of 1100 ° C, a bimorph heat-shielding coating 3 foamed to a distant boundary 12 allows maintaining a temperature difference of at least 350 ° C for bimorph heat-shielding coating 3 for at least 350 ° C, while ensuring an outdoor temperature shockproof layer 4 not higher than 750 ° C.

After at least 20 minutes, the foamed bimorph heat-insulating coating 3 begins to collapse under the continuing influence of the flame, the surface of the outer shock-resistant layer 4 is gradually exposed and by the end of the 25th minute the outer shock-resistant layer 4 is openly heated by an external flame, reaching a temperature of 1100 ° С.

With further high-temperature impact on the external shock-resistant layer 4 of the external heat flux with a temperature of 1100 ° C, a gradual heating of the intermediate heat-shielding layer 6 formed from a refractory dry porous material with high thermal insulation properties occurs.

Due to the low thermal conductivity of the material of the intermediate heat-protective layer 6, it is heated to a temperature of 120 ° C for 5-10 minutes.

Thus, approximately 30 minutes after the accident, accompanied by an external comprehensive exposure to a flame with a temperature of 1100 ° C, the temperature of the outer surface of the inner heat-protective layer 7 can reach a critical value of 120 ° C.

In another situation stipulated by TSO standards - an external comprehensive smoldering fire exposure with a temperature of 260 ° C, a bimorph heat-insulating coating 3, foamed to the near boundary 11, allows you to maintain a temperature drop of at least 50 ° C between the near boundary 11 of the coating and the outer for about 1.5 hours the surface of the outer shockproof layer 4, providing a temperature in the outer shockproof layer 4 not higher than 210 ° C.

After 1.5 hours, the foamed bimorph heat-protective coating 3 begins to break down, the surface of the outer shock-resistant layer 4 is gradually exposed and by the end of the second hour, the outer shock-resistant layer 4 is openly heated by a smoldering flame to a temperature of 260 ° C.

With further exposure to the external shock-resistant layer 4 of the external heat flux with a temperature of 260 ° C, the intermediate heat-shielding layer 6 is gradually heated to a temperature of 120 ° C for 25-35 minutes.

Thus, approximately 2.5 hours after the accident, accompanied by smoldering fire with a temperature of 260 ° C, the temperature on the outer surface of the inner heat-shielding layer 7 can reach 120 ° C.

As crystalline hydrates forming the inner heat-shielding layer 7, for example, metal hydrosulphates, including nickel, copper and iron, hydrosulphates of double metals, including potassium and aluminum, crystalline hydrates of double salts, including sulfate, can be used potassium and chromium, potassium sulfate and aluminum, metal hydroxides, including aluminum, hydrated alkali metal silicates, including sodium, potassium and lithium.

The temperatures T _o dehydration of these crystalline hydrates are in the range from 105 ° C to 400 ° C. So, for example, for the least heat-resistant of the listed crystalline hydrates - potassium dodecahydrosulfate - aluminum KAl (SO ₄ ) ₂ · 12Н ₂ O, the dehydration temperature is Т _о = 105 ° С; for the most heat-resistant crystalline hydrate - sodium decahydrotetraborate Na ₂ B ₄ O ₇ · 10H ₂ OT _o = 400 ° C; for crystalline hydrate with intermediate heat resistance - iron heptahydrosulfate FeSO ₄ · 7H ₂ OT _o = 300 ° C.

The inner heat-protective layer 7 is formed of at least two crystalline hydrates with different dehydration temperatures T _о , for example, with a dehydration temperature of a relatively less heat-resistant crystalline hydrate T _о1 = 120 ° С and a dehydration temperature of a relatively more heat-resistant crystalline hydrate Т _о2 = 400 ° С. The inner heat-protective layer 7 consists of a mixture of these crystalline hydrates.

When exposed to a protective shell of a comprehensive heat flux with a temperature of 1100 ° C, the temperature of the outer surface of the inner heat-shielding layer 7 approximately 30 minutes after the start of exposure reaches T _o1 = 120 ° C, and a relatively less heat-resistant crystalline hydrate begins to dehydrate. Because Since the heat of dehydration of crystalline hydrate includes two components: the heat of dehydration of crystalline hydrate and the heat of evaporation of water, the amount of heat required for dehydration of crystalline hydrate is almost 1.5 times the heat of boiling free water.

Accordingly, the dehydration time of a relatively less heat-resistant crystalline hydrate also exceeds the boiling time of an equivalent mass of water by at least 1.5 times.

However, as the thermal decomposition of the less heat-resistant crystalline hydrate is thermally decomposed, the outer part of the inner heat-protective layer 7 is gradually warmed up by external heat, its temperature rises to a value of Т _о > 120 ° С and dehydration of the more heat-resistant crystalline hydrate begins.

Because the amount of heat required for dehydration of this crystalline hydrate is almost 2 times higher than the heat of boiling free water, the dehydration time significantly exceeds the boiling time of an equivalent amount of water.

Thus, in the process of thermal dehydration of the material of the inner heat-protective layer 7, the temperature in this layer is maintained at not higher than 400 ° C, and in the region close to the inner surface, not higher than 120 ° C, and as the internal heat-protective layer 7 is heated, the dehydration boundary gradually shifts inside the inner heat-shielding layer 7, reaching the protected volume not less than 75 minutes after the start of external exposure to a bimorph heat-shielding coating with a flame with a temperature of 1100 ° С 3. This allows 75-85 minutes from the moment of the accident to maintain the temperature not exceeding 150 ° C in the protected volume, which allows you to fully maintain the health of the stored object.

When exposed to a protective shell of a comprehensive heat flux with a temperature of 260 ° C, the temperature of the outer surface of the inner heat-shielding layer 7 approximately 3 hours after the start of exposure reaches a value of T _o1 = 120 ° C, and a relatively less heat-resistant crystalline hydrate begins to dehydrate.

In the process of heating the inner heat-shielding layer 7, the temperature of the dehydrated layer region does not exceed T _o1 = 120 ° C, and the temperature of the region where thermal decomposition has already occurred does not exceed 260 ° C.

Moreover, a more heat-resistant crystalline hydrate, the dehydration temperature of which is Т _о2 > 260 ° С, does not undergo thermal decomposition and plays the role of a passive heat-insulating material. For approximately 11 hours after the start of smoldering fire with a temperature of 260 ° C, the temperature inside the protected volume does not exceed 150 ° C.

This makes it possible within 11 hours from the time of the accident to ensure the full operability of the stored microelectronic object.

Both in the first (at an external temperature of 1100 ° С) and in the second (at an external temperature of 260 ° С) emergency situations provided by TSO, water vapor generated in the inner heat-shielding layer 7 as a result of its evaporation during dehydration of crystalline hydrates passes through perforations in external heat-reflecting gasket 8, then through the pores in the material of the intermediate heat-protective layer 6, cooling this material to the temperature of water vapor, and then, through the drain holes 5 in the outer shock-resistant layer 4 go beyond Properties.

To create conditions for the most efficient cooling of the intermediate heat-shielding layer with 6 water vapor, it is necessary to maintain an excessive vapor pressure inside the outer shock-resistant layer 4, which is ensured by the choice of a certain ratio between the diameter of the drainage hole 5 and the thickness of the outer shock-resistant layer 4.

When the ratio of the diameter of the drainage hole 5 to the thickness of the outer shockproof layer 4 exceeds 0.5, free flow of water vapor through the drainage holes 5 occurs, and no excess pressure is created inside the outer shockproof layer 4. In the case when the specified ratio does not exceed 0.5, the effect of throttling of water vapor through the drainage holes 5 is observed, causing excessive pressure inside the outer shock-resistant layer 4, the greater the smaller the value of the specified ratio.

However, with a significant reduction in the ratio to a value of 0.1, it is possible to clog the drainage holes 5 with the thermal destruction products of the intermediate heat-shielding layer 6, the inner heat-shielding layer 7 and, as a result, decrease the cooling efficiency of the intermediate heat-shielding layer 6 with steam. Therefore, the ratio of the diameter of the drainage hole 5 to the thickness of the outer shock-resistant layer 4 is chosen to be greater than 0.1 and not exceeding 0.5.

Thus, new significant features provide protection of the stored microelectronic object when exposed to mechanical and thermal overloads, including the comprehensive exposure to high temperature of 1100 ° C for 1 hour, as well as long-term comprehensive exposure to elevated temperature of 260 ° C for 10 hours.

Claims (1)

A device for thermal and mechanical protection of an object, consisting of successively arranged layers: an external shock-resistant layer made of heat-resistant metals, an intermediate heat-protective layer made of refractory dry porous material, and an internal heat-protective layer formed of a water-containing material enclosed between the external and internal heat-reflecting gaskets, characterized in that an additional bimore is formed on the outer surface of the outer shock-resistant layer a full heat-insulating coating of a heat-insulating composite material with adhesion to the surface of the outer shock-resistant layer and the ability to increase in volume by at least 10 times when heat is applied by a flame to it, while the outer shock-resistant layer is perforated with through drainage holes, the diameter of each of which does not exceed half the thickness of the outer shock-resistant layer, heat-reflecting gaskets are made of metal foil, and the external heat-reflecting gasket is per is formed, and the inner heat-shielding layer is formed using at least two crystalline hydrates, such that the dehydration temperature of one of them exceeds the dehydration temperature of the other by at least two times.