RU2182293C1 - Wood drying and working device - Google Patents

Abstract

FIELD: wood working at drying of wood and lumbers, for example, boards, cants, blanks of various shapes, applicable in working of other fibrous materials based on wood or having similar conditions of drying, in working of poor wood species, such as asp, as well as for production of high-quality wood and manufacture of products of various complex shape, in particular, musical instruments. SUBSTANCE: the device has heat-insulated sealed chamber 1 accommodating container 2 with a rack and/or spacers, whose floor and ceiling are provided with holes producing a flow of gaseous atmosphere inside container 2 with the aid of fans 5 installed in the ends faces of sealed chamber 1 and directed upwards, gaseous atmosphere heating device 9 is positioned under the floor of container 2, and/or along its side walls, and/or above its ceiling, and the outlet device is provided with actuator valve 8 for control of the pressure variation rate in the sealed chamber. For enhancing the uniformity of circulation of the flow of gaseous atmosphere inside the container and, respectively, for enhancing the uniformity of wood heating the following condition must be satisfied: S₁>S₂, and S₄>S₃, where S₁ - the fan outlet area; S₂ - the total area of holes in the container floor; S₃ - the total area of holes in the container ceiling; S₄ - the fan outlet area. EFFECT: enhanced uniformity of flow rate of gaseous atmosphere and its temperature inside the sealed chamber in the container, which results in enhancing of uniformity of moisture evaporation by the volume of dried wood, maintained preset parameters of the gaseous atmosphere pressure temperature and humidity. 14 cl, 3 dwg

Description

 The invention relates to the field of heat-moisture processing of materials and can be used in the field of processing wood and wood materials in the woodworking industry when drying lumber, for example boards, beams, blanks of various shapes. In the processing of other fibrous materials based on wood, cellulose or others having similar drying conditions. The claimed invention relates to a device that can be used for chamber drying of sawn timber of any wood species and is particularly effective both in the processing of hardwood, such as, for example, oak, beech, ash, and low-value wood, such as, for example, aspen, as well as for obtaining high-quality wood and products from it of various shapes, in particular, in the manufacture of musical instruments.

 The drying process involves the extraction of moisture saturating the material on its surface and its removal from the surface. It is known that when drying fibrous materials such as wood, two main processes occur simultaneously: heat transfer to evaporate the liquid and mass transfer of the liquid inside the material to be processed to its surface through capillary channels.

 The movement of moisture in wood occurs in liquid and gaseous (steam) form in accordance with the laws of fluidity and diffusion of liquid and gas and changes in the capillary properties of the material due to its thermal expansion. Factors affecting these processes determine the rate and degree of moisture removal from the material during its drying.

 Under natural conditions, the drying of materials is carried out by air having the temperature and humidity of the environment in which the drying takes place. In this case, air is a heat carrier and transfers to the material and the liquid in it the heat necessary for the evaporation of the liquid. Therefore, drying in natural conditions requires considerable time and only allows you to get the moisture content of the material, corresponding to the humidity of the air.

 Compared to drying under natural conditions, the use of drying chambers significantly reduces the duration of the drying process and makes it possible to obtain the required material properties.

 There are various designs of drying chambers from the simplest, which are simply shelter from precipitation, made in the form, for example, of a canopy, to vacuum chambers in which the material is heated by high-frequency currents (UHF).

 A device for drying wood is known (US 4620373, F 26 B 5/04, 1986), comprising a drying chamber with a platform for accommodating a stack of layered wood, heaters, evaporators, a cooling system and a compressor for condensing steam, a pump for removing condensate and container for collecting removed moisture, temperature sensors in the stack. In this device, heaters, transferring heat to wood and air in the drying chamber, accelerate the process of removing moisture from wood.

 A known drying unit (SU 1191703, F 26 B 3/347, 1983), containing a sealed cylindrical housing with thermal insulation, a drying chamber and a drying agent path connected to it with flow distribution means. The dryer contains a condenser, a fan, and an air heater arranged in series with the drying agent. In addition, it includes a vacuum pump, a condensate drain pipe connected to the bottom of the body, and an outside air inlet pipe equipped with shutoff valves. The path of the drying agent is made in the form of an external channel with respect to the housing, connected at the opposite ends of the housing and equipped with a drain pipe in the area where the condenser is located, which, together with the bottom drain pipe, is connected to a vacuum condensate collector.

 The distribution agent of the drying agent is made in the form of screens placed on the side wall of the housing, an external air inlet pipe is connected to the upper part of the housing. The installation is equipped with means for dielectric heating of the material. The unit is used for vacuum convective drying, without the use of dry outdoor air, because the outside air is only allowed to discharge the vacuum. The thermal energy of condensation is not used in the installation, and a special vacuum collector is used to collect condensate. Due to the fact that the humidity of the drying agent is limited only by the moisture content of the material, the technological capabilities of the installation are limited only by drying and it is impossible to carry out other types of thermo-wet processing, for example, conditioning dry wood. Thus, the installation is complex in design, limited technological capabilities and not fully utilized energy capabilities.

 Known devices for drying wood do not allow for the evaporation of moisture from wood while maintaining the structure of the wood during all periods of drying, because do not contain the necessary funds for this. In known devices, the controls of the environmental parameters in the drying chamber support certain predetermined averaged drying modes, usually at reduced pressure. In this case, the drying conditions do not correspond to periods with a constant and decreasing rate of moisture evaporation, and the processes of forcing out resinous substances and moisture evaporation are combined. This leads to an increase in drying time, a decrease in the quality of wood and an increase in energy consumption.

 The closest in purpose and combination of features to the claimed invention is a device for drying and processing wood (RU 2137995, F 26 B 9/06, 1999). This device includes a sealed chamber with thermal insulation, a device for placing wood, a device for heating a gas medium, a device for circulating a gas medium inside a sealed chamber, which includes a fan and distribution devices, an exhaust device with a condenser, a vacuum pump, a temperature and humidity control system.

 This wood drying and processing apparatus uses heated air as a drying agent. The heater, made in the form of a heater, is located above the stack of the processed material. The circulation of heated air is carried out horizontally in the sealed chamber due to the fact that guide vanes are installed in one side wall of the switchgear screen, made in the form of a distribution grid, and a fan suction hole is located on the opposite side wall of the screen. The bottom of the sealed chamber is made without thermal insulation and serves as a moisture condenser. In the same part of the sealed chamber, there are means for draining the condensate and letting in external air.

 The known device for drying and processing wood does not provide the required uniformity of heating of wood during the drying process due to the horizontal direction of the flow of the drying agent, which is heated air, and side blowing of the wood stack, and also due to the lack of complete thermal insulation of the sealed chamber in the lower part which is condensation of the released moisture and the influx of cold atmospheric air at the first stage of drying. Uneven heating of the wood leads to uneven shrinkage and, as a result, to the appearance of a lead of lumber. The influx of cold atmospheric air into the chamber during drying leads to an increase in the consumption of energy for its heating. The presence of only a temperature and humidity control system does not allow maintaining the optimal temperature and pressure of the gaseous medium in a sealed chamber at which moisture and resinous substances are released from the wood without violating its structure.

 The technical problem to which the present invention is directed is to provide a device for drying and processing wood, in which physical drying conditions are realized, providing quantitatively controlled extraction of moisture from the wood, increasing the uniformity of heating of the entire volume of wood placed in the device.

When solving this problem, the following technical results are achieved:
1. an increase in the uniformity of the flow rate of the gaseous medium and its temperature inside the sealed chamber in the container, which leads to an increase in the uniformity of moisture evaporation in the volume of dried wood and in its length,
2. the ability to maintain the specified parameters of the temperature of the pressure and humidity of the gaseous medium, providing a decrease in the hygroscopicity of wood due to the filling of pores freed from water with resinous substances,
3. increasing the density of wood without changing the shape due to a more uniform shrinkage of wood as a result of increasing the uniformity of moisture and resinous substances from the wood, ensuring uniform shrinkage of wood up to 20% by volume, increasing the uniformity of the distribution of strength properties over the volume of wood, across and along the fibers beyond account for providing a given distribution of the flow rate of the gaseous medium in a sealed chamber
4. improving the efficiency and effectiveness of the installation due to the direction of the gas flow from the bottom up,
5. providing the ability to obtain a given color of wood during its processing under specified conditions of temperature and pressure, due to the color change of chemical compounds in the wood in a natural state.

 To achieve technical results, a device for drying and processing wood, consisting of a sealed chamber with thermal insulation, a device for placing wood, a device for heating a gas medium, a device for circulating a gas medium inside a sealed chamber, which includes a fan and a distribution device, an exhaust device with a condenser , a temperature and humidity control system, an additional gas pressure control system has been introduced, associated with a temperature and humidity control system. The thermal insulation of the sealed chamber is made in such a way that it is completely thermally insulated. A device for placing wood, functionally combined with a distribution device, is made in the form of a container in which a rack and / or gaskets can be located. The floor and ceiling of the container are provided with openings that provide inside the container with at least one fan installed in the end of the sealed chamber, the flow of the gas medium directed from the bottom up. The device for heating the gas medium is located under the floor of the container, and / or along its sides, and / or above the ceiling of the container, and the exhaust device is equipped with a control valve to adjust the rate of change (decrease or increase) in pressure in the sealed chamber.

It is advisable to increase the uniformity of the flow of the gaseous medium inside the container and, accordingly, increase the uniformity of heating the wood, the following conditions: S ₁ > S ₂ , and S ₄ > S ₃ , where S ₁ is the cross-sectional area of the fan outlet, S ₂ is the cross-sectional area of the holes in the container floor, S ₃ is the cross-sectional area of the holes in the container ceiling, S ₄ is the cross-sectional area of the fan inlet.

 Preferably, in the device for heating the gas medium, the heating elements are located with a gap for the passage of the gas stream along the length of the dried material, and some of them were made in the form of thermoelectric heaters.

 It is also advisable that in the device for heating the gas medium, part of the heating elements was made of pipes with a diameter of 15-20 mm, in which water or steam circulate as a heat carrier.

 In addition, in the device for heating the gas medium, part of the heating elements can be made in the form of thermoelectric heaters, and part in the form of pipes in which steam or water circulate as a heat carrier.

 It is advisable for wood processing that at least one heating element made in the form of a pipe has at least one means, for example, an adjustment valve or a hole for the inlet of water and / or steam, and / or their mixture into an airtight the camera.

 Preferably, the floor of the container is removable with wheels so that it acts as a cart for moving, loading and unloading wood from the chamber.

 It is advisable to equip the device for heating the gas medium with a control system and adjust the temperature of the heating elements.

 At the same time, it is also advisable that the temperature, humidity and pressure control systems of the gas medium in the chamber, as well as the temperature control and adjustment system of the heating elements, are connected to a controller connected to the control valve of the exhaust device to increase the accuracy of adjustment and maintain the desired drying and wood processing mode .

 To increase the uniformity of the distribution of the evaporation rate along the length of the chamber, it is advisable to make shelves in the form of a grid made of a metal bar with a diameter of 10-12 mm.

 Inside the container there is a rack, the shelves of which are made in the form of a grid made of a metal bar with a diameter of 10-12 mm or gaskets made in the form of a L-shaped and / or T-shaped metal bar.

 The device can be equipped with two fans, one of which is installed on the opening cover.

 The device may be further provided with a device for filling the sealed chamber with inert and / or carbon dioxide and / or a neutralizing agent and / or a mixture thereof.

 It is advisable to provide the control valve with a control mechanism connected to a system for monitoring the temperature, humidity and pressure of the gas medium.

Figure 1. General view of a device for drying and processing wood, where
1 - sealed chamber with thermal insulation,
2 - a device for placing wood,
3 - the cavity under the container,
4 - cavity above the container,
5 - fan
6 - removable end panel of the container,
7 - removable floor of the container, made in the form of a trolley equipped with wheels,
8 - control valve of the exhaust device,
9 - a device for heating a gas medium in a sealed chamber,
10 - vacuum pump
11 is an exhaust device including a capacitor,
12 - overpass for loading and unloading a sealed chamber,
13 - gaskets providing the required clearance for the circulation of the gas medium,
14 - pump, providing a coolant in a device for heating a gas medium,
15 - a device for heating the coolant,
16 - compensation tank.

FIG. 2. The scheme of circulation of the gas medium inside the sealed chamber, a longitudinal section, where
1 - sealed chamber with thermal insulation,
2 - a device for placing wood,
3 - the cavity under the container,
4 - cavity above the container,
5 - fan
6 - removable end panel of the container,
7 - removable floor of the container, made in the form of a trolley equipped with wheels,
8 - control valve of the exhaust device,
9 - a device for heating a gas medium in a sealed chamber,
17 - holes in the floor and ceiling of the container for the passage of the gas medium
Figure 3. The scheme of the circulation of the gas medium inside the sealed chamber, cross section.

 Information confirming the possibility of carrying out the invention.

A device for drying and processing wood, contains a sealed thermally insulated chamber 1 with thermal insulation. The sealed chamber 1 is a cylindrical vessel, operating with variable pressure (0.05 - 5 kg / cm ² ) and temperature (5 - 200 ^o C), in one of the ends of which a sealed door is arranged.

 A cylindrical vessel is placed in a box, also opening from one of the ends, designed to insulate the working cavity and place the units providing the drying cycle.

 The device for placing wood is made in the form of a collapsible container 2 with a rack and / or gaskets 13, the floor 7 and the ceiling of which are provided with holes 17. A material to be drained, for example wood, is placed inside the sealed chamber 1 in the box 2, which is a parallelepiped (Fig. 2, 3 ) inscribed in the cylinder.

 Wood, such as lumber, can be stacked on a rack made in the form of a grid of a metal bar with a diameter of 12 mm, or separated by spacers 13 to provide the required clearance in the stack. The gas flow pumped by at least one fan 5, rising through a section of 20 mm, is divided into two parts and passes into the forming channels of 10 mm. Such a stacking system and the aspect ratio between the boards in width and height allows the gases circulating inside the sealed chamber to evenly wash the entire surface of the board. Between the side surfaces of the stack and the side walls of the container 2, the distance is about 10 mm.

Given the inefficiency of the movement of gases under natural thermal circulation, a forced internal circulation system is introduced in the sealed chamber, which intensifies the natural gas flow. For this, the fan 5, installed at the end of the sealed chamber 1, provides the circulation of the gas medium. Additionally, to increase the flow rate of the gaseous medium, a second fan can be installed on the opening cover of the sealed chamber. The holes 17 in the floor 7 and the ceiling of the container are made in such a way that they allow you to get the specified flow of the gas medium along the entire length of the container 2. It has been experimentally established that in order to increase the uniformity of the flow of the gaseous medium inside the container and to increase the intensity of heat exchange between the gaseous medium and wood placed in a sealed chamber, it is advisable to fulfill the following conditions: S ₁ > S ₂ and S ₄ > S ₃ , where S _{1 is} the cross-sectional area the fan outlet, S ₂ is the cross-sectional area of the openings in the container floor, S ₃ is the cross-sectional area of the openings in the container ceiling, S ₄ is the cross-sectional area of the fan inlet.

The centrifugal fan 5 (FIG. 2) of the internal circulation system is installed in the “blind” end of the sealed chamber 1. The fan 5 from the outlet opening having a cross-sectional area S ₁ directs the flow of the gas medium into the cavity 3, under the container 2, for example, with lumber, passing through the radiator of the gas medium heating device 9, located under the floor of the container, and the holes 17 in the floor of the container 7, the cross-sectional area of which is S ₂ , the heated gas medium, which is atmospheric air, which has filled hermetically when loading wood into it, it enters the stack with lumber and, passing through it up through the openings in the container ceiling, the cross-sectional area of which is S ₃ , enters the cavity 4 between the container ceiling and the wall of the sealed chamber 1, moves to the fan inlet 5 whose cross-sectional area is S ₄ .

 Perforation (holes 17) in the floor is designed for a given distribution of the gas pressure field under the floor of the container, which makes it possible to provide the necessary gas velocity along the length and width of the container floor and at the entrance to the stack.

The perforation can be arranged in such a way that the total area S _{1 of the} holes uniformly distributed on the floor of the container is approximately 1/5 (20%) less than the total area S _{2 of the} outlet openings (there are two of them), which can be, for example, two. This provides increased pressure under the floor of the container and allows you to get a uniform gas flow in all openings of the floor, regardless of their remoteness from the fan 5.

The total area S _{3 of the} cross section of the openings on the container ceiling is approximately 1/5 (20%) less than the area S _{4 of the} fan inlet, which in turn creates a reduced pressure zone above the container ceiling and, accordingly, ensures a uniform gas flow through the openings in the container ceiling .

 In some cases, depending on the quantity and shape of the wood loaded into the container, the number and diameter of the holes 17 or their area can vary along the length of the floor 7 and the ceiling of the container to increase the uniformity of the flow of the gas medium passing through them and increase the uniformity of heating of the wood.

 Organized in this way, the internal circulation of the gaseous medium makes it possible to realize intense heat transfer in a stack of lumber, constantly supplying heated gases and taking away the temperature-giving wood, provided that the temperature and gas flow fields are uniform.

 The reduced pressure zone of the internal circulation system is located only in the cavity formed by the ceiling of the container and the wall of the sealed chamber. In all other cavities, such as the cavities formed by the side walls of the container and the wall of the sealed chamber, the floor of the container and the wall of the sealed chamber, the end part of the sealed chamber from the side of the loading door and the end wall of the container formed by the removable panel 6, occupies a pressure zone. Such a large total cross-sectional area for gases moving in the high pressure zone at high speed avoids unnecessary heat loss.

 The device for heating the gas medium 9 is located under the floor of the container and can also be along its lateral sides. To ensure a predetermined temperature field in the stack, under the floor 7 of the container 2 along its length there is a device 9 for heating the gas medium, made, for example, in the form of pipes connected to a register in which the coolant circulates, which can be used, depending on the used thermal installation, or superheated water with the required temperature or steam. The register is a radiator of pipes with a diameter of 15-20 mm with a total heat transfer area of about 300 square meters. m. The direction of the coolant currents in the radiator is organized in such a way that in each adjacent pipe the coolant moves in the opposite direction, which ensures a uniform temperature field along the length and width of the register.

 To increase the efficiency and economy of the installation, part of the heating elements of the gas medium heating device can be additionally installed above the container ceiling.

 The energy carrier participating in the operation of the device for heating the gas medium of the sealed chamber can be any (including firewood). If thermoelectric elements are used as the device 9 for heating the gaseous medium, then the energy carrier is electricity and a source of electricity of the corresponding power is used.

If a register is used as the device 9 for heating the gas medium, then, depending on the type of energy carrier, two heat carriers are possible: water or steam. In this case, the device for heating the coolant 15, i.e. the source of steam, for example, can be a steam boiler of the OGV type with a capacity sufficient to provide the necessary amount of steam for heating the gas medium of a specific pressurized chamber, depending on its loading volume. Also, as a device for heating the coolant 15, water heating can be applied with the help of electrotenes, which are installed in a container that allows you to raise the water temperature to 150 ^o C at a pressure of 5 kg / cm ² . The circulation of fluid in the register is provided by a circulation pump.

 The gas medium, passing through the heating device 9, heats up and enters the wood. Due to the processes of heat and mass transfer, wood is heated, the release and evaporation of moisture that saturates it. The predetermined mode of drying and processing of wood is monitored and maintained using installed sensors of temperature, pressure and humidity of the gas environment, as well as temperature and humidity of wood connected to the controller. The change of mode can be carried out by changing the temperature of the heating device 9, either by changing the speed of circulation of the gas medium, or by changing the pressure of the gas medium in the sealed chamber. When the wood is heated, the moisture released from it turns into steam, which increases the pressure of the gas medium in the sealed chamber.

 In some cases, to increase the heat capacity of the gaseous medium circulating in the sealed chamber, at the beginning of the heating cycle, it is possible to supply water or water vapor, or a mixture thereof, to the sealed chamber.

 To maintain the required pressure in the sealed chamber 1, an exhaust device 11 is used.

 The exhaust device 11 (Fig. 1) is a condenser for separating and purifying liquids released from wood with containers for collecting them. It is located above the pressurized chamber and is equipped with an adjustment valve 8, which provides the vapor-gas mixture from the pressurized chamber at a given speed, determined by the required rate of pressure change in the pressurized chamber during the drying and processing of wood.

 The control mechanism of the control valve is connected to a system for monitoring the temperature, humidity and pressure of the gas medium and to a controller that provides the required drying and processing of wood.

 The condenser provides during the cooling and condensation of the vapor-gas mixture discharged from the sealed chamber, its separation into water and other components released from the wood during drying, their cleaning and collection. The gas medium is discharged from the sealed chamber 1 at a certain speed by means of a control valve 8, which can be made, for example, in the form of a valve through which the gas medium discharged from the sealed chamber, passing through a condenser mounted on top of the drying chamber, is cooled and divided into fractions. The liquid resulting from condensation, removed from the wood, is cleaned and collected for further processing.

 After reducing the pressure of the gaseous medium in the sealed chamber 1 below atmospheric, the vacuum pump 10 takes over the work to remove the gaseous medium from the sealed chamber. It can be installed on top of the sealed chamber 1 in the pipeline between the control valve 8 and the condenser. The supply line to it is thermally insulated to prevent premature condensation. The pump inlet is located above the outlet to effectively drain moisture from the vacuum pump. The vacuum pump must provide a pressure reduction in the sealed chamber 1, at least up to 10 Pa.

 The specific technical characteristics of the fan, radiator, heater, and vacuum pump are determined by the volume of the specific sealed chamber and the desired rate of temperature rise in the chamber. Any fan, radiator, heater, and vacuum pump that are suitable for their technical characteristics can be used.

To maintain the required temperature and pressure modes during drying and wood processing, a temperature, pressure and humidity control system for the gas medium is used, as well as a temperature control and adjustment system for the heating elements of the gas medium heating device 9. For this, temperature and humidity sensors, temperature, pressure and humidity sensors for the gas medium, as well as temperature sensors for the heating elements of the gas medium heating device 9 are installed in the sealed chamber 1. The control valve 8 of the exhaust device can be equipped with a servo-drive for automatically changing the degree of its opening, as well as means for changing the direction of the flow of the gaseous medium discharged from the sealed chamber 1. The flow of the gaseous medium can be directed directly to the condenser or, if The pressure in the sealed chamber 1 reaches the outside through the vacuum pump. The heating elements may be provided with a device for adjusting their temperature. The outputs of the sensors are connected to the inputs of the controller, and the input of the servo drive of the control valve and the input of the device for adjusting the temperature of the heating elements are connected to its outputs. A computer can be used as a controller
To increase productivity, the floor 7 of the container 2 is equipped with wheels and is a trolley. The container is equipped with at least two of these carts. In the process, one truck, on which a stack of lumber is laid, is in a sealed chamber, and the other is overloaded at this time.

Claims (14)

1. A device for drying and processing wood, containing a sealed chamber (1) with thermal insulation, a device (2) for placing wood, a device for heating a gas medium (9), a device for circulating a gas medium inside a sealed chamber, consisting of a fan (5) and a distribution device, an exhaust device (8) with a condenser (11), a temperature and humidity control system, characterized in that the temperature and humidity control system is additionally equipped with a gas pressure control system, a sealed chamber (1) thermally insulated, a device for placing wood, functionally combined with a switchgear, is made in the form of a container (2), which provides at least one fan (5) for circulating the flow of the gas medium, the device (9) for heating the gas medium is located under the floor of the container, and / or along its lateral sides and / or above its ceiling, the exhaust device (11) is equipped with an adjustment valve (8), and the floor and ceiling of the container are equipped with openings, the dimensions of which ensure that S ₁ > S ₂ and S ₄ > S ₃ where S ₁ is the cross-sectional area of the fan outlet, S ₂ is the total cross-sectional area of the holes in the container floor, S ₃ is the total cross-sectional area of the holes in the container ceiling, S ₄ is the cross-sectional area of the fan inlet.  2. The device according to claim 1, characterized in that in the device (9) for heating the gaseous medium, the heating elements are arranged with a gap that allows the passage of the gaseous medium along the length of the material to be dried, and some of them are made in the form of thermoelectric heaters.  3. The device according to claim 1 or 2, characterized in that in the device for heating the gas medium, part of the heating elements is made of pipes with a diameter of 15-20 mm, in which water or steam circulates as a heat carrier.  4. The device according to any one of paragraphs. 1-3, characterized in that in the device for heating the gas medium, part of the heating elements is made in the form of thermoelectric heaters, and part in the form of pipes in which steam or water circulates as a heat carrier.  5. The device according to any one of paragraphs. 1-4, characterized in that at least one heating element has at least one means for the inlet of water and / or steam, and / or mixtures thereof into an airtight chamber.  6. The device according to any one of paragraphs. 1-5, characterized in that the device for heating the gas medium is equipped with a system for monitoring and adjusting the temperature of the heating elements.  7. The device according to any one of paragraphs. 1-6, characterized in that the control system for temperature, humidity and pressure of the gas medium, as well as a system for monitoring and adjusting the temperature of the heating elements are connected to the controller associated with the control valve of the exhaust device.  8. The device according to any one of paragraphs. 1-7, characterized in that it is additionally equipped with a vacuum pump connected to the exhaust device.  9. The device according to any one of paragraphs. 1-8, characterized in that the floor of the container is removable in the form of a trolley.  10. The device according to any one of paragraphs. 1-9, characterized in that a container is located inside the container, the shelves of which are made in the form of a grid made of a metal bar with a diameter of 10-12 mm.  11. The device according to any one of paragraphs. 1-10, characterized in that inside the container there are gaskets made in the form of a L-shaped and / or T-shaped metal bar.  12. The device according to any one of paragraphs. 1-11, characterized in that it is equipped with two fans, one of which is mounted on an opening lid.  13. The device according to any one of paragraphs. 1-12, characterized in that it is further provided with a device for filling the sealed chamber with an inert and / or carbon dioxide, and / or a neutralizing agent.  14. The device according to any one of paragraphs. 1-13, characterized in that the control valve is equipped with a control mechanism connected to a system for monitoring the temperature, humidity and pressure of the gas medium.

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