RU2040744C1 - Vacuum dielectric drying chamber - Google Patents

Abstract

FIELD: wood-working industry. SUBSTANCE: drying chamber has tight housing 1, evacuating system, system for water cooling of housing 1, system for collecting and discharging condensate, high- frequency generator 4, system for supplying high- frequency voltage to electrodes 7 to provide uniform electric field both over the length of stack 3 of material to be dried and over the height owing to increasing the number of points for supplying power to electrodes 7 and positioning the electrodes at an 0.5-2.0 deg angle with respect to walls of stack 3. EFFECT: more uniform heating of wood. 4 cl, 2 dwg

Description

 The invention relates to techniques for drying wood and can be used in woodworking, furniture and other industries, mainly for drying hard hardwood and coniferous hard-drying species.

 Known vacuum-dielectric drying chamber for wood, containing a sealed enclosure with a stack of dried material placed in it, connected to a vacuum pump, a high-frequency generator connected to the electrodes located horizontally in the cavity of the casing.

 The known device is equipped with a complex mechanism of pressing and moving the electrode, and the characteristics of the dried material located in different parts of the stack can be heterogeneous.

 A vacuum dielectric wood dryer is known, comprising a sealed enclosure, a cart for moving a stack of wood, a vacuum pump, a condensate collection and removal system, and a high-frequency generator connected via conductive busbars to electrodes located on both sides of the stack side walls. This technical solution is the closest to the proposed.

 In the known device due to the heterogeneity of the generated electric field is also observed heterogeneity of the characteristics of the dried material both in length and in height of the stack.

 The purpose of the invention is to improve the quality of drying by increasing the uniformity of the electric field created in the chamber.

 In FIG. 1 schematically depicts the described drying chamber a longitudinal section; figure 2 is a transverse section of the camera.

 The drying chamber contains a sealed housing 12, a trolley 2 for moving a stack of 3 dried lumber, a vacuum pump, a body water cooling system and a condensate collection and removal system. A high-frequency generator 4 and a device for its air cooling with a channel for supplying cooling air and a channel 5 for removing heated air are installed on a platform located above the housing 1.

The generator 4 is connected through conductive busbars 6 to electrodes 7 arranged in the form of perforated plates located on both sides of the side walls of the stack 3 on the inside of the housing. The number of contact points in the upper part of each electrode can be from 4 to 16, depending on the length of the stack 3 and the required uniformity characteristics of the generated electric field. The electrodes 7 have a length of 1.02-1.1 of the maximum length of the stack 3 and a height of 1.1-1.4 of its height and are located at an angle of 0.5-2.0 ^about to the vertical with the formation with the side walls of the stack 3 of the gap, the magnitude of which increases in the direction from top to bottom, and adjacent to the upper sections of the stack 3.

In the upper part of the housing 1 is sealed enclosure 8, which cavity communicates with the heated air discharge conduit 5 of the air cooling unit of the generator 4. For a better condensate base body 1 may be arranged at an angle to the horizontal ^of 1-1.5.

 The drying chamber operates as follows.

A stack of 3 dried lumber is placed between the electrodes 7 in the housing 1 and the location of the electrodes 7 is fixed, after which the doors of the housing 1 are hermetically closed. Air is pumped out of the housing 1 using a vacuum pump, and the pressure of the medium inside the housing 1 is reduced to 0.2-0.08 atm. Then, the high-frequency generator 4 is turned on and the material is heated, the intensity of which depends on the moisture content of the wood, the electric field in which it is located, and is controlled by a change in the electric field strength. The increase in the feeding points of the electrodes 7 and their placement at an angle relative to the walls of the stack 3 helps to increase the uniformity of the electric field both along the length and height of the stack 3. To ensure high quality and drying speed of wood, optimal values of the RF field strength and residual pressure in the chamber are selected . To eliminate cracking due to internal stresses during drying of high density wood, several stages of drying (different values of the RF field strength and residual pressure) of different durations are set. The steam extracted from the wood is condensed on the pipes of special coolers of the water cooling system of the housing 1. The presence of a metal casing 8 in the upper part of the housing 1, into which the air heated after the high-frequency generator is discharged, eliminates the condensation of steam on the chamber vault and condensate droplets falling onto the stack of 3 pilometals in drying process. Due to the inclination of the base of the housing 1 by 1-1.5 ^about condensate through a hole in the wall by gravity enters the condensate tank. The main sign of the end of drying is the condensate evolution of a predetermined volume measured by the electronic system.

 The proposed drying chamber is very effective for high-speed drying of valuable wood species in the first quality category, as well as for drying timber and is easy to use.

Claims (4)

1. VACUUM-DIELECTRIC DRYING CHAMBER for wood, containing a sealed enclosure, means for moving a stack of wood, a vacuum system, cooling the chamber, collecting and removing condensate, and a high-frequency generator with a system for supplying high-frequency voltage to the electrodes located in the cavity of the housing on both sides relative to the side walls of the stack, characterized in that the voltage supply system includes conductive busbars installed in contact with 4 16 points in the upper part of each electrode, with than the electrodes adjacent to the side walls of the stack in its upper part and are located at an angle of 0.5 to 2.0 ^o to the vertical with the formation between them and the side walls of the stack of gaps, the value of which increases in the direction from top to bottom.  2. The chamber according to claim 1, characterized in that the electrodes are made in the form of perforated plates with a length of 1.02 1.1 maximum stack length and a height of 1.1 1.4 stack height.  3. The camera according to paragraphs. 1 and 2, characterized in that the generator is equipped with an air cooling device with channels for supplying cooling air and for discharging heated air, and in the upper part of the body there is a metal casing, the cavity of which is in communication with the aforementioned channel for discharging heated air. 4. The camera according to paragraphs. 1 and 2, characterized in that the base of the housing is located at an angle of 1 1.5 ^o to the horizontal.

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