RU2157489C2 - Wood-drying plant - Google Patents

Abstract

FIELD: wood-working industry, applicable for drying of wood and other water-containing materials. SUBSTANCE: two sealed heat-insulated chambers, with a circulating duct in the cavity of each of them accommodating a blower and an air heater, have air conduits interconnecting the cavity for by-pass of steam successively formed in one of the chambers. The air conduits connected the regions of raised pressure of each chamber to the regions of lowered pressure of the adjacent chamber. Controlled dampers are installed in each air conduit. EFFECT: considerably reduced power consumption connected with wood drying at minium capital investments due to the use of water vapors formed at drying of one lumber pile for heating of the other pile. 3 cl, 1 dwg

Description

 The invention relates to the woodworking industry and can be used for drying wood, as well as other water-containing materials.

 Known drying chambers containing a thermally insulated body, in the cavity of which there is a circulation channel with a fan and a heater located in it [1].

 A stack of lumber located in the chamber is exposed to the action of a drying agent circulating in the chamber heated by a heater. Water vapor formed during the drying of sawn timber is released into the atmosphere through an exhaust window equipped with a controlled gate. In this case, the energy spent on the evaporation of water is lost. A known method of heat recovery using a heat pump [1, p. 116]. However, this method has not found wide application due to its inherent disadvantages: a significant increase in capital investments and operating costs. Recuperators for heating the fresh air entering the chamber due to the heat of the spent drying agent are also known. But at the same time, energy consumption is reduced by only a few percent due to the low heat content of the dry air entering the chamber and is not recommended for batch kilns [1, p. 122].

 The purpose of the invention is the reduction of energy costs for drying wood with minimal capital investment through the use of water vapor generated by drying one stack of lumber to heat another stack.

 This is achieved by the fact that two sealed thermally insulated chambers, in the cavity of each of which a circulation channel is formed with a fan and air heater located in it, contain air ducts connecting these cavities. Ducts connect the areas of high pressure (behind the fan) with the areas of low pressure (in front of the fan) of each chamber. Each duct has a controlled gate. Loading a stack of lumber in one of the chambers is done after the heating of the lumber is finished in the other chamber and the intensive evaporation of water has begun. In this case, the warming of the newly loaded stack occurs due to the supply of steam generated in the adjacent chamber through the duct connecting these chambers.

 The drawing schematically shows the proposed installation.

 The installation consists of two heat-insulated chambers 1 and 2, separated by a sealed partition 3. In each chamber above the false ceiling 4 there is a fan 5 and air heater 6. The chambers are interconnected by air ducts 7 and 8, in which controlled gates 9 are installed. Each chamber can have a stack of lumber 10 is placed.

 The procedure for working on the installation is as follows. A stack is loaded into one of the chambers (for example, chamber 1). When the fan and heater are switched on, the stack is heated in a known manner (without air exchange with the environment) [2,3]. After reaching the temperature set in the drying mode in the chamber 1, the stack is loaded into the chamber 2, the fan of this chamber is turned on and the gate opens in the duct 7 connecting the high pressure region of the chamber 1 with the low pressure region of the chamber 2. Water vapor coming from the chamber 1 to the chamber 2, they condense on the stack, heating it, and condensate flows to the bottom of the chamber and is removed. Towards the end of drying the stack in chamber 1, the stack in chamber 2 is already heated to a temperature close to that set by the drying mode. After replacing the stack in the chamber 1, the process proceeds in the opposite direction, and the air source for the evaporation of water in the chamber 2 is a heater.

Consider the energy parameters of the process when drying a pine board with an initial humidity of 60% to a final humidity of 12% at an average annual temperature of +4 ^o C in various modes. The mass of 1 cubic meter of board is 640 kg, the amount of evaporated water is 192 kg.

1. Normal operation with a drying temperature of 85 ^o C.

Energy consumption for heating the material
Q _ave = pxC • (t _m - t _o),
Q _ave = 640 • 3 • (85-4) = 155500 kJ.
where C is the heat capacity of wood.

Heat consumption for evaporation
The heat content of 1 kg of steam at 85 ^o C - 2650 kJ.

Heat consumption for evaporation of 1 kg of water
q = i - Cb • 85 = 2650 - 4.19 • 85 = 2300 kJ
The total heat consumption for evaporation of 192 kg of water
Q _use = 2300 • 192 = 441600 kJ
Total heat consumption
Q = Q _pr + Q _pr = 597100 kJ
Since the heating of the boards is due to the energy of the steam obtained by drying the stack in an adjacent chamber, energy from external sources is not consumed for heating.

Energy savings will be E = Q _pr / Q = 0.26 or 26%.

2. High temperature with a drying temperature of 120 ^o C.

 This drying mode is increasingly used with the use of additional energy sources such as high or ultra high frequency currents. Calculation by the same methodology as in clause 1 shows that energy savings will be 33.6%.

 Thus, the proposed device without significant capital costs and without increasing operating costs allows you to save a significant part of the energy spent on drying.

Literature
1. P.V. Sokolov, G.N. Kharitonov, S.V. Dobrynin, "Forestry chambers", - M .: Forestry industry, 1987

 2. RF patent N 2030698.

 3. RF patent N 2027127.

Claims (3)

 1. Installation for drying wood, containing two sealed thermally insulated chambers, in the cavity of each of which a circulation channel is formed with a fan and a heater located in it, characterized in that the chamber cavities are connected by air ducts with the possibility of alternating bypassing formed in one of the chambers couple.  2. Installation according to claim 1, characterized in that the ducts interconnect the areas of high pressure (behind the fan) with areas of low pressure (in front of the fan) of each chamber.  3. Installation according to claim 1, characterized in that the ducts are equipped with controlled gates.