RU2360793C1 - Device for orientation of wood particles - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: device for orientation of wood particles comprises detector of chip mattress thickness, detector of wood particles weight, detector, three blocks of setting, distraction block, rooting block, two division blocks, non-linearity block, multiplication block, switch and amplifier, at that blocks are interrelated with each other. Displacement of flexible component happens with such speed, at which maximum orientation of wood particles takes place, independently on length of particles and thickness of formed chip mattress. At this speed of flexible component displacement, angle of orientation of wood particles in chip mattress is minimum, and strength of manufactured wood-particle boards is maximum.

EFFECT: increased quality of orientation due to reduction of wood particle orientation angle, increased strength of manufactured wood-particle boards.

2 dwg

Description

The invention relates to the woodworking industry and can be used in the manufacture of chipboards.

A device for the orientation of lignocellulosic particles, including a guide body made in the form of an infinite flexible tape, and a drive to move adjacent branches of the guide body in opposite directions at a constant speed [German Patent No. 2730403, M.cl ⁵ B29J 5/04. Vorrichtung zum Ausrichten von mit einem Bindemittel versehenen lignozellulosehaltigen Teilchen, 1980].

A device for orienting wood particles is known, including an infinite flexible organ configured to move its neighboring branches in opposite directions at a constant speed using a drive [A.S. USSR No. 1449344, M.cl. ⁶ B27N 3/14. A device for orienting wood particles, 1989, BI No. 1].

A disadvantage of the known devices is that when the length of the oriented wood particles is changed and / or the thickness of the formed carpet changes at a constant speed of movement of the flexible organ, the angle of particle orientation increases, which leads to a decrease in the strength of the manufactured chipboards.

A device for orienting wood particles is known, including an endless flexible organ located in a horizontal plane, the neighboring branches of which are mounted to move in opposite directions at a constant speed using a drive [A.S. USSR No. 1544568, M.cl. ⁶ B27N 3/14. A device for orienting wood particles, 1990, BI No. 7].

A disadvantage of the known device is that the constant speed of movement of the flexible organ is optimal only for one specific length of oriented particles, at which the strength of the manufactured plates is maximum. In the manufacture of plates from particles of greater or lesser length, the orientation angle α increases, which causes a decrease in the strength of the manufactured plates.

The invention solves the problem of improving the quality of orientation of wood particles.

The technical result from the use of the invention is to improve the quality of orientation by reducing the angle of orientation of wood particles, which increases the strength of the manufactured chipboards.

This is achieved by the fact that the device for orienting wood particles, including an endless flexible organ placed in a horizontal plane, the neighboring branches of which are mounted to move in opposite directions at a constant speed by means of a drive, according to the invention is equipped with a chip thickness sensor, a particle mass sensor, detector, three task blocks, subtraction block, root extraction block, two division blocks, nonlinearity block, multiplication block, switch and an amplifier, the outputs of the first task unit and the output of the chip carpet thickness sensor connected to the inputs of the subtraction unit, the output of which through the root extraction unit is connected to the second input of the first division unit, the output of the second task unit is connected to the first inputs of the division units, to the second input of the second unit the fission through the detector is connected to the output of the tree particle mass sensor, the output of the second fission block through the nonlinearity block is connected to the second input of the multiplication block, the first input of which is connected to the first input Single division multiplier output is connected to the second switch input, which is connected to the first output of the third reference input of the unit, and output through the amplifier - a flexible actuator body.

The inventive device for orienting wood particles is distinguished by the introduction of a chip thickness sensor, a wood particle mass sensor, a detector, three task blocks, a subtraction block, a root extraction block, two division blocks, a nonlinearity block, a multiplication block, a switch and an amplifier, as well as connections between the blocks .

Improving the quality of orientation is achieved by moving the flexible organ at a speed at which the maximum orientation of wood particles occurs, regardless of the length of the particles and the thickness of the formed chip carpet.

Figure 1 presents the structural diagram of the device, figure 2 is a characteristic block of nonlinearity.

The device for orienting wood particles comprises a horizontal endless flexible (aka guide) body 1 arranged in the form of an endless thread or tape enveloping the rollers 2 and a drive roller 3, which is driven by a drive 4 made, for example, in the form of an electric motor with gear (not shown). The device is equipped with a sensor 5 for the mass of wood particles, made, for example, in the form of a sensor IRDM-1 [I.A. Otlev Intensification of the production of particle boards. - M.: Forest. Promst, 1989. - 192 p., p. 149], placed above the flexible body in the flow of wood particles, detector 6, sensor 7 of the thickness of the chip carpet, made, for example, in the form of a potentiometer. The device also contains three task blocks 8, 9 and 10, a subtraction block 11, a root extraction block 12, two division blocks 13 and 14, a nonlinearity block 15, a multiplication block 16, a switch 17 and an amplifier 18, the output of the first task block 8 and the output the chip thickness gauge 7 is connected to the inputs of the subtraction unit 11, the output of which through the root extraction unit 12 is connected to the second input of the first division unit 13, the output of the second task unit 9 is connected to the first inputs of the division units 13 and 14, to the second input of the second division unit 14 through detector 6 is connected to the output of the wood particle mass sensor 5, the output of the second division unit 14 is connected via a nonlinearity block 15 to the second input of the multiplication unit 16, to the first input of which the output of the first division unit 13 is connected, the output of the multiplication unit 16 is connected to the second input of the switch 17, the first input of which is connected to the output of the third block 10 of the job, and the output through the amplifier 18 to the drive 4 of the flexible organ 1.

The device operates as follows. The voltage of the first block of task 8 is set proportional to the distance H ₀ between the plane of the flexible organ 1 and the plane of the forming conveyor, the voltage of the second block of task 9 is proportional to the distance h between adjacent branches of the flexible organ 1 (orientation step), and the voltage of the third block of task 10 is proportional to the initial speed V movement of the flexible organ 1 Switch 17 is set to position 1.

Using drive 4, the flexible organ 1 is moved, the neighboring branches of which move in opposite directions with speeds proportional to the voltage supplied from the third block of task 10. The forming conveyor is driven, the chips are fed to the flexible organ 1, and part of the chip flow flows around the mass sensor 5 wood particles. After the thickness of the chip carpet reaches the calculated value of N _to (4-20 seconds after the supply of chips), the switch 17 is set to position 2.

The boundary angle at which particles come off the branches of a flexible organ:

where h is the distance between adjacent branches of the flexible organ 1 (orientation step), m;

l is the length of the oriented particles, m

а на выходе первого блока 13 деления - величине выхода датчика

С выхода датчика 5 массы древесных частиц импульсный сигнал (количество импульсов пропорционально числу частиц, а амплитуда - массе частиц) поступает на вход детектора 6, на выходе которого аналоговый сигнал пропорционален средней массе, и, следовательно, средней длине древесных частиц l. С выхода второго блока 14 деления сигнал, пропорциональный отношению h/l, поступает на вход блока 15 нелинейности, на выходе которого формируется сигнал U₁₅, пропорциональный величине

В блоке 16 умножения этот сигнал перемножается с выходным сигналом первого блока 13 деления, и на выходе блока 16 формируется сигнал, пропорциональный величине

Данный сигнал через переключатель 17 и усилитель 18 и подается на привод 4, который перемещает гибкий орган 1 со скоростью:Particles falling at an angle less than α _beginning pass through the flexible organ l without a turn, and particles falling at an angle greater than α _beginning are turned around by branches of flexible organ 1 and are placed on a forming conveyor in a chip carpet. The thickness of the formed chip carpet is measured by the thickness sensor of the chip carpet 7, and the sensor 7 is configured so that the signal at its output is proportional to half the thickness of the chip carpet H ₀ . In this case, the signal at the output of the subtraction unit 11 is proportional to the value (H ₀ -0.5 · H _k ), at the output of the root extraction unit 12, to the value

and at the output of the first division unit 13 - the value of the sensor output

From the output of the sensor 5 for the mass of wood particles, a pulse signal (the number of pulses is proportional to the number of particles, and the amplitude is proportional to the mass of particles) is fed to the input of the detector 6, at the output of which the analog signal is proportional to the average mass, and, therefore, the average length of wood particles l. From the output of the second division unit 14, a signal proportional to the h / l ratio is fed to the input of the nonlinearity block 15, the output of which is the signal U ₁₅ proportional to

In the multiplication block 16, this signal is multiplied with the output signal of the first division block 13, and a signal proportional to the value is generated at the output of the block 16

This signal through the switch 17 and the amplifier 18 and is fed to the actuator 4, which moves the flexible organ 1 with a speed:

При этом скорость гибкого органа V имеет размерность м/с.where the coefficient 0.0193 is the product of the gain of the multiplication unit 16, the amplifier 18, the gear ratio of the drive 4, consisting of the gear ratio of the electric motor, the gear ratio of the gearbox and the radius of the drive roller 3 and has a dimension. The speed of the flexible organ V has the dimension

The speed of the flexible organ V has a dimension m / s.

With an increase in the length l of oriented wood particles, the initial angle at which the particles come off the branches of the flexible organ decreases, the particles are “redeployed” in the carpet. In this case, the amplitude of the signal at the output of the wood particle mass sensor 5 increases, the signal at the second input of the second division unit 14 increases, and at its output decreases, the signal U ₁₅ at the output of the nonlinearity block 15 decreases (dependence in Fig. 2), the output signals of the multiplication unit 16 and at the output of the amplifier 18 are also reduced, the speed of movement of the flexible organ 1 is reduced, and the angle of rotation of the particles during the fall into the chip carpet is also reduced, so the angle of the particles in the carpet (orientation angle) will be minimal.

With increasing thickness of the chipboard carpet H _k , for example, due to the transition to the manufacture of plates of greater thickness, the angle of rotation of wood particles during their fall into the carpet decreases, the particles are placed in the carpet "underdeveloped". In this case, the signal at the output of the chip carpet thickness sensor 7 increases, and at the outputs of the subtraction unit 11 and the root extraction unit 12, it decreases, therefore, the signals at the output of the division unit 13, the multiplication unit 16, and the amplifier 18 increase, the speed of the flexible organ increases, and the rotation angle particles will also increase. Moreover, the angle of orientation of the particles will also be minimal.

Thus, the proposed device implements a method of orienting wood particles [Patent 2315689 Russian Federation, IPC B27N 3/14. The method of orientation of wood particles / Plotnikov S.M .; applicant and patent holder Siberia. Technologist, Institute - Application No. 2006122908/12; declared 06/27/2006; publ. 01/27/2008. Bull. No. 3]. At this speed of movement of the flexible (guide) organ, the orientation angle of the wood particles laid in the chip carpet is minimal, and the strength of the manufactured chipboards is maximum.

Claims (1)

A device for orienting wood particles, including an endless flexible organ placed in a horizontal plane, the neighboring branches of which are mounted to move in opposite directions at a constant speed by means of a drive, characterized in that the device is equipped with a chip thickness sensor, a particle mass sensor, a detector, three task blocks, a subtraction block, a root extraction block, two division blocks, a nonlinearity block, a multiplication block, a switch and an amplifier, moreover, the output of the first task unit and the output of the chip carpet thickness sensor are connected to the inputs of the subtraction unit, the output of which through the root extraction unit is connected to the second input of the first division unit, the output of the second task unit is connected to the first inputs of the division units, to the second input of the second division unit through the detector the output of the particle mass sensor is connected, the output of the second division block through the nonlinearity block is connected to the second input of the multiplication block, to the first input of which the output of the first division block is connected, the output One of the multiplication unit is connected to the second input of the switch, the first input of which is connected to the output of the third task unit, and the output through the amplifier is connected to the drive of the flexible organ.

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