RU2284032C1 - Method of ultrasonic testing of round-shaped timber wood - Google Patents

Abstract

FIELD: woodworking; forestry.

SUBSTANCE: method can be used for certification of wood and for quality check of round-shaped timer under different condition of storage as well as for estimation of ecological state and ecological mode of terrain by ultrasonic properties of timber barred at the terrain. Sample in form of chock is sawn out of round-shaped timber wood and radial lines with marks are drawn at edges of chock symmetrically. Radiuses of marks are measured on the base of the lines from centers of annual rings. Detectors of ultrasonic device are installed in relation to symmetrical marks at edges of chock; one of detectors is assigned to receiver. Then ultrasonic parameters of wood between edges of chock are measured twice for all marks and among centers of annual rings of chock's edges while putting detector on place of receiver. Pattern of change in ultrasonic parameters of wood are revealed along radiuses of chock.

EFFECT: simplified process of measurement; reduced labor input.

5cl, 3 dwg

Description

The invention relates to technical wood in the form of round timber and can be used in the certification of wood under conditions of logging, forestry and woodworking, while controlling the quality of round timber in various storage conditions. The invention can also be used in environmental engineering in assessing the ecological state and ecological regime of a territory by the ultrasonic properties of the wood of round timber harvested in that territory.

A known method of ultrasonic testing of wood of growing trees according to patent No. 2224416, MKI A 01 G 23/00, G 01 N 33/46, including the choice of a reference tree, grooves with ends parallel to each other and coaxially located symmetrically with respect to the longitudinal axis of the trunk of a growing or felled tree, measurement of ultrasonic parameters of wood.

The disadvantage is the difficulty of conducting test operations directly on harvested round timber, which also already have ends at their ends.

There is also known a method of ultrasonic testing of industrial wood according to patent No. 2224415, MKI A 01 G 23/00, G 01 N 33/46, including the manufacture of round timber at least two grooves with a jumper between them, fixing the sensors of the ultrasonic device in the grooves the ends of the jumper and the measurement of ultrasonic parameters of wood between the grooves.

The disadvantage is the high complexity of manufacturing grooves on round timber located in the stack, so it is almost impossible to ultrasonically test the log wood without rolling the stack.

The technical result is to simplify the process and reduce the complexity of ultrasonic testing and certification of industrial wood in the form of round timber.

This technical result is achieved by the fact that a sample in the form of a chock is sawed from round timber, radial lines with marks are symmetrically applied to the ends of the marks, the radii of the marks are measured along these lines from the centers of the tree rings, the sensors are installed relative to the symmetric marks on the ends of the chocks, one of the sensors is a receiver, then the measurement of ultrasonic parameters of wood between the ends of the chocks along all marks and between the centers of the annual rings of the ends of the chocks is performed twice, changing the position of the sensor with the reception nick, and then reveal patterns of changes in the ultrasonic parameters of wood along the radii of the chock.

Two ends of the lump in relation to the longitudinal axis of the tree trunk in the direction from the butt to the top are taken for the upper end and the lower end, and between the ends of the lump of the test wood is taken no less than the length of the standard sample for ultrasonic testing, i.e. more than 300 mm.

Radial lines with marks on the ends are plotted in geodesic directions, and the lines and marks are taken symmetrical about the longitudinal axis of the chock passing between the centers of the annual rings located at the ends of the chock; therefore, ultrasonic measurement lines parallel to the longitudinal axis of the chock are formed between the marks of both ends of the chock.

The ultrasonic parameters of wood are measured by symmetrical marks and end centers in the directions from the butt to the top and from the top to the butt of the model tree, from which round timber is harvested and lump is sawn, and the technical quality of round timber and the ecological quality of the territory are evaluated by the difference in ultrasonic parameters, on which round timber was harvested.

The patterns of changes in the ultrasonic parameters of wood along the radii of the chocks are revealed by the speed of ultrasound according to the following formulas:

where ν is the ultrasound velocity, m / s;

L is the length of the chock, mm;

τ is the ultrasound transit time shown on the screen of a portable ultrasound device, ms;

ν ₀ is the initial value of the ultrasound velocity with respect to the longitudinal axis of the chock, that is, between the centers of tree rings located at the ends of the chock, m / s;

R is the radius of the mark at the end of the chock in one of the geodesic directions, cm;

a ₁ - activity of the exponential growth of the speed of ultrasound from the center to the periphery, that is, from the core to the cambial layer;

and ₂ - the intensity of the exponential growth of the speed of ultrasound along the radius of the tree trunk from the core to sapwood.

является устойчивым законом экспоненциального роста скорости ультразвука по радиусу ствола, параметры a₁ и а₂ которого изменяются в зависимости от качества древесины срубленного модельного дерева (измерения через несколько минут после рубки дерева) или заготовленных круглых лесоматериалов по результатам испытания после их какого-то срока хранения, при этом этот закон изменяет значения параметров ν₀, а₁ и а₂ экспоненциального закона в зависимости от направления измерений:Formula

is a stable law of the exponential increase in the speed of ultrasound along the radius of the trunk, the parameters a ₁ and a _{2 of} which vary depending on the quality of the wood of the felled model tree (measurements a few minutes after cutting) or harvested round timber according to the test results after their storage period while this law changes the values of the parameters ν ₀ , and ₁ and a _{2 of the} exponential law, depending on the direction of measurement:

1) the direction from the butt to the top, that is, the movement of mineral substances from the roots to the crown along the sapwood cells

2) the direction from the top to the butt, that is, by the movement of assimilation products from the crown to the roots along the cells of the cortex

Moreover, for healthy wood, the condition ν ₁ > ν ₂ is observed.

The essence of the proposed technical solution lies in the fact that lumps sawn from logs, depending on the quality of the source information are considered in two ways. On the one hand, a simplified approach assumes that there are logs in the stack of round timber that do not have a northern direction (this label is for model trees and their saw circles), and the ratio of the ends of the logs to the butt or to the top of the tree is unknown (although long logs it is noticeable). On the other hand, in the conditions of forest inventory, there is all the initial information on chocks, sawn in the form of circles-saw cuts from the trunks of model trees.

The essence also lies in the fact that a new physical phenomenon has been found that differences in ultrasound velocity values in two different longitudinal directions of the tree trunk. Moreover, this difference, as well as the value of the speed of ultrasound itself, depends on the quality of the wood and on the quality of the place of growth of the tree. In order to be comparable with standard samples for ultrasonic testing, a chock length of more than 300 mm is adopted. However, the value of this length is not of fundamental importance, since with a decrease in length less than 300 m, correction factors can be introduced.

The novelty of the technical solution lies in the fact that log cuttings, which are always available in round timber warehouses, are taken as objects of study of the quality of the entire batch of round timber, for example, stacks from one cutting area. Moreover, if the background to the harvesting of this batch of round timber is known, then testing of chocks, which were considered irrevocable and useless waste of wood, allows you to create an ecological picture of the felled forest. And for various consignments of round timber and ultrasonic testing of wood, carried out at different times, a complex of information is formed about the environmental monitoring of forests. If you establish a constant mode of the proposed chock tests, then you will be able to manage industrial forests, since any impact on the trees will affect the exponential patterns of changes in the speed of ultrasound along the chocks being tested.

A positive effect is achieved with the help of portable ultrasonic devices and the use of chocks (which only require straight ends), sawn from logs. As a result, a simple way of certification of wood appears, which is located both in stacks of round timber from loggers or consumers, and in the standing on designated forest areas in the form of model trees.

In this regard, the proposed technical solution has novelty, a positive effect and ease of practical implementation (after accumulation of statistical comparative data, it is also possible to environmental monitoring by the logging and forestry processes themselves in terms of growing targeted high-quality forests). In the scientific, technical and patent literature, materials discrediting the novelty of the proposed technical solution were not found.

Figure 1 shows a sample in the form of chocks with a length of at least 300 mm, a view in space with an upper end oriented in the direction of growth of the tree; figure 2 shows a diagram of the measurement of ultrasonic parameters of wood and the location of the sensor and receiver relative to the ends of the chocks; figure 3 shows an exemplary diagram showing graphs of changes in the speed of ultrasound along the radius of the barrel in two directions: 1) from the butt to the top; 2) from the top to the butt.

A method for ultrasonic testing of round timber timber comprises the following steps.

The maximum possibilities of applying the method will be with actions that allow both to certify technical wood and obtain baseline data for environmental monitoring by the territory on which round timber harvesting processes were carried out.

On chock 1, sawn off or already finished with a length L of at least 300 mm (from a log or other type of round timber), the upper end 2 and lower end 3 are made and radial lines of geodesic directions with marks 4 are drawn on them (as an example, marks are shown No. 1 ... 6 from the center of tree rings to the chock periphery in the following four geodesic directions: C - north; B - east; South - south; W - west). The same lines with marks are applied on the lower end of the chocks. Radii from the center of the tree rings measure values of radius R to the corresponding marks.

In this case, the upper end is directed towards the top of the former tree, and the lower end is oriented towards the butt of the tree trunk. The lines and marks on the upper and lower ends of the chocks are symmetrical about the longitudinal axis 5 of the chocks passing through the centers of the tree rings located at the ends of the chocks. Between the marks of both ends, lines of 6 measurements parallel to the longitudinal axis of the chocks are formed.

Regarding the lines 6 between the marks on the ends of the chocks, the sensor 7 and the receiver 8 of the portable ultrasonic device are pressed along the corresponding marks on one of the lines of geodetic directions. Measurements in several repetitions (at least 4-5) are performed twice, changing the relative positions of the sensor and receiver. In these cases, the ultrasound travel distance L is measured in two vertical (with respect to the trunk of a growing tree) directions along the line 6 of measurements: 1) from the butt to the top; 2) from the top to the butt.

The speed of ultrasound in these two directions of movement of mineral substances and products of assimilation of foliage (needles) of the crown turns out to be different along the entire radius.

The quality of industrial wood and the quality of the ecological regime of growth and development of a felled tree are estimated from the values of ultrasound velocity, which vary depending on the radius of the trunk, and their difference in the directions of movement of nutrients.

In addition to marks 4, the time required for ultrasound to travel along the center of the tree rings at both ends of the chock along axis 5 is necessarily measured. This allows us to take two common principles for all geodesic directions in the direction of ultrasonic waves from the butt to the top and from the top to the butt (in FIG. 2 shows the location of the sensor 7 and receiver 8 for measuring in the direction of movement of the products of assimilation of foliage (needles) from the top to the butt).

After testing in the form of a series of ultrasonic measurements of wood on one chock (for all marks in four geodetic directions, with at least 4-5 repetitions of ultrasonic measurements on each line 6), patterns of changes in the speed of ultrasound are revealed by the following formulas:

where ν is the ultrasound velocity, m / s;

L is the length of the chock, mm;

τ is the ultrasound transit time shown on the screen of a portable ultrasound device, ms;

ν ₀ is the initial value of the ultrasound velocity with respect to the longitudinal axis of the chock, that is, between the centers of tree rings located at the ends of the chock, m / s;

R is the radius of the mark at the end of the chock in one of the geodesic directions, cm;

and ₁ - activity of the exponential growth of the speed of ultrasound from the center to the periphery, that is, from the core to the cambial layer;

and ₂ - the intensity of the exponential growth of the speed of ultrasound along the radius of the tree trunk from the core to sapwood.

Then the test is carried out on the next chock, which also knows the geodesic directions, that is, the model tree method was used, for example, in forest inventory. And also on the chock the upper and lower ends should be marked, showing the direction of movement of the juices in the tree. At the same time, for environmental monitoring, taxation indicators of experimental forest plots from which model trees were taken should also be known, and mugs in the form of chocks with a length of at least 300 mm should be taken from the latter.

является устойчивым законом экспоненциального роста скорости ультразвука по радиусу ствола модельного дерева, параметры a₁ и а₂ которого изменяются в зависимости от качества древесины срубленного модельного дерева (измерения через несколько минут после рубки дерева) или заготовленных круглых лесоматериалов по результатам испытания после их какого-то срока хранения. А по значениям скорости ультразвука можно ориентировочно оценить и прочностные показатели древесины, так как между скоростью ультразвука и физико-механическими свойствами древесины наблюдается прямолинейная зависимость.Formula

is a stable law of the exponential growth of ultrasound velocity along the radius of the trunk of a model tree, the parameters a ₁ and a _{2 of} which vary depending on the quality of the wood of the felled model tree (measurements a few minutes after cutting) or harvested round timber according to the test results after some shelf life. And according to the values of the ultrasound speed, it is possible to tentatively evaluate the strength characteristics of wood, since a direct relationship is observed between the speed of ultrasound and the physicomechanical properties of wood.

This indicated law changes the values of the parameters ν ₀ , a ₁ and a ₂ (exponential law) depending on the direction of measurement. Therefore, for each of them, you can write patterns in the form of mathematical expressions (figure 3):

1) the direction from the butt to the top, that is, the movement of mineral substances from the roots to the crown along the sapwood cells

2) the direction from the top to the butt, that is, by the movement of assimilation products from the crown to the roots along the living cells of the cortex

For healthy wood, the condition ν ₁ > ν ₂ is observed.

The method of ultrasonic testing of wood of round timber, for example logs that are stacked in a timber warehouse, is as follows.

Here, as a rule, the geodesic directions are not known for chocks, and the orientation of their ends may also be unknown.

On chock 1 with a length L of at least 300 mm, selected at the warehouse or sawn from the end of the log from the stack, ends 2 and 3 are made and arbitrary radial lines with marks 4 are drawn (as an example, marks No. 1 ... 6 from the center of annuals are shown rings to the periphery of the chocks. The same lines with marks symmetrically with respect to the longitudinal axis 5 of the chocks are applied to the lower end of the chocks. Radii R to the corresponding marks are measured along the radii from the center of the annual rings.

Regarding the measurement lines 6, between the marks on the ends of the chocks, the sensor 7 and the receiver 8 of the portable ultrasonic device are pressed. Measurements in several repetitions (at least 4-5) are performed twice, changing the relative positions of the sensor and receiver. In these cases, the ultrasound travel distance L is measured in two vertical directions: 1) from the butt to the apex; 2) from the top to the butt. But at the same time, these directions are unknown before and during measurements, and they can be judged by the results of ultrasonic measurements, since the condition ν ₁ > ν ₂ is observed for healthy wood.

The ultrasound velocity, which varies depending on the radius of the trunk, and their difference in the direction of movement of nutrients, assesses the quality of industrial wood and the quality of the ecological regime of growth and development of felled tree.

In addition to labels 4, it is necessary to measure the ultrasound transit time in the center of tree rings at both ends of the chocks along axis 5. This allows us to take two common principles for any radial directions.

After a series of ultrasonic measurements of wood on one chock (for all marks in all radial directions, with at least 4-5 repetitions of ultrasonic measurements on each line 6), patterns of changes in the ultrasound speed are revealed by the following formulas:

where ν is the ultrasound velocity, m / s;

L is the length of the chock, mm;

τ is the ultrasound transit time shown on the screen of a portable ultrasound device, ms;

ν ₀ is the initial value of the ultrasound velocity with respect to the longitudinal axis of the chock, that is, between the centers of tree rings located at the ends of the chock, m / s;

R is the radius of the mark at the end of the chock in one of the geodesic directions, cm;

and ₁ - activity of the exponential growth of the speed of ultrasound from the center to the periphery, that is, from the core to the cambial layer;

a ₂ - the intensity of the exponential growth of the speed of ultrasound along the radius of the tree trunk from the core to sapwood.

является устойчивым законом экспоненциального роста скорости ультразвука по радиусу чурки, параметры a₁ и а₂ которого изменяются в зависимости от качества древесины заготовленных круглых лесоматериалов.Formula

is a stable law of the exponential growth of the speed of ultrasound along the radius of the chock, the parameters a ₁ and a _{2 of} which vary depending on the quality of the wood harvested round timber.

According to this exponential law, the values of the parameters ν ₀ , and ₁ and a _{2 are} compared, and by the condition ν ₁ > ν ₂ , the names of the ends of the chocks (upper or lower) and the measurement directions are set:

1) the direction from the butt to the top, that is, the movement of mineral substances from the roots to the crown along the sapwood cells

2) the direction from the top to the butt, that is, by the movement of assimilation products from the crown to the roots along the living cells of the cortex

The number of chocks necessary for a reliable judgment on the quality of timber and on the ecological quality of the territory from which the stacks of round timber were obtained is established by methods known in statistics.

The proposed method simplifies the process of ultrasonic testing of wood round timber through the use of chocks, which are easy to get in the warehouses of logs. The data of ultrasonic tests also make it possible to tentatively evaluate the indicators and parameters of mechanical strength. It allows in the future to switch to monitoring the processes of wood harvesting, and then to monitoring the cultivation of wood in this area. In this case, there is the possibility of operational certification of wood in warehouses, among loggers and woodworkers, as well as in leshozes and forestries, and at the root during forest management. The proposed method allows you to quickly identify the quality and environmental efficiency of the processes of all forest management through the ultrasonic properties of wood of round timber, in the future to ensure the output of the most valuable assortments.

Claims (5)

1. The method of ultrasonic testing of wood of round timber, which consists in the fact that a round sample is sawn off of round timber, the ends of which are radially marked with marks symmetrically, the radii of the marks are measured along these lines from the centers of the tree rings, the sensors of the ultrasonic device are installed relatively symmetrical marks at the ends of the chocks, one of the sensors being the receiver, and then twice measure the ultrasonic parameters of the wood between the ends of the chocks for all marks and between ntrams of annual rings of the ends of the chocks, changing the position of the sensor with the receiver, after which the patterns of changes in the ultrasonic parameters of the wood along the radii of the chock are revealed. 2. The method of ultrasonic testing of wood of round timber according to claim 1, characterized in that one end of the lump in relation to the longitudinal axis of the tree trunk from which it is sawn off, is taken for the top end in the direction to the top, and the other end in the direction of the butt - for the lower end, and the distance between the ends of the chunks of the test wood is taken not less than the length of the standard sample for ultrasonic testing. 3. The method of ultrasonic testing of wood of round timber according to claim 1 or 2, characterized in that the radial lines with marks on the ends are applied in geodesic directions, the lines and marks being symmetrical about the longitudinal axis of the chock passing between the centers of the tree rings located at the ends chocks to perform ultrasonic measurements. 4. The method of ultrasonic testing of wood of round timber according to claim 1, characterized in that the measurement of ultrasonic parameters of the wood according to symmetrical marks and end centers is carried out in directions from the butt to the top and from the top to the butt of the model tree, from which round timber is harvested and sawn off moreover, the technical quality of the round timber and the ecological quality of the territory on which the round timber was harvested are estimated by the difference in ultrasonic parameters. 5. The method of ultrasonic testing of wood of round timber according to claim 1 or 2, characterized in that the patterns of change in the ultrasonic parameters of the wood along the radii of the chock are detected by the speed of propagation of ultrasound ν = L / τ or

ν is the propagation velocity of ultrasound, m / s; L is the length of the chock, mm; τ is the ultrasound transit time shown on the screen of a portable ultrasound device, ms; ν ₀ is the initial value of the ultrasound velocity with respect to the longitudinal axis of the chock, that is, between the centers of tree rings located at the ends of the chock, m / s; R is the radius of the mark at the end of the chock in one of the geodesic directions, cm; a ₁ - activity of the exponential growth of the speed of ultrasound from the center to the periphery, that is, from the core to the cambial layer; and ₂ - the intensity of the exponential growth of the speed of ultrasound along the radius of the tree trunk from the core to sapwood.

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