RU2522862C2 - Method of comparative timber test - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: invention refers to timber industry, wood-processing industry, and can be applied in standing wood certification at forestries and lumber camps, and in certification of round and sawn lumber at raw wood treatment and mechanical timber processing facilities. Method involves comparative test at least at one process operation of mechanical timber processing, between ultrasonic test of core samples and at least one standardised test method with standard samples, such as wood strength test with 20x20x30 mm samples, further calculation of transition factor values for acoustic parameters of core samples taken from growing wood or stapled round and sawn lumber to wood strength in standard samples made of the same materials, and further extension of transition factors obtained to the whole wood batch produced at the same wood-cutting area or forestry. After core sampling, standard samples are made and measured by ultrasonic instrument and further tested for mechanical parameters, and test results are used to calculate transition factors between ultrasonic parameters for core samples and standard samples and transition factors between ultrasonic parameters of core samples and mechanical parameters of standard samples.

EFFECT: improved test reliability and extended functionality.

3 cl, 1 ex, 3 dwg

Description

The invention relates to the forestry, woodworking industry and can be used in certification of standing timber in forestry and logging conditions, as well as in the certification of round and sawn wood materials in the processing of wood raw materials and mechanical processing of wood.

A known method of ultrasonic testing of industrial wood (see book: Ugolev BN Wood science with the basics of forest products. - M .: MGUL, 2001, p. 131) on standard samples 20 × 20 × 300 mm, including fixing the sample, including ultrasound instrument with sensors at the ends of the wood sample, measuring the ultrasound transit time along the length of the wood sample, determining the strength and quality of the wood.

The disadvantage is the inconsistency among themselves of the technology for testing standard wood samples for strength and other physical and mechanical properties of wood. Therefore, it is necessary to produce standard samples of various sizes, for example, 20 × 20 × 30 mm for testing the compressive strength of wood and 20 × 20 × 300 mm for testing for ultrasonic indicators for the selection of resonant wood, as well as the impossibility of determining the strength of wood on these samples growing condition.

There is also a method of ultrasonic testing of wood of growing trees using cores according to patent No. 214185, which includes taking a core, measuring its dimensional and ultrasonic parameters and refining them, taking into account amendments to the corners of the core relative to the trunk of a growing tree.

The advantage of the prototype is that for the determination of ultrasonic parameters does not require the production of standard samples with dimensions of 20 × 20 × 300 mm Therefore, the prototype allows you to extract cores from wood of any condition (growing tree, sawn and felled tree, whip, longitude, log, assortment, logs, churak, timber or other lumber, etc.) in the machining processes of round and sawn wood materials. This gives a practical opportunity to select not only resonant wood, but also other types of valuable special assortments at various technological operations.

The disadvantage is the inability to determine the strength of wood without the manufacture of standard samples with dimensions of 20 × 20 × 30 mm or bending strength on samples with dimensions of 20 × 20 × 300 mm, both in a growing state and in further processes of primary processing and deep processing of harvested wood into rough and fair wood blanks. This disadvantage does not allow to expand the functionality of the known method of ultrasonic testing of wood for strength, and in the future for other physical and mechanical parameters of wood without the manufacture of standard samples.

EFFECT: expanding the functional capabilities of the method by introducing comparative tests, at least in one technological operation of mechanical processing of wood, between ultrasonic testing on cores and at least one standardized testing method on standard samples, for example, on the strength of wood on samples with dimensions 20 × 20 × 300 mm, then determining the values of the transition coefficient from the acoustic parameters of cores extracted from a growing tree or round and sawn timber, finding they are in the stack, to the strength of wood on standard samples made from the same wood billets, and then the application of the obtained values of the transition coefficient for the entire volume of the batch of wood harvested from a single cutting area or forest area.

This technical result is achieved in that a method of comparative testing of wood, including taking a core, measuring its dimensional and ultrasonic parameters and refining them, taking into account corrections for the corners of the core relative to the trunk of a growing tree, characterized in that after taking the cores, standard samples are made, they are measured ultrasonic device, then the standard samples are tested for mechanical properties of wood, and according to the test results calculate the transition coefficients between ultrasounds values of core samples and standard samples, as well as transition coefficients between ultrasonic core indicators and mechanical indicators of standard samples.

Comparative tests are carried out on a small part of growing trees, sawn and felled trees, whips, longitude, sawing chocks with a length within 350-500 mm from a knotless part, and chunks of specified length moreover, at least one radial core is first extracted from the experimental chocks, and then standard samples for mechanical tests are made from drilled chocks, which should be oriented strictly along the anisotropy axes and do not contain vices.

Comparative tests are carried out on at least one technological operation of mechanical processing of wood, between ultrasonic testing on cores and at least one standardized test method on standard samples, for example, on the strength of wood on samples with dimensions of 20 × 20 × 300 mm, then determining the values of the transition coefficient from acoustic indicators of cores extracted from a growing tree, or round and sawn timber stored in a stack, to the strength of wood on standard samples, made s of the same wood blanks, and then the obtained values of the transition coefficient is used for the entire volume of the wood batch harvested from one or forestry felling site.

It is much easier to extract cores, therefore, for the certification of other batches of wood from the same place of growth of forest trees, wood tests are carried out only by cores.

The essence is that in addition to the technological processes of wood harvesting with various types of round and sawn timber, comparative tests are introduced, at least on one technological operation of mechanical processing of wood from raw materials to finished products, between ultrasonic testing on cores and at least one standardized test method on standard samples, for example, on the strength of wood on samples with dimensions of 20x20x300 mm.

The essence also lies in the fact that then, according to the results of comparative tests, the values of the transition coefficient are determined from the acoustic parameters of cores extracted from a growing tree, or round and sawn timber stored in a pile, to the strength of wood on standard samples made from the same wood blanks, and then the application of the obtained values of the transition coefficient for the entire volume of the consignment of wood harvested from one cutting area or forest site.

The essence of the proposed technical solution consists in combining on samples obtained from wood of the same origin and growing conditions, and even (if not known the origin of wood blanks) on the same round and sawn timber, the methods of ultrasonic and strength testing of wood from growing conditions (trees in the period of ripening of the forest stand, at the age of ripeness of healthy and high-quality trees) to standard samples that were previously used mainly at enterprises mechanically th woodworking.

The essence lies also in the fact that with the fame of the history of the consignment of round or sawn timber, there is the practical possibility of an ecological assessment of the cutting area or forest plot based on the results of comparative wood tests. If the background of the batch of wood is unknown, then the results of the comparative test apply only to the processes of subsequent selection and certification of the batch of wood for subsequent targeted use, which will increase the profitability of woodworking.

A positive effect is achieved in technological considerations from a growing tree set aside to the final wood products in the form of special-purpose blanks. At all stages from a growing tree, harvesting assortments, rough blanks, turning them into structural details, we apply the ultrasonic method on cores and the method on standard samples on a small part of a batch of wood.

With the technical development of the proposed method, statistical material is accumulated (transition factors). Therefore, a moment will come at a logging enterprise when, using ultrasonic measurements of cores of growing trees, it will be possible to calculate strength indices without all the technology for manufacturing standard samples. Thus, wood science will move from wood processing enterprises directly to logging enterprises and forestry. In this case, there will be real forest management and targeted forest tree growing for long-term orders of woodworkers.

Thus, the proposed method allows in the future to abandon standard samples and rough blanks and switch to monitoring wood in a growing state and during harvesting. In this case, there is the possibility of operational certification of standing wood, quick identification of its quality and effective output of the most valuable assortments. The certified wood obtained in this way will be distributed to consumers according to the certified data, and not “blindly”, as is now customary. This will bring loggers a significant economic effect, since certified wood will be sold on the basis of the corresponding properties of a batch of whips, logs, lumber, rough and even final blanks.

In this regard, the proposed method has a novelty, a positive effect. Materials discrediting the novelty of this invention were not found.

Figure 1 shows the location of the core and, for example, the rough log of wood in a segment in the middle of the cross section of the tree trunk; figure 2 - layout of the core in the rough draft; figure 3 - diagram of the cutting of the rough blanks with a length of 500 mm into standard samples with a length of 300 mm for testing wood bending.

A method of testing wood, for example, in comparative tests in a forest area of logged tree trunks, includes the following steps.

A model tree is selected in the cutting area or forest area, from which core 2 is extracted along the radius of the trunk section 1. After taking from each core, geometric and dimensional parameters are measured.

Then each core is placed in a test tube and sent to the laboratory.

In laboratory conditions, the properties of wood are determined for each core, taking into account corrections for angles. A chock is made from a model tree in a section of the trunk with a core, which is sawn in special laboratories in a laboratory for roughing 3 into standard samples 4 for strength tests. As the studied and refined properties of wood, strength and acoustic indicators are taken. In this case, the core is cut into segments 5. After which the transition coefficient is revealed from the acoustic parameters of the core to the mechanical indicators of standard samples and rough blanks.

Standard samples are measured, as well as core sections, with an ultrasonic device, then standard samples are tested for mechanical parameters of wood, and according to the test results, the transient coefficients between the ultrasonic indicators of the core and standard samples, as well as the transition coefficients between the ultrasonic indicators of the core and the mechanical indicators of the standard samples, are calculated.

Comparative tests are carried out on a small part of growing trees, sawn and felled trees, whips, longitude, sawing chocks with a length within 350-500 mm from a knotless part, and chunks of specified length moreover, at least one radial core is first extracted from the experimental chocks, and then standard samples for mechanical tests are made from drilled chocks, which should be oriented strictly along the anisotropy axes and do not contain vices.

It is much easier to extract cores, therefore, for the certification of other batches of wood from the same place of growth of forest trees, wood tests are carried out only by cores.

A method of testing wood, for example, in comparative tests on a rough log of wood includes the following steps.

Comparative tests are carried out on at least one technological operation of mechanical processing of wood, between ultrasonic testing on cores and at least one standardized test method on standard samples, for example, on the strength of wood on samples with dimensions of 20 × 20 × 300 mm, then determining the values of the transition coefficient from acoustic indicators of cores extracted from a growing tree or round and sawn timber located in a stack, to the strength of wood on standard samples made of the same wood billets, and then the obtained values of the transition coefficient are used for the entire volume of a consignment of wood harvested from one cutting area or forest site.

To determine the acoustic performance along the diameter of the trunk 1 of the tree or round timber, core segments 2 are used. To determine the transition coefficient from the acoustic performance of the core to the strength of standard samples 4 from the rough blank 3, the rough blank is sawn and then planed into standard samples of 20 × 20 × 300 mm and 20 × 20 × 30 mm, and the cores - into segments of a length of 20 mm. Ready standard samples and core sections are subjected to ultrasonic testing, for example, according to the prototype. After that, samples of 20 × 20 × 300 mm can be tested using a standard bending procedure.

Then, the acoustic indices of the segments and the cores themselves are compared with the acoustic and strength indices of the standard samples and the transition coefficients are calculated.

To compare the performance of core wood and rough blanks in general, it is necessary to take into account the influence of all factors: sample lengths, anisotropy, wood defects.

The wavelength for rough blanks when changing the length from 1500 to 300 mm varies within 9.8 ... 7.1 mm, and it is greater than the cross section of the sample. The length of the sample is much longer than the wavelength. Under these conditions, the acoustic performance of the rough blank varies slightly, so the extraction of cores from the trunk for comparison is possible both through 300 mm and through 1500 mm, that is, in sections of the trunk between branches and branches.

The influence of wood defects (knots, tarring, cracks) on acoustic performance is significant, therefore, when conducting experiments, it is necessary to exclude core wood samples and standard ones with defects.

Example.

A core is extracted from the trunk of a healthy model tree between whorls of branches along the radius of the cross section of the trunk. After taking each core in laboratory conditions, geometric and dimensional parameters are measured.

In laboratory conditions, the density, ultrasound velocity, acoustic constant and acoustic resistance are determined for each core, taking into account corrections for angles. Chock is made from a model tree on a section of the trunk with a core, which is sawn on special blanks on special machines. The rough blank is sawn into standard samples measuring 20 × 20 × 300 mm for strength tests. Standard samples are voiced by an ultrasonic device. As the studied and refined properties of wood, strength and acoustic indicators are taken. In this case, the core is cut into segments. Then reveal the transition coefficient from the acoustic performance of the core to the mechanical performance of standard samples and rough blanks.

Standard samples are measured, as well as core sections, with an ultrasonic device, then standard samples are tested for mechanical parameters of wood, and according to the test results, the transient coefficients between the ultrasonic indicators of the core and standard samples, as well as the transition coefficients between the ultrasonic indicators of the core and the mechanical indicators of the standard samples, are calculated.

For example, the value of the acoustic constant core of high-quality resonant wood is 4.0 m ⁴ / (kg-s), and the acoustic constant of wood of standard samples when sonicated by an ultrasonic device along the fibers is 12 m ⁴ / (kg-s). Then the transition coefficient between the acoustic constant of the cores and standard samples is 3.1.

Hence, tests of spruce wood in growing condition on cores (see book: A. Kolesnikova, A. Study of the properties of wood by cores. - Yoshkar-Ola: MarSTU, 2002. - 178 p.), Including ultrasonic measurements along the length of the core and length standard sample, determination of the transition coefficient from the acoustic performance of core samples to standard samples.

Having tested the standard samples for strength, we can determine the transition coefficient from the acoustic constant of the core segments to the strength of the standard samples.

Measurements of the ultrasonic parameters of wood during testing together with the determination of strength to find the transition equations must be carried out on samples without defects, strictly oriented along the anisotropy axes, or the angle of inclination of the fibers in the longitudinal radial and radial tangential planes of wood anisotropy should be taken into account.

The production of standard samples is very time-consuming, therefore comparative tests on a small number of wood billets (growing tree, sawn and felled tree, whip, longitude, log, assortment, logs, churak, timber or other lumber, etc.) allows you to certify the entire batch of wood on one or even several cutting areas or forest areas.

Claims (3)

1. A method for comparative testing of wood on cores and standard samples, including taking a core, measuring its dimensional and ultrasonic parameters and refining them, taking into account corrections for the corners of the core relative to the trunk of a growing tree, as well as manufacturing a standard sample and its mechanical test, different the fact that the tests are performed by sawing chocks 350-500 mm long, on the same wood billet after taking cores, standard samples are made with dimensions of 20 × 20 × 30 mm, they are measured with an ultrasonic device, then they test on the mechanical parameters of wood, and according to the results of tests of cores and standard samples, the transition coefficients between ultrasonic and mechanical indicators are calculated. 2. The method according to claim 1, characterized in that comparative tests are performed on a small part of growing trees, sawn and felled trees, whips, longitude by sawing chocks from a knotless part, from logs, assortments, logs, churaks, beams or other lumber, moreover standard samples for mechanical tests are first extracted from the experimental chocks, which should be oriented strictly along the anisotropy axes and not contain defects. 3. The method of claim 1, characterized in that comparative tests are carried out on at least one technological operation of mechanical processing of wood, between ultrasonic testing on cores and at least one standardized test method on standard samples, for example, on the strength of wood on samples.

Images