RU2247985C2 - Method of testing wood - Google Patents

Abstract

FIELD: wood-working industry.

SUBSTANCE: method comprises measuring variations of pulse loading of the conical head during its penetration into the wood in radial direction. The wood quality can be judged by relative force pulse duration.

EFFECT: enhanced reliability.

4 cl, 9 dwg

Description

The invention relates to the forest industry and can be used in the certification of technical wood and technological monitoring of mechanical processing of wood in various woodworking enterprises, for example, continuous certification and sorting of wood raw materials and semi-finished products on the quality of wood in woodworking industries during storage of round, chipped and sawn timber, and also during logging operations. The invention can also be used in technological monitoring of old wooden structures (houses, bridges, etc.), for example, to control the quality and reliability of wooden structures.

A known method of testing wood by compressing across the fibers on a part of the length and width of the sample in the radial direction in the three-phase deformation mode to a quarter of the initial height of the sample without visible signs of destruction to the limit of proportionality in the compression diagram, without bringing the test sample to destruction from local crushing (see book: Perelygin A.M. Wood Science. - M.: Forestry Industry, 1969. - 320 p. - S.158-162).

The disadvantage of this method is the complexity and high difficulty of studying wood on the so-called standard samples, which must be produced with dimensions of 20 × 20 × 60 mm. On solid workpieces, you must have a flat surface. Moreover, the method does not allow testing technical wood directly in storage conditions in warehouses and woodworking workshops. In addition, it is impossible to test the elements of wooden structures, for example old buildings, for which it is necessary to test industrial wood in order to verify the reliability and strength of structures.

There is also a method of testing wood, based on the difference in the depth of penetration (immersion) in the wood of the rod with a conical tip with the same control force on it, and the value of the depth of immersion of the rod judges the properties (quality) of wood (Leonov L.V. Technological measurements and instruments in forestry and woodworking industry. - M.: Forestry industry, 1984. - S.76-81).

The disadvantage is that during radial local compression with a conical head having a shape that is not optimal for wood, an uneven change in force occurs from the early and late zones of the annual layer. Therefore, it is impossible to judge the quality of industrial wood by just changing the effort. Therefore, the main property is not the penetration force, but the rhythm of the cracks from the penetrating head. Therefore, the test of industrial wood involves in the simplest case the measurement of pulses of changes in the sounding force, its duty cycle and rhythm.

EFFECT: simplification of the wood testing process, expansion of the application from a growing state to various types of semi-finished products (trees, as well as round, chipped and sawn materials) and wood building products, as well as monitoring the strength and reliability of old wooden structures in the form of houses, pillars , bridges and others.

This is achieved by the fact that in the method of testing wood, including immersion of the cone head in the test material, the calculation of the indicator of the properties of the test material by the penetration force of the cone head, and the immersion is performed using feed mechanisms, and the strength of the test material is judged by the resistance of the material to immersion of the cone head, when testing material from industrial wood, a conical head of a streamlined shape is used, in addition, the momenta of the change in the penetration force are measured of a cone head in a streamlined shape in the radial direction, positioning material from industrial wood relative to the vector of movement of the head from the periphery to the core of the tree trunk, and the quality of the technical wood is judged by the duty cycle and rhythm of the force pulses.

On dry wood of building structures, impulses are measured by sound signals transmitted from the cone head in the form of creaks from the destruction of the late zone of the annual layer, and the percentage of late wood of annual layers is judged by the duty cycle of the sound signal.

Simultaneously record the force and impulse penetration diagrams of the biconical head into the test material, compare the local destruction forces of the late and early zones of each layer and judge the quality of the technical wood of building products and logs under long-term storage in relation to these efforts.

When testing growing trees and raw materials from industrial wood, impulses of changes in penetration force are compared with measurements of annual layers and their early and late zones on wood cores obtained by a hollow biconical head.

Testing of growing trees is carried out during the growing season during the maximum movement of the sap of woody plants.

The essence of the technical solution lies in the fact that distinguish between dry and wet technical wood. In the first case, sound pulses are measured that accompany the abrupt change in the force of penetration of the two-cone head into the test material. At the same time, one can judge the quality of wood, even without recording the penetration power.

In the second case, sound pulses are weak and can only be measured by piezoelectric sensors. However, on a raw-growing tree and raw material (for example, alloy wood), it is possible to produce wood cores that are formed due to the small penetration force.

The wider the annual layer, the more noticeable is the change in the penetration force (Fig. 2) and sound from the destruction of the late zone of the annual layer. Modern piezoelectric sensors manage to accurately measure the dynamics of force and sound penetration in heterogeneous wood in the radial direction. At the same time, from the periphery to the core it is possible to obtain clear impulses of force and sound. This condition on trees and logs is fulfilled by itself, and on the croaker (figure 3) and on the board (figure 4) this direction is taken into account.

In this regard, the technical solution has significant distinguishing features, novelty, positive effect and the prospect of practical application (there are many buildings and structures made of stem wood in Russia, including buildings of historical significance).

From the analysis of scientific, technical and patent literature review, materials discrediting the novelty of the proposed method were not found.

Figure 1 shows the log area of the building structure in the process of testing industrial wood; figure 2 is a typical graph of changes in the penetration of wood depending on the depth of penetration into the test element of the building structure; figure 3 is a diagram of the test technical wood on the slab during the process of sawing logs; figure 4 is a diagram of the penetration of industrial wood on a thick unedged board; 5 is a diagram of a test log of a wooden house; Fig.6 is a diagram of the penetration of the trunk of a growing tree; Fig.7 - the head of the penetrometer for industrial wood; on Fig is a diagram of the head of the penetrometer for testing industrial wood in a growing state with an internal hole; Fig.9 is a diagram of a test of industrial wood in a growing state with a hollow penetrometer with wood core extraction.

The method of testing wood includes the following steps.

All construction products from industrial wood can be divided into three groups:

a) old wooden structures with elements of logs, beams and boards, which must be checked for strength and reliability in order to decide on further operation;

b) building logs and other semi-finished products that need to be checked and certified for use in various building structures;

c) growing trees, their trunks and large branches, from which it is planned to obtain construction logs and other semi-finished products for the manufacture of various wooden structures from forest taxis (trunk zones from which construction logs can be obtained are also known on a growing tree).

A penetrometer 2 with a cone-shaped head is slowly immersed in the test article 1, which can be hollow for testing growing trees and raw wood products (for example, alloy logs). The cone-shaped head is double-conical with sharpening angles of 60-80 degrees at the apex of 3 and 15-16 degrees at the base of 4 double-cone heads, which allows you to bring the shape of the penetrating body to a parabolic shape, optimal for penetration into the wood.

To improve the orientation of the double-cone head, a cylindrical chamfer is carried out on it 5. The diameter of the penetrometer is taken to be the smallest according to the conditions of strength and stability when penetrating into wood. It is practically enough to accept a diameter of the chamfer of the head of 5-6 mm, and with an internal cavity for a core of 4-5 mm, the diameter of the penetrometer is 8-10 mm.

In all cases, penetration is performed from the periphery of the tree trunk to its center. On boards, an edge is used for this, and on slabs they are oriented along the radius of the annual layers. Therefore, the test is carried out, if possible, strictly in the radial direction from the periphery to the center.

In the proposed method, several physical effects are used. The first refers to a typical graph of changes in penetration effort (Pechenkin V.E., Mazurkin P.M. Chipless wood cutting. - M.: Timber industry, 1986. - P. 42-43). According to it, the penetration path can be divided into two parts: firstly, zone I of unstable growth of force to a maximum value, which is characterized by an increase in the contact area until the biconical head is completely buried in the wood; secondly, zone II of a uniform change in penetration force from a certain value of P _p for early wood to a value of P _n for late wood. The second effect relates to the ratio of penetration forces P _n / P _p , which varies in the range 1.2-3.0 for different types of wood and different humidity. For rotten wood, this ratio approaches unity, while the force also decreases sharply. Therefore, the proposed test method allows you to find and designate the depth of spread of rot from the core to the periphery of a tree trunk or log. The third effect is the streamlined shape of the double-cone head, described in detail in the book (Pechenkin V.E., Mazurkin P.M. Chipless wood cutting. - M.: Timber industry, 1986. - P.50-52). The quadratic parabola formulas are shown here, which makes it possible to determine the heights of both cones from the top to the base, depending on the diameter of the chamfer of the penetrometer rod.

A method of testing industrial wood is implemented, for example, on a log of a wooden house as follows.

First, at the construction site, product 1 is selected and inspected for possible penetration of the penetrometer. Then the penetration of the two-cone head of the penetrometer into the wood is slowly performed.

In zone I, penetration indicators (sound strength and impulse) are not measured, and measurements begin from the moment the two-cone head 3 and 4 and the chamfer 5 of the penetrometer are completely deepened 2. The strength of the sound and the structure as a whole are judged by the evenness of the change in force and sound.

On a growing tree, for example, in the spring, at the maximum sap flow, a two-cone head is penetrated at a selected location (most often at the height of the researcher’s chest, that is, at a height of 1.3 m) and a portable hollow penetrometer is tested. After recording the forces, the core of the wood is extracted and its annual layers are compared with the recording of the dynamics of the forces P _n / P _p (the sound here will be weak, so the sound pulses can not be recorded).

The proposed method is universal for many wooden building objects, and also allows even before harvesting building logs to test trunks and branches of growing trees to assess their suitability in construction. As a result, technological monitoring of building structures from wooden elements is implemented in the entire life cycle from a growing tree to old structures.

Claims (5)

1. A method of testing wood, including immersion of the cone head in the test material, calculating an indicator of the properties of the test material according to the penetration force of the cone head, the immersion being performed using feed mechanisms, and the strength of the test material is judged by the resistance of the material to immersion of the cone head, characterized in that when testing material from industrial wood, a cone-shaped head of a streamlined shape is used; additionally, momenta of change in the penetration force of the cone are measured th head of streamlined shape in the radial direction, having a material from the technical wood head with respect to the displacement vector from the periphery to the core of the tree trunk, wherein the duty ratio of pulses and rhythm strength judged as technical wood. 2. The method of testing wood according to claim 1, characterized in that on dry wood of building structures, pulses are measured by sound signals transmitted from the cone head in the form of creaks from the destruction of the late zone of the annual layer, and the percentage of late wood annual is judged by the duty cycle of the sound signal layers. 3. The method of testing wood according to claim 1, characterized in that the graphs of the effort and impulses of penetration of the biconical head into the test material are recorded simultaneously, the local destruction forces of the late and early zones of each layer are compared, and the quality of the technical construction wood is judged with respect to these efforts products and logs in long-term storage. 4. The method of testing wood according to claim 1, characterized in that when testing growing trees and raw materials from industrial wood, the impulses of changes in the penetration force are compared with measurements of annual layers and their early and late zones on wood cores obtained by a hollow biconical head. 5. The method of testing wood according to claim 1 or 4, characterized in that the test of growing trees is performed during the growing season during the maximum movement of the sap of woody plants.

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