RU2228608C2 - Method for ultrasonic testing of growing tree bearing capacity - Google Patents

Abstract

FIELD: ecological engineering and forestry. SUBSTANCE: method involves forming at least one slot in peripheral part of growing plant in site to be tested along axis of this part to layer to be sonicated from bark surface including first year's layers of growing plant sapwood in site under test. Method allows ecological monitoring of territory to be effectuated by means of growing tree properties, as well as quality certification of individual trees and plantations to be provided on the basis of accounted trees in the course of, for example, forest regulation, allocation of forest areas for landscaping of territory and proving forest cleaning cuttings. EFFECT: wider operational capabilities of ultrasonic testing of construction bearing capacity, increased measurement precision at different moisture content of bark, cambium and first year's layer of growing tree sapwood. 8 cl, 14 dwg

Description

The invention relates to methods for ecological monitoring of the territory by the properties of growing trees and can be used in environmental engineering, as well as in forestry for certification of the quality of individual trees and forest stands for accounting trees, for example, during forest inventory, allocation of forest areas for landscape arrangement of the territory and for justification thinning of the forest.

A known method of ultrasonic testing of wood on standard samples obtained from growing trees after felling, mechanical cutting and subsequent processing by cutting, dimensions 20 × 20 × 300 mm (the last size along the fibers), including fixing the sample, sticker ferromagnetic plates on the corresponding places of the wood sample according to GOST 16483.31-74, the inclusion of an electromagnetic pathogen, a change in vibration frequencies to bring the sample into a resonant state (see, for example, the book: Ugolev BN Wood science with the basics of meat merchandising M .: MSFU, 2001. -. p.131).

The disadvantage is the high complexity of manufacturing standard samples of rectangular cross-section, the one-time testing of a growing tree, which does not allow the use of this method in environmental engineering, environmental monitoring, and also in forestry.

There is also a method of ultrasonic testing of the bearing capacity of centrifuged reinforced concrete struts of contact network supports (see data in the publication: scientific article by V.N. Kozlov, V.I. Podolsky, A.A. Samokrutov, V.G. Shevaldykin), including speed measurement the propagation of longitudinal ultrasonic waves in the body of the rack in the longitudinal and transverse directions. With surface sounding of reinforced concrete pillar material in two mutually perpendicular directions (across and along the pillar axis), the test is carried out in one or more of its places. Moreover, the method of surface sounding allows you to control the strength near damage in any places of the racks.

The disadvantage is that the prototype is designed for a specific field of application in the form of reinforced concrete racks and therefore, as applied to growing trees, it takes into account significantly new distinctive features. Moreover, the very concept of “bearing capacity” is expanding by us and the mechanical strength for a growing tree becomes only a special case. For a growing tree, we understand the bearing capacity primarily as the dynamic ability to carry flows of physiological solutions: nutrients in the cambial layer located between the first annual layer and the bark, as well as mineral juice in the first several annual layers of sapwood and photosynthesis products in layers adjacent to the cambium bark. Moreover, in the bark and annual tree layers, the flows of nutrient solutions are multidirectional. In addition, the disadvantage is the fact that according to the prototype it is necessary to provide dry point contact of the ultrasonic tester sensors, which is impossible for a growing tree, the moisture content of which in the cambial zone reaches 250% or more.

Thus, a new method is needed to apply a small wound in the cortex in the test location of a growing tree: sequentially, first to the bast, then to the cambium, and then to the first annual layer of sapwood of the growing tree (after this, the first annual layer may tear off wood, for example, at the end of the growing season). Moreover, the prototype is used depending on the type and place of surface damage, and the test place on a growing tree is taken from the need to implement environmental, technical or other goals (for example, to study the hydraulic parameters of the tree's vital products flows). At the same time, the study of various mechanical tree injuries (frost cracks, burls, growths, places of active resin discharge, bifurcations of the trunk, etc.), as well as places of damage by various pests and diseases of bark and wood, is of great importance.

The technical result is the expansion of the technological capabilities of ultrasonic testing of the structural bearing capacity, the ecological properties of the bark, cambium and wood, the nutrient flows of the vital products of a growing tree, as well as improving the accuracy of measurements at various humidity of the bark, cambium and the first annual layer of sapwood of a growing tree.

This technical result is achieved in that at least one recess along the axis of this part is made in the peripheral part of the growing tree in the test place to the sounding layer from the bark surface, including the first annual layers of sapwood of the growing tree in the test place.

The recess is square in shape to accommodate the sensors of a short-base ultrasonic tester.

The inclined parts of growing trees are tested in several places: to assess the ecological state on the side of the slope surface, to evaluate industrial wood, the place of sounding is chosen according to the slope, and to assess the physiological processes of the growing tree - against the slope.

For comparison with standard samples along the part of the tree, two recesses are made, located at least 300 mm apart from each other.

For the sanitary assessment of growing trees, places for sounding are chosen near wood defects, and the bottom of the recess should not have cracks or other mechanical damage.

Additionally measure the humidity of the surface of the bottom of the recess electronic hygrometer.

For a long-base ultrasonic tester, the dimensions of the square recess are taken by one tester sensor.

To compare with standard samples, measurements on the same recess are carried out until the equilibrium moisture content of the bark, bast, cambium or sapwood is stabilized as the cells naturally dry.

The essence of the invention lies in the fact that measurements with an ultrasonic device during surface scoring are transferred directly to specific and characteristic places of a growing tree, both on the trunk and on the branches and roots. Therefore, the whole tree does not need to be felled and destroyed. This significantly increases the information content of measurements, as well as the speed and accuracy of environmental monitoring by the properties of individual layers of the bark and annual layers of living sapwood in a growing state.

The essence of the technical solution also lies in the fact that during environmental monitoring, a growing tree is wounded only once and the formed depressions allow multiple measurements to be made, after the humidity of the sounding surface is stabilized in a selected place of the growing tree, for example, during the day, moon cycle, season, vegetation season period, as well as to identify long-term cyclic patterns of change in the properties of wood in a growing state. In this case, the recess once made, for example, using a scalpel, is used repeatedly. In the future, it becomes possible to identify the causes of the formation of dead trees, as well as the causes of diseases and the settlement of pests on a growing tree.

It is important that the object of measurement during repeated observations does not change geometrically, and the measurement of the properties of the bark, cambium and primary annual layers of wood in the measurement zone, for example, during experiments, can be taken into account by correction coefficients from the results of observations obtained from the beginning of the manufacture of recesses. According to the same data, amendments are introduced to change the moisture content of bark and wood.

Thus, the same accounting tree becomes the carrier of many bio-indicators in the form of various places of surface scoring, as well as the ecological and physiological state of the growing tree and its parts (it is known that each branch is a separate organism), taking into account the delay in the response of the physiological reactions of the woody plant to various natural (temperature and humidity, sunlight, groundwater level, diseases, pests, injuries, etc.) and artificial (harmful chemicals, rot, resulting damage, silvicultural techniques effects, thinning, etc. oshmyg cortex.) stimuli.

With good handling of surface recesses for ultrasonic measurements, from the moment of their manufacture, environmental monitoring is possible up to the complete aging of the reference tree as a biological indicator of environmental and technological (in forestry) conditions. Moreover, such small artificially made and treated with special substances wounds do not harm the body of this accounting tree, therefore, do not affect physiological processes.

The positive effect is that one-time wounding allows for long-term environmental monitoring of the territory in which accounting trees grow. In this case, it is possible to use existing types of portable ultrasonic devices, for example, a pocket tester like UK-1401, and other modern devices (for example, used in medicine) with point contact of sensors.

The recesses do not harm large and medium-sized trees. Therefore, the proposed method is focused on adult trees, and environmental monitoring is carried out for the current or past year on the periphery of the trunk, branch or root. And from these recesses, you can easily find the registration tree itself, however, its marking cannot be applied to the surface of the recess due to the high sensitivity of the method. The surface of the recess should not contain scratches, therefore, the production of a sounding surface at the bottom of the recess is possible only by cutting the fibers along the edges of the recess and by carefully removing individual layers of bark, bast, cambium or wood on annual layers with only a sharp instrument, for example, a medical scalpel.

The proposed technical solution has significant differences, novelty and positive effect. Materials discrediting the novelty of this invention, we have not found.

Figure 1 shows a diagram of the implementation of the proposed method on the trunk of a growing adult tree, front view; figure 2 is a section aa in figure 1; figure 3 is a section bB in figure 1; figure 4 is a diagram of a square recess on an inclined tree trunk or on its branches on the side of the plane of inclination; figure 5 - scheme of sounding by ultrasound of the surface of the tree from the side of the slope; Fig.6 is a diagram of the sounding of the surface of the trunk from the side opposite to the inclination of the tree; 7 is a diagram of the implementation of the method with two recesses; on Fig is a diagram of the implementation of the method with a long-base ultrasonic tester, the sensors of which are located at least 300 mm along the tree trunk; figure 9 is a section bb in Fig; figure 10 - scheme of sounding the surface of the birch peel short-base ultrasonic tester; 11 is a diagram of surface sounding after removing a piece of birch bark; on Fig - continuation of the recess to cambium; on Fig - diagram of the deepening and testing of the bearing capacity of the surface of the birch trunk without bark and cambium; on Fig - test scheme of birch wood after removal of the first annual layer.

The method of ultrasonic testing of the bearing capacity of growing trees includes the following steps.

On the trunk 1 (similarly to a branch or root) of a growing tree, a recess 2, for example, of a square shape, is made in the place selected for testing. At the contact points 3, the sensors of the ultrasonic tester 4 are pressed, and thereby measurements of the time and velocity of propagation of the speed of ultrasound along the bottom surface of the recess are performed. In this case, measurements are made across and along the axis of the barrel.

Short-base testers are performed, for example, with a distance between contact points of 50 mm, which allows testing trunks, branches or roots with a diameter of more than 120-160 mm.

If necessary, comparisons with the results of testing using standard samples, square recesses of smaller sizes (Fig. 8 and Fig. 9) are made along the trunk (branch or root) to accommodate one sensor, and the distance between the contact points 3 is taken at least 300 mm, with This ultrasound passes along the surface of the annual layer, taking into account the internal propagation of ultrasonic waves along the annual layer.

On young trees with a trunk diameter of 120 mm or less, it is recommended to test the bearing capacity only along the axis of the trunk.

The method of ultrasonic testing of the bearing capacity of growing trees is implemented, for example, on the trunk of an adult birch as follows.

First, an accounting tree is selected, which is able by its behavior to characterize the ecological state of the territory. Then, on the trunk 1 of the accounting tree, a place is chosen for making the recess 2. First, the sound of birch bark is performed, on the surface previously cleaned at the measurement site.

In the manufacture of a recess, for example with a scalpel, first birch bark fibers are cut across the fibers along the borders of an approximately square recess. Then, with the same scalpel, trimming the grooves on the sides is performed. After that, a piece of birch bark is carefully removed and the bottom of the indentation opens in the form of a birch bark. Measurements are performed along and across the axis of the barrel at points 3 of contact by an ultrasonic tester 4. If necessary, a further deepening of the measurement site is carried out to the cambial layer, to the surface of the barrel without bark, and even with the removal of the first or several annual layers in their fresh state.

Measurements at any level of increasing the depth of the deepening are carried out until a conditionally equilibrium state of moisture of the bark, bast, cambium or surface of sapwood occurs. Thus, various combinations of experimental studies are possible, depending on the objectives of the study. If necessary, it is possible to additionally measure humidity at the contact point with an electromagnetic moisture meter.

The proposed method allows you to measure environmental indicators and compare them with the speed of ultrasound, which changes its value depending on the physiological state of the accounting tree. Moreover, measurements can be performed without the manufacture of recesses, on a clean surface of the crust. However, the most reliable data will be obtained when measuring at a certain depth of the bark and sapwood. Statistical modeling of data dynamics reveals the patterns of both the physiology of a given tree and changes in the ecological condition of the territory during the day, weeks, several months and 2-5 years.

Claims (8)

1. The method of ultrasonic testing of the bearing capacity of growing trees, including the choice of a reference tree, surface sounding in two mutually perpendicular directions along and across the axis of the trunk or other part of the tree, characterized in that at least one recess is performed in the peripheral part of the growing tree in the test place along the axis of this part to the sounding layer from the surface of the bark, including the first annual layers of sapwood of the growing tree in the test place. 2. The method of ultrasonic testing of the bearing capacity of growing trees according to claim 1, characterized in that the recess is square in shape to accommodate the sensors of a short-base ultrasonic tester. 3. The method of ultrasonic testing of the load-bearing capacity of wood of growing trees according to claim 1, characterized in that the inclined parts of the growing trees are tested in several places: to assess the ecological state on the side of the surface of the slope, to evaluate the technical wood, the place of sounding is chosen according to the slope, and to assess the physiological processes of a growing tree - against tilt. 4. The method of ultrasonic testing of the bearing capacity of growing trees according to claims 1 and 2, characterized in that for comparison with standard samples along the part of the tree, there are two recesses located at least 300 mm apart. 5. The method of ultrasonic testing of the carrying capacity of wood of growing trees according to claims 1 and 2, characterized in that for the sanitary assessment of growing trees, places for sounding are chosen near the wood defects, and the bottom of the recess should not have cracks or other mechanical damage. 6. The method of ultrasonic testing of the carrying capacity of wood of growing trees according to claim 1, characterized in that it further measures the moisture content of the surface of the bottom of the recess with an electronic moisture meter. 7. The method of ultrasonic testing of the bearing capacity of growing trees according to claim 1, characterized in that for a long-base ultrasonic tester, the dimensions of the square recess take one sensor of the tester. 8. The method of ultrasonic testing of the load-bearing capacity of wood of growing trees according to claims 1, 2, 4 and 6, characterized in that for comparison with standard samples, measurements on one recess are carried out until the equilibrium moisture content of the bark, bast, cambium or sapwood is stabilized as natural drying out the cells.

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