LV13743B - A method and equipment for shear deformation of rigid plastic foams, a method and a device for determination of shear displacement and their application for determination of shear properties of other porous materials - Google Patents

Abstract

The invention especially relates to the method and equipment for shear deformation of rigid plastic foams as well as to the method and the device for determination of the shear displacement of rigid plastic foams, but is also applicable for determination of shear properties of other porous materials, e.g. balsa wood, metal foams etc. in case the stiffness of the test material is such that the stiffness of the extensometer itself has a small influence on the measurement results. The offered shear deformation equipment consists of 2 U-profile supports (1) with such a wall thickness that insures occurrence of no pealing of the sample (2) from the supports during deformation. In the offered shear deformation method adapters (3) prior to their attaching to the supports are modified in such way that the action line of the external force is directed through the longitudinal axis of the sample, parallel to it, when samples of different thickness are tested. The offered device for determination of shear displacement consists of extensometer (4) with extensions of the measuring legs made in such a way their plane of movement is parallel to the deformation plane ZOX and displacement is being determined on the sample (2).

Description

Method and apparatus for shear deformation of rigid foam, method and device for determining shear displacement and their application to determine shear properties of other porous materials

Description of the Invention

The invention relates in particular to a method and apparatus for shear deformation of a rigid foam, to a method and device for determining a shear displacement of a rigid foam, and to a method, apparatus and device for determining the shear properties of other porous materials.

Analysis of prior art to the applicant

Signs used. With the term "adapter" in several analogs (International Organization for Standardization ISO 1922; 2001; "Determination of shear strength of rigid cellular plastics" and Latvian standard LVS EN 12090; 2002; "Thermal insulation materials for use in construction. and the identical European Standard EN 12090: 1997) and this description identifies a component of a rigid foam shear deforming device that transmits an external force line through the center of the sample parallel to its longitudinal axis.

The term "lust", as used herein, refers to a component of a rigid foam shear deforming device which provides clamping of a «holding plate-sample» system with the grips of a test machine.

Analog 1

1.1) Known method of shear deformation for rigid foams (German Democratic Republic standard DIN 53 427 "Determination of shear strength of rigid foams between metal plates", 1986), which includes: 1) attaching a force action line adapter at each end of two planes metal clamping plates and sample sticking between both clamping plates, 2) clamping the clamping plates with the grips of the test machine by means of an adapter extension, 3) sliding the sample by applying an external force through the longest axis of symmetry of the sample and measuring the external force equipment readings.

The drawbacks of the technique are: 1) ignoring the total weight of the carrier plate and adapter, which may become significant at the recommended carrier plate dimensions, in determining the external force value, 2) the rigid coupling prevents the holding plate sample from parallelizing the applied external force normal stresses as a result of bending relative to the pure shear deformation state. This leads to premature loss of strength and premature collapse of the specimen.

1.2) Known apparatus for implementing the shear deformation method for rigid foams according to 1.1 consists of two flat specimen holder plates, the thickness d of which must be greater than d> 0.4 (r _max ) ^1/2 = 9.2 mm, if the shear foam to be tested strength T _max > 150 kPa to reduce bending moment in and retention of specimen plates. One end of each retaining plate has a force line adapter which allows external force to pass through the longitudinal axis of symmetry of the sample, parallel to it, thus creating the prerequisites for achieving a pure shear deformation in the sample.

The drawbacks of the apparatus are: 1) the sample holding plates are flat, therefore, for higher density and stiffness foam tests, the plate bending moment may be insufficient, the holding plates may bend, deforming the sample and distorting the shear stress in the sample, and causing the sample holder to rest. are firmly engaged with the grips of the test machine.

1.3) Neither the method nor the device for determining shear displacement is described.

Analog 2

2.1) A method of shear deformation for rigid foams is known (International Standardization Organization Standard ISO 1922, 2001; "Hard Cellular Plastics - Determination of Shear Strength"), which includes: 1) attaching a force line adapter and a hook to each of the two planes metal clamping plates at one end and gluing the specimen between the two clamping plates, 2) clamping the clamping plates to the clamps of the test machine by means of hangers that allow the "clamping plate-sample" system to rotate about two mutually perpendicular axes; the longest axis of symmetry of the sample, parallel to it and determining the value of the external force, after reading the force recorder of the test machine. In the technique, the total weight of the holding plate, adapter and hanger is taken into account by subtracting (adding) it from the readings of the force recorder of the test machine if the recorder is above (below) the specimen.

2.2) Known apparatus for implementing the shear deformation method for rigid foams according to 2.1 consists of two planar specimen holding plates having at each end: 1) a force line adapter which transmits external force through the longitudinal axis of symmetry of the specimen, thereby creating preconditions achieving pure shear deformation in the sample; 2) a lust consisting of two cylindrical shamers which provide turns around two mutually perpendicular axes.

The disadvantage of the apparatus is that the sample carrier plates are flat, therefore, for higher density and stiffness foam tests, the plate bending moment may be insufficient, the carrier plates may bend, deforming the sample and distorting the shear stress in the sample, and causing the sample to rest.

2.3. Known method of measuring shear displacement for a sample deformed in shear according to 2.1; on the equipment described in 2.2), involves determining the displacement of the shear after the traverse of the test machine. A major disadvantage of this technique is that the shear displacement, determined after the traverse movement of the test machine, includes the test machine grip, hangers, adapters, holding plates, adhesive layers, as well as the shear, tensile and compression deformation components of the specimen. This prevents the material characteristics from being determined accurately in a pure shear with a near deformation in the central portion of the sample.

2.4) The known shear displacement measuring device for the implementation of the method according to 2.3 is a test machine. The disadvantage of this device is that its measuring devices are not designed to detect shear displacement directly on the sample.

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Analog 3

3.1) The shear deformation technique for heat insulating materials is known, incl. foams (Latvian standard LVS EN 12090; 2002; Thermal insulation materials for use in construction - Determination of shear properties) and identical European standard

EN 12090: 1997), which includes: 1) attaching a force line adapter and hanger to each of the two flat metal holding plates and gluing a sample between the two holding plates, selecting the adhesive according to the foam specifications so that the adhesive has a shear strength and modulus shear strength and modulus of foam., 2) clamping of the holding plates by the clamps of the test machine by means of lugs providing rotation of the "Top carrier plate" system around two mutually perpendicular axes, 3) loading by shearing, applying a line of action of external force through parallel to it and determining the magnitude of the external force from the indication of the force recorder of the test machine.

The disadvantage is that the total weight of the holding plate, adapter, hanger and both cylindrical pivots is not taken into account when determining the value of the external force applied to the sample.

at the end are: (1) a force line adapter which allows external force to pass through the longitudinal axis of symmetry of the sample, parallel to it, thus providing the prerequisites for achieving pure shear deformation in the sample; 2) a lance consisting of two cylindrical pivots which provide for turns around two mutually perpendicular axes.

The disadvantage of the apparatus is that the sample holding plates are flat, so for higher density and stiffness foam tests, the plate bending moment may be insufficient, the holding plates may bend, deforming the sample and distorting the shear stress in the sample, and causing the sample to burst.

3.3) Known method of measuring shear displacement for thermal insulation materials, incl. foams; sample deformed by the method described in 3.1; The equipment described in paragraph 3.2. above shall include the determination of the shear displacement both after the traverse of the test machine and by the displacement transducers. The disadvantage of the technique is that the analog does not describe the displacement transducer placement and measurement method, and the transverse displacement erosion is corrected by the displacement of the test machine's grip, hangers, adapters, holding plates and glue layers as determined by the "blank" test the sample is replaced by a metal sample.

The disadvantage of the technique is that the shear displacement, determined after the traverse movement of the test machine, includes the test machine's grip, adapter, hangers, holding plates, adhesive layers, as well as sample shear, tensile and compression deformation components. in a shear close to the deformation in the central part of the sample.

3.4) The known shear displacement sensing devices for implementing the method of (3.3) are: (1) a test machine, or (2) displacement sensors. The disadvantage of the test machine is that its measuring equipment is not designed to detect shear displacement directly on the sample.

Analog 4

4.1) Tensile and compressive shear deformation techniques for sandwich core materials are known (US Standard AST C 273 / C 273 -07a "Standard Test Method for Shear Properties for Sandwich Core Materials"), which includes: 1) Attaching a hanger to each of two flat metal holding plates 2) clamping the support plates with the clamps of the test machine, using hangers in the case of tensile shear, so as to ensure the rotation of the "support plate-sample" system around two mutually perpendicular axes and, in the case of compression shear, with a load coupling a test machine with one short tapered edge of each support plate resting on the V-groove of the respective load block; 3) the subsequent loading is shifted so that the line of action of the external force passes through the diagonal plane of the sample parallel to it; c inspection machines force recorders display.

The drawbacks of the techniques are: 1) Since the techniques for implementing the techniques do not include force line adapters, the external force is directed diagonally across the specimen at an angle to the longitudinal axis of the specimen. The external force F component, Fj = F, in the case of tensile shear, tears off the ends of the sample from the retaining plates, but in the case of compressive shear, compresses the ends of the sample; 2) from an energy point of view, this type of loading is less advantageous than the line of action of the force passing through the longitudinal axis of the sample, since a part of the power of the test machine is consumed in a

Fi provision; (3) no correction is made to the force shown on the test machine power indicator by the total weight of the carrier plate and hanger.

4.2.1) Known machine for point shear sandwich core materials

4.1) For implementation, consists of two flat specimen holder plates, the thickness of which is varied according to the strength of the sandwich to be tested to minimize bending effects, each holder having a lace at one end, consisting of two cylindrical pivots providing rotations about two mutually perpendicular axes. The lust is designed so that the line of action of the external force passes through the diagonal plane of the sample, parallel to it.

The drawbacks of the apparatus are: 1) There are no power line adapters, so the external force is directed spatially diagonally to the specimen at an angle α to the longitudinal axis of the specimen. (2) from an energy point of view, this type of loading is less advantageous than where the line of action of the force passes through the longitudinal axis of the sample, since part of the power of the test machine is wasted to provide the component Fj, 3 ) the sample holding plates are flat, therefore, for higher density and stiffness foam tests, the bending moment of the plates may be insufficient, the holding plates may bend, deforming the sample and distort the shear stress in the sample, and cause the sample to break from the holding plates;

4.2.2) Known apparatus for pressurized sandwich core material according to Clause 4.1) consists of flat metal holding plates, the thickness of which is varied according to the strength of the tested sandwich to reduce the bending effect, with one short edge flush with each holding plate. test machine load block The mold groove and load units are firmly coupled to the test machine.

The disadvantages of the apparatus are: 1) There is no force line adapter, so the external force is directed diagonally across the specimen at an angle to the longitudinal axis of the specimen. External component F component Fi = F rails compress the ends of the sample; 2) from an energy point of view, this type of loading is less favorable than where the force acting line passes through the longitudinal axis of the specimen, since part of the power of the test machine is wasted to provide component Fj; 3) the load blocks are tightly coupled to the test machine so that the external force passes through its spatial diagonal parallel to it, 4) the sample holding plates are flat, so that for higher density and stiffness foam tests the bending moment of the plates may be insufficient, the holding plates may bend, distorting the sample and distorting the shear stress (5) no correction shall be made to the force shown on the test machine power indicator by the total weight of the carrier plate and the hanger.

4.3. Known method for measuring shear displacement of a sample of sandwich core material deformed by the method described in 4.1; on the equipment described in items 4.2.1) or 4.2.2) involves the determination of shear displacement by strain gauges: deflectometers, compressors or extensometers, fixed to holding plates opposite to the center of the sample in the longitudinal direction of the sample.

The disadvantage of the technique is that when measuring the gauges to the support plates, they determine the relative displacement between the support plates, so this displacement includes the displacement of the support plates, gauge mounts, adhesive layers and the entire sample, which may differ from the material characteristics of pure shear deformation in the central part of the sample.

4.4) The known shear displacement measuring device according to 4.3 is equipped with strain gauges: deflectometers, compressors or extensometers with an accuracy of at least ± 1%. No method is provided for applying these devices to the determination of shear displacement directly on the sample.

Analog 5

5.1) Known Shear Deformation Technique for Rigid Foam (Doctor of Engineering degree thesis, R.Renz... Deformation of Rigid Polymeric Foam Materials under Even and Cyclic Loading, 1977), which includes: 1) sticking a sample between two flat support plates, each the adapter functions by a single convex end, 2) clamping of the holding plates with the grips of the test machine by means of a curved end extension, 3) loading by sliding the external force through the longitudinal axis of symmetry of the sample parallel to it .

The disadvantage of the technique is that due to the tight coupling of the "holding plate - sample" system to the test machine, the sample exhibits an increase in zero strain as compared to the pure shear deformation state. This leads to premature loss of strength and premature collapse of the specimen.

5.2) The known apparatus for implementing the shear deformation method for rigid foam according to 5.1 consists of two flat holding plates. One end of each retaining plate is curved such that the exterior load is directed at the center of the sample parallel to its longitudinal axis. With the clamps of the test machine, the holding plates are rigidly clamped using the curved end extension.

The disadvantages of the device are: 1) the support plates are only 5 mm thick and flat, without bending stiffeners. For high-shear foam, the deflection of the retaining plates as well as the residual curvature of the endplate may become significant. Then the force acting line no longer runs along the center of the sample parallel to its longitudinal axis, even in its center no pure shear deformation occurs, nor does the normal stress increase, 2) the holding plates through the elongated end extensions are rigidly clamped with the state of pure shear deformation. This leads to premature loss of strength and premature collapse of the specimen.

5.3. Known method for measuring the displacement of a sample distorted by the method described in 5.1; The apparatus described in paragraph 5.2. above shall include the determination of shear displacement by means of inductive strain gauges which are fixed to the ends of the holding plates. The disadvantage of the technique is that the displacement thus determined involves displacement of the retaining plates, layers of glue and the entire sample, which may result in a difference in the material characteristics of the pure shear with a near deformation in the central part of the sample.

5.4) The known shear displacement measuring device according to 5.3 is implemented by inductive strain gauges. No method is provided for applying these devices to the determination of shear displacement directly on the sample.

Analogue 6

6.1) The Shear Deformation Technique for Polypropylene Foam is known (Thomas Weber Diploma Paper, "Numerical Modeling and Testing of Polypropylene Foam Force-Deformation Behavior with Experimental Data", Kaiserslautham University, 1994). The technique and the machine are based on DIN 53 427 as applied to NEOPOLEN® P polypropylene foam. The method comprises: 1) attaching hangers at one end of each of the two flat metal holding plates and gluing a sample between the two holding plates with adhesive Araldit AW 106 having a high shear strength greater than the shear strength of the foam, (2) clamping the holding plates with the grips of the test machine using lugs that provide rotation of the "holding plate" system about three mutually perpendicular axes, (3) sliding the load so that the outer lumbar action line passes through and determining the size of the external lard according to the indication of the force recorder of the test machine

The drawbacks of the method are: 1) Since the method implementation device does not have force line adapters, the external force is directed along the spatial diagonal of the sample at an angle α to the longitudinal axis of the sample.

The external force F component Fi = F rails promotes the separation of the ends of the sample from the holding plates; 2) from an energy point of view, this type of loading is less favorable than the force line passing through the longitudinal axis of the sample; (3) no correction is made to the force shown on the test machine power indicator by the total weight of the carrier plate and hanger.

6.2) Known apparatus for shear deformation of rigid foams according to 6.1 consists of two flat specimen carrier plates each having a lace at each end (a carabiner in the form of a chain link and a metal plate) which together provide for turns around three mutually perpendicular axes. parallel to external force.

The drawbacks of the apparatus are: 1) There are no power line adapters, so the external force is directed spatially diagonally to the specimen at an angle α to the longitudinal axis of the specimen. The external force F component Fj = F rails promotes the separation of the ends of the sample from the holding plates, 2) from an energy point of view this loading is less advantageous than which force line passes through the longitudinal axis of the sample since part of the test machine power is wasted; ) the holding plates are flat, without bending stiffeners, so the bending of the holding plates is possible, which increases the effect of the normal stresses and the numerical value of the displacement, and facilitates the release of the sample from the consumption plates at the adhesive layer.

6.3. Known method for measuring the displacement of a sample distorted by the method described in 6.1; on the equipment described in paragraph 6.2., involves determining the displacement of the shear after the traverse of the test machine.

The drawbacks of the technique are that the displacement thus determined involves displacement in the clamps of the machine, the latch (carabiner and metal plate), the holding plates, the layers of glue and the entire sample, which may differ from the material characteristics of the pure shear.

6.4) The known shear displacement detection device for the implementation of the method of 6.3 is a test machine. The disadvantage of this device is that its measuring devices are not designed to detect shear displacement directly on the sample. Slips on machine grips and other elements are possible.

Summary of prior art analysis

1) Several known techniques for shear deformation of rigid foam include the use of adapters of constant shape and size to provide a line of action of force through the longitudinal axis of the sample, parallel to it. Thus, it is not possible to test samples of different thicknesses. In some known ways, the force line adapters are not used, so that the external force F passes through the spatial diagonal of the sample, parallel to it, forming an angle α with the longitudinal axis of the sample. Under such loading, the external force F component Fi = F rails facilitates the separation of the ends of the sample from the holding plates. From an energy point of view, this type of loading is less advantageous than the line of action of the force passing through the longitudinal axis of the sample, since a part of the power of the test machine is consumed in a useless component.

Fi.

In accordance with known techniques, the sample is glued between the two holding plates, with the adhesive being selected in accordance with the foam specifications so that the adhesive has a shear strength and modulus substantially greater than the foam shear strength and modulus. The holding plates are entangled with the grips of the test machine by means of hangings which, in several known ways, enable the "holding plate sample" system to be oriented parallel to the line of action of the external force. In some known ways, lust forms a strong coupling with the grips of the test machine, which increases the normal stresses in the specimen as a result of bending compared to the state of pure shear deformation. This leads to premature loss of strength and premature collapse of the specimen.

Apply an external shear force to the test machine. Some known techniques take into account the total weight of the support plate, adapter, and hanger by subtracting (adding) it from the test machine's force recorder readings, depending on the position of the force recorder above / below the sample.

2) A number of known rigid foam shear deformation machines consist of two flat specimen metal holding plates, each having an adapter of constant shape and size at each end and a lust for clutching the test machine. Each lust ensures the orientation of the «holding plate - sample» system parallel to the line of action of the external force. The disadvantage of the equipment is that the sample carrier plates are flat, so that for the higher density and stiffness of the foam tests the bending moment of the plates may be insufficient. The holding plates may bend, deforming the sample and distorting the shear stress in the sample, as well as causing the sample to break from the holding plates. Constant shape and size adapters prevent specimen thicknesses from being tested.

In some known devices, the adapter is not used, so that the external force F passes through the spatial diagonal of the sample, parallel to it, forming an angle α with the longitudinal axis of the sample. Under such loading, the external force F component Fj = F shin promotes tearing off the ends of the sample from the holding plates. From an energy point of view, this type of loading is less advantageous than where the line of action of the force passes through the longitudinal axis of the sample, since part of the power of the test machine is wasted to provide component Fj.

In some known devices, lust forms a rigid coupling with the grips of the test machine, which increases the normal stresses in the specimen as a result of bending compared to the state of pure shear deformation. This leads to premature loss of strength and premature collapse of the specimen.

(3) Known techniques for determining shear displacement of rigid foam are characterized in that the displacement is fixed: (a) after the shear displacement of the test machine; (b) with inductive strain gauges fixed to the ends of the holding plates; (c) by deflectometers, compressors or extensometers fixed to the holding plates opposite to the center of the sample in the longitudinal direction of the sample. Shear displacement, determined by the traverse movement of the test machine, includes the test machine's grips, adapters, hangers, holding plates, adhesive layers as well as the shear, tensile and compression deformation components of the specimen that preclude accurate determination of material characteristics in the central part of the sample. Attaching gauges to support plates, they measure relative displacement between support plates, thus including displacement in support plates, strain gauge mounts, adhesive layers, and throughout the sample, which may result in differences in material characteristics with a pure shear near the center of the sample. .

There is no known technique for using inductive strain gauges, deflectometers, compressometers and extensometers to determine displacement directly on a sample.

(4) Known rigid foam shear displacement measuring devices are test machines; inductive strain gauges; deflectometers, compressors or extensometers. The disadvantage of the test machine as a displacement measuring device is that its corresponding measuring equipment is not designed to measure shear displacement directly on the sample. Inductive strain gauges, deflectometers, compressometers and extensometers are also known to be fixed in a known manner to the sample holder plates and there is no way of adjusting these devices to determine displacement directly on the sample.

Technical problem and its solution according to the invention

It is a technical object of the invention to provide a method of loading rigid foam specimens under shear deformation conditions and a device for implementing this deformation, and a method for measuring rigid foam shear displacement and a device for performing this method.

According to the invention:

1) The method of shear deformation of rigid foams involves modifying the adapters before attaching them to the metal support plates so that the external force line passes parallel to the longitudinal axis of the sample. When testing specimens of varying thicknesses, the number and / or thickness of the adapter washers will vary depending on the thickness of the specimen. Two flat metal plates connected to a metal chain link are used to clamp the U-shaped metal profiles to the clamps of the test machine in each pendant, thereby ensuring that the "holding plate-sample" system is oriented parallel to the external force action line, one of which is fixed at the adapter screw, the other at the grip of the test machine. This allows a sufficient bending moment to be obtained at the same or less weight of the support plates so that the support plates do not bend and the sample tears.

(2) The rigid foam shear deformation apparatus shall consist of support plates made in the form of U-shaped metal profiles with a wall thickness sufficient to prevent the specimen from tearing off the support plates as a result of their curvature during testing. A power line adapter is attached to one end of each retaining plate. Each adapter consists of a screw, washers of variable number and / or thickness and a nut with washer. The number and / or thickness of the adapter washers, depending on the thickness of the specimen, are used to provide a line of action of external force through the longitudinal axis of the test specimen parallel to it. The machine also includes clutches for the clamps of the test machine, each lance being designed as a mechanical connection between two metal plates and a metal chain link that provides the system's "holding plate-sample" turns around three mutually perpendicular axes. One of the plates is fixed to the adapter screw and the other to the grip of the test machine.

(3) The method of determining the shear displacement of rigid foams involves the use of a strain gauge (extensometer) directly to determine the shear displacement on a sample pasted between the holding plates of the apparatus described in (2). the striker is positioned relative to the sample so that the plane of movement of the gauge gauges with extensions is parallel to the plane of shear deformation of the sample, the metal needles at the ends of the gauge gauges insert into the sample, whereby the distance between the needles horizontally determines the measuring layer height; and the length is changed by changing the length and shape of the mountaineer extensions, balancing the weight of the buzzer, with a link to conquer it in a spring that is hung on a hook. The hook shall be rigidly attached to the upper adapter screw of the device described in point 2). Each gauge is pressed against the specimen with a metal compression spring, the end of which is attached to the free end of the needle with one end of the needle attached to the free end of the needle and the other end folded against the opposite face of the specimen.

(4) The rigid foam shear displacement detecting device shall consist of a strain gauge strain gauge with its metal extension needles extending in such a way that the plane of movement of the gauge and extension strain during the shear deformation of the sample is parallel to said deformation.

In the LV 1374i plane, the needles are inserted directly into the sample, the length and shape of the mite extenders determine the height and length of the measuring layer. The device also includes a strap, a spring for balancing the weight of the meter, a hook and its fixed elements on the top adapter screw of the device described in 2), as well as two metal clamping springs for pressing the gauge and needles.

The proposed device allows to determine the shear displacement directly on the sample.

List of drawings illustrating the invention:

1st knows. Rigid foam in shear deformation machine with shear displacement detection device (front view);

Fig. 2 Desire and grip of test machine;

Fig. 3 Hanging plates;

Fig. 4 Rigid foam shear deformation device with shear displacement device (bottom view and section).

Fig. 5 Solid foam shear displacement gauge extensions:

(a) Upper extender;

(b) lower extender;

Fig. 6 Hook for hanging springs.

Fig. 7 Compression spring.

Example of implementation of the invention

1) An apparatus for loading rigid foam under shear deformation is illustrated in Figures 1-4. fig. The apparatus consists of two metal holding plates (1), each of which is made in the form of a U-shaped wall of sufficient thickness to ensure that the sample plates (2) are not inflated during the test by bending. A power line adapter consisting of a screw (3), variable number and / or thickness washers (4) and a nut (5) with a washer (6) is attached to one end of each retaining plate. The adapters are modified prior to their attachment to the holding plates (1) such that the external force acting line passes through the longitudinal axis of the sample (2), parallel to it. When testing specimens of different thicknesses (2), the number and / or thickness of the adapter washers (4) are varied depending on the thickness of the specimen (2). Attached to each clamping plate adapter screw is a latch for clutching with the test machine grip (7), and the latch is designed as a mechanical connection between two metal plates (8), (9) and a metal chain link (10) to provide a system 'Turns around three mutually perpendicular axes.

2) Solid foam shear deformation technique using Figs. The equipment shown and described in point 1 is implemented as follows. When testing specimens of different thicknesses (2), the adapters are modified so that the line of external force passes through the longitudinal axis of the specimen before being fixed to the support plates (1). This is done by changing the number and / or thickness of the adapter washers (4) depending on the thickness of the sample (2). Each of the U-shaped support plates (1) holds the modified power line adapter and hanger at one end, respectively. The sample (2) is glued between the two retaining plates (1), the glue being selected according to the foam specifications so that the adhesive shear strength and modulus are significantly higher than the foam shear strength and modulus. The holding plates (1) are laced with the clamps (7) of the test machine by means of hangers which are fastened to the adapter screws. Each hanger uses plates (8) and (9) connected to a chain link (10), thereby ensuring that the "holding plate - sample" system is oriented parallel to the external force action line, rotating about three mutually perpendicular axes ΟΧ, OY and OZ. Apply an external shear force parallel to the OZ axis using the test machine. The total weight of the holding plate (1), adapter and hanger shall be taken into account by subtracting (adding) it from the readings of the force recorder of the test machine depending on the position of the force recorder above / below the sample.

3) A device for determining shear displacement of rigid foam, when the shear deformation is implemented on the apparatus described in (1) in accordance with the method described in (2), is shown in Figures 1 and 4-8. The device consists of a strain gauge (12) connected to the signal cable (11), the extensions (15), (16) of the gauge (13), (14) with the needles (17) being formed according to fig. such that the plane of motion of the gauges with extensions is parallel to the shear deformation plane of the sample paraug. Needle tips and staples (18); unladen latch (19). the length and shape of mite extensions determine the height and length of the measuring layer. The device also includes a link (20), a cylindrical spring (21) for balancing the weight of the gauge, a hook (22) for hanging the spring formed in Fig. 6. as shown and the elements for rigidly attaching the hook to the upper adapter screw of the device described in (1), the nuts (23), (24) of this device. With the metal compression springs (25) and (26), each gauge is pressed against the specimen with the needle by closing the end of the compression spring with a hole on the free end of the needle and supporting the other folded end against the opposite face of the specimen.

(4) The method for determining the shear displacement of rigid foams using the device described in (3) shall be implemented as follows. For the determination of the shear displacement directly on the sample (2), a strain gauge (extensometer; eg TS odel 632.11C-20) (12) shall be used which, relative to the sample (2) pasted between the two mounting plates of the apparatus described in positioned so that the plane of motion of the gauge (13), (14) with the extensions (15), (16) is parallel to the shear deformation plane ΖΟΥ of the sample. Insert the needles (17) into the face of sample (2) parallel to the ΥΟΖ plane. The displacement is determined by a measuring layer of a certain height and length, the height of the layer being determined by the distance between the needles in the horizontal and the length by the distance in the vertical, the buoyant weight being balanced by a link (20) by hanging it in a spring (21) . The hook (22) is shaped such that, in its arrangement, the longitudinal axis of the spring (21) passes through a major plane of symmetry of the housing (12) parallel to it. The hook (22) is fixed rigidly to the upper adapter screw (3) of the device described in (1), in this case the nuts (23), (24). Use an extensometer (12) of low weight P] relative to the external force exerted on the sample (2) parallel to the OZ axis so that no significant displacement of the longitudinal axis of the "carrier plate - sample" system can be caused. Each gauge is pressed against the specimen with a metal compression spring (25) and (26). Pull out the lock (19). Apply an external shear force to the sample (2) of the rigid foam shear deformation technique described in (2), parallel to the OZ axis, and collect data from the strain gauge (12) to the data acquisition system.

Possible Industrial Application of the Invention

Injection into cracks and crevices of building elements to provide thermal insulation is a widely used polyurethane and the like. foam application. Under these conditions, the foam absorbs a certain proportion of the shear loads that occur during operation, thereby ensuring the durability and integrity of said building elements. Shear deformation conditions also occur in sandwich sandwich elements where foam is used as filler. This makes it necessary to study the shear properties of foam.

The described apparatus for shear stiffening of rigid foams, the related method, as well as the device for determining the shear displacement of rigid foams and the related method are in principle applicable for determining the shear properties of any solid, porous material (e.g. foam, balsa, metal foam, etc.). ,

- the rigidity of which is such that the rigidity of the strain gauge itself has little effect on the results of the measurements; .

- capable of inserting needle extension needles without deforming them.

Claims (5)

Claims 1. A method of shear deformation of rigid foam comprising attaching a force line adapter and a hook at one end to each of the two sample metal holding plates, gluing the sample between the two holding plates, selecting adhesive according to the foam shear strength and modulus significantly greater than the foam. shear strength and modulus; clamping the holding plates with the grips of the test machine by means of lugs which enable the "holding plate - sample" system to be oriented parallel to the line of action of the external force; applying external shear force by means of a test machine; taking into account the total weight of the retaining plate, adapter and hanger, subtracted from or added to the reading of the force recorder of the test machine, depending on the position of the force recorder above / below the sample, with the difference that: - adapting the adapters to the support plates formed in the form of U-shaped metal profiles by changing the number and / or thickness of the washers in the adapter depending on the thickness of the specimen, - For attaching the holding plates to the testing machine, two flat metal plates are mechanically connected to each other by a metal chain link, one plate is fixed to the adapter screw and the other to the clamp of the test machine. Apparatus for implementing the method of deforming a rigid foam shear according to claim 1, comprising two sample metal holding plates each having an adapter attached at one end and a clamping device for clamping the test machine, each lance providing the system "holding plate - sample" orientation. parallel to the line of action of the external force, differing in that: - the supporting plates are made in the form of U-shaped metal profiles with a wall thickness which provides sufficient bending moment for the holding plates to prevent the sample from rupturing from the holding plates during the test, - each force line adapter consists of a screw, a variable number and / or thickness washers and a nut with washers, and the number and / or thickness of the adapter washers, depending on the thickness of the specimen, are selected to allow the external force line to pass through the longitudinal axis of in parallel, - each latching clutch is designed as a mechanical coupling between two metal plates and a metal chain link, which provides for a system of "holding plate-sample" turns around three mutually perpendicular axes, one plate mounted on the adapter screw and the other on the test machine grasped. 3. A method for determining the shear displacement of rigid foam which involves the use of a displacement gauge, the application of an external shear force by means of a testing machine parallel to the longitudinal axis of the sample and the collection of shear displacement data from the displacement gauge. - used to determine the tensile strain gauge (extensometer) in shear displacement directly on the sample deformed according to claim 1, wherein the gauge relative to the sample pasted between the two holding plates of the device described in claim 2 such that the gauge the plane of movement of the gauges with its extensions is parallel to the plane of shear deformation of the sample, - measuring needle extension needles are inserted into the sample, the distance between the needles being 5 horizontally determines the height of the measuring layer and the distance between the needles vertically determining its length, - the weight of the meter is balanced by hanging it by means of a hook in a spring which is suspended on the hook, whereby the hook is fixed rigidly to the upper adapter screw of the device described in claim 2, - each gauge is pressed against the specimen by a metal compression spring, one end of which is attached to the free end of the needle by a hole and the other end of which is folded against the opposite face of the specimen in the direction opposite its length. An apparatus for implementing the method of claim 3, wherein; - consists of a strain gauge strain gauge, whose gauge legs and their extensions are designed so that the plane of motion of the gauges and extensions is parallel to the deformation plane during the deformation of the sample, the length and shape of the gauge extensions being varied according to test height and length. , - includes a meter weight balancing system comprising a strap, a spring, a hook, and elements for rigidly securing the meter to the top of the device described in claim 2. 20 adapter screws, - includes two metal compression springs for pressing the gauge and needle onto the sample. Use of the method and apparatus of claims 1 and 2 for applying shear deformation to any solid porous material, e.g. balms for wood, metal foam, etc. for solid, porous materials, if the stiffness of the material to be tested is such that the stiffness of the strain gauge itself has little effect on the measurement results and may result in the insertion of the needles of the extensions without the need for deflection. Use of the method and device of claims 3 and 4 for determining shear displacement for any solid porous material, e.g. balms for wood, metal foam, etc. for porous materials, if the stiffness of the material to be tested is such that the stiffness of the strain gauge itself has little effect on the results of the measurement and can cause insertion of the needles of the gauge extensions without deformation.