CN112763372A - Wood humidity detection and tensile property detection equipment - Google Patents

Abstract

The invention relates to the field of wood detection, in particular to equipment for detecting humidity and tensile property of wood, which is developed along with modern detection technology, the detection is simpler and simpler at the moment, and the moisture content of the wood can be read by inserting a probe, but the detection method can not detect the moisture content of some harder woods.

Description

Wood humidity detection and tensile property detection equipment

Technical Field

The invention relates to the field of wood detection, in particular to wood humidity detection and tensile property detection equipment.

Background

Along with modern detection technology is more and more developed, detect at that time also more and more simple, probe insertion can read out timber's moisture content, but this detection method can't detect some comparatively hard timber moisture content, and above-mentioned problem has been solved to this equipment.

Disclosure of Invention

The invention aims to provide equipment for detecting the humidity and the tensile property of wood, which can clamp wood in various shapes, can detect the water content of any wood and can detect the tensile property of any wood.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a timber humidity detects and tensile properties check out test set thereof, detects the assembly including pressing from both sides tight assembly, humidity and tensile properties, press from both sides tight assembly and be connected with humidity detection assembly, humidity detects the assembly and is connected with tensile properties detection assembly.

As a further optimization of the technical scheme, the clamping combination comprises an equipment support I, a handle I, a worm support, a worm wheel shaft, a gear I, a gear ring I, a gear II, a gear ring II, a clamping jaw I, a clamping jaw II, a clamping jaw shaft, a rotating clamping block, a handle II, a pointed thread shaft, a thread support, an equipment support II and a hammer sliding groove, wherein the handle I is connected with the worm, the worm is rotatably connected with the worm support, the worm support is connected with the equipment support I, the worm is in meshing connection with the worm wheel, the worm wheel is connected with the worm wheel shaft, the worm wheel shaft is rotatably connected with the equipment support I, the worm wheel shaft is connected with the gear I and the gear II, the gear I is in meshing connection with the gear ring I, the gear ring I is connected with the clamping jaw I, the gear ring II is connected with the clamping jaw II, and the clamping jaw shaft are both in, the clamping jaw shaft is connected with the equipment support I, the clamping jaw I and the clamping jaw II are respectively rotatably connected with the two rotating clamping blocks, the handle II is connected with the tip threaded shaft, the tip threaded shaft is in threaded connection with the threaded support, the tip threaded shaft is in sliding connection with the equipment support I, the two ends of the threaded support are respectively connected with the equipment support I and the equipment support II, the equipment support II is connected with the equipment support I, and the hammering sliding groove is located on the equipment support I.

As a further optimization of the technical scheme, the humidity detection assembly comprises a motor I, a motor I shaft bracket, a knocking blade, a hammer I sliding rail, a tension spring I, a hammer II sliding rail, a spring I, a tension spring II, a motor I switch, a sliding frame, a frame sliding rail, a sampling probe, a motor II shaft bracket, a motor II shaft, a conveying gear I, a conveying gear II, a conveying roller, a belt wheel I shaft, a conveying gear III, a belt shaft gear, a conveying gear IV shaft, a sample feeding port, a motor III shaft, a drying box, a heating fan blade, a belt wheel II shaft, a friction wheel, a heating disc, a sliding cylinder, a mass sensor, a rotating shaft, a deflector rod, a sample outlet, a sliding chute I and a sliding chute II, wherein the motor I is connected with the motor I shaft, the shaft of a motor I is rotatably connected with a shaft bracket of a motor I, the shaft bracket of the motor I is connected with an equipment bracket I, the shaft of the motor I is connected with a knocking leaf, a hammer I is slidably connected with a slide rail of a hammer I, the slide rail of the hammer I is connected with the equipment bracket I, two ends of a tension spring I are respectively connected with the upper part of the slide rail of the hammer I, the hammer I is connected with the tension spring I, the hammer II is slidably connected with a slide groove of the hammer II, the slide rail of the hammer II is connected with the equipment bracket I, the spring I is sleeved on the slide rail of the hammer II, the spring I is in a compression state, two ends of the tension spring II are respectively connected with the equipment bracket I and a sliding frame, the tension spring II is in a tension state, the switch of the motor I is connected with the equipment bracket I, the sliding frame is connected with two frame slide rails, the two frame slide rails are, the sampling probe is connected with the sliding frame, the motor II is connected with the motor II shaft, the motor II shaft is rotationally connected with the motor II shaft bracket, the motor II is connected with the motor II shaft bracket, the motor II shaft bracket is connected with the sliding frame, the motor II shaft is connected with the conveying gear I, the conveying gear I is meshed with the conveying gear II, the conveying gear II is connected with the conveying gear II shaft, the conveying gear II shaft is rotationally connected with the motor II shaft bracket, the motor II shaft and the conveying gear II shaft are respectively connected with the two conveying rollers, the conveying gear II shaft is connected with the belt wheel I, the two belt wheels I are provided, the two belt wheels I are connected through a belt I, one belt wheel I is connected with the belt wheel I shaft, the belt wheel I shaft is rotationally connected with the sampling probe, the belt wheel I shaft is connected with the conveying gear III, and the conveying gear III is meshed with the conveying gear IV through, two belt shaft gears are rotatably connected with a sampling probe, a conveying gear IV is connected with a conveying gear IV shaft, the conveying gear IV shaft is rotatably connected with the sampling probe, a belt wheel I shaft and a conveying gear IV shaft are respectively connected with two conveying rollers, a sample feeding hole is positioned on a drying box, a motor III is connected with a sliding frame, a motor III is connected with a motor III shaft, the motor III shaft is rotatably connected with the drying box, the motor III shaft is connected with a heating fan blade, the motor III shaft is connected with a belt wheel II, two belt wheels II are arranged, the two belt wheels II are connected through a belt II, the belt wheel II is connected with a belt wheel II shaft, the belt wheel II shaft is rotatably connected with the drying box, the drying box is connected with the sliding frame, the belt wheel II shaft is connected with a friction wheel, the friction wheel is contacted with a heating plate, the heating plate is connected with a sliding barrel, the sliding barrel is slidably connected with a rotating, quality sensor is connected with the sliding frame bottom, and quality sensor contacts with the dish that generates heat, driving lever and stoving case sliding connection, and sample outlet, spout I, spout II all are located sliding frame, and the transport roller surface is crude.

As a further optimization of the technical scheme, the tensile property detection assembly comprises a hexagonal rotary head, a bidirectional threaded shaft, threaded blocks, sliding supports, sample supports, a sample clamp and a spring II, wherein the hexagonal rotary head is connected with the bidirectional threaded shaft, the bidirectional threaded shaft is provided with two threads with opposite rotation directions, the bidirectional threaded shaft is rotatably connected with a sliding frame, the two threads with opposite rotation directions on the bidirectional threaded shaft are respectively connected with the two threaded blocks, the two threaded blocks are both slidably connected with a sliding groove II, the two sliding supports are both slidably connected with a sliding groove I, the two sliding supports are connected through the spring II, the spring II is in a normal state, the two sliding supports are respectively connected with the two sample supports, and the two sliding supports are respectively rotatably connected with the two sample clamps.

The wood humidity detection and tensile property detection equipment has the beneficial effects that: arrange equipment in circular timber or square timber top, press from both sides tight assembly through the control and can press from both sides equipment tight in timber, strike through the hammer and strike and can pierce arbitrary timber inside with the sampling probe and accomplish the sample, the humidity detects the assembly and can take notes ligneous dry weight and wet weight after the sample, can obtain ligneous absolute and relative moisture content through the calculation, tensile properties detects the tensile properties of assembly detectable sample.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a first schematic structural view of the clamping assembly 1 of the present invention;

FIG. 3 is a second schematic structural view of the clamping assembly 1 of the present invention;

FIG. 4 is a schematic structural view III of the clamping assembly 1 of the present invention;

FIG. 5 is a first schematic view of the humidity sensing assembly 2 of the present invention;

FIG. 6 is a first sectional view of the humidity sensing assembly 2 of the present invention;

FIG. 7 is a second schematic structural view of the humidity sensing assembly 2 of the present invention;

FIG. 8 is a second sectional view of the humidity sensing assembly 2 of the present invention;

FIG. 9 is a third schematic structural view of the humidity sensing assembly 2 of the present invention;

FIG. 10 is a fourth schematic structural view of the humidity sensing assembly 2 of the present invention;

FIG. 11 is a schematic diagram of a fifth embodiment of the humidity sensing assembly 2 of the present invention;

FIG. 12 is a sixth schematic view of the humidity sensing assembly 2 of the present invention;

FIG. 13 is a seventh schematic structural view of the humidity sensing assembly 2 of the present invention;

FIG. 14 is a schematic view eight of the structure of the humidity sensing assembly 2 of the present invention;

FIG. 15 is a schematic view of the first embodiment of the tensile property testing assembly 3 of the present invention;

fig. 16 is a schematic structural diagram of the tensile property testing assembly 3 of the present invention.

In the figure: a clamping assembly 1; 1-1 part of an equipment support I, 1-2 parts of a handle I, 1-3 parts of a worm support, 1-4 parts of a worm, 1-5 parts of a worm wheel, 1-6 parts of a worm wheel shaft, 1-7 parts of a gear I, 1-8 parts of a gear ring, 1-9 parts of a gear II, 1-10 parts of a gear ring, 1-11 parts of a clamping jaw, 1-12 parts of a clamping jaw, 1-13 parts of a clamping jaw shaft, 1-14 parts of a rotating clamping block, 1-15 parts of a handle II, 1-16 parts of a pointed threaded shaft, 1-17 parts of a threaded support and 1-18 parts; hammer chutes 1-19; a humidity detection assembly 2; the device comprises a motor I2-1, a motor I shaft 2-2, a motor I shaft bracket 2-3, a knocking blade 2-4, a hammer I2-5, a hammer I slide rail 2-6, a tension spring I2-7, a hammer II 2-8, a hammer II slide rail 2-9, a spring I2-10, a tension spring II 2-11, a motor I switch 2-12, a sliding frame 2-13, a frame slide rail 2-14, a sampling probe 2-15, a motor II 2-16, a motor II shaft bracket 2-17, a motor II shaft 2-18, a conveying gear I2-19, a conveying gear II 2-20, a conveying gear II shaft 2-21, a conveying roller 2-22, a belt wheel I2-23, a belt I2-24, a belt wheel I shaft 2-25, a conveying gear III 2-26, a belt wheel II 2-20, a belt wheel II shaft 2-24, a belt, 2-27 parts of a gear with a shaft, 2-28 parts of a conveying gear IV, 2-29 parts of a conveying gear IV shaft, 2-30 parts of a sample feeding hole, 2-31 parts of a motor III, 2-32 parts of a motor III shaft, 2-33 parts of a drying box, 2-34 parts of heating fan blades, 2-35 parts of a belt wheel II, 2-36 parts of a belt, 2-37 parts of a belt wheel II shaft, 2-38 parts of a friction wheel, 2-39 parts of a heating disc, 2-40 parts of a sliding cylinder, 2-41 parts of a mass sensor, 2-42 parts of a rotating shaft, 2-43 parts of a deflector rod, 2-44 parts of a sample; chutes II 2-46; a tensile property detection assembly 3; 3-1 parts of a hexagonal rotary head, 3-2 parts of a bidirectional threaded shaft, 3-3 parts of a threaded block, 3-4 parts of a sliding support, 3-5 parts of a sample support and 3-6 parts of a sample clamp; and springs II 3-7.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 16, and the wood moisture detection and tensile property detection apparatus includes a clamping assembly 1, a moisture detection assembly 2, and a tensile property detection assembly 3, where the clamping assembly 1 is connected to the moisture detection assembly 2, and the moisture detection assembly 2 is connected to the tensile property detection assembly 3.

The second embodiment is as follows:

the embodiment is described below by combining with figures 1-16, and the embodiment is further described, wherein the clamping assembly 1 comprises an equipment bracket I1-1, a handle I1-2, a worm bracket 1-3, a worm 1-4, a worm wheel 1-5, a worm wheel shaft 1-6, a gear I1-7, a gear I1-8, a gear II 1-9, a gear II 1-10, a clamping jaw I1-11, a clamping jaw II 1-12, a clamping jaw shaft 1-13, a rotating clamping block 1-14, a handle II 1-15, a pointed thread shaft 1-16, a thread bracket 1-17, an equipment bracket II 1-18 and a hammer sliding groove 1-19, the handle I1-2 is connected with the worm 1-4, the worm 1-4 is rotationally connected with the worm bracket 1-3, the worm support 1-3 is connected with the equipment support I1-1, the worm 1-4 is meshed with the worm wheel 1-5, the worm wheel 1-5 is connected with the worm wheel shaft 1-6, the worm wheel shaft 1-6 is rotationally connected with the equipment support I1-1, the worm wheel shaft 1-6 is connected with the gear I1-7 and the gear II 1-9, the gear I1-7 is meshed with the gear ring I1-8, the gear II 1-9 is meshed with the gear ring II 1-10, the gear ring I1-8 is connected with the clamping jaw I1-11, the gear ring II 1-10 is connected with the clamping jaw II 1-12, the clamping jaw I1-11 and the clamping jaw II 1-12 are rotationally connected with the clamping jaw shaft 1-13, the clamping jaw shaft 1-13 is connected with the equipment support I1-1, the clamping jaws I1-11 and the clamping jaws II 1-12 are respectively rotatably connected with two rotating clamping blocks 1-14, the handles II 1-15 are connected with pointed thread shafts 1-16, the pointed thread shafts 1-16 are in threaded connection with threaded supports 1-17, the pointed thread shafts 1-16 are in sliding connection with equipment supports I1-1, two ends of the threaded supports 1-17 are respectively connected with the equipment supports I1-1 and the equipment supports II 1-18, the equipment supports II 1-18 are connected with the equipment supports I1-1, and the hammer chutes 1-19 are positioned on the equipment supports I1-1.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 16, and the present embodiment further describes the first embodiment, wherein the humidity detection assembly 2 includes a motor i 2-1, a motor i shaft 2-2, a motor i shaft bracket 2-3, a striking blade 2-4, a hammer i 2-5, a hammer i slide rail 2-6, a tension spring i 2-7, a hammer ii 2-8, a hammer ii slide rail 2-9, a spring i 2-10, a tension spring ii 2-11, a motor i switch 2-12, a slide frame 2-13, a frame slide rail 2-14, a sampling probe 2-15, a motor ii 2-16, a motor ii shaft bracket 2-17, a motor ii shaft 2-18, a conveying gear i 2-19, a conveying gear ii 2-20, a conveying gear ii shaft 2-21, a sampling probe 2-15, a motor ii 2-16, a motor ii shaft bracket 2-17, a motor, 2-22 parts of conveying roller, 2-23 parts of belt wheel I, 2-24 parts of belt I, 2-25 parts of shaft of belt wheel I, 2-26 parts of conveying gear III, 2-27 parts of shaft gear of belt wheel, 2-28 parts of conveying gear IV, 2-29 parts of shaft of conveying gear IV, 2-30 parts of sample feeding port, 2-31 parts of motor III, 2-32 parts of shaft of motor III, 2-33 parts of drying box, 2-34 parts of heating fan blade, 2-35 parts of belt wheel II, 2-36 parts of belt, 2-37 parts of shaft of belt wheel II, 2-38 parts of friction wheel, 2-39 parts of heating disc, 2-40 parts of sliding cylinder, 2-41 parts of mass sensor, 2-42 parts of rotating shaft, 2-43 parts of deflector rod, 2-44 parts of sample outlet, 2-45 parts of sliding chute I and 2-46 parts of sliding chute II, the motor I shaft 2-2 is rotatably connected with the motor I shaft bracket 2-3, the motor I shaft 2-1 and the motor I shaft bracket 2-3 are both connected with the equipment bracket I1-1, the motor I shaft 2-2 is connected with the knocking blade 2-4, the hammer I2-5 is slidably connected with the hammer I slide rail 2-6, the hammer I slide rail 2-6 is connected with the equipment bracket I1-1, two ends of the tension spring I2-7 are respectively connected with the upper part of the hammer I slide rail 2-6 and the hammer I2-5, the tension spring I2-7 is in a stretching state, the hammer II 2-8 is slidably connected with the hammer slide groove 1-19, the hammer II 2-8 is slidably connected with the hammer II slide rail 2-9, the hammer II slide rail 2-9 is connected with the equipment bracket I1-1, the spring I2-10 is sleeved on the slide rail 2-9 of the hammer II, the spring I2-10 is in a compressed state, two ends of the tension spring II 2-11 are respectively connected with the equipment support I1-1 and the sliding frame 2-13, the tension spring II 2-11 is in a stretched state, the motor I switch 2-12 is connected with the equipment support I1-1, the sliding frame 2-13 is connected with the two frame slide rails 2-14, the two frame slide rails 2-14 are respectively connected with the equipment support II 1-18 and the equipment support I1-1, the sampling probe 2-15 is connected with the sliding frame 2-13, the motor II 2-16 is connected with the motor II shaft 2-18, the motor II shaft 2-18 is rotatably connected with the motor II shaft support 2-17, the motor II 2-16 is connected with the motor II shaft support 2-17, the motor II-shaft support 2-17 is connected with the sliding frame 2-13, the motor II-shaft 2-18 is connected with the conveying gear I2-19, the conveying gear I2-19 is meshed with the conveying gear II 2-20, the conveying gear II 2-20 is connected with the conveying gear II shaft 2-21, the conveying gear II shaft 2-21 is rotatably connected with the motor II-shaft support 2-17, the motor II-shaft 2-18 and the conveying gear II shaft 2-21 are respectively connected with the two conveying rollers 2-22, the conveying gear II shaft 2-21 is connected with the belt wheels I2-23, the belt wheels I2-23 are provided with two belt wheels I2-23, the two belt wheels I2-24 are connected through a belt I2-24, one belt wheel I2-23 is connected with the belt wheel I shaft 2-25, the belt wheel I shaft 2-25 is rotatably connected with the sampling probe 2-15, the I shaft 2-25 of the belt wheel is connected with a conveying gear III 2-26, the conveying gear III 2-26 is meshed with a conveying gear IV 2-28 through two shaft gears 2-27, the two shaft gears 2-27 are both rotatably connected with a sampling probe 2-15, the conveying gear IV 2-28 is connected with a conveying gear IV shaft 2-29, the conveying gear IV shaft 2-29 is rotatably connected with a sampling probe 2-15, the I shaft 2-25 of the belt wheel and the conveying gear IV shaft 2-29 are respectively connected with two conveying rollers 2-22, a sample feeding port 2-30 is positioned on a drying box 2-33, a motor III 2-31 is connected with a sliding frame 2-13, a motor III 2-31 is connected with a motor III shaft 2-32, and a motor III shaft 2-32 is rotatably connected with the drying box 2-33, the motor III shaft 2-32 is connected with the heating fan blades 2-34, the motor III shaft 2-32 is connected with a belt wheel II 2-35, two belt wheels II 2-35 are arranged, two belt wheels II 2-35 are connected through a belt II 2-36, one belt wheel II 2-35 is connected with a belt wheel II shaft 2-37, the belt wheel II shaft 2-37 is rotatably connected with the drying box 2-33, the drying box 2-33 is connected with the sliding frame 2-13, the belt wheel II shaft 2-37 is connected with the friction wheel 2-38, the friction wheel 2-38 is contacted with the heating disc 2-39, the heating disc 2-39 is connected with the sliding cylinder 2-40, the sliding cylinder 2-40 is slidably connected with the rotating shaft 2-42, the rotating shaft 2-42 is rotatably connected with the bottom of the sliding frame 2-13, the mass sensor 2-41 is connected with the bottom of the sliding frame 2-13, the mass sensor 2-41 is in contact with the heating disc 2-39, the deflector rod 2-43 is in sliding connection with the drying box 2-33, the sample outlet 2-44, the chute I2-45 and the chute II 2-46 are all positioned on the sliding frame 2-13, and the surface of the conveying roller 2-22 is rough.

The fourth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 16, which further describes the first embodiment, the tensile property detecting assembly 3 includes a hexagonal head 3-1, a bidirectional threaded shaft 3-2, threaded blocks 3-3, a sliding support 3-4, a sample support 3-5, a sample clamp 3-6 and a spring ii 3-7, the hexagonal head 3-1 is connected to the bidirectional threaded shaft 3-2, the bidirectional threaded shaft 3-2 is provided with two threads with opposite rotation directions, the bidirectional threaded shaft 3-2 is rotatably connected to the sliding frame 2-13, the two threads with opposite rotation directions on the bidirectional threaded shaft 3-2 are respectively connected to the two threaded blocks 3-3, the two threaded blocks 3-3 are both slidably connected to the sliding chutes ii 2-46, the two sliding supports 3-4 are both slidably connected to the sliding chutes i 2-45, the two sliding supports 3-4 are connected through springs II 3-7, the springs II 3-7 are in a normal state, the two sliding supports 3-4 are respectively connected with the two sample supports 3-5, and the two sliding supports 3-4 are respectively connected with the two sample clamps 3-6 in a rotating mode.

The invention relates to a device for detecting the humidity and the tensile property of wood, which has the working principle that: the equipment is placed above a wood board or a round bar wood, if the wood to be detected is in a round bar shape, the wood is clamped by clamping jaws I1-11 and clamping jaws II 1-12, if the wood to be detected is square, the wood is clamped by two rotating clamping blocks 1-14, after being aligned with the wood, a handle I1-2 is rotated, a handle I1-2 drives a worm 1-4 to rotate, a worm 1-4 drives a worm wheel 1-5 to rotate, the worm wheel 1-5 drives a worm wheel shaft 1-6 to rotate, the worm wheel shaft 1-6 drives a gear I1-7 and a gear II 1-9 to rotate at the same angle, the gear I1-7 and the gear II 1-9 respectively drive the clamping jaws I1-11 and the clamping jaws II 1-12 to rotate at the same angle, the clamping jaws I1-11 and the clamping jaws II 1-12 are close to, two rotating clamping blocks 1-14 are close to each other to clamp square timber, the square timber cannot be loosened after being clamped due to the transmission self-locking effect of a worm 1-4 and a worm wheel 1-5, two groups of clamps can clamp timber with irregular length or diameter, a handle II 1-15 is rotated after being clamped, the handle II 1-15 drives a pointed thread shaft 1-16 to rotate, the pointed thread shaft 1-16 moves downwards through the thread effect with a thread support 1-17 to pierce into the timber, the pointed thread shaft 1-16 is rotated continuously, the clamped combination 1 of the equipment is completely positioned without displacement, a switch 2-12 of a motor I is started, the motor I2-1 rotates, the motor I2-1 drives a shaft 2-2 of a motor I, the shaft 2-2 of the motor I drives a knocking blade 2-4 to rotate, and the knocking blade 2-4 knocks a hammer I2-5 in a reciprocating manner, the hammer I2-5 reciprocates up and down to strike the hammer II 2-8 under the action of the pulling of the tension spring I2-7, the hammer II 2-8 strikes the sliding frame 2-13 under the action of the pushing force of the spring I2-10 along the sliding rail 2-9 of the hammer II, the sliding frame 2-13 moves downwards to drive the sampling probe 2-15 to pierce into the wood, a sample with the length equal to that of the sampling probe 2-15 is taken out of the wood, the sample is not separated from the wood at the moment, the moisture of the sample cannot be lost when the sampling probe 2-15 is wrapped, when the sampling probe 2-15 fully pierces into the wood, the sample moves to a position between two conveying rollers 2-22, the motor II 2-16 is started, the motor II 2-16 drives the motor II shaft 2-18 to rotate, the motor II shaft 2-18 drives the conveying gear I2-19 to rotate, the conveying gears I2-19 drive the conveying gears II 2-20 to rotate, the conveying gears II 2-20 drive the conveying gear II shafts 2-21 to rotate, the motors II 2-18 and the conveying gear II shafts 2-21 respectively drive the two conveying rollers 2-22 to rotate oppositely, the conveying gear II shafts 2-21 drive the belt pulleys I2-23 to rotate, one belt pulley I2-23 drives the other belt pulley I2-23 to rotate through a belt I2-24, the other belt pulley I2-23 drives the belt pulley I shafts 2-25 to rotate, the belt pulley I shafts 2-25 drive the conveying gears III 2-26 to rotate, the conveying gears III 2-26 drive the conveying gears IV 2-28 to rotate through the two belt shaft gears 2-27, and the conveying gears IV 2-28 drive the conveying gear IV shafts 2-29 to rotate, the belt wheel I shaft 2-25 and the conveying gear IV shaft 2-29 respectively drive the two conveying rollers 2-22 to rotate oppositely, the surfaces of the two conveying rollers 2-22 are rough, a sample is positioned between the two conveying rollers 2-22 and is driven by the conveying rollers 2-22 to move upwards, the sample is separated from wood under the action of the two conveying rollers 2-22, the friction force borne by the sampling probe 2-15 is reduced, the sliding frame 2-13 rebounds under the action of the tension force of the tension spring II 2-11 to be in contact with the motor I switch 2-12, the motor I switch 2-12 is disconnected by a trigger circuit, the motor I2-1 informs to rotate, the hammer II 2-8 does not knock the sliding frame 2-13, the sliding frame 2-13 resets, the sample is conveyed into the two conveying rollers 2-22 at the upper end through the two conveying rollers 2-22 at the lower end, then the sample is separated from the upper end conveying roller 2-22, because the upper end two conveying rollers 2-22 are higher and lower, the sample slides to the lower end and enters the heating disc 2-39 in the drying box 2-33 through the sample feeding hole 2-30, the heating fan blades 2-34 and the heating disc 2-39 have heating function, the heating disc 2-39 drives the sliding barrel 2-40 to move downwards along the rotating shaft 2-42, the heating disc 2-39 presses the mass sensor 2-41, the degree of the mass sensor 2-41 is the wet weight of the sample, the motor III 2-31 is started, the motor III 2-31 drives the motor III shaft 2-32 to rotate, the motor III shaft 2-32 drives the heating fan blades 2-34 to rotate, the heating fan blades 2-34 blow hot air to the upper part of the sample to dry the upper part of the sample, heating the lower part of a sample by a heating disc 2-39, drying the lower part of the sample by a motor III shaft 2-32 driving a belt wheel II 2-35 to rotate, one belt wheel II 2-35 driving another belt wheel II 2-35 to rotate by a belt II 2-36, the other belt wheel II 2-35 driving a belt wheel II shaft 2-37 to rotate, the belt wheel II shaft 2-37 driving a friction wheel 2-38 to rotate, the friction wheel 2-38 driving a heating disc 2-39 to rotate, the sample slowly rotates to make the drying effect better, a mass sensor 2-41 driving the heating disc 2-39 to move upwards gradually as the sample gradually becomes lighter, when the reading of the mass sensor 2-41 is unchanged, recording the sample weight as the sample dry weight, calculating the relative water content and the absolute water content of the sample after knowing the sample dry weight and the wet weight, and turning a deflector rod 2-43 after drying, the deflector rod 2-43 drives the sample to slide out from the sample outlet 2-44, the experiment is completed, the sample before or after being dried is arranged on two sample supports 3-5, the hexagonal head 3-1 is rotated by a torque wrench, the hexagonal head 3-1 drives the bidirectional threaded shaft 3-2 to rotate, the bidirectional threaded shaft 3-2 is axially limited by the sliding frame 2-13, the bidirectional threads on the bidirectional threaded shaft 3-2 respectively drive two threaded blocks 3-3 to be away from each other, the two threaded blocks are respectively contacted with the bottoms of two sample clamps 3-6, the two sample clamps 3-6 rotate around the rotating shaft of the sliding support 3-4 to clamp the sample on the sample support 3-5, the two sample clamps 3-6 drive the two sliding supports 3-4 to be away from each other, when the sample is stretched and broken, and recording the degree of the torque wrench at the moment, wherein the reading is the maximum tensile resistance of the sample.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (4)

1. The utility model provides a timber humidity detects and tensile properties check out test set thereof, detects assembly (3) including pressing from both sides tight assembly (1), humidity and detecting assembly (2) and tensile properties, its characterized in that: the clamping assembly (1) is connected with the humidity detection assembly (2), and the humidity detection assembly (2) is connected with the tensile property detection assembly (3).

2. The wood moisture detection and tensile property detection apparatus of claim 1, wherein: the clamping combination body (1) comprises an equipment support I (1-1), a handle I (1-2), a worm support (1-3), a worm (1-4), a worm wheel (1-5), a worm wheel shaft (1-6), a gear I (1-7), a gear ring I (1-8), a gear II (1-9), a gear ring II (1-10), a clamping jaw I (1-11), a clamping jaw II (1-12), a clamping jaw shaft (1-13), a rotating clamping block (1-14), a handle II (1-15), a pointed threaded shaft (1-16), a threaded support (1-17), an equipment support II (1-18) and a hammer sliding groove (1-19), wherein the handle I (1-2) is connected with the worm (1-4), and the worm (1-4) is rotationally connected with the worm support (1-3), the worm support (1-3) is connected with the equipment support I (1-1), the worm (1-4) is in meshed connection with the worm wheel (1-5), the worm wheel (1-5) is connected with the worm wheel shaft (1-6), the worm wheel shaft (1-6) is in rotary connection with the equipment support I (1-1), the worm wheel shaft (1-6) is connected with the gear I (1-7) and the gear II (1-9), the gear I (1-7) is in meshed connection with the gear ring I (1-8), the gear II (1-9) is in meshed connection with the gear ring II (1-10), the gear ring I (1-8) is connected with the clamping jaw I (1-11), the gear ring II (1-10) is connected with the clamping jaw II (1-12), the clamping jaw I (1-11) and the clamping jaw II (1-12) are in rotary connection with the clamping jaw shaft (1-13), the clamping jaw shafts (1-13) are connected with the equipment support I (1-1), the clamping jaws I (1-11) and the clamping jaws II (1-12) are respectively rotatably connected with the two rotating clamping blocks (1-14), the handles II (1-15) are connected with the pointed thread shafts (1-16), the pointed thread shafts (1-16) are in threaded connection with the thread supports (1-17), the pointed thread shafts (1-16) are in sliding connection with the equipment support I (1-1), two ends of the thread supports (1-17) are respectively connected with the equipment support I (1-1), the equipment supports II (1-18) are connected, the equipment supports II (1-18) are connected with the equipment supports I (1-1), and the hammer chutes (1-19) are located on the equipment supports I (1-1).

3. The wood moisture detection and tensile property detection apparatus of claim 1, wherein: the humidity detection assembly (2) comprises a motor I (2-1), a motor I shaft (2-2), a motor I shaft support (2-3), a knocking blade (2-4), a hammer I (2-5), a hammer I sliding rail (2-6), a tension spring I (2-7), a hammer II (2-8), a hammer II sliding rail (2-9), a spring I (2-10), a tension spring II (2-11), a motor I switch (2-12), a sliding frame (2-13), a frame sliding rail (2-14), a sampling probe (2-15), a motor II (2-16), a motor II shaft support (2-17), a motor II shaft (2-18), a conveying gear I (2-19), a conveying gear II (2-20), a conveying gear II shaft (2-21), Conveying roller (2-22), belt wheel I (2-23), belt I (2-24), belt wheel I shaft (2-25), conveying gear III (2-26), belt shaft gear (2-27), conveying gear IV (2-28), conveying gear IV shaft (2-29), sample feeding hole (2-30), motor III (2-31), motor III shaft (2-32), drying box (2-33), heating fan blade (2-34), belt wheel II (2-35), belt II (2-36), belt wheel II shaft (2-37), friction wheel (2-38), heating disc (2-39), sliding cylinder (2-40), mass sensor (2-41), rotating shaft (2-42), deflector rod (2-43), A sample outlet (2-44), a sliding groove I (2-45) and a sliding groove II (2-46), wherein a motor I (2-1) is connected with a motor I shaft (2-2), the motor I shaft (2-2) is rotationally connected with a motor I shaft bracket (2-3), the motor I (2-1) and the motor I shaft bracket (2-3) are both connected with an equipment bracket I (1-1), the motor I shaft (2-2) is connected with a knocking blade (2-4), a knocking hammer I (2-5) is slidably connected with a knocking hammer I sliding rail (2-6), the knocking hammer I sliding rail (2-6) is connected with the equipment bracket I (1-1), two ends of a tension spring I (2-7) are respectively connected with the upper part of the knocking hammer I sliding rail (2-6) and the knocking hammer I (2-5), the tension spring I (2-7) is in a stretching state, the hammer II (2-8) is in sliding connection with the hammer sliding groove (1-19), the hammer II (2-8) is in sliding connection with the hammer II sliding rail (2-9), the hammer II sliding rail (2-9) is connected with the equipment support I (1-1), the spring I (2-10) is sleeved on the hammer II sliding rail (2-9), the spring I (2-10) is in a compressing state, two ends of the tension spring II (2-11) are respectively connected with the equipment support I (1-1) and the sliding frame (2-13), the tension spring II (2-11) is in a stretching state, the motor I switch (2-12) is connected with the equipment support I (1-1), the sliding frame (2-13) is connected with the two frame sliding rails (2-14), two frame sliding rails (2-14) are respectively connected with an equipment support II (1-18) and an equipment support I (1-1), a sampling probe (2-15) is connected with a sliding frame (2-13), a motor II (2-16) is connected with a motor II shaft (2-18), the motor II shaft (2-18) is rotatably connected with a motor II shaft support (2-17), the motor II (2-16) is connected with the motor II shaft support (2-17), the motor II shaft support (2-17) is connected with the sliding frame (2-13), the motor II shaft (2-18) is connected with a conveying gear I (2-19), the conveying gear I (2-19) is meshed with the conveying gear II (2-20), the conveying gear II (2-20) is connected with a conveying gear II shaft (2-21), the conveying gear II shaft (2-21) is rotationally connected with the motor II shaft bracket (2-17), the motor II shaft (2-18) and the conveying gear II shaft (2-21) are respectively connected with the two conveying rollers (2-22), the conveying gear II shaft (2-21) is connected with the belt wheel I (2-23), two belt wheels I (2-23) are arranged, the two belt wheels I (2-23) are connected through belts I (2-24), one belt wheel I (2-23) is connected with the belt wheel I shaft (2-25), the belt wheel I shaft (2-25) is rotationally connected with the sampling probe (2-15), the belt wheel I shaft (2-25) is connected with the conveying gear III (2-26), and the conveying gear III (2-26) is meshed with the conveying gear IV (2-28) through the two belt shaft gears (2-27), two gears (2-27) with shafts are rotatably connected with a sampling probe (2-15), a conveying gear IV (2-28) is connected with a conveying gear IV shaft (2-29), the conveying gear IV shaft (2-29) is rotatably connected with the sampling probe (2-15), a belt wheel I shaft (2-25) and the conveying gear IV shaft (2-29) are respectively connected with two conveying rollers (2-22), a sample feeding hole (2-30) is positioned on a drying box (2-33), a motor III (2-31) is connected with a sliding frame (2-13), the motor III (2-31) is connected with a motor III shaft (2-32), the motor III shaft (2-32) is rotatably connected with the drying box (2-33), the motor III shaft (2-32) is connected with a heating fan blade (2-34), the motor III shaft (2-32) is connected with a belt wheel II (2-35), two belt wheels II (2-35) are arranged, the two belt wheels II (2-35) are connected through a belt II (2-36), one belt wheel II (2-35) is connected with a belt wheel II shaft (2-37), the belt wheel II shaft (2-37) is rotatably connected with a drying box (2-33), the drying box (2-33) is connected with a sliding frame (2-13), the belt wheel II shaft (2-37) is connected with a friction wheel (2-38), the friction wheel (2-38) is contacted with a heating disc (2-39), the heating disc (2-39) is connected with a sliding cylinder (2-40), the sliding cylinder (2-40) is slidably connected with a rotating shaft (2-42), the rotating shaft (2-42) is rotatably connected with the bottom of the sliding frame (2-13), the mass sensor (2-41) is connected with the bottom of the sliding frame (2-13), the mass sensor (2-41) is in contact with the heating disc (2-39), the deflector rod (2-43) is in sliding connection with the drying box (2-33), the sample outlet (2-44), the chute I (2-45) and the chute II (2-46) are all positioned on the sliding frame (2-13), and the surface of the conveying roller (2-22) is rough.

4. The wood moisture detection and tensile property detection apparatus of claim 1, wherein: the tensile property detection assembly (3) comprises a hexagonal rotary head (3-1), a two-way threaded shaft (3-2), threaded blocks (3-3), a sliding support (3-4), a sample support (3-5), a sample clamp (3-6) and a spring II (3-7), the hexagonal rotary head (3-1) is connected with the two-way threaded shaft (3-2), the two-way threaded shaft (3-2) is provided with two threads with opposite rotation directions, the two-way threaded shaft (3-2) is rotatably connected with a sliding frame (2-13), the two threads with opposite rotation directions on the two-way threaded shaft (3-2) are respectively connected with the two threaded blocks (3-3), the two threaded blocks (3-3) are both slidably connected with a sliding chute II (2-46), and the two sliding supports (3-4) are both slidably connected with a sliding chute I (2-45), the two sliding supports (3-4) are connected through a spring II (3-7), the spring II (3-7) is in a normal state, the two sliding supports (3-4) are respectively connected with the two sample supports (3-5), and the two sliding supports (3-4) are respectively in rotating connection with the two sample clamps (3-6).

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