CN112782391A - Timber sampling detects water content equipment - Google Patents

Abstract

The invention relates to equipment for detecting water content, in particular to equipment for sampling and detecting the water content of wood, which comprises a plate cutting mechanism, a cutting linkage mechanism and an evaporation and collection mechanism, wherein the equipment can cut cylindrical wood into circular thin plates, the equipment can cut irregular circular thin plates into regular circular thin plates, the equipment can adsorb the circular thin plates to an evaporation box of the equipment, the equipment can evaporate and collect water in the circular thin plates, the plate cutting mechanism is connected with the cutting linkage mechanism, and the cutting linkage mechanism is connected with the evaporation and collection mechanism.

Description

Timber sampling detects water content equipment

Technical Field

The invention relates to a device for detecting water content, in particular to a device for sampling and detecting water content of wood.

Background

In timber water content detection, process flow is comparatively loaded down with trivial details, and the quality of sampling all needs relevant equipment to process alone, but does not have the water content check out test set that teaches on the market, so designed this kind of timber sampling and detected water content equipment.

Disclosure of Invention

The invention mainly solves the technical problem of providing a device for detecting the water content in the sampled wood, which can cut cylindrical wood into round thin plates, cut irregular round thin plates into regular round thin plates, adsorb the round thin plates to an evaporation box of the device, and evaporate and collect the water in the round thin plates.

In order to solve the technical problem, the invention relates to equipment for detecting water content, in particular to equipment for detecting the water content by sampling wood, which comprises a plate cutting mechanism, a cutting linkage mechanism and an evaporation collecting mechanism, wherein the equipment can cut cylindrical wood into circular thin plates, the equipment can cut irregular circular thin plates into regular circular thin plates, the equipment can adsorb the circular thin plates to an evaporation box of the equipment, and the equipment can evaporate and collect water in the circular thin plates.

The cutting plate forming mechanism is connected with the cutting linkage mechanism, and the cutting linkage mechanism is connected with the evaporation collecting mechanism.

As a further optimization of the technical scheme, the wood sampling water content detection equipment comprises a cutting plate forming mechanism, a motor shaft, a belt a, a connecting shaft a, a friction wheel b, a cam, a connecting shaft b, a belt b, a connecting shaft c, a belt c, a cutting saw limiting block, a connecting plate a, a connecting plate b, a connecting plate c, a connecting plate d, a connecting plate e and a wood column, wherein the motor is connected with the motor shaft, the motor is connected with the connecting plate a, the motor shaft is in friction connection with the belt a, the belt a is in friction connection with the connecting shaft a, the connecting shaft a is connected with the friction wheel a, the connecting shaft a is connected with a bearing of the connecting plate a, the friction wheel a is in friction connection with the friction wheel b, the friction wheel b is connected with the cam, the friction, the cam is connected with the cutting saw in a sliding way, a connecting shaft b is connected with a belt b in a friction way, the connecting shaft b is connected with a cutting saw limiting block in a sliding way, the connecting shaft b is connected with a connecting plate a in a sliding way, the belt b is connected with a connecting shaft c in a bearing way, the connecting shaft c is connected with a belt c in a friction way, the connecting shaft c is connected with the cutting saw limiting block in a sliding way, the connecting shaft c is connected with the cutting saw limiting block in a threaded way, the connecting shaft c is connected with the connecting plate a in a threaded way, the connecting shaft c is connected with the connecting plate e in a threaded way, the cutting saw is connected with the connecting plate a in a sliding way, the cutting saw is connected with the connecting plate c in a sliding way, the connecting plate a is connected with the connecting plate b, the connecting plate b is, the connecting plate c is connected with the connecting plate e.

As a further optimization of the technical scheme, the invention relates to a device for sampling and detecting water content in wood, wherein a cutting linkage mechanism comprises a friction wheel I, a belt II, a connecting shaft I, a friction wheel II, an air suction duct a, a connecting plate I, a connecting plate II, a bearing ring, a circular cutting knife, an air suction duct b, a connecting plate III, a belt III, a connecting shaft II, a belt IV, a friction wheel III, a connecting shaft III, a reaction force propeller, a connecting plate IV and a device installation box, wherein the friction wheel I is in friction connection with the belt I, the friction wheel I is connected with the connecting shaft B, the belt II is in friction connection with the connecting shaft B, the connecting shaft I is connected with the friction wheel II, the connecting shaft I is connected with a bearing of the connecting plate I, the connecting shaft I is in friction connection with the belt III, the connecting shaft I is connected with a bearing of the connecting plate a, the air suction duct a is connected with the second connecting plate in a sliding mode, the air suction duct a is connected with a bearing ring bearing, the air suction duct a is connected with the circular cutting knife in a sliding mode, the air suction duct a is connected with the air suction duct b in a sliding mode, the first connecting plate is connected with the second connecting plate, the second connecting plate is connected with the first connecting plate, the bearing ring is connected with the circular cutting knife, the air suction duct b is connected with the third connecting plate, the third connecting plate is connected with an equipment installation box, the third belt is connected with the second connecting shaft in a friction mode, the second connecting shaft is connected with the fourth belt in a friction mode, the fourth belt is connected with the fourth connecting plate bearing in a friction mode, the third friction wheel is connected with the third connecting shaft, the third connecting shaft is connected with a reaction force propeller, the third connecting shaft is connected with the equipment installation box.

As a further optimization of the technical scheme, the invention relates to a device for sampling and detecting water content in wood, wherein the evaporation and collection mechanism comprises an inclined plate, a mounting plate a, a hinged plate, a supporting block, a supporting shaft, a supporting spring, a supporting limit plate, a mounting plate b, an electric heater, a collecting tank, a guiding plate and a collection port, the inclined plate is connected with the mounting plate a, the inclined plate is connected with a device mounting box, the mounting plate a is hinged with the hinged plate, the mounting plate a is connected with the mounting plate b, the mounting plate a is slidably connected with the device mounting box, the hinged plate is slidably connected with the supporting block, the supporting block is connected with the supporting shaft, the supporting shaft is connected with the supporting limit plate, the supporting shaft is slidably connected with the mounting plate b, the supporting shaft is slidably connected with the electric heater, the supporting shaft is slidably connected with the, the electric heater is connected with the equipment installation box, and the collecting vat is connected with the equipment installation box, and the guide board is connected with the equipment installation box, collects the opening and opens on the equipment installation box.

As a further optimization of the technical scheme, the invention relates to a device for sampling and detecting the water content of the wood.

As a further optimization of the technical scheme, the invention provides the wood sampling water content detection device, wherein a large number of resistors are arranged in the electric heater, and a metal heat conduction layer outside the electric heater can emit heat after the power supply is switched on.

The wood sampling water content detection equipment has the beneficial effects that:

the invention relates to a device for sampling and detecting water content of wood, which can cut cylindrical wood into round thin plates, cut irregular round thin plates into regular round thin plates, adsorb the round thin plates to an evaporation box of the device, and evaporate and collect water in the round thin plates.

Drawings

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

Fig. 1 is a schematic structural diagram of a device for detecting water content in wood samples according to the present invention.

Fig. 2 is a schematic structural diagram of a device for detecting water content in wood samples according to the present invention.

Fig. 3 is a first structural schematic diagram of a board cutting mechanism 1 of the wood sampling water content detection device of the invention.

Fig. 4 is a schematic structural diagram of a second board cutting mechanism 1 of the wood sampling water content detection device of the invention.

Fig. 5 is a schematic structural diagram three of a board cutting mechanism 1 of the wood sampling water content detection device of the invention.

Fig. 6 is a fourth schematic structural diagram of a board cutting mechanism 1 of the wood sampling water content detection device of the invention.

Fig. 7 is a schematic structural diagram five of a board cutting mechanism 1 of the wood sampling water content detection device of the invention.

Fig. 8 is a sixth schematic structural diagram of a board cutting mechanism 1 of the wood sampling water content detection device of the invention.

Fig. 9 is a seventh structural diagram of a board cutting mechanism 1 of the wood sampling water content detection device of the invention.

Fig. 10 is a first structural schematic diagram of a cutting linkage mechanism 2 of the wood sampling water content detection device.

Fig. 11 is a second structural schematic diagram of a cutting linkage mechanism 2 of the wood sampling water content detection device of the invention.

Fig. 12 is a third structural schematic diagram of a cutting linkage mechanism 2 of the wood sampling water content detection device.

Fig. 13 is a fourth structural schematic diagram of a cutting linkage mechanism 2 of the wood sampling water content detection device of the invention.

Fig. 14 is a schematic structural diagram of an equipment installation box 2-20 of the wood sampling water content detection equipment.

Fig. 15 is a schematic structural diagram of an evaporation collection mechanism 3 of a device for sampling and detecting water content in wood according to the present invention.

Fig. 16 is a schematic structural diagram of an evaporation collection mechanism 3 of the wood sampling water content detection device.

Fig. 17 is a third schematic structural diagram of an evaporation collection mechanism 3 of the device for sampling and detecting water content in wood according to the invention.

Fig. 18 is a fourth schematic structural diagram of an evaporation collection mechanism 3 of the wood sampling water content detection device.

In the figure: cutting into a plate mechanism 1; a motor 1-1; a motor shaft 1-2; belt a 1-3; connecting shaft a 1-4; friction wheel a 1-5; friction wheel b 1-6; 1-7 of a cam; connecting shaft b 1-8; belt b 1-9; connecting shaft c 1-10; belt c 1-11; 1-12 of a cutting saw; 1-13 parts of a cutting saw limiting block; connection board a 1-14; connecting plate b 1-15; connecting plate c 1-16; connecting plate d 1-17; connecting plate e 1-18; 1-19 of wood columns; a cutting linkage mechanism 2; 2-1 of a first friction wheel; 2-2 parts of a first belt; 2-3 parts of a second belt; connecting shafts I2-4; 2-5 parts of a second friction wheel; an inspiratory duct a 2-6; 2-7 of a first connecting plate; 2-8 of a second connecting plate; 2-9 parts of bearing ring; 2-10 parts of a circular cutting knife; an inspiratory duct b 2-11; 2-12 parts of a connecting plate III; 2-13 parts of a third belt; connecting shafts II 2-14; 2-15 parts of a belt; 2-16 parts of a friction wheel III; connecting shafts III 2-17; reaction force propellers 2-18; 2-19 parts of a connecting plate; 2-20 parts of an equipment installation box; an evaporation collection mechanism 3; an inclined plate 3-1; mounting plate a 3-2; a hinged plate 3-3; 3-4 of a supporting block; 3-5 parts of a support shaft; 3-6 parts of supporting springs; supporting limit plates 3-7; mounting plate b 3-8; 3-9 parts of an electric heater; collecting tank 3-10; guide plates 3-11; and a collection port 3-12.

Detailed Description

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the present invention relates to a device for detecting water content by sampling wood, and more specifically, to a device for detecting water content by sampling wood, which includes a cutting-into-plate mechanism 1, a cutting-linking mechanism 2, and an evaporation-collection mechanism 3, and is capable of cutting cylindrical wood into circular thin plates, cutting irregular circular thin plates into regular circular thin plates, adsorbing the circular thin plates to an evaporation tank of the device, and evaporating and collecting water in the circular thin plates.

The cutting plate forming mechanism 1 is connected with the cutting linkage mechanism 2, and the cutting linkage mechanism 2 is connected with the evaporation collecting mechanism 3.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the present embodiment further describes the present embodiment, where the cutting plate-forming mechanism 1 includes a motor 1-1, a motor shaft 1-2, a belt a1-3, a connecting shaft a1-4, a friction wheel a1-5, a friction wheel b1-6, a cam 1-7, a connecting shaft b1-8, a belt b1-9, a connecting shaft c1-10, a belt c1-11, a cutting saw 1-12, a cutting saw stopper 1-13, a connecting plate a1-14, a connecting plate b1-15, a connecting plate c1-16, a connecting plate d1-17, a connecting plate e1-18, and a wood column 1-19, the motor 1-1 is connected with the motor shaft 1-2, the motor 1-1 is connected with a connecting plate a1-14, the motor shaft 1-2 is connected with a belt a1-3 in a friction mode, the belt a1-3 is connected with a connecting shaft a1-4 in a friction mode, the connecting shaft a1-4 is connected with a friction wheel a1-5, the connecting shaft a1-4 is connected with a connecting plate a1-14 in a bearing mode, the friction wheel a1-5 is connected with a friction wheel b1-6 in a friction mode, the friction wheel a1-5 is connected with a friction wheel b1-6 in a friction mode, the friction wheel b1-6 is connected with a cam 1-7, the friction wheel b1-6 is connected with a connecting shaft b1-8 in a thread mode, the cam 1-7 is connected with a connecting shaft b1-8 in a thread mode, the cam 1-7 is connected with a cutting saw 1-12 in a sliding mode, connecting shafts b1-8 are slidably connected with cutting saw limit blocks 1-13, connecting shafts b1-8 are slidably connected with connecting plates a1-14, connecting shafts b1-8 are slidably connected with connecting plates e1-18, belts b1-9 are connected with connecting shafts c1-10 by bearings, connecting shafts c1-10 are frictionally connected with belts c1-11, connecting shafts c1-10 are slidably connected with cutting saw limit blocks 1-13, connecting shafts c1-10 are in threaded connection with cutting saw limit blocks 1-13, connecting shafts c1-10 are in threaded connection with connecting plates a1-14, connecting shafts c1-10 are in threaded connection with connecting plates e1-18, cutting saws 1-12 are slidably connected with connecting plates a1-14, cutting saws 1-12 are slidably connected with connecting plates c1-16, cutting saw limit blocks 1-13 are connected with connecting plates a1-14, the cutting saw limiting blocks 1-13 are connected with connecting plates c1-16 in a sliding mode, the connecting plates a1-14 are connected with connecting plates b1-15, the connecting plates b1-15 are connected with connecting plates c1-16 in a sliding mode, the connecting plates b1-15 are connected with connecting plates d1-17 in a sliding mode, the connecting plates c1-16 are connected with connecting plates d1-17, the connecting plates c1-16 are connected with connecting plates e1-18, the equipment can cut cylindrical wood into circular thin plates, the cylindrical wood is placed in an interval formed by the connecting plates c1-16 and the connecting plates d1-17, one end of the cylindrical wood is abutted against the connecting plates b1-15, the motor 1-1 works to drive the motor shaft 1-2 to rotate, the motor shaft 1-2 rotates to drive the a1-4 to rotate through the belts a1, the connecting shaft a1-4 rotates to drive the friction wheel a1-5 to rotate, the friction wheel a1-5 rotates to drive the friction wheel b1-6 to rotate, the friction wheel b1-6 rotates to drive the connecting shaft b1-8 to rotate, the connecting shaft b1-8 rotates to drive the connecting shaft c1-10 to rotate through the belt b1-9, the connecting shaft c1-10 rotates to drive the other connecting shaft c1-10 to rotate through the belt c1-11, the other connecting shaft c1-10 rotates to drive the other connecting shaft b1-8 to rotate through the belt b1-9, the connecting plate e1-18 is driven to move upwards or downwards when the connecting shaft b1-8 and the connecting shaft c1-10 rotate in the same direction, when the connecting plate e1-18 moves upwards, the connecting plate e1-18 moves to drive the connecting plate d1-17 through the connecting plate c1-16, the connecting plate d1-17 moves to drive the wood columns 1-19 to move, the cams 1-7 are also driven to rotate when the friction wheel b1-6 rotates, the two cams 1-7 rotate to drive the cutting saw 1-12 to transversely reciprocate, and the wood columns 1-19 are cut into circular thin plates when the cutting saw 1-12 transversely reciprocates and the wood columns 1-19 move upwards.

The third concrete implementation mode:

the first embodiment is further described with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18. the cutting linkage mechanism 2 includes a first friction wheel 2-1, a first belt 2-2, a second belt 2-3, a first connecting shaft 2-4, a second friction wheel 2-5, a suction duct a2-6, a first connecting plate 2-7, a second connecting plate 2-8, a bearing ring 2-9, a circular cutting knife 2-10, a suction duct b2-11, a third connecting plate 2-12, a third belt 2-13, a second connecting shaft 2-14, a fourth belt 2-15, a third friction wheel 2-16, a third connecting shaft 2-17, a fourth connecting shaft b2-11, a second suction duct b2-11, 2-18 parts of reaction force propeller, 2-19 parts of connecting plate IV and 2-20 parts of equipment installation box, wherein a first friction wheel 2-1 is in friction connection with a first belt 2-2, a first friction wheel 2-1 is connected with a connecting shaft b1-8, a second belt 2-3 is in friction connection with a first connecting shaft 2-4, a second belt 2-3 is in friction connection with a connecting shaft b1-8, a first connecting shaft 2-4 is connected with a second friction wheel 2-5, a first connecting shaft 2-4 is in bearing connection with a first connecting plate 2-7, a first connecting shaft 2-4 is in friction connection with a third belt 2-13, a first connecting shaft 2-4 is in bearing connection with a connecting plate a1-14, a second friction wheel 2-5 is in friction connection with an air suction duct a2-6, and an air suction duct a2-6 is in sliding connection with a second, an air suction duct a2-6 is connected with a bearing ring 2-9 through a bearing, an air suction duct a2-6 is connected with a circular cutting knife 2-10 in a sliding mode, an air suction duct a2-6 is connected with an air suction duct b2-11 in a sliding mode, a connecting plate I2-7 is connected with a connecting plate II 2-8, the connecting plate II 2-8 is connected with a connecting plate a1-14, the bearing ring 2-9 is connected with a circular cutting knife 2-10, an air suction duct b2-11 is connected with a connecting plate III 2-12, the connecting plate III 2-12 is connected with an equipment installation box 2-20, a belt III 2-13 is connected with a connecting shaft II 2-14 in a friction mode, the connecting shaft II 2-14 is connected with a belt IV 2-15 in a friction mode, the connecting shaft II 2-14 is connected with a connecting plate IV 2-19 through a bearing, the belt IV 2-15, the friction wheel III 2-16 is connected with the connecting shaft III 2-17, the connecting shaft III 2-17 is connected with the reaction force propeller 2-18, the connecting shaft III 2-17 is connected with the equipment installation box 2-20 through a bearing, the connecting plate IV 2-19 is connected with the equipment installation box 2-20, the equipment installation box 2-20 is connected with the connecting plate a1-14, the equipment can cut an irregular round thin plate into regular round thin plates, the equipment can adsorb the round thin plates to the equipment evaporation box, when the equipment cuts the thin plates, the connecting shaft a1-4 is in a rotating state, the connecting shaft a1-4 rotates to drive the friction wheel I2-1 to rotate, the friction wheel I2-1 rotates to drive the other friction wheel I2-1 to rotate through the belt I2-2, the connecting shaft a1-4 also drives the connecting shaft I2-4 to rotate through the belt II 2-3 when the connecting shaft a1-, the first connecting shaft 2-4 rotates to drive the second friction wheel 2-5 to rotate, the second friction wheel 2-5 rotates to drive the air suction duct a2-6 to move longitudinally under the limitation of the second connecting plate 2-8, when the air suction duct a2-6 moves towards the direction of the bearing ring 2-9, the air suction duct a2-6 moves to drive the bearing ring 2-9 to move, the bearing ring 2-9 moves to drive the circular cutting knife 2-10 to move, when the bearing ring 2-9 moves to contact with the first belt 2-2, the first belt 2-2 and the bearing ring 2-9 are in friction connection, the bearing ring 2-9 is driven to rotate, the bearing ring 2-9 rotates to drive the circular cutting knife 2-10 to rotate, the circular cutting knife 2-10 rotates to cut irregular circular thin plates into regular circular thin plates, the rotating of the first connecting shaft 2-4 also drives a second connecting shaft 2-14 to rotate through a third belt 2-13, the rotation of the second connecting shaft 2-14 drives the rotation of the second connecting shaft 2-14 through a fourth belt 2-15, the rotation of the third friction wheel 2-16 is also driven when the fourth belt 2-15 moves along, the rotation of the third friction wheel 2-16 drives the rotation of the third connecting shaft 2-17, the rotation of the third connecting shaft 2-17 drives the rotation of the reaction force propeller 2-18, the reaction force propeller 2-18 blows air or inhales air in the direction of the third connecting plate 2-12 when rotating, the air is adsorbed through holes on the third connecting plate 2-12 when inhaling air in the direction of the third connecting plate 2-12, the round thin plate cut by the round cutting knife 2-10 is contacted and adsorbed with the air suction duct b2-11 through the air suction duct a2-6, the adsorbed circular thin plates fall onto the hinged plates 3-3 in the equipment installation box 2-20 when contacting the connecting plates three 2-12, wood slag generated during cutting is adsorbed into a space formed by the equipment installation box 2-20, the inclined plate 3-1 and the mounting plate a3-2 through holes in the connecting plates three 2-12, and the wood slag is inclined out of the equipment under the action of the inclined plate 3-1.

The fourth concrete implementation mode:

referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, the present embodiment is further described, and the present embodiment is further described, wherein the evaporation collection mechanism 3 includes a tilting plate 3-1, a mounting plate a3-2, a hinge plate 3-3, a support block 3-4, a support shaft 3-5, a support spring 3-6, a support limit plate 3-7, a mounting plate b3-8, an electric heater 3-9, a guide plate 3-10, a collection groove 3-11, and a collection port 3-12, the tilting plate 3-1 is connected to the mounting plate a3-2, the tilting plate 3-1 is connected to the equipment mounting box 2-20, the mounting plate a3-2 is hinged to the hinge plate 3-3, the mounting plate a3-2 is connected with the mounting plate b3-8, the mounting plate a3-2 is connected with the equipment mounting box 2-20 in a sliding manner, the hinged plate 3-3 is connected with the supporting block 3-4 in a sliding manner, the supporting block 3-4 is connected with the supporting shaft 3-5, the supporting shaft 3-5 is connected with the supporting limiting plate 3-7, the supporting shaft 3-5 is connected with the mounting plate b3-8 in a sliding manner, the supporting shaft 3-5 is connected with the electric heater 3-9 in a sliding manner, the supporting shaft 3-5 is connected with the equipment mounting box 2-20 in a sliding manner, the supporting spring 3-6 is sleeved on the supporting shaft 3-5 and limited on the supporting block 3-4 and the mounting plate b3-8, the mounting plate b3-8 is connected with the equipment mounting box 2-20, the collecting groove 3-10 is connected with the equipment installation box 2-20, the guide plate 3-11 is connected with the equipment installation box 2-20, the collecting opening 3-12 is arranged on the equipment installation box 2-20, the equipment can evaporate and collect water in the round thin plate, the round thin plate falling on the hinge plate 3-3 in the equipment installation box 2-20 presses the supporting block 3-4, the supporting block 3-4 moves downwards under the guide of the supporting shaft 3-5, the hinge plate 3-3 can automatically reset under the action of the supporting spring 3-6, when the round thin plate presses the hinge plate 3-3 to enable the round thin plate to incline to the installation plate b3-8, the guide plate 3-11 helps the round thin plate to incline to the installation plate b3-8, the electric heater 3-9 is powered on, and the electric heater 3-9 gives out heat to the installation plate b3-8, the water in the round thin plate is evaporated under the heat conduction of the mounting plate b3-8, and the water vapor generated during the evaporation is inclined into the space formed by the equipment mounting box 2-20 and the collecting tank 3-10 under the action of the hinge plate 3-3.

The fifth concrete implementation mode:

the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the present embodiment further describes the first embodiment in which a large number of holes are arranged on the surface of the connecting plate three 2-12.

The sixth specific implementation mode:

in the following, the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 and 18. in the present embodiment, a large number of electric resistors are arranged inside the electric heaters 3 to 9, and the metal heat conductive layer outside the electric heaters 3 to 9 can emit heat after the power is turned on.

The working principle of the device is as follows: the device can cut cylindrical wood into circular thin plates, the cylindrical wood is placed in an interval formed by connecting plates c1-16 and connecting plates d1-17, one end of the cylindrical wood is abutted against connecting plates b1-15, a motor 1-1 works, the motor 1-1 works to drive a motor shaft 1-2 to rotate, the motor shaft 1-2 rotates to drive a connecting shaft a1-4 to rotate through a belt a1-3, the connecting shaft a1-4 rotates to drive a friction wheel a1-5 to rotate, the friction wheel a1-5 rotates to drive a friction wheel b1-6 to rotate, the friction wheel b1-6 rotates to drive a connecting shaft b1-8 to rotate, the connecting shaft b1-8 rotates to drive a connecting shaft c1-10 to rotate through a belt b1-9, the connecting shaft c1-10 rotates to drive another connecting shaft c1-10 to rotate through a belt c1-11, the other connecting shaft c1-10 rotates to drive the other connecting shaft b1-8 to rotate through a belt b1-9, when the connecting shaft b1-8 and the connecting shaft c1-10 rotate in the same direction, the connecting plate e1-18 is driven to move upwards or downwards, when the connecting plate e1-18 moves upwards, the connecting plate e1-18 moves to drive the connecting plate d1-17 through the connecting plate c1-16, the connecting plate d1-17 moves to drive the wood columns 1-19 to move, when the friction wheel b1-6 rotates, the cams 1-7 are also driven to rotate, the two cams 1-7 rotate to drive the cutting saw 1-12 to reciprocate transversely, when the cutting saw 1-12 reciprocates transversely and the wood columns 1-19 move upwards, the wood columns 1-19 are cut into round thin plates, the equipment can cut irregular round thin plates into regular round thin plates, the equipment can adsorb a circular thin plate to an equipment evaporation box, when the equipment cuts the thin plate, a connecting shaft a1-4 is in a rotating state, the connecting shaft a1-4 rotates to drive a first friction wheel 2-1 to rotate, the first friction wheel 2-1 rotates and drives another first friction wheel 2-1 to rotate through a first belt 2-2, the connecting shaft a1-4 also drives the first connecting shaft 2-4 to rotate through a second belt 2-3 when rotating, the first connecting shaft 2-4 rotates to drive a second friction wheel 2-5 to rotate, the second friction wheel 2-5 rotates to drive an air suction duct a2-6 to longitudinally move under the limitation of a second connecting plate 2-8, when the air suction duct a2-6 moves towards the direction of a bearing ring 2-9, the air suction duct a2-6 moves to drive the bearing ring 2-9 to move, the bearing ring 2-9 moves to drive the circular cutting knife 2-10 to move, when the bearing ring 2-9 moves to be contacted with the belt I2-2, the belt I2-2 and the bearing ring 2-9 are in friction connection, the bearing ring 2-9 is driven to rotate, the bearing ring 2-9 rotates to drive the circular cutting knife 2-10 to rotate, the circular cutting knife 2-10 rotates to cut the irregular circular thin plate into regular circular thin plates, the connecting shaft I2-4 also drives a connecting shaft II 2-14 to rotate through the belt III 2-13, the connecting shaft II 2-14 rotates to drive the other connecting shaft II 2-14 to rotate through the belt IV 2-15, the friction wheel III 2-16 also drives the friction wheel III 2-16 to rotate when the belt IV 2-15 follows to move, the friction wheel III 2-16 rotates to drive the connecting shaft III 2-17 to rotate, the connecting shaft III 2-17 rotates to drive the reaction force propeller 2-18 to rotate, the reaction force propeller 2-18 blows air or sucks air in the direction of the connecting plate III 2-12 when rotating, the air is adsorbed through holes on the connecting plate III 2-12 when sucking air in the direction of the connecting plate III 2-12, the circular thin plate cut by the circular cutting knife 2-10 is contacted and adsorbed through an air suction duct a2-6 and an air suction duct b2-11, the adsorbed circular thin plate falls onto a hinge plate 3-3 in the equipment installation box 2-20 when contacting the connecting plate III 2-12, wood slag generated during cutting is adsorbed into a space formed by the equipment installation box 2-20, the inclined plate 3-1 and the installation plate a3-2 through holes on the connecting plate III 2-12, and the wood slag is inclined out of the equipment under the action of the inclined plate 3-1, the device can evaporate and collect the moisture in the round thin plate, the round thin plate falling on the hinge plate 3-3 in the device mounting box 2-20 presses the support block 3-4, the support block 3-4 moves downwards under the guide of the support shaft 3-5, the hinge plate 3-3 can automatically reset under the action of the support spring 3-6, when the round thin plate presses the hinge plate 3-3 to enable the round thin plate to incline to the mounting plate b3-8, the guide plate 3-11 helps the round thin plate to incline to the mounting plate b3-8, the electric heater 3-9 is powered on, the electric heater 3-9 gives out heat to the mounting plate b3-8, the moisture in the round thin plate is evaporated under the heat conduction of the mounting plate b3-8, and the water vapor generated during evaporation is under the action of the hinge plate 3-3, is inclined into the space formed by the equipment installation box 2-20 and the collecting tank 3-10.

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 (6)

1. The utility model provides a timber sampling detects water content equipment, includes that the cutting becomes board mechanism (1), cutting link gear (2), evaporation and collects mechanism (3), its characterized in that: the cutting plate forming mechanism (1) is connected with the cutting linkage mechanism (2), and the cutting linkage mechanism (2) is connected with the evaporation collecting mechanism (3).

2. The wood sampling moisture content measuring apparatus according to claim 1, wherein: the cutting and plate forming mechanism (1) comprises a motor (1-1), a motor shaft (1-2), a belt a (1-3), a connecting shaft a (1-4), a friction wheel a (1-5), a friction wheel b (1-6), a cam (1-7), a connecting shaft b (1-8), a belt b (1-9), a connecting shaft c (1-10), a belt c (1-11), a cutting saw (1-12), a cutting saw limiting block (1-13), a connecting plate a (1-14), a connecting plate b (1-15), a connecting plate c (1-16), a connecting plate d (1-17), a connecting plate e (1-18) and a wood column (1-19), wherein the motor (1-1) is connected with the motor shaft (1-2), the motor (1-1) is connected with a connecting plate a (1-14), the motor shaft (1-2) is connected with a belt a (1-3) in a friction way, the belt a (1-3) is connected with a connecting shaft a (1-4) in a friction way, the connecting shaft a (1-4) is connected with a friction wheel a (1-5), the connecting shaft a (1-4) is connected with a bearing of the connecting plate a (1-14), the friction wheel a (1-5) is connected with a friction wheel b (1-6) in a friction way, the friction wheel b (1-6) is connected with a cam (1-7), the connecting shaft b (1-6) is connected with a connecting shaft b (1-8) in a thread way, the cam (1-7) is connected with a b (1-8) in a thread way, the cam (1-7) is connected with the cutting saw (1-12) in a sliding way, the connecting shaft b (1-8) is connected with the belt b (1-9) in a friction way, the connecting shaft b (1-8) is connected with the cutting saw limiting block (1-13) in a sliding way, the connecting shaft b (1-8) is connected with the connecting plate a (1-14) in a sliding way, the connecting shaft b (1-8) is connected with the connecting plate e (1-18) in a sliding way, the belt b (1-9) is connected with the connecting shaft c (1-10) in a bearing way, the connecting shaft c (1-10) is connected with the belt c (1-11) in a friction way, the connecting shaft c (1-10) is connected with the cutting saw limiting block (1-13) in a sliding way, the connecting shaft c (1-10) is connected with the cutting saw limiting block (1-13) in a threaded way, and the, the connecting shaft c (1-10) is in threaded connection with the connecting plate e (1-18), the cutting saw (1-12) is in sliding connection with the connecting plate a (1-14), the cutting saw (1-12) is in sliding connection with the connecting plate c (1-16), the cutting saw limiting block (1-13) is connected with the connecting plate a (1-14), the cutting saw limiting block (1-13) is in sliding connection with the connecting plate c (1-16), the connecting plate a (1-14) is connected with the connecting plate b (1-15), the connecting plate b (1-15) is in sliding connection with the connecting plate c (1-16), the connecting plate b (1-15) is in sliding connection with the connecting plate d (1-17), the connecting plate c (1-16) is connected with the connecting plate d (1-17), and the connecting plate c (1-16) is connected with the connecting plate e (1-18).

3. The wood sampling moisture content measuring apparatus according to claim 1, wherein: the cutting linkage mechanism (2) comprises a friction wheel I (2-1), a belt I (2-2), a belt II (2-3), a connecting shaft I (2-4), a friction wheel II (2-5), an air suction duct a (2-6), a connecting plate I (2-7), a connecting plate II (2-8), a bearing ring (2-9), a circular cutting knife (2-10), an air suction duct b (2-11), a connecting plate III (2-12), a belt III (2-13), a connecting shaft II (2-14), a belt IV (2-15), a friction wheel III (2-16), a connecting shaft III (2-17), a reaction force propeller (2-18), a connecting plate IV (2-19) and an equipment installation box (2-20), wherein the friction wheel I (2-1) is in friction connection with the belt I (2-2), the friction wheel I (2-1) is connected with a connecting shaft b (1-8), the belt II (2-3) is in friction connection with the connecting shaft I (2-4), the belt II (2-3) is in friction connection with the connecting shaft b (1-8), the connecting shaft I (2-4) is connected with the friction wheel II (2-5), the connecting shaft I (2-4) is in bearing connection with the connecting plate I (2-7), the connecting shaft I (2-4) is in friction connection with the belt III (2-13), the connecting shaft I (2-4) is in bearing connection with the connecting plate a (1-14), the friction wheel II (2-5) is in friction connection with an air suction duct a (2-6), the air suction duct a (2-6) is in sliding connection with the connecting plate II (2-8), the air suction duct a (2-6) is in bearing connection with a bearing ring (2-9), an air suction duct a (2-6) is connected with a circular cutting knife (2-10) in a sliding way, the air suction duct a (2-6) is connected with an air suction duct b (2-11) in a sliding way, a connecting plate I (2-7) is connected with a connecting plate II (2-8), the connecting plate II (2-8) is connected with a connecting plate a (1-14), a bearing ring (2-9) is connected with the circular cutting knife (2-10), the air suction duct b (2-11) is connected with a connecting plate III (2-12), the connecting plate III (2-12) is connected with an equipment installation box (2-20), a belt III (2-13) is connected with a connecting shaft II (2-14) in a friction way, the connecting shaft II (2-14) is connected with a belt IV (2-15) in a friction way, the connecting shaft II (2-14) is connected with a connecting plate IV (2-19) in a bearing way, the belt IV (2-15) is in friction connection with the friction wheel III (2-16), the friction wheel III (2-16) is connected with the connecting shaft III (2-17), the connecting shaft III (2-17) is connected with the reaction force propeller (2-18), the connecting shaft III (2-17) is in bearing connection with the equipment installation box (2-20), the connecting plate IV (2-19) is connected with the equipment installation box (2-20), and the equipment installation box (2-20) is connected with the connecting plate a (1-14).

4. The wood sampling moisture content measuring apparatus according to claim 1, wherein: the evaporation collecting mechanism (3) comprises an inclined plate (3-1), a mounting plate a (3-2), a hinged plate (3-3), a supporting block (3-4), a supporting shaft (3-5), a supporting spring (3-6), a supporting limiting plate (3-7), a mounting plate b (3-8), an electric heater (3-9), a collecting tank (3-10), a guiding plate (3-11) and a collecting port (3-12), wherein the inclined plate (3-1) is connected with the mounting plate a (3-2), the inclined plate (3-1) is connected with an equipment mounting box (2-20), the mounting plate a (3-2) is hinged with the hinged plate (3-3), the mounting plate a (3-2) is connected with the mounting plate b (3-8), and the mounting plate a (3-2) is connected with the equipment mounting box (2-20) in a sliding manner, the hinged plate (3-3) is connected with the supporting block (3-4) in a sliding manner, the supporting block (3-4) is connected with the supporting shaft (3-5), the supporting shaft (3-5) is connected with the supporting limit plate (3-7), the supporting shaft (3-5) is connected with the mounting plate b (3-8) in a sliding manner, the supporting shaft (3-5) is connected with the electric heater (3-9) in a sliding manner, the supporting shaft (3-5) is connected with the equipment mounting box (2-20) in a sliding manner, the supporting spring (3-6) is sleeved on the supporting shaft (3-5) and limited on the supporting block (3-4) and the mounting plate b (3-8), the mounting plate b (3-8) is connected with the equipment mounting box (2-20), and the electric heater (3-9) is connected with the equipment mounting box (2, the collecting tank (3-10) is connected with the equipment installation box (2-20), the guide plate (3-11) is connected with the equipment installation box (2-20), and the collecting port (3-12) is formed in the equipment installation box (2-20).

5. The wood sampling moisture content measuring apparatus according to claim 1, wherein: and a large number of holes are arranged on the surface of the connecting plate III (2-12).

6. The wood sampling moisture content measuring apparatus according to claim 1, wherein: a large number of resistors are arranged in the electric heaters (3-9), and after the power supply is switched on, the metal heat conduction layers outside the electric heaters (3-9) can emit heat.

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