CN112666253A - A capability test equipment for carborundum inhale ripples awl - Google Patents

Abstract

The invention relates to a performance test device, in particular to a performance test device for a silicon carbide wave-absorbing pointed cone, which comprises a machine body mechanism, a power mechanism and a linkage mechanism, wherein the device can clamp the silicon carbide wave-absorbing pointed cone, the device can change the test distance, water or mixed solution can be added into the device, the device can accelerate water drainage, the device can add wind test factors, the machine body mechanism is connected with the power mechanism, and the machine body mechanism is connected with the linkage mechanism.

Description

A capability test equipment for carborundum inhale ripples awl

Technical Field

The invention relates to a performance test device, in particular to a performance test device for a silicon carbide wave-absorbing pointed cone.

Background

In the performance test of the silicon carbide wave-absorbing pointed cone, the traditional test equipment cannot well simulate various test environments, so the performance test equipment for the silicon carbide wave-absorbing pointed cone is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing a performance test device for a silicon carbide wave-absorbing pointed cone, the device can clamp the silicon carbide wave-absorbing pointed cone, the device can change the test distance, water or mixed solution can be added into the device, the device can accelerate drainage, and the device can add wind test factors.

In order to solve the technical problem, the invention relates to a performance test device, in particular to a performance test device for a silicon carbide wave-absorbing pointed cone.

The machine body mechanism is connected with the power mechanism, and the machine body mechanism is connected with the linkage mechanism.

As a further optimization of the technical scheme, the machine body mechanism of the performance testing equipment for the silicon carbide wave-absorbing pointed cone comprises a box body, a threaded rod, a friction wheel, a servo motor, a coupler, a bearing seat, a long friction wheel with a shaft, a wind wheel cavity, a lead screw, a limiting slide rod, a transfer drawing box, a seat with double holes, a connecting pipe, an acceleration stirring box, a bearing seat I, an inlet pipe I, a seat with double rods, a spring, an inclined driving seat, an inclined matching seat, a spring, a square column, a servo motor I, a driven belt pulley, a transmission belt, a driving belt pulley, a coupler I, a servo motor II, an upper movable seat, a lower movable seat, a clamping seat, a cross slide block with threaded holes, a cross chute, a bidirectional lead screw, a piston, a one-way valve I, a sound wave generator, a base, a fixed platform and a thread control plug, the friction wheel is in friction connection with a long friction wheel with a shaft, the long friction wheel with the shaft is in rotational connection with a bearing seat, a base is connected with the bearing seat, the long friction wheel with the shaft is connected with a servo motor through a coupler, a wind wheel cavity is arranged on a box body, a lead screw is in rotational connection with the box body, the box body is in sliding connection with a limiting slide rod, a transfer drawing box is communicated with the box body, the transfer drawing box is connected with the base, the transfer drawing box is connected with a double-hole seat, the transfer drawing box is communicated with a stirring acceleration box through a connecting pipe, the stirring acceleration box is connected with a bearing seat I, the stirring acceleration box is communicated with an inlet pipe, the inlet pipe I is communicated with the stirring acceleration box, a spring is sleeved on the double-rod seat with the double-hole seat, the double-rod seat is in sliding connection with the double-hole seat, two ends of the spring are connected on the double-rod seat with an inclined-rod, the spring is sleeved on the square column, the spring is abutted against the inclined plane matching seat and the transfer pull box, the servo motor I is connected with the fixed platform, the fixed platform is connected with the limit slide bar, the lead screw is rotationally connected with the fixed platform, the servo motor I is connected with the driving belt pulley, the driving belt pulley is frictionally connected with the driving belt, the driving belt pulley is frictionally connected with the driven belt pulley, the driven belt pulley and the driving belt pulley are both connected with the lead screw, the coupler I is connected with the servo motor II, the servo motor II is connected with the upper movable seat and the lower movable seat, the upper movable seat and the lower movable seat are rotationally connected with the lead screw, the upper movable seat and the lower movable seat are slidably connected with the limit slide bar, the clamping seat is connected with the crosshead shoe with the threaded hole, the crosshead shoe with the threaded hole is slidably connected with the crosshead shoe with the threaded hole, two-way lead screw links to each other with shaft coupling I, and the piston links to each other with the square column, and square column, piston all with transfer pull case sliding connection, check valve setting are in transfer pull incasement, and check valve I sets up in the connecting tube, and the sound wave sender sets up on the threaded rod, threaded control stopper and box threaded connection.

As a further optimization of the technical scheme, the power mechanism of the performance testing equipment for the silicon carbide wave-absorbing pointed cone comprises a driving motor, a coupling A, a stirring wheel, a rotating shaft, a limiting disc, a reset spring, a special-shaped shaft, a belt pulley A, a bevel gear, a limiting disc I, a pushing wheel carrier, a special-shaped support, a servo motor A, a coupling B, a polished rod, a bearing seat A, a cam with a shaft, a belt pulley B, a belt A, a bevel gear A, a special-shaped hole, a lead screw A and a transmission belt pulley, wherein the driving motor is connected with the rotating shaft through the coupling A, the stirring wheel is connected with the rotating shaft, the rotating shaft is provided with the limiting disc, the limiting disc is connected with the special-shaped shaft, the special-shaped shaft is connected with the limiting disc I, the reset spring is sleeved on the special-shaped shaft, the belt pulley A is connected, the pushing wheel is abutted to the bevel gear, the pushing wheel is rotatably connected with the pushing wheel frame, the pushing wheel frame is slidably connected with the polished rod, the polished rod is arranged on the special-shaped support, the servo motor A is connected with the lead screw A through a coupler B, the bearing seat A is rotatably connected with the belt shaft cam, the belt shaft cam is connected with the belt pulley B, the belt pulley B is in friction connection with the belt A, the belt A is in friction connection with the transmission belt pulley, the transmission belt pulley is connected with the bevel gear A, the bevel gear A is rotatably connected with the bearing seat A, the bevel gear A is meshed with the bevel gear, the special-shaped support is rotatably connected with the lead screw A, the base is connected with the driving motor, the special-shaped support, the servo motor A and the bearing seat A, the lead screw A is.

As a further optimization of the technical scheme, the linkage mechanism of the performance testing equipment for the silicon carbide wave-absorbing pointed cone comprises a belt shaft friction wheel a, a belt shaft friction wheel B, a belt pulley C, a curved arm bearing seat, a belt B, a wind wheel belt pulley and a wind wheel a, wherein the belt shaft friction wheel a is in friction connection with the belt shaft friction wheel B, the belt shaft friction wheel B is connected with the belt pulley C, the belt pulley C is in friction connection with the belt B, the belt B is in friction connection with the wind wheel belt pulley, the wind wheel belt pulley is connected with the wind wheel a, the belt shaft friction wheel a and the belt shaft friction wheel B are both in rotational connection with the curved arm bearing seat, the curved arm bearing seat is connected with a base, and the wind wheel a is in rotational connection with a wind wheel cavity.

As a further optimization of the technical scheme, the wind wheel A is made of stainless steel by the performance testing equipment for the silicon carbide wave-absorbing pointed cone.

The performance test equipment for the silicon carbide wave-absorbing pointed cone has the beneficial effects that:

according to the performance test equipment for the silicon carbide wave-absorbing pointed cone, disclosed by the invention, the equipment can be used for clamping the silicon carbide wave-absorbing pointed cone, the test distance can be changed, water or a mixed solution can be added into the equipment, the equipment can be used for accelerating drainage, and the test factor of wind can be added into the equipment.

Drawings

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

Fig. 1 is a first structural schematic diagram of a performance testing device for a silicon carbide wave-absorbing pointed cone of the invention.

Fig. 2 is a structural schematic diagram of a second performance testing device for a silicon carbide wave-absorbing pointed cone of the invention.

Fig. 3 is a third structural schematic diagram of the performance testing equipment for the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 4 is a fourth structural schematic diagram of the performance testing equipment for the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 5 is a schematic structural diagram five of the performance testing equipment for the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 6 is a first structural schematic diagram of a body mechanism 1 of the device for testing the performance of the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 7 is a second structural schematic diagram of the body mechanism 1 of the device for testing the performance of the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 8 is a third structural schematic diagram of the body mechanism 1 of the device for testing the performance of the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 9 is a fourth structural schematic diagram of the body mechanism 1 of the device for testing the performance of the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 10 is a first structural schematic diagram of a power mechanism 2 of the device for testing the performance of the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 11 is a second structural schematic diagram of a power mechanism 2 of the device for testing the performance of the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 12 is a third schematic structural diagram of a power mechanism 2 of the device for testing the performance of the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 13 is a schematic structural diagram of a power mechanism 2 of the device for testing the performance of the silicon carbide wave-absorbing pointed cone of the invention.

Fig. 14 is a schematic structural diagram of a linkage mechanism 3 of the performance testing equipment for the silicon carbide wave-absorbing pointed cone of the invention.

In the figure: a body mechanism 1; a box body 1-1; 1-2 parts of a threaded rod; 1-3 of a friction wheel; 1-4 of a servo motor; 1-5 of a coupler; 1-6 of a bearing seat; long friction wheels with shafts 1-7; 1-8 parts of a wind wheel cavity; 1-9 parts of a screw rod; 1-10 parts of a limiting slide bar; 1-11 parts of a transfer drawing box; 1-12 parts of a double-hole seat; connecting pipes 1-13; 1-14 parts of a stirring acceleration box; bearing seats I1-15; inlet pipes 1-16; an inlet pipe I1-17; 1-18 with double-rod seat; springs 1-19; 1-20 parts of an inclined plane driving seat; 1-21 of a bevel matching seat; springs 1-22; 1-23 of square column; servo motors I1-24; passive belt pulleys 1-25; drive belts 1-26; drive pulleys 1-27; a coupler I1-28; servo motor II 1-29; 1-30 parts of upper and lower movable seats; 1-31 of a clamping seat; 1-32 of a crosshead shoe with a threaded hole; 1-33 of a cross sliding chute; 1-34 of a bidirectional screw; 1-35 of a piston; 1-36 of a one-way valve; a check valve I1-37; acoustic emitters 1-38; bases 1-39; 1-40 of a fixed platform; thread control plugs 1-41; a power mechanism 2; a driving motor 2-1; a coupler A2-2; 2-3 of a stirring wheel; 2-4 of a rotating shaft; 2-5 of a limiting disc; 2-6 of a return spring; 2-7 of a special-shaped shaft; pulley A2-8; bevel gears 2-9; a limiting disc I2-10; pushing wheels 2-11; pushing the wheel carrier 2-12; 2-13 of special-shaped supports; a servo motor A2-14; a coupler B2-15; 2-16 parts of a polished rod; bearing seat A2-17; cam with shaft 2-18; pulley B2-19; belt A2-20; bevel gears a 2-21; special-shaped holes 2-22; lead screw A2-23; 2-24 parts of a transmission belt pulley; a link mechanism 3; a friction wheel with a shaft A3-1; a belt shaft friction wheel B3-2; pulley C3-3; 3-4 of a bent arm bearing block; belt B3-5; 3-6 of a wind wheel belt pulley; wind wheel A3-7.

Detailed Description

The first embodiment is as follows:

the 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, and fig. 14, and the present invention relates to a performance testing apparatus, and more specifically, to a performance testing apparatus for a silicon carbide wave-absorbing pointed cone, which includes a body mechanism 1, a power mechanism 2, and a linkage mechanism 3, and the apparatus can clamp the silicon carbide wave-absorbing pointed cone, can change a testing distance, can add water or a mixed solution, can accelerate drainage, and can add a testing factor of wind.

The machine body mechanism 1 is connected with the power mechanism 2, and the machine body mechanism 1 is connected with the linkage 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, and the present embodiment further describes the present embodiment, where the fuselage mechanism 1 includes a box 1-1, a threaded rod 1-2, a friction wheel 1-3, a servo motor 1-4, a coupling 1-5, a bearing seat 1-6, a long friction wheel with an axis 1-7, a wind wheel cavity 1-8, a lead screw 1-9, a limit slide bar 1-10, a transfer pull box 1-11, a seat with two holes 1-12, a connecting pipe 1-13, an acceleration box 1-14, a bearing seat I1-15, an inlet pipe 1-16, an inlet pipe I1-17, a seat with two rods 1-18, a spring 1-19, a spring, a connecting pipe, a connecting, 1-20 parts of an inclined plane driving seat, 1-21 parts of an inclined plane matching seat, 1-22 parts of a spring, 1-23 parts of a square column, 1-24 parts of a servo motor I1, 1-25 parts of a driven belt pulley, 1-26 parts of a transmission belt, 1-27 parts of a driving belt pulley, 1-28 parts of a coupling I1, 1-29 parts of a servo motor II1, 1-30 parts of an upper movable seat and a lower movable seat, 1-31 parts of a clamping seat, 1-32 parts of a cross slide block with a threaded hole, 1-33 parts of a cross slide groove, 1-34 parts of a two-way lead screw, 1-35 parts of a piston, 1-36 parts of a one-way valve I1-37 parts of a one-way valve, 1-38 parts of a sound wave generator, 1-39 parts of a base, 1-40 parts of a fixed, the friction wheel 1-3 is in friction connection with the long friction wheel 1-7 with the shaft, the long friction wheel 1-7 with the shaft is in rotation connection with the bearing seat 1-6, the base 1-39 is connected with the bearing seat 1-6, the long friction wheel 1-7 with the shaft is connected with the servo motor 1-4 through the coupling 1-5, the box body 1-1 is provided with a wind wheel cavity 1-8, the lead screw 1-9 is in rotation connection with the box body 1-1, the box body 1-1 is in sliding connection with the limiting slide bar 1-10, the transfer drawing box 1-11 is communicated with the box body 1-1, the transfer drawing box 1-11 is connected with the base 1-39, the transfer drawing box 1-11 is connected with the base 1-12 with the double-hole seat, the transfer drawing box 1-11 is communicated with the stirring acceleration box 1-14 through the connecting pipe 1-, the stirring acceleration box 1-14 is connected with a bearing seat I1-15, the stirring acceleration box 1-14 is communicated with an inlet pipe 1-16, an inlet pipe I1-17 is communicated with the stirring acceleration box 1-14, a spring 1-19 is sleeved on a seat 1-18 with a double rod, the seat 1-18 with the double rod is connected with a seat 1-12 with a double hole in a sliding way, two ends of the spring 1-19 are connected on the seat 1-18 with the double rod and the seat 1-12 with the double hole, the seat 1-18 with the double rod is connected with an inclined plane driving seat 1-20, the inclined plane driving seat 1-20 is contacted with an inclined plane matching seat 1-21, the inclined plane matching seat 1-21 is connected with a square column 1-23, the spring 1-22 is sleeved on the square column 1-23, the spring 1-22 is abutted against the inclined plane matching seat 1-21 and a pulling box 1-11, the servo motor I1-24 is connected with the fixed platform 1-40, the fixed platform 1-40 is connected with the limit slide bar 1-10, the lead screw 1-9 is rotationally connected with the fixed platform 1-40, the servo motor I1-24 is connected with the driving belt pulley 1-27, the driving belt pulley 1-27 is frictionally connected with the driving belt pulley 1-26, the driving belt pulley 1-26 is frictionally connected with the driven belt pulley 1-25, the driven belt pulley 1-25 and the driving belt pulley 1-27 are both connected with the lead screw 1-9, the coupling I1-28 is connected with the servo motor II1-29, the servo motor II1-29 is connected with the upper and lower movable seat 1-30, the upper and lower movable seats 1-30 are rotationally connected with the lead screw 1-9, the upper and lower movable seats 1-30 are slidably connected with the limit slide bar 1-10, the clamping seats 1-31 are connected with cross sliding blocks 1-32 with threaded holes, the cross sliding blocks 1-32 with threaded holes are connected with cross sliding chutes 1-33 in a sliding manner, the cross sliding chutes 1-33 are arranged on upper and lower movable seats 1-30, two-way lead screws 1-34 are connected with upper and lower movable seats 1-30 in a rotating manner, the two-way lead screws 1-34 are connected with the cross sliding blocks 1-32 with threaded holes in a threaded manner, the two-way lead screws 1-34 are connected with couplings I1-28, pistons 1-35 are connected with square columns 1-23, the square columns 1-23 and the pistons 1-35 are both connected with transfer drawing boxes 1-11 in a sliding manner, one-way valves 1-36 are arranged in the transfer drawing boxes 1-11, one-way valves I1-37 are arranged in connecting pipes 1-13, sound wave transmitters 1-38 are arranged on threaded rods 1, the thread control plug 1-41 is in threaded connection with the box body 1-1, the silicon carbide wave-absorbing pointed cone is placed between two clamping seats 1-31, then the servo motor II1-29 is operated to drive the coupling I1-28 to rotate, the coupling I1-28 drives the bidirectional lead screw 1-34 to rotate, the bidirectional lead screw 1-34 drives the cross slide blocks 1-32 with threaded holes at two sides to approach each other, so as to drive the two clamping seats 1-31 to approach each other, so as to clamp the wave-absorbing pointed cone, then the servo motor I1-24 is operated to drive the driving belt pulley 1-27 to rotate, the driving belt pulley 1-27 drives the driven belt pulley 1-25 to synchronously rotate through the transmission belt 1-26, the driving belt pulley 1-27 and the driven belt pulley 1-25 drive the lead screws 1-9 at two sides to synchronously rotate, the screw rod 1-9 drives the upper movable seat 1-30 and the lower movable seat 1-30 to move downwards, the upper movable seat 1-30 and the lower movable seat 1-30 drive the clamped pointed cone to descend to the position which is the same with the horizontal line of the sound wave emitter 1-38, and then the servo motor I1-24 stops running.

The third concrete implementation mode:

the 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, and the embodiment further describes the embodiment, where the power mechanism 2 includes a driving motor 2-1, a coupling a2-2, a stirring wheel 2-3, a rotating shaft 2-4, a spacing disc 2-5, a return spring 2-6, a special-shaped shaft 2-7, a belt pulley a2-8, a bevel gear 2-9, a spacing disc I2-10, a pushing wheel 2-11, a pushing wheel frame 2-12, a special-shaped support 2-13, a servo motor a2-14, a coupling B2-15, a polish rod 2-16, a bearing seat a2-17, a cam with a shaft 2-18, a belt pulley B2-19, a belt a2-20, a cam with a shaft, Bevel gear A2-21, special-shaped hole 2-22, lead screw A2-23, driving pulley 2-24, driving motor 2-1 and rotating shaft 2-4 are connected through coupling A2-2, stirring wheel 2-3 is connected with rotating shaft 2-4, limiting disc 2-5 is arranged on rotating shaft 2-4, limiting disc 2-5 is connected with special-shaped shaft 2-7, special-shaped shaft 2-7 is connected with limiting disc I2-10, return spring 2-6 is sleeved on special-shaped shaft 2-7, pulley A2-8 is connected with bevel gear 2-9, special-shaped hole 2-22 is arranged on bevel gear 2-9, special-shaped hole 2-22 is connected with special-shaped shaft 2-7 in a sliding manner, special-shaped shaft 2-7 is connected with bevel gear 2-9, pushing wheel 2-11 is supported on bevel gear 2-9, the pushing wheels 2-11 are rotationally connected with the pushing wheel frames 2-12, the pushing wheel frames 2-12 are slidably connected with the polish rod 2-16, the polish rod 2-16 is arranged on the special-shaped supports 2-13, the servo motors A2-14 are connected with the lead screws A2-23 through the couplings B2-15, the bearing seats A2-17 are rotationally connected with the cam with a shaft 2-18, the cam with a shaft 2-18 is connected with the belt pulleys B2-19, the belt pulleys B2-19 are frictionally connected with the belt A2-20, the belt A2-20 is frictionally connected with the driving belt pulleys 2-24, the driving belt pulleys 2-24 are connected with the bevel gears A2-21, the bevel gears A2-21 are rotationally connected with the bearing seats A2-17, the bevel gears A2-21 are meshed with the special-shaped bevel gears 2-9, the supports 2-13 are rotationally connected with the lead screws A, the base 1-39 is connected with the driving motor 2-1, the special-shaped support 2-13, the servo motor A2-14 and the bearing seat A2-17, the lead screw A2-23 is connected with the pushing wheel carrier 2-12 by screw thread, the cam with shaft 2-18 is contacted with the double-rod seat 1-18, the servo motor 1-4 is operated to drive the shaft coupling 1-5 to rotate, the shaft coupling 1-5 can drive the long friction wheel with shaft 1-7 to rotate, the long friction wheel with shaft 1-7 can drive the friction wheel 1-3 to rotate, the friction wheel 1-3 can drive the threaded rod 1-2 to rotate, because the threaded rod 1-2 is connected with the box body 1-1 by screw thread, the threaded rod 1-2 can drive itself to move by screw thread when rotating, thereby driving the sound wave emitter 1-38 to move, thereby changing the distance between the acoustic emitter 1-38 and the clamped tip cone; the equipment can be added with water or mixed solution, a servo motor A2-14 operates to drive a coupler B2-15 to rotate, a coupler B2-15 drives a screw A2-23 to rotate, the screw A2-23 drives a pushing wheel carrier 2-12 to move, the pushing wheel carrier 2-12 drives a pushing wheel 2-11 to push a bevel gear 2-9, the bevel gear 2-9 is disengaged from a bevel gear A2-21 but does not reach the position contacted with a friction wheel A3-1 with a shaft, at the moment, two liquids which are added into a stirring acceleration box 1-14 from an inlet pipe 1-16 and an inlet pipe I1-17 are operated to drive a motor 2-1 to drive a coupler A2-2 to rotate, the coupler A2-2 drives a stirring wheel 2-3 to rotate through a rotating shaft 2-4, the stirring wheel 2-3 can stir the two liquids, if the bevel gear 2-9 is driven by the servo motor A2-14 which runs in the reverse direction to reset, the bevel gear 2-9 which rotates along with the rotating shaft 2-4 can drive the bevel gear A2-21 to rotate, the bevel gear A2-21 can drive the belt shaft cam 2-18 to rotate through the transmission belt of the transmission belt pulley 2-24, the belt A2-20 and the belt pulley B2-19, the belt shaft cam 2-18 drives the belt double-rod seat 1-18 to do reciprocating linear motion through the matching of the belt shaft cam 2-18 and the spring 1-19, the belt double-rod seat 1-18 can drive the inclined plane driving seat 1-20 to do reciprocating linear motion, the inclined plane driving seat 1-20 can extrude the inclined plane matching seat 1-21 through the inclined plane of the inclined plane driving seat 1-20, the inclined plane matching seat 1-21 can do reciprocating motion in the up, the square column 1-23 can drive the piston 1-35 to reciprocate up and down, so that the pressure difference in the transfer pulling box 1-11 is changed, the liquid in the stirring acceleration box 1-14 is continuously sucked into the transfer pulling box 1-11 by flushing the one-way valve I1-37, then the pressurized liquid is pressurized and then flows into the box body 1-1 by flushing the one-way valve 1-36 until the pointed cone is submerged, and the wave absorbing performance in the liquid can be tested.

The fourth concrete implementation mode:

referring 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, the present embodiment further illustrates the present embodiment, where the linkage mechanism 3 includes a friction wheel with shaft A3-1, a friction wheel with shaft B3-2, a pulley C3-3, a curved-arm bearing seat 3-4, a belt B3-5, a wind wheel pulley 3-6, a wind wheel A3-7, a friction wheel with shaft A3-1 and a friction wheel with shaft B3-2, a friction wheel with shaft B3-2 and a pulley C3-3, a pulley C3-3 and a belt B3-5 are frictionally connected, a belt B3-5 and a pulley 3-6 are frictionally connected, a pulley 3-6 and a pulley a wind wheel A3-7 are connected, a belt shaft friction wheel A3-1 and a belt shaft friction wheel B3-2 are rotatably connected with a bent arm bearing seat 3-4, the bent arm bearing seat 3-4 is connected with a base 1-39, a wind wheel A3-7 is rotatably connected with a wind wheel cavity 1-8, when water needs to be drained, a servo motor A2-14 is used for driving a push wheel 2-11 to push a bevel gear 2-9 in a forward running mode, so that a belt pulley A2-8 is in contact with a belt shaft friction wheel A3-1, power is transmitted to the belt shaft friction wheel A3-1, the belt shaft friction wheel A3-1 can drive the belt shaft friction wheel B3-2 to rotate, the belt shaft friction wheel B3-2 can drive a wind wheel A3-7 to rotate through a belt pulley C3-3, a belt B3-5 and a wind wheel pulley 3-6, and the wind wheel A3-7 can form thrust, after the screw control plugs 1-41 are unscrewed, the water is pushed out to be drained in an accelerated way.

The fifth concrete implementation mode:

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, and fig. 14, and the first embodiment is further described, in which the material of the wind wheel a3-7 is stainless steel.

The working principle of the device is as follows: the equipment can clamp a silicon carbide wave absorbing pointed cone, the silicon carbide wave absorbing pointed cone is placed between two clamping seats 1-31, then a servo motor II1-29 is operated to drive a coupler I1-28 to rotate, the coupler I1-28 drives a bidirectional lead screw 1-34 to rotate, the bidirectional lead screw 1-34 drives cross sliders 1-32 with threaded holes on two sides to approach each other so as to drive the two clamping seats 1-31 to approach each other so as to clamp the wave absorbing pointed cone, then a servo motor I1-24 is operated to drive a driving belt pulley 1-27 to rotate, the driving belt pulley 1-27 drives a driven belt pulley 1-25 to synchronously rotate through a transmission belt 1-26, the driving belt pulley 1-27 and the driven belt pulley 1-25 drive the lead screws 1-9 on two sides to synchronously rotate, the screw rod 1-9 can drive the upper movable seat 1-30 and the lower movable seat 1-30 to move downwards, the upper movable seat 1-30 and the lower movable seat 1-30 can drive the clamped pointed cone to descend to the position which is the same with the horizontal line of the sound wave emitter 1-38, and then the servo motor I1-24 stops running; the device can change the testing distance, the servo motor 1-4 is operated to drive the shaft coupling 1-5 to rotate, the shaft coupling 1-5 can drive the long friction wheel 1-7 with the shaft to rotate, the long friction wheel 1-7 with the shaft can drive the friction wheel 1-3 to rotate, the friction wheel 1-3 can drive the threaded rod 1-2 to rotate, the threaded rod 1-2 is in threaded connection with the box body 1-1, the threaded rod 1-2 can drive the self to move through threads when rotating, and therefore the sound wave emitter 1-38 is driven to move, and the distance between the sound wave emitter 1-38 and the clamped pointed cone is changed; the equipment can be added with water or mixed solution, a servo motor A2-14 operates to drive a coupler B2-15 to rotate, a coupler B2-15 drives a screw A2-23 to rotate, the screw A2-23 drives a pushing wheel carrier 2-12 to move, the pushing wheel carrier 2-12 drives a pushing wheel 2-11 to push a bevel gear 2-9, the bevel gear 2-9 is disengaged from a bevel gear A2-21 but does not reach the position contacted with a friction wheel A3-1 with a shaft, at the moment, two liquids which are added into a stirring acceleration box 1-14 from an inlet pipe 1-16 and an inlet pipe I1-17 are operated to drive a motor 2-1 to drive a coupler A2-2 to rotate, the coupler A2-2 drives a stirring wheel 2-3 to rotate through a rotating shaft 2-4, the stirring wheel 2-3 can stir the two liquids, if the bevel gear 2-9 is driven by the servo motor A2-14 which runs in the reverse direction to reset, the bevel gear 2-9 which rotates along with the rotating shaft 2-4 can drive the bevel gear A2-21 to rotate, the bevel gear A2-21 can drive the belt shaft cam 2-18 to rotate through the transmission belt of the transmission belt pulley 2-24, the belt A2-20 and the belt pulley B2-19, the belt shaft cam 2-18 drives the belt double-rod seat 1-18 to do reciprocating linear motion through the matching of the belt shaft cam 2-18 and the spring 1-19, the belt double-rod seat 1-18 can drive the inclined plane driving seat 1-20 to do reciprocating linear motion, the inclined plane driving seat 1-20 can extrude the inclined plane matching seat 1-21 through the inclined plane of the inclined plane driving seat 1-20, the inclined plane matching seat 1-21 can do reciprocating motion in the up, the square column 1-23 can drive the piston 1-35 to reciprocate up and down, so that the pressure difference in the transfer pull box 1-11 is changed, the liquid in the stirring acceleration box 1-14 is continuously sucked into the transfer pull box 1-11 by flushing the one-way valve I1-37, then the pressurized liquid is pressurized by flushing the one-way valve 1-36 and flows into the box body 1-1 until the pointed cone is submerged, and the wave absorbing performance in the liquid can be tested; the equipment can accelerate drainage, when drainage is needed, a servo motor A2-14 runs in the forward direction to drive a push wheel 2-11 to push a bevel gear 2-9, so that a belt pulley A2-8 is in contact with a belt shaft friction wheel A3-1, power is transmitted to the belt shaft friction wheel A3-1, the belt shaft friction wheel A3-1 drives a belt shaft friction wheel B3-2 to rotate, the belt shaft friction wheel B3-2 drives a wind wheel A3-7 to rotate through transmission of a belt pulley C3-3, a belt B3-5 and a wind wheel belt pulley 3-6, the wind wheel A3-7 forms thrust, and after a thread control plug 1-41 is screwed off, water can be pushed out in an accelerated mode to be drained; the device can add a wind test factor, and the rotating wind wheel A3-7 can form wind force, so that the wind drying factor can be reliably added.

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 (5)

1. The utility model provides a capability test equipment for carborundum ripples of inhaling awl, includes fuselage mechanism (1), power unit (2), link gear (3), its characterized in that: the machine body mechanism (1) is connected with the power mechanism (2), and the machine body mechanism (1) is connected with the linkage mechanism (3).

2. The performance test equipment for the silicon carbide wave-absorbing pointed cone according to claim 1, characterized in that: the machine body mechanism (1) comprises a box body (1-1), a threaded rod (1-2), a friction wheel (1-3), a servo motor (1-4), a coupler (1-5), a bearing seat (1-6), a long friction wheel with a shaft (1-7), a wind wheel cavity (1-8), a lead screw (1-9), a limiting slide rod (1-10), a transfer drawing box (1-11), a seat with double holes (1-12), a connecting pipe (1-13), a stirring acceleration box (1-14), a bearing seat I (1-15), an inlet pipe (1-16), an inlet pipe I (1-17), a seat with double rods (1-18), a spring (1-19), an inclined plane driving seat (1-20), an inclined plane matching seat (1-21), Springs (1-22), square columns (1-23), servo motors I (1-24), driven belt pulleys (1-25), transmission belts (1-26), driving belt pulleys (1-27), couplings I (1-28), servo motors II (1-29), upper and lower movable seats (1-30), clamping seats (1-31), cross sliding blocks (1-32) with threaded holes, cross sliding chutes (1-33), two-way lead screws (1-34), pistons (1-35), one-way valves (1-36), one-way valves I (1-37), sound wave generators (1-38), bases (1-39), fixed platforms (1-40) and thread control plugs (1-41), wherein a box body (1-1) is in threaded connection with a threaded rod (1-2), the threaded rod (1-2) is connected with the friction wheel (1-3), the friction wheel (1-3) is connected with the long friction wheel (1-7) with the shaft in a friction way, the long friction wheel (1-7) with the shaft is rotationally connected with the bearing seat (1-6), the base (1-39) is connected with the bearing seat (1-6), the long friction wheel (1-7) with the shaft is connected with the servo motor (1-4) through the coupler (1-5), the box body (1-1) is provided with the wind wheel cavity (1-8), the lead screw (1-9) is rotationally connected with the box body (1-1), the box body (1-1) is slidably connected with the limiting slide bar (1-10), the transfer drawing box (1-11) is communicated with the box body (1-1), the transfer drawing box (1-11) is connected with the base (1-39), the middle rotating drawing box (1-11) is connected with a seat (1-12) with double holes, the middle rotating drawing box (1-11) is communicated with an agitating acceleration box (1-14) through a connecting pipe (1-13), the agitating acceleration box (1-14) is connected with a bearing seat I (1-15), the agitating acceleration box (1-14) is communicated with an inlet pipe (1-16), the inlet pipe I (1-17) is communicated with the agitating acceleration box (1-14), a spring (1-19) is sleeved on the seat (1-18) with double rods, the seat (1-18) with double rods is connected with the seat (1-12) with double holes in a sliding way, two ends of the spring (1-19) are connected on the seat (1-18) with double rods and the seat (1-12) with double holes, the seat (1-18) with double rods is connected with an inclined plane driving seat (1-20), the inclined plane driving seat (1-20) is contacted with the inclined plane matching seat (1-21), the inclined plane matching seat (1-21) is connected with the square column (1-23), the spring (1-22) is sleeved on the square column (1-23), the spring (1-22) is propped against the inclined plane matching seat (1-21) and the transfer drawing box (1-11), the servo motor I (1-24) is connected with the fixed platform (1-40), the fixed platform (1-40) is connected with the limiting slide bar (1-10), the screw rod (1-9) is rotatably connected with the fixed platform (1-40), the servo motor I (1-24) is connected with the driving belt pulley (1-27), the driving belt pulley (1-27) is in friction connection with the driving belt pulley (1-26), the driving belt (1-26) is in friction connection with the driven belt pulley (1-25), the driven belt pulleys (1-25) and the driving belt pulleys (1-27) are connected with a screw rod (1-9), a coupler I (1-28) is connected with a servo motor II (1-29), the servo motor II (1-29) is connected with an upper movable seat (1-30) and a lower movable seat (1-30), the upper movable seat (1-30) and the lower movable seat (1-9) are rotatably connected with the screw rod (1-9), the upper movable seat (1-30) and the lower movable seat (1-30) are slidably connected with a limiting slide rod (1-10), a clamping seat (1-31) is connected with a cross slide block (1-32) with a threaded hole, the cross slide block (1-32) with the threaded hole is slidably connected with a cross slide groove (1-33), the cross slide groove (1-33) is arranged on the upper movable seat (1-30) and the lower movable seat (1-30), a bidirectional screw rod (, the bidirectional screw rod (1-34) is in threaded connection with a cross slide block (1-32) with a threaded hole, the bidirectional screw rod (1-34) is connected with a coupler I (1-28), a piston (1-35) is connected with a square column (1-23), the square column (1-23) and the piston (1-35) are in sliding connection with a transfer drawing box (1-11), a one-way valve (1-36) is arranged in the transfer drawing box (1-11), the one-way valve I (1-37) is arranged in a connecting pipe (1-13), a sound wave emitter (1-38) is arranged on a threaded rod (1-2), and a thread control plug (1-41) is in threaded connection with a box body (1-1).

3. The performance test equipment for the silicon carbide wave-absorbing pointed cone according to claim 1, characterized in that: the power mechanism (2) comprises a driving motor (2-1), a coupler A (2-2), a stirring wheel (2-3), a rotating shaft (2-4), a limiting disc (2-5), a reset spring (2-6), a special-shaped shaft (2-7), a belt pulley A (2-8), a bevel gear (2-9), a limiting disc I (2-10), a pushing wheel (2-11), a pushing wheel carrier (2-12), a special-shaped support (2-13), a servo motor A (2-14), a coupler B (2-15), a polished rod (2-16), a bearing seat A (2-17), a cam with a shaft (2-18), a belt pulley B (2-19), a belt A (2-20), a bevel gear A (2-21), a special-shaped hole (2-22), A screw rod A (2-23) and a transmission belt pulley (2-24), a driving motor (2-1) is connected with a rotating shaft (2-4) through a coupling A (2-2), a stirring wheel (2-3) is connected with the rotating shaft (2-4), a limiting disc (2-5) is arranged on the rotating shaft (2-4), the limiting disc (2-5) is connected with a special-shaped shaft (2-7), the special-shaped shaft (2-7) is connected with a limiting disc I (2-10), a reset spring (2-6) is sleeved on the special-shaped shaft (2-7), a belt pulley A (2-8) is connected with a bevel gear (2-9), a special-shaped hole (2-22) is arranged on the bevel gear (2-9), the special-shaped hole (2-22) is connected with the special-shaped shaft (2-7) in a sliding manner, the special-shaped shaft (2-7) is connected with the bevel gear (, the pushing wheels (2-11) are abutted against the bevel gears (2-9), the pushing wheels (2-11) are rotationally connected with pushing wheel frames (2-12), the pushing wheel frames (2-12) are slidably connected with polished rods (2-16), the polished rods (2-16) are arranged on special-shaped supports (2-13), a servo motor A (2-14) is connected with a lead screw A (2-23) through a coupler B (2-15), a bearing seat A (2-17) is rotationally connected with a cam (2-18) with a shaft, the cam (2-18) with the shaft is connected with a belt pulley B (2-19), the belt pulley B (2-19) is frictionally connected with a belt A (2-20), the belt A (2-20) is frictionally connected with a transmission belt pulley (2-24), the transmission belt pulley (2-24) is connected with the bevel gears A (2-21), the bevel gear A (2-21) is rotationally connected with the bearing seat A (2-17), the bevel gear A (2-21) is meshed with the bevel gear (2-9), the special-shaped support (2-13) is rotationally connected with the lead screw A (2-23), the base (1-39) is connected with the driving motor (2-1), the special-shaped support (2-13), the servo motor A (2-14) and the bearing seat A (2-17), the lead screw A (2-23) is in threaded connection with the pushing wheel carrier (2-12), and the cam (2-18) with the shaft is in contact with the seat (1-18) with the double rods.

4. The performance test equipment for the silicon carbide wave-absorbing pointed cone according to claim 1, characterized in that: the linkage mechanism (3) comprises a belt shaft friction wheel A (3-1), a belt shaft friction wheel B (3-2), a belt pulley C (3-3), a bent arm bearing seat (3-4), a belt B (3-5), a wind wheel belt pulley (3-6) and a wind wheel A (3-7), the belt shaft friction wheel A (3-1) is in friction connection with the belt shaft friction wheel B (3-2), the belt shaft friction wheel B (3-2) is connected with the belt pulley C (3-3), the belt pulley C (3-3) is in friction connection with the belt B (3-5), the belt B (3-5) is in friction connection with the wind wheel belt pulley (3-6), the wind wheel belt pulley (3-6) is connected with the wind wheel A (3-7), the belt shaft friction wheel A (3-1) and the belt shaft friction wheel B (3-2) are in rotation connection with the bent arm bearing seat (3-4), the bent arm bearing seat (3-4) is connected with the base (1-39), and the wind wheel A (3-7) is rotatably connected with the wind wheel cavity (1-8).

5. The performance test equipment for the silicon carbide wave-absorbing pointed cone according to claim 4, characterized in that: the wind wheel A (3-7) is made of stainless steel.

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