阅读说明：本技术 一种纳米材料中转缓冲装置 (Nano-material transfer buffer device ) 是由 赵永轩 于 2020-11-26 设计创作，主要内容包括：本发明涉及纳米材料生产技术领域,且公开了一种纳米材料中转缓冲装置,包括机台,所述机台的左侧固定连接有连接板,所述连接板的表面设置有循环机构,所述机台的上表面设置有连接机构,所述机台的上表面固定连接有台座,所述台座的上表面设置有调节机构,所述调节机构的顶部设置有座套,所述座套的内部设置有传送缓冲机构。该纳米材料中转缓冲装置,通过对物料的传送时,当材料倒入传送带上面时,料板受到材料的重力作用,会带动料板下沉,而弹簧起到很好的缓冲作用,来降低物料在转运过程中所造成的物料损伤,而料板的材质也是采用的橡胶缓冲材料,进一步的降低了纳米材料的转运损伤,来提高材料的整体完整度。(The invention relates to the technical field of nano material production, and discloses a nano material transfer buffer device which comprises a machine table, wherein a connecting plate is fixedly connected to the left side of the machine table, a circulating mechanism is arranged on the surface of the connecting plate, a connecting mechanism is arranged on the upper surface of the machine table, a pedestal is fixedly connected to the upper surface of the machine table, an adjusting mechanism is arranged on the upper surface of the pedestal, a seat sleeve is arranged at the top of the adjusting mechanism, and a transmission buffer mechanism is arranged inside the seat sleeve. This nano-material transfer buffer, through the conveying to the material, when the material poured the conveyer belt upper surface into, the flitch received the action of gravity of material, can drive the flitch and sink, and the spring plays fine cushioning effect, reduces the material damage that the material caused in the transportation, and the material of flitch is the rubber buffer material who adopts also, further reduction nano-material's transportation damage, improve the whole complete degree of material.)

1. The utility model provides a buffer in nano-material transfer, includes board (1), its characterized in that: the utility model discloses a cabinet, including board (1), fixed surface, the upper surface of board (1) is provided with coupling mechanism (10), the upper surface of board (2) is provided with circulation mechanism (9), the upper surface of board (1) is provided with coupling mechanism (10), the upper surface fixed surface of board (1) is connected with pedestal (5), the upper surface of pedestal (5) is provided with adjustment mechanism (6), the top of adjustment mechanism (6) is provided with seat cover (7), the inside of seat cover (7) is provided with conveying buffer gear (8), the inside sliding connection of board (1) has baffle (3), the fixed surface of baffle (3) is connected with base (4).

2. The nano-material transfer buffer device of claim 1, wherein: the rear portion fixedly connected with support (12) of board (1), the top welding of support (12) has feed plate (11), the right side of feed plate (11) and the surface of baffle (3) contact each other.

3. The nano-material transfer buffer device of claim 1, wherein: the adjusting mechanism (6) comprises a double screw (61), a movable plate (64) is connected to the surface of the double screw (61) in a threaded mode, an upper plate (63) and a lower plate (62) are connected to the surface of the movable plate (64) in a rotating mode respectively, the upper plate (63) is located above the lower plate (62), the bottom of the lower plate (62) and the top of the upper plate (63) are connected to the upper surface of the pedestal (5) and the bottom of the seat cover (7) in a rotating mode respectively, and the surface of the double screw (61) is connected to the inside of the pedestal (5) in a rotating mode.

4. The nano-material transfer buffer device of claim 3, wherein: the quantity of fly leaf (64) is provided with two, and two fly leaves (64) all use the central line of pedestal (5) to distribute as symmetry axis symmetry, half the surface of twin-screw (61) is the positive screw thread, and half is the derotation screw thread, the left side fixedly connected with rack (65) of seat cover (7).

5. The nano-material transfer buffer device of claim 4, wherein: the surface meshing of rack (65) has material pouring gear (66), the axle center department fixedly connected with fixed axle (68) of material pouring gear (66), the fixed surface fixedly connected with feeding case (67) of fixed axle (68), the last fixed surface of feeding case (67) is connected with a plurality of blend stop (69), the surface rotation of fixed axle (68) is connected at the upper surface of base (4).

6. The nano-material transfer buffer device of claim 1, wherein: conveying buffer gear (8) are including fixed case (81), there are servo motor (82) front portion of fixed case (81) through bolted connection, the output fixedly connected with actuating lever (83) of servo motor (82), the fixed surface of actuating lever (83) is connected with drive roller (85), the surface of drive roller (85) is passed through conveyer belt (84) and is connected with the surface transmission of driving roller (86), the axle center department of driving roller (86) is connected on the surface of fixed case (81) through the axostylus axostyle rotation, the inside of conveyer belt (84) is provided with feed arrangement (87), the surface welding of fixed case (81) is on the surface of seat cover (7).

7. The nano-material transfer buffer device of claim 6, wherein: feed arrangement (87) is including flitch (871), both sides fixedly connected with cardboard (876) of flitch (871), cardboard (876) are located the inside of conveyer belt (84), the inside sliding connection of fixed case (81) has traveller (873), spring (874) have been cup jointed on the surface of traveller (873), top fixedly connected with smooth ball (875) of traveller (873), the equal fixedly connected with limiting plate (872) in both sides of flitch (871), limiting plate (872) are located the top of cardboard (876), the spout has been seted up to the bottom of limiting plate (872), the surface sliding connection of flitch (871) is in the inside of conveyer belt (84).

8. The nano-material transfer buffer device of claim 1, wherein: circulating mechanism (9) are including connecting gear (91), the surface meshing of connecting gear (91) has pinion rack (93), the surperficial sliding connection of pinion rack (93) is in the inside of board (1), the fixed cover (96) of left side fixedly connected with of pinion rack (93), the inside sliding connection of fixed cover (96) has slide bar (95), the right-hand member fixedly connected with crank (94) of slide bar (95), the left side fixedly connected with rotating electrical machines (92) of connecting plate (2), the output of rotating electrical machines (92) and the left side fixed connection of crank (94), the surperficial rotation of connecting gear (91) is connected at the upper surface of board (1).

9. The nano-material transfer buffer device of claim 8, wherein: the connecting mechanism (10) comprises a first shaft (103) and a second shaft (104), the surfaces of the first shaft (103) and the second shaft (104) are fixedly connected with a first connecting rod (105), the surface of the first connecting rod (105) is rotationally connected with a second connecting rod (106), the interior of the second connecting rod (106) is rotationally connected with a supporting plate (107) through a shaft lever, the top of the supporting plate (107) is fixedly connected with the bottom of the base (4), one end of the first shaft (103) is fixedly connected with a first gear (101), the other end of the first shaft (103) is fixedly connected with the axis of the connecting gear (91), a second gear (102) is meshed with the surface of the first gear (101), the axial center of the second gear (102) is fixedly connected with the surface of a second shaft (104), the surface of the second shaft (104) is rotatably connected to the upper surface of the machine table (1).

Technical Field

The invention relates to the technical field of nano material production, in particular to a nano material transfer buffer device.

Background

The basic concept and the basic physical effect of the nano material, the characterization technology of the structure, the size and the appearance of the nano material, the preparation and the surface modification of the nano powder material, the preparation of the one-dimensional nano material, the preparation of the nano composite material, the preparation of the nano structure material, the physical characteristics and the application of the nano material, the basic principle and the micro processing technology of nano electronic devices, the latest progress and the development trend of the nano material and the nano technology and the like.

And at present many nano-materials are in the in-process of transporting after producing, and a lot of processing production that all need pass through multichannel process, so need transport mechanism to transport it, and many transfer device are at present highly can't control nano-material, can only be fixed, and the in-process of transporting is fixed conveying basically simultaneously, leads to piling up the in-process of transporting to appear and collides each other, causes the problem of the damage of material, so proposes a nano-material transfer buffer to solve above-mentioned problem that proposes.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a nano material transfer buffer device, which solves the problems of uncontrollable height and easy stacking collision in the re-transferring process of nano materials.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a nano-material transfer buffer, includes the board, the left side fixedly connected with connecting plate of board, the surface of connecting plate is provided with circulation mechanism, the upper surface of board is provided with coupling mechanism, the last fixed surface of board is connected with the pedestal, the upper surface of pedestal is provided with adjustment mechanism, adjustment mechanism's top is provided with the seat cover, the inside of seat cover is provided with conveying buffer gear, the inside sliding connection of board has the baffle, the fixed surface of baffle is connected with the base.

Preferably, the rear portion fixedly connected with support of board, the welding of the top of support has the feed plate, the right side of feed plate and the surface of baffle contact each other.

Preferably, the adjusting mechanism comprises a double screw, a movable plate is connected to the surface of the double screw in a threaded manner, an upper plate and a lower plate are respectively connected to the surface of the movable plate in a rotating manner, the upper plate is located above the lower plate, the bottom of the lower plate and the top of the upper plate are respectively connected to the upper surface of the pedestal and the bottom of the seat cover in a rotating manner, and the surface of the double screw is connected to the inside of the pedestal in a rotating manner.

Preferably, the number of the movable plates is two, the two movable plates are symmetrically distributed by taking the center line of the pedestal as a symmetry axis, one half of the surface of the double screw is a positive-rotation thread, the other half of the surface of the double screw is a negative-rotation thread, and the left side of the seat cover is fixedly connected with a rack.

Preferably, the surface of rack meshes has the material pouring gear, the axle center department fixedly connected with fixed axle of material pouring gear, the fixed surface fixedly connected with feeding case of fixed axle, the last fixed surface of feeding case is connected with a plurality of blend stop, the surface of fixed axle rotates the upper surface of connecting at the base.

Preferably, conveying buffer gear is including fixed case, there is servo motor fixed case's front portion through bolted connection, servo motor's output fixedly connected with actuating lever, the fixed surface of actuating lever is connected with the drive roller, the surface transmission of conveyer belt and driving roller is passed through on the surface of drive roller and is connected, the axle center department of driving roller rotates the surface of connecting at fixed case through the axostylus axostyle, the inside of conveyer belt is provided with feed arrangement, the surface welding of fixed case is on the surface of seat cover.

Preferably, feed arrangement is including the flitch, the both sides fixedly connected with cardboard of flitch, the cardboard is located the inside of conveyer belt, the inside sliding connection of fixed case has the traveller, the spring has been cup jointed on the surface of traveller, the top fixedly connected with ball of traveller, the equal fixedly connected with limiting plate in both sides of flitch, the limiting plate is located the top of cardboard, the spout has been seted up to the bottom of limiting plate, the inside at the conveyer belt of surface sliding connection of flitch.

Preferably, the circulation mechanism is including connecting gear, connecting gear's surface meshing has the pinion rack, the sliding surface connection of pinion rack is in the inside of board, the fixed cover of left side fixedly connected with of pinion rack, the inside sliding connection of fixed cover has the slide bar, the right-hand member fixedly connected with crank of slide bar, the left side fixedly connected with rotating electrical machines of connecting plate, rotating electrical machines's output and articulate left side fixed connection, connecting gear's surface rotates the upper surface of connection at the board.

Preferably, the connecting mechanism comprises a first shaft and a second shaft, a first connecting rod is fixedly connected to the surfaces of the first shaft and the second shaft, a second connecting rod is rotatably connected to the surface of the first connecting rod, a supporting plate is rotatably connected to the inside of the second connecting rod through a shaft rod, the top of the supporting plate is fixedly connected to the bottom of the base, a first gear is fixedly connected to one end of the first shaft, the other end of the first shaft is fixedly connected to the axis of the connecting gear, a second gear is meshed with the surface of the first gear, the axis of the second gear is fixedly connected to the surface of the second shaft, and the surface of the second shaft is rotatably connected to the upper surface of the machine table.

Compared with the prior art, the invention provides a nano-material transfer buffer device, which has the following beneficial effects:

1. this nano-material transfer buffer, through the conveying to the material, the spring has been cup jointed on the traveller surface, when the material was poured into the conveyer belt upper surface, the flitch received the action of gravity of material, can drive the flitch and sink, and the spring plays fine cushioning effect, reduces the material damage that the material caused in the transportation, and the material of flitch also is the rubber buffer material that adopts, further reduction nano-material's transportation damage, improve the whole completeness of material.

2. This nano-material transfer buffer, through the effect of the twin-screw of two-way screw thread, the fly leaf carries out relative motion, and then control seat cover and conveying buffer gear's whole effect that rises, realizes the conveying to different height positions to improve the whole commonality and the suitability of equipment.

3. This nano-material transfer buffer, when utilizing the gear of falling the material along with the base goes up, when the rising of falling the material gear was rotated with rack toothing on the way, will drive the rotation of feeding case, will pour the upper surface of conveyer belt into the nano-material upset of feeding incasement portion to the realization need not the manual work and operates, and is simple and convenient to the automatic material effect of falling of material, thereby improves holistic conveying efficiency.

4. This nano-material transfer buffer controls the rotation of rotating electrical machines, controls articulate rotation, and the crank rotates the rotation that drives the slide bar, and then drives the base and carry out the operation of not intermittent type from top to bottom, realizes the effect of circulation pay-off, further improvement holistic transfer conveying efficiency.

5. This nano-material transfer buffer rises through the base, and the baffle also can rise this moment, keeps off on the surface of feed plate, carries out the material and cuts extremely, and then plays the material to the feed plate position and blocks the effect, restricts the outflow of material, avoids the condition that the material scatters and drops.

Drawings

Fig. 1 is a schematic view of an overall structure of a nanomaterial transfer buffer device according to the present invention;

FIG. 2 is a schematic view of a connection between a machine table and a feeding plate of a nanomaterial transfer buffer structure according to the present invention;

FIG. 3 is a schematic view of an adjusting mechanism of a transfer buffer device for nanomaterials according to the present invention;

FIG. 4 is a schematic structural diagram of a feeding box of a nano-material transfer buffer device according to the present invention;

FIG. 5 is a schematic view of a transfer buffer mechanism of a nanomaterial transfer buffer apparatus according to the present invention;

FIG. 6 is a schematic view of a feeding device of a nanomaterial transfer buffer device according to the present invention;

FIG. 7 is a schematic view of a circulation mechanism of a nanomaterial transfer buffer apparatus according to the present invention;

fig. 8 is a schematic view of a connection mechanism of a nano-material transfer buffer device according to the present invention.

In the figure: 1. a machine platform; 2. a connecting plate; 3. a baffle plate; 4. a base; 5. a pedestal; 6. an adjustment mechanism; 61. double screw; 62. a lower plate; 63. an upper plate; 64. a movable plate; 65. a rack; 66. a material pouring gear; 67. a feeding box; 68. a fixed shaft; 69. blocking strips; 7. a seat cover; 8. a transfer buffer mechanism; 81. a fixed box; 82. a servo motor; 83. a drive rod; 84. a conveyor belt; 85. a drive roller; 86. a driving roller; 87. a feeding device; 871. a material plate; 872. a limiting plate; 873. a traveler; 874. a spring; 875. a sliding ball; 876. clamping a plate; 9. a circulating mechanism; 91. a connecting gear; 92. a rotating electric machine; 93. a toothed plate; 94. a crank; 95. a slide bar; 96. fixing a sleeve; 10. a connecting mechanism; 101. a first gear; 102. a second gear; 103. a first shaft; 104. a second shaft; 105. a first connecting rod; 106. a second connecting rod; 107. a support plate; 11. a feeding plate; 12. and (4) a bracket.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, a nanomaterial transfer buffer device includes a machine table 1, a connecting plate 2 is fixedly connected to the left side of the machine table 1, a circulating mechanism 9 is arranged on the surface of the connecting plate 2, a connecting mechanism 10 is arranged on the upper surface of the machine table 1, a pedestal 5 is fixedly connected to the upper surface of the machine table 1, an adjusting mechanism 6 is arranged on the upper surface of the pedestal 5, a seat cover 7 is arranged at the top of the adjusting mechanism 6, a transmission buffer mechanism 8 is arranged inside the seat cover 7, a baffle 3 is slidably connected inside the machine table 1, and a base 4 is fixedly connected to the surface of the baffle 3.

In this embodiment, rear portion fixedly connected with support 12 of board 1, the welding of the top of support 12 has feed plate 11, and the right side of feed plate 11 and the surface of baffle 3 contact each other.

Through the design of feed plate 11, can place the nano-material above that to the automatic feeding of control material need not the manual work and carries out the material loading, reduce cost, and base 4 rises, and baffle 3 also can rise this moment, keeps off on the surface of feed plate 11, carries out the material and cuts extremely, and then plays the material blocking effect to feed plate 11 positions, and the outflow of restriction material avoids the condition that the material scatters and drops.

Further, the adjusting mechanism 6 comprises a double screw 61, a movable plate 64 is screwed on the surface of the double screw 61, an upper plate 63 and a lower plate 62 are respectively rotatably connected on the surface of the movable plate 64, the upper plate 63 is positioned above the lower plate 62, the bottom of the lower plate 62 and the top of the upper plate 63 are respectively rotatably connected on the upper surface of the pedestal 5 and the bottom of the seat cover 7, and the surface of the double screw 61 is rotatably connected inside the pedestal 5.

Through the effect of twin-screw 61, fly leaf 64 carries out relative motion, and then control seat cover 7 and conveying buffer gear 8's whole effect that rises, realizes the conveying to different height positions to improve the whole commonality and the suitability of equipment.

Furthermore, two movable plates 64 are provided, and the two movable plates 64 are symmetrically distributed with the center line of the pedestal 5 as the symmetry axis, half of the surface of the double screw 61 is a positive screw thread, and half is a negative screw thread, and the rack 65 is fixedly connected to the left side of the seat cover 7.

Through two kinds of screw threads that revolve to, just can realize realizing the effect of going up and down to the relative movement of fly leaf 64, control the not nano-material transfer operation of co-altitude, improve equipment's holistic practicality.

In addition, a material pouring gear 66 is engaged with the surface of the rack 65, a fixed shaft 68 is fixedly connected to the axis of the material pouring gear 66, a material feeding box 67 is fixedly connected to the surface of the fixed shaft 68, a plurality of barrier strips 69 are fixedly connected to the upper surface of the material feeding box 67, and the surface of the fixed shaft 68 is rotatably connected to the upper surface of the base 4.

Utilize the gear 66 of falling to expect when rising along with base 4, the rising of the gear 66 of falling expects during with rack 65 meshing rotation, will drive the rotation of feeding case 67, will pour the inside nanometer material upset of feeding case 67 into the upper surface of conveying buffer gear 8 to the realization is to the automatic material effect of falling of material, need not the manual work and operates simple and convenient.

Besides, the conveying buffer mechanism 8 comprises a fixed box 81, the front part of the fixed box 81 is connected with a servo motor 82 through a bolt, the output end of the servo motor 82 is fixedly connected with a driving rod 83, the surface of the driving rod 83 is fixedly connected with a driving roller 85, the surface of the driving roller 85 is in transmission connection with the surface of the driving roller 86 through a conveying belt 84, the axis of the driving roller 86 is rotatably connected to the surface of the fixed box 81 through a shaft rod, a feeding device 87 is arranged inside the conveying belt 84, and the surface of the fixed box 81 is welded to the surface of the seat cover 7.

When the servo motor 82 rotates, the conveyor belt 84 is driven to rotate and convey under the action of the driving roller 85, so that the nano material is conveyed, the automatic transfer conveying effect of the nano material is realized, and the whole conveying efficiency is improved.

It is worth noting, feed arrangement 87 is including the flitch 871, the both sides fixedly connected with cardboard 876 of flitch 871, cardboard 876 is located the inside of conveyer belt 84, the inside sliding connection of fixed case 81 has traveller 873, spring 874 has been cup jointed on the surface of traveller 873, the top fixedly connected with smooth ball 875 of traveller 873, the equal fixedly connected with limiting plate 872 in both sides of flitch 871, limiting plate 872 is located the top of cardboard 876, the spout has been seted up to the bottom of limiting plate 872, the surface sliding connection of flitch 871 is in the inside of conveyer belt 84.

When the conveying to the material, the spring 874 has been cup jointed on the traveller 873 surface, and when the material poured the conveyer belt 84 above, flitch 871 received the action of gravity of material, can drive flitch 871 and sink, and spring 874 plays fine cushioning effect, reduces the material damage that the material caused in the transportation, improves the whole integrity of material.

Example 2

Referring to fig. 7-8, based on embodiment 1, in this embodiment, the circulating mechanism 9 includes a connecting gear 91, a toothed plate 93 is engaged with a surface of the connecting gear 91, the surface of the toothed plate 93 is slidably connected inside the machine 1, a fixing sleeve 96 is fixedly connected to a left side of the toothed plate 93, a sliding rod 95 is slidably connected inside the fixing sleeve 96, a crank 94 is fixedly connected to a right end of the sliding rod 95, a rotating motor 92 is fixedly connected to a left side of the connecting plate 2, an output end of the rotating motor 92 is fixedly connected to a left side of the crank 94, and a surface of the connecting gear 91 is rotatably connected to an upper surface of the machine 1.

The rotation of the crank 94 is controlled by the rotation of the rotating motor 92, and the crank 94 rotates to drive the slide bar 95 to rotate, so as to drive the base 4 to operate without intermittence from top to bottom, thereby realizing the effect of circular feeding and further improving the overall transfer conveying efficiency.

In this embodiment, the connecting mechanism 10 includes a first shaft 103 and a second shaft 104, a first connecting rod 105 is fixedly connected to the surfaces of the first shaft 103 and the second shaft 104, a second connecting rod 106 is rotatably connected to the surface of the first connecting rod 105, a supporting plate 107 is rotatably connected to the inside of the second connecting rod 106 through a shaft rod, the top of the supporting plate 107 is fixedly connected to the bottom of the base 4, a first gear 101 is fixedly connected to one end of the first shaft 103, the other end of the first shaft 103 is fixedly connected to the axis of the connecting gear 91, a second gear 102 is engaged with the surface of the first gear 101, the axis of the second gear 102 is fixedly connected to the surface of the second shaft 104, and the surface of the second shaft 104 is rotatably connected to the upper.

Through the meshing effect of the two bevel gears, the folding ascending of the first connecting rod 105 and the second connecting rod 106 is controlled, so that the integral ascending and descending effect of the whole base 4 is achieved, the automatic material ascending and descending effect is achieved, and the nanometer materials can be conveyed in different heights well.

The working principle is that the rotation of the rotary motor 92 is directly controlled, the rotation of the crank 94 is controlled, the rotation of the crank 94 drives the rotation of the sliding rod 95, the sliding rod 95 slides in the fixing sleeve 96, the fixing sleeve 96 is driven to circularly slide left and right, the rotation of the toothed plate 93 is further driven, the toothed plate 93 slides left and right, the movement of the connecting gear 91, which performs half positive rotation and half negative rotation, is controlled, the rotation speed of the rotary motor 92 is relatively slow, at the moment, the rotation of the connecting gear 91 directly drives the rotation of the first gear 101 through the first shaft 103, the rotation of the first gear 101 through the meshing of the bevel gears drives the rotation of the second shaft 104, the first shaft 103 and the second shaft 104 rotate, through the rotational connection of the first connecting rod 105 and the second connecting rod 106, the up-and-down movement of the base 4 is driven, when the base 4 descends to the lower side of the feeding plate 11, at the moment, the nano, slide down to the top of feed box 67, and then base 4 rises, and baffle 3 also can rise this moment, and then plays the material to feed plate 11 position and blocks the effect, restricts the outflow of material.

In the process that the base 4 continuously rises, when the material pouring gear 66 is meshed with the rack 65 to rotate in the rising process, the feeding box 67 is driven to rotate to pour the nano material in the feeding box 67 to the upper surface of the conveyor belt 84 in a turnover manner, when the servo motor 82 rotates, the conveyor belt 84 is driven to rotate and convey under the action of the driving roller 85 to achieve the effect of conveying the nano material, in the conveying process, a plurality of material plates 871 are arranged on the conveyor belt 84 to divide the material, so that the material is prevented from being stacked and colliding during the conveying process, the material is prevented from being damaged, meanwhile, in the conveying process, the limiting plates 872 at two sides of the material plates 871 pass through the sliding balls 875 on the sliding columns 873, the springs 874 are sleeved on the upper surface of the sliding columns 873, and when the material is poured onto the conveyor belt 84, the material sinking plate 871 is driven to drive the material plates 871 under the action of, when sinking, it sinks to drive traveller 873, and spring 874 plays fine cushioning effect, reduce the material damage that the material caused in the transportation process, and the material of flitch 871 is the rubber buffer material who also adopts, further reduced nano-material's transportation damage, improve the whole complete degree of material, and the height of conveying can be through the rotation of manual control twin-screw 61, two fly leaf 64 are through the effect of the twin-screw 61 of two-way screw thread, relative motion carries out, and then control seat cover 7 and conveying buffer gear 8's whole effect that rises, realize the conveying to different height positions, improve the whole commonality and the suitability of equipment.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.