CN220685336U - Material collecting mechanism of ultra-short fiber cutting machine - Google Patents

Abstract

The utility model relates to an ultrashort fiber cutter mechanism that gathers materials belongs to fiber cutter technical field, and it includes discharging pipe, collecting hopper and to the blast apparatus that the discharging pipe is inside to be bloied, the discharging pipe with the collecting hopper is connected, blast apparatus includes the blowing pipe and provides the high-pressure air supply of high-pressure gas for the blowing pipe, the blowing pipe sets up at least one, set up on the discharging pipe and supply the blowing pipe to blow in the discharging pipe the blast hole of high-pressure gas, the quantity of blast hole with the quantity of blowing pipe is unanimous. The application has the effect of blowing off agglomerated filaments.

Description

Material collecting mechanism of ultra-short fiber cutting machine

Technical Field

The application relates to the field of fiber cutting machines, in particular to an aggregate mechanism of an ultra-short fiber cutting machine.

Background

The fiber cutting machine is a cutting device for textile fiber products, and can cut off various textile fiber products according to different requirements, so as to meet the requirements of people on materials.

The utility model provides an ultrashort fiber cutter, the structure of ultrashort fiber cutter is one kind of fiber cutter, ultrashort fiber cutter is copper clamping ring slope design, the fiber silk bundle is through rotatory ball hub area to the copper clamping ring low point department of slope press to the blade department of placing horizontally below to cut off the silk bundle, the fiber silk after cutting off is thrown to the mechanism that gathers materials that is located its below through rotatory blade disc in, gather materials the mechanism and include funnel-shaped collecting hopper and the discharging pipe of being connected with the collecting hopper, the discharging pipe is connected with the funnel neck one end of collecting hopper, the discharging pipe is located the below of collecting hopper, the fiber silk in the collecting hopper falls into its below conveyor through the discharging pipe and supplies follow-up even packing.

With respect to the related art described above, the inventors considered that the cut filaments easily agglomerate in the hopper due to the characteristics of part of the filaments themselves, affecting the subsequent packing.

Disclosure of Invention

In order to disperse agglomerated fiber filaments, the present application provides an ultra-short fiber cutter aggregate mechanism.

The application provides an ultrashort fiber cutter mechanism that gathers materials adopts following technical scheme:

the utility model provides an ultrashort fiber cutter mechanism that gathers materials, includes discharging pipe, collecting hopper and to the blast apparatus that the discharging pipe is inside to be bloied, the discharging pipe with the collecting hopper is connected, blast apparatus includes the blowing pipe and provides the high-pressure air supply of high-pressure gas for the blowing pipe, the blowing pipe sets up at least one, set up on the discharging pipe and supply the blowing pipe to blow in the discharging pipe the blast hole of high-pressure gas, the quantity of blast hole with the quantity of blowing pipe is unanimous.

Through adopting above-mentioned technical scheme, when the cellosilk that takes place the agglomeration in the collecting hopper when the discharging pipe, the blowpipe blows off high-pressure gas in to the discharging pipe and blows off the cellosilk that the agglomeration of passing through the discharging pipe for the cellosilk that the cellosilk group became even before falling into conveyor, convenient follow-up packing.

Optionally, the discharging pipe is the pipe, the blowing pipe sets up three, the blowing hole has seted up three, three the blowing hole is followed the periphery wall evenly distributed of discharging pipe, three the blowing pipe one-to-one cartridge is in three in the blowing hole.

Through adopting above-mentioned technical scheme, when the cellosilk that takes place the reunion passes through the discharging pipe, the cellosilk is blown off it by the high-pressure gas of a plurality of positions, better to the cellosilk blow off, three blowhole is along the periphery wall evenly distributed of discharging pipe simultaneously, three blowpipe is same along the periphery wall evenly distributed of discharging pipe promptly, the direction of every blowpipe direct blowing does not have the influence of the high-pressure gas that other blowpipes blown off, the cellosilk after breaking up is more even at the intraductal distribution of discharging, further convenient subsequent packing.

Optionally, the blast apparatus further includes a blast pipe and a distributing pipe, one end of the blast pipe is connected with the high pressure air source, the other end of the blast pipe is connected with one end of the distributing pipe, the distributing pipe is communicated with three blast pipes, one of the blast pipes is connected with one end of the distributing pipe far away from the blast pipe, and the distributing pipe is bent into a fan ring shape along the peripheral wall of the discharging pipe.

Through adopting above-mentioned technical scheme, compare in three blowpipes and be connected with high-pressure air source respectively, reduced the quantity that is used for sending into the conveyer pipe in the discharging pipe with high-pressure air, effectually improved the succinct degree of the near environment of discharging pipe, reduced the space occupation near the discharging pipe.

Optionally, the blowing device further comprises a blast pipe and a distributing pipe, one end of the blast pipe is connected with the high-pressure air source, the distributing pipe is connected with three blowing pipes, the distributing pipe is communicated with three blowing pipes, and the distributing pipe is formed into an annular shape which is connected end to end along the peripheral wall of the discharging pipe and is communicated end to end.

Through adopting above-mentioned technical scheme, compare in three blowpipes and be connected with high-pressure air source respectively, reduced the quantity that is used for sending into the conveyer pipe in the discharging pipe with high-pressure air, effectually improved the succinctness of the nearby environment of discharging pipe, reduced the space occupation near the discharging pipe, the distributing pipe forms the cyclic annular of a head and the tail intercommunication along the periphery wall of discharging pipe simultaneously for the wind through the distributing pipe forms a circulation, makes the wind speed that three blowpipes blown out comparatively even.

Optionally, the distributing pipe comprises three distributing sub-pipes and a three-way connector, two adjacent sections of the distributing sub-pipes are connected through the three-way connector, and the blowpipe is communicated with the distributing sub-pipes through the three-way connector.

Through adopting above-mentioned technical scheme for the distribution pipe is assembled by several distribution sub-pipes, and the installation of convenient distribution pipe, and two adjacent distribution sub-pipes pass through three way connection and connect, make only need dismantle the one section of distribution sub-pipe of damage when damage appears in a section of distribution sub-pipe and change, and then make more convenient when maintaining.

Optionally, the discharging pipe is connected the one end of collecting hopper is provided with first ring flange, the collecting hopper is connected the one end of discharging pipe is provided with the second ring flange, the second ring flange with first ring flange passes through hexagonal bolt connection, blast apparatus still includes the installed part, the installed part is the connecting rope, connecting rope one end centre gripping in the spiral shell head of hexagonal bolt with between the second ring flange, the connecting rope other end with the distributing pipe is connected.

Through adopting above-mentioned technical scheme, be connected first ring flange and second ring flange through the hex bolts, and then realize being connected between discharging pipe and the collecting hopper for be convenient for change when discharging pipe damages, improve the firmness of distributing pipe installation through the connecting piece, connect the rope and press from both sides tightly by hex bolts's spiral shell head and second ring flange and realize fixedly, make the installation of connecting the rope comparatively convenient, the distributing pipe is connected with connecting the rope, on the one hand makes more convenient when connecting, on the other hand changes more conveniently when the distributing pipe damages.

Optionally, the discharging pipe is connected the one end of collecting hopper is provided with first ring flange, the collecting hopper is connected the one end of discharging pipe is provided with the second ring flange, the second ring flange with first ring flange passes through hexagon bolt connection, blast apparatus still includes the installed part, the installed part is thin billet, thin billet one end centre gripping in hexagon bolt's spiral shell head with between the second ring flange, thin billet other end bending type has the bearing the bent pin of distributing pipe.

Through adopting above-mentioned technical scheme, the discharging pipe passes through hexagonal bolt with first ring flange and second ring flange with the collecting hopper and is connected for be convenient for change when the discharging pipe damages, thin billet one end is pressed from both sides tightly with the second ring flange by hexagonal bolt's spiral shell head and is realized fixedly, improves the firmness of distributing pipe installation through the connecting piece, makes the installation of thin billet comparatively convenient, and thin billet other end is through accomplishing the formation bent foot, and the distributing pipe passes through the bearing of bent foot and connects on the discharging pipe, makes more convenient when distributing pipe is connected.

Optionally, the discharging pipe is connected the one end of collecting hopper is provided with first ring flange, the collecting hopper is connected the one end of discharging pipe is provided with the second ring flange, the second ring flange with first ring flange passes through hexagonal bolt connection, blast apparatus still includes the installed part, the installed part include the sleeve and with the bearing hook that the distribution pipe is connected, the bearing hook set up in on the sleeve, the sleeve suit in on hexagonal bolt's the spiral shell head, sleeve interference suit in on hexagonal bolt's the spiral shell head.

Through adopting above-mentioned technical scheme, discharging pipe and collecting hopper pass through hexagonal bolt with first ring flange and second ring flange are connected for be convenient for change when discharging pipe damages, sleeve interference is installed on hexagonal bolt's spiral shell head, and then do not influence the connection stability of ring flange itself, fix the bearing hook on the sleeve, the distribution pipe obtains the bearing of bearing hook, make the bearing of distribution pipe installation more firm, only need demolish the sleeve when bearing hook damages and change, need not become flexible hexagonal bolt, the stability that discharging pipe and collecting hopper are connected has been improved.

Optionally, the blowing pipe is inclined toward the direction of the collecting hopper at one end of the blowing pipe.

Through adopting above-mentioned technical scheme, the one end that the blowing pipe was sent air to the discharging pipe is bloied towards the direction slope of collecting hopper, exerts an ascending wind-force of slope to it when blowing off the cellosilk that gathers, makes take place to paste on the inner wall of discharging pipe under the effect of high-pressure gas after the cellosilk that gathers blows off not easily.

Optionally, the blowing device further comprises a blast pipe, one end of the blast pipe is connected with the high-pressure air source, the other end of the blast pipe is used for blowing air into the blast pipe, and a flow control valve is arranged on the blast pipe.

Through adopting above-mentioned technical scheme, the flow size of the high-pressure gas that the blowing pipe blown out can be controlled in the setting of flow control valve, can be according to the cellosilk state that falls, constantly adjusts the flow size of high-pressure gas to more suitable state, reasonable regulation and control reduces unnecessary energy consumption, more green energy-conservation.

In summary, the present application includes at least one of the following beneficial technical effects:

the fiber clusters passing through the discharge pipe are blown by the blowing device, so that the fiber clusters are blown away to form uniform fiber yarns, and the subsequent packaging of the fiber yarns is facilitated;

the three blowpipes are evenly distributed along the peripheral wall of the discharging pipe, so that the air blown by the three blowpipes forms a convection, and the effect of blowing away the fiber clusters is better.

Drawings

Fig. 1 is a schematic structural view of an aggregate mechanism of an ultra-short fiber cutter in an embodiment of the present application.

Fig. 2 is a schematic diagram of a connection structure of the aggregate mechanism in the embodiment of the present application.

Fig. 3 is a schematic view of the mounting structure of the blower device in the embodiment of the present application.

Fig. 4 is a sectional view of a mounting structure of the blower device in the embodiment of the present application.

Fig. 5 is a sectional view of a mounting structure of a blower according to another embodiment of the present application.

Fig. 6 is a schematic view of a connection structure of a first distribution sub-pipe of the present application.

Fig. 7 is a schematic view of a connection structure of a second distribution sub-pipe of the present application.

Fig. 8 is a schematic view of a connection structure of a third distribution sub-pipe of the present application.

Reference numerals illustrate: 1. a discharge pipe; 11. a first flange; 12. a blowing hole; 2. a blowing device; 21. a high pressure air source; 22. an air supply pipe; 23. a flow control valve; 24. a dispensing tube; 241. dispensing the sub-tubes; 242. a three-way connector; 243. a two-way connector; 244. a three-way pipe; 25. a blowing pipe; 26. a mounting member; 261. a sleeve; 2611. a support hook; 262. a connecting rope; 263. a thin steel bar; 2631. bending the feet; 3. a collecting hopper; 31. a second flange; 32. a hexagonal bolt.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-8.

The embodiment of the application discloses an ultra-short fiber cutter aggregate mechanism. Referring to fig. 1, the collecting mechanism of the ultra-short fiber cutting machine comprises a collecting hopper 3, a discharging pipe 1 positioned below the collecting hopper 3 and a blowing device 2 for conveying high-pressure gas into the discharging pipe 1.

Referring to fig. 1 and 2, in order to facilitate the processing of the tapping pipe 1 in the present embodiment, it is preferable that the tapping pipe 1 is a circular pipe. One end of the discharging pipe 1 connected with the collecting hopper 3 is integrally connected with a first flange plate 11. The collecting hopper 3 is used for receiving the cellosilk that goes out through blade cut-off processing, for better gathering the cellosilk, and in this embodiment, collecting hopper 3 is the funnel form, and the one end an organic whole of collecting hopper 3 funnel neck is connected with second ring flange 31, and first ring flange 11 passes through hexagonal bolt 32 with second ring flange 31 to be connected, and the spiral shell head of hexagonal bolt 32 is located on the second ring flange 31.

Referring to fig. 3, the blowing device 2 includes a high pressure air source 21, an air supply pipe 22, a distribution pipe 24, and a blowing pipe 25, and the high pressure air source 21 may be an air pump or an ultra-high pressure centrifugal blower, and in this embodiment, is preferably an air pump. One end of the air supply pipe 22 is connected with the high-pressure air source 21, and the other end of the air supply pipe 22 is connected with the distributing pipe 24.

Referring to fig. 3 and 4, the distribution pipe 24 forms an annular channel for high-pressure gas flowing end to end along the peripheral wall of the discharge pipe 1, and the distribution pipe 24 is sleeved on the discharge pipe 1. The distributing pipe 24 includes three distributing sub-pipes 241, three-way pipes 244 and three-way connectors 242, in this embodiment, three distributing sub-pipes 241 are communicated with each other through the three-way connectors 242, and blowpipes 25 are installed at the remaining ports of each three-way connector 242, obviously, in this embodiment, three blowpipes 25 are installed at the three-way connectors 242 in a one-to-one correspondence.

Meanwhile, one of the distribution sub-pipes 241 is communicated with one end, far away from the high-pressure air source 21, of the air supply pipe 22 through a three-way pipe 244, and the flow control valve 23 is arranged on the air supply pipe 22, so that high-pressure air is sent into the air supply pipe 22 through the high-pressure air source 21, the high-pressure air is further sent into the distribution pipe 24, and the distribution sub-pipes 241 respectively send the high-pressure air into the three air blowing pipes 25.

The discharging pipe 1 is provided with the blowing holes 12 with the same number as the blowing pipes 25, the three blowing holes 12 are uniformly arranged along the circumferential direction of the peripheral wall of the discharging pipe 1, and the three blowing holes 12 penetrate through the outer wall of the collecting hopper 3 along the radial direction of the discharging pipe 1. One end of each of the three blowing pipes 25 is inserted into the discharging pipe 1 through the corresponding blowing holes 12, high-pressure gas is blown into the feeding pipe through the blowing pipes 25, and one end of each of the blowing pipes 25 inserted into the discharging pipe 1 can extend along the radial direction of the discharging pipe 1 and also can extend obliquely towards the direction of the collecting hopper 3.

When the three blowing pipes 25 blow high-pressure gas in the radial direction of the discharge pipe 1, the high-pressure gas blown out from the three blowing pipes 25 forms convection, and the agglomerated fiber filaments are more easily blown away in a state in which the high-pressure gas blown out from the three blowing pipes 25 forms convection.

When three blowpipes 25 are inserted into the blowholes 12 and then are inclined towards the direction of the collecting hopper 3 for blowing, the three blowpipes 25 apply an upward inclined wind force to the agglomerated fiber yarns while blowing off the agglomerated fiber yarns, so that the agglomerated fiber yarns are not easy to be stuck to the inner wall of the discharging pipe 1 under the action of high-pressure gas after being blown off.

Referring to fig. 3 and 5, in another embodiment, the distribution pipe 24 is bent into a fan shape along the outer peripheral wall of the tapping pipe 1, and the distribution pipe 24 is not connected end to end. The dispensing tube 24 includes a dispensing sub-tube 241, a tee 244, a tee connector 242, and a two-way connector 243. In this embodiment, two distribution sub-pipes 241 are provided, the two distribution sub-pipes 241 are communicated through a three-way connector 242, a blowing pipe 25 is installed at the other port of the three-way connector 242, the remaining port of one distribution sub-pipe 241 is communicated with the blowing pipe 22 through a three-way pipe 244, a blowing pipe 25 is installed at the remaining port of the three-way pipe 244, and the other distribution sub-pipe 241 is communicated with the blowing pipe 25 through a two-way connector 243.

Referring to fig. 6, the blowing apparatus 2 further includes a mounting member 26, the mounting member 26 including a sleeve 261 and a support hook 2611, the support hook 2611 being welded to an outer wall of the sleeve 261. The sleeve 261 is installed on the screw head of the hexagonal bolt 32 in an interference mode, the supporting hooks 2611 bend towards the outer wall direction of the discharging pipe 1, and the distribution sub-pipe 241 enables the distribution sub-pipe 241 to be limited under the action of gravity through the supporting of the supporting hooks 2611 and cannot fall.

Referring to fig. 7, the mounting member 26 may be a connection rope 262, and when the mounting member 26 is the connection rope 262, one end of the mounting member 26 is clamped between the screw head of the hexagonal bolt 32 and the second flange 31, and the other end of the mounting member 26 is connected with the dispensing sub-pipe 241 in a binding manner.

Referring to fig. 8, the mounting member 26 may be a thin steel bar 263, and when the mounting member 26 is the thin steel bar 263, one end of the mounting member 26 is bent to form an arc shape, sleeved on the screw of the hexagonal bolt 32, and clamped between the screw head of the hexagonal bolt 32 and the second flange 31. The other end of the mounting piece 26 is bent with a bending foot 2631 for supporting the distributing pipe 24, the bending foot 2631 is bent towards the outer wall of the discharging pipe 1, and the distributing pipe 24 is placed in the bending foot 2631 and supported by the bending foot 2631.

The embodiment of the application provides an implementation principle of an ultra-short fiber cutter aggregate mechanism, which comprises the following steps: when the fiber yarn which is subjected to cutting and then is positioned in the collecting hopper 3 and agglomerated passes through the discharging pipe 1, the blowing pipe 25 inserted in the discharging pipe 1 is used for blowing the fiber mass, so that the agglomerated fiber yarn is blown away for subsequent packaging.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (10)

1. An ultrashort fiber cutter mechanism that gathers materials, its characterized in that: including discharging pipe (1), collecting hopper (3) and blow device (2) to blowing in discharging pipe (1), discharging pipe (1) with collecting hopper (3) are connected, blow device (2) include blowing pipe (25) and provide high-pressure air supply (21) of high-pressure gas for blowing pipe (25), blowing pipe (25) set up at least one, set up on discharging pipe (1) supply blowing pipe (25) to blow in high-pressure gas's blowhole (12) in discharging pipe (1), the quantity of blowhole (12) with the quantity of blowing pipe (25) is unanimous.

2. The ultra-short fiber cutter aggregate mechanism of claim 1, wherein: the discharging pipe (1) is a round pipe, three blowing pipes (25) are arranged, three blowing holes (12) are formed, the three blowing holes (12) are uniformly distributed along the peripheral wall of the discharging pipe (1), and the three blowing pipes (25) are inserted in the three blowing holes (12) in a one-to-one correspondence mode.

3. The ultra-short fiber cutter aggregate mechanism of claim 2, wherein: the blowing device (2) further comprises a blowing pipe (22) and a distributing pipe (24), one end of the blowing pipe (22) is connected with the high-pressure air source (21), the other end of the blowing pipe (22) is connected with one end of the distributing pipe (24), the distributing pipe (24) is communicated with three blowing pipes (25), one of the blowing pipes (25) is connected with one end, away from the blowing pipe (22), of the distributing pipe (24), and the distributing pipe (24) is bent into a fan ring shape along the peripheral wall of the discharging pipe (1).

4. The ultra-short fiber cutter aggregate mechanism of claim 2, wherein: the blowing device (2) further comprises a blowing pipe (22) and a distributing pipe (24), one end of the blowing pipe (22) is connected with the high-pressure air source (21), the distributing pipe (24) is connected with three blowing pipes (25), the distributing pipe (24) is communicated with the three blowing pipes (25), and the distributing pipe (24) is formed into an annular shape which is connected end to end along the peripheral wall of the discharging pipe (1) and is communicated end to end.

5. The ultra-short fiber cutter aggregate mechanism of claim 4, wherein: the distributing pipe (24) comprises three distributing sub-pipes (241) and a three-way connector (242), two adjacent sections of the distributing sub-pipes (241) are connected through the three-way connector (242), and the blowing pipe (25) is communicated with the distributing sub-pipes (241) through the three-way connector (242).

6. The ultra-short fiber cutter aggregate mechanism of claim 3, wherein: the utility model discloses a discharging pipe, including discharging pipe (1), collecting hopper (3), connecting rope (262) one end be provided with first ring flange (11), collecting hopper (3) are connected the one end of discharging pipe (1) is provided with second ring flange (31), second ring flange (31) with first ring flange (11) are connected through hex bolts (32), blast apparatus (2) still include installed part (26), installed part (26) are connecting rope (262), connecting rope (262) one end centre gripping in the spiral shell head of hex bolts (32) with between second ring flange (31), connecting rope (262) other end with distributing pipe (24) are connected.

7. The ultra-short fiber cutter aggregate mechanism of claim 3, wherein: the utility model discloses a blowing device, including discharging pipe (1), collecting hopper (3), blowing device (2), distributing pipe (24), discharging pipe (1), collecting hopper (3) are connected the one end of discharging pipe (1) is provided with first ring flange (11), second ring flange (31) with first ring flange (11) are connected through hexagon bolt (32), blast device (2) still includes installed part (26), installed part (26) are thin billet (263), thin billet (263) one end centre gripping in the spiral shell head of hexagon bolt (32) with between second ring flange (31), thin billet (263) other end bending type has support bent pin (2631) of distributing pipe (24).

8. The ultra-short fiber cutter aggregate mechanism of claim 3, wherein: the utility model discloses a blowing device, including discharging pipe (1), distributing pipe (24), discharging pipe (1), supporting hook (2611) set up in on sleeve (261), sleeve (261) suit in on the screw head of hex bolts (32), sleeve (261) interference suit in on the screw head of hex bolts (32), discharging pipe (1) connect the one end of collecting hopper (3) is provided with first ring flange (11), collecting hopper (3) connect second ring flange (31) with first ring flange (11) are connected through hex bolts (32), blast apparatus (2) still include installed part (26), installed part (26) include sleeve (261) and with supporting hook (2611) that distributing pipe (24) are connected.

9. The ultra-short fiber cutter aggregate mechanism of claim 1, wherein: one end of the blowing pipe (25) which feeds air to the discharging pipe (1) is inclined towards the direction of the collecting hopper (3).

10. The ultra-short fiber cutter aggregate mechanism of claim 1, wherein: the blowing device (2) further comprises a blowing pipe (22), one end of the blowing pipe (22) is connected with the high-pressure air source (21), the other end of the blowing pipe (22) is provided with a blowing pipe (25) for blowing air, and the blowing pipe (22) is provided with a flow control valve (23).