CN112047064B - Disc type single-shot detonator shell sequencing device and sequencing and lifting integrated equipment - Google Patents

Abstract

The invention discloses a disc type single-shot detonator shell sorting device which comprises a rack, wherein a vibration disc is arranged on the rack, a material outlet of the vibration disc is provided with a discharging guide rail, a plurality of discharging channels for containing detonator shells are arranged on the discharging guide rail, and the discharging channels are used for taking the detonator shells away from the vibration disc. The invention also discloses a lifting chain arranged beside the storage device, wherein the lifting chain is arranged obliquely upwards, a plurality of accommodating parts for accommodating detonator shells entering from the storage device are arranged on the lifting chain, and the lifting chain is used for lifting the detonator shells. The invention solves the defects of time and labor waste, low working efficiency, potential safety hazard, difficulty in realizing production automation, high production cost and the like in the prior art.

Description

Disc type single-shot detonator shell sequencing device and sequencing and lifting integrated equipment

Technical Field

The invention relates to the technical field of detonator production lines, in particular to a disc type single-shot detonator shell sorting device and a sorting and lifting integrated device.

Background

At present, in the field of detonator production, most manufacturers manually arrange a certain number (usually 50 pieces at a time) of detonator shells into a combined die according to the consistent direction of the tube orifice direction of the detonator shells to sequence the detonator shells, then sequentially fill high explosive and initiating explosive, and finally insert an ignition device to seal and manufacture the detonator. The intensive labor mode is time-consuming and labor-consuming, low in working efficiency, potential safety hazards exist, production automation is not facilitated to be achieved, and the intensive labor mode is separated from a follow-up lifting device, so that the production cost is high.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides a disc type single detonator shell sequencing device and sequencing and lifting integrated equipment, and solves the defects of time and labor waste, low working efficiency, potential safety hazard, inconvenience for realizing production automation, higher production cost and the like in the prior art.

The technical scheme adopted by the invention for solving the problems is as follows:

the disc type single-shot detonator shell sequencing device comprises a rack, wherein a vibrating disc is arranged on the rack, a discharging guide rail is arranged at a material outlet of the vibrating disc, a plurality of discharging channels for containing detonator shells are arranged on the discharging guide rail, and the discharging channels are used for taking the detonator shells away from the vibrating disc.

In the technical scheme, the vibrating disk is used for screening or changing the postures of detonator shells to be sequenced through a series of tracks in the working process of the detonator shells, and then orderly, directionally and neatly arranged and accurately conveyed into the discharging channel of the discharging guide rail. Therefore, the work efficiency of detonator shell sequencing is improved, the personnel operation is greatly reduced, the potential safety hazard is reduced, and the sequencing automation degree is improved.

Preferably, the detonator shell vibration plate further comprises a transition guide rail, wherein a plurality of transition channels with the width gradually narrowed from the width and finally keeping the width matched with the diameter size of the detonator shell are arranged on the transition guide rail, one end of each transition channel is connected with a discharge channel, and the other end of each transition channel extends in the direction far away from the vibration plate.

The transition channel gradually narrows from the width, finally keeps the width matched with the diameter of the detonator tube shell, guides the detonator tube shells to be arranged more orderly, plays a role in gathering, guiding and adjusting the sequenced detonator tube shells, and ensures that the sequencing accuracy of the detonator tube shells is higher.

Preferably, still include collection wheel, the collection wheel mount pad of vertical setting, the collection wheel is installed on the collection wheel mount pad, and the collection wheel can rotate, and the one end that vibration dish was kept away from to ejection of compact channel is close to the collection wheel, the collection wheel includes a plurality of interval distribution's collection piece, the circumference annular distribution of collection piece along the collection wheel, the interval between two adjacent collection pieces constitutes the chamber of keeping in that holds the detonator tube, ejection of compact channel is used for bringing the detonator tube into the intracavity of keeping in.

A row of detonator shells on the transition guide rail sequentially enters an empty temporary storage cavity of the collecting wheel, after the row of detonator shells completely enter the temporary storage cavity, the collecting wheel rotates by a certain angle, the next empty temporary storage cavity of the collecting wheel is rotated to a set position, and then the detonator shells continue to enter. The detonator shell collection is effectively realized, and the ordering uniformity is kept.

Preferably, the collecting wheel mounting seat comprises an upward convex curved surface, the curved surface is used for extruding detonator shells in a temporary storage cavity at the top of the curved surface in the rotating process of the collecting wheel, and the curved surface is positioned on one side of the collecting wheel in the axial direction.

The collecting wheel rotates for many times, and the detonator tube shell is extruded out of the temporary storage cavity along with the curved surface. The control structure is convenient and quick to operate, convenient to further automate and beneficial to further improving the production efficiency; and be favorable to extruding the detonator tube in proper order step by step, effectively kept the regularity, prevented that a plurality of detonator tubes from leaving the disorder that the chamber of keeping in brings simultaneously.

Preferably, a storage device is arranged outside the collecting wheel and used for preventing the detonator tube shell in the temporary storage cavity from falling and receiving and transferring the detonator tube shell in the temporary storage cavity in the rotating process of the collecting wheel.

Preferably, the material storage device comprises a first baffle and a second baffle which are arranged in parallel, the first baffle and the second baffle are respectively positioned on two sides of the axial direction, one end of the first baffle and one end of the second baffle are connected with a vertical third baffle together, the third baffle is positioned on one side of the radial direction of the collecting wheel, the bottom ends of the first baffle and the second baffle are connected with a bottom plate together, and the bottom plate is positioned on the other side of the radial direction of the collecting wheel; the first baffle, the second baffle and the third baffle are used for preventing the detonator tube shells in the temporary storage cavity from falling in the rotation process of the collecting wheel, and the bottom plate is used for receiving and transferring the detonator tube shells in the temporary storage cavity.

The first baffle, the second baffle and the third baffle effectively prevent the detonator tube shell from falling off along with the rotation process of the collecting wheel, and are also favorable for keeping the regularity of the detonator tube shell, so that the detonator tube shell can smoothly and orderly reach the bottom plate for subsequent operation.

Preferably, the vibration disc further comprises a hopper, and a proximity switch is arranged in the hopper.

With proximity switch setting in the hopper suitable position, proximity switch can effectively respond to and feed back the quantity data of the inside detonator tube of vibration dish, and this is convenient for insert electrical system, is convenient for judge the opportunity of adding the detonator tube automatically, is convenient for further realize automated control.

The utility model provides a contain sequencing promotion integral type equipment of single shot detonator tube sequencing device of disc type, still including locating the other promotion chain of storage device, promote the chain slope and upwards set up, it is used for accomodating the portion of holding of the detonator tube that gets into from storage device to be equipped with a plurality of on the promotion chain, it is used for promoting the detonator tube to promote the chain.

Preferably, the accommodating part comprises an L-shaped plate, and the inner space at the joint of the horizontal part and the vertical part of the L-shaped plate provides a space for accommodating the detonator shell entering from the bottom plate.

The detonator shell enters the accommodating part on the lifting chain from the material storage device, the lifting chain drives the detonator shell to do lifting motion, and the inclined arrangement is favorable for keeping the detonator shell to gradually move in the lifting process so as to keep the orderliness; meanwhile, in the process that the L-shaped plate moves to the top of the lifting chain along with the lifting chain, the vertical part of the L-shaped plate is gradually and stably changed into the horizontal direction, and therefore the detonator shell is smoothly placed.

Preferably, a horizontally arranged feeding device is arranged beside the top of the lifting chain and used for receiving the detonator shell output from the top of the lifting chain.

The feeding device provides a placing space for the detonator shell so as to be convenient for collection and the next operation.

Compared with the prior art, the invention has the following beneficial effects:

(1) the detonator shell sorting device improves the low work efficiency of detonator shell sorting, greatly reduces the personnel operation, reduces the potential safety hazard, and improves the automation degree of sorting;

(2) the transition channel guides the detonator shells to be arranged more orderly, so that the sequenced detonator shells have the functions of gathering, guiding and adjusting, and the sequencing accuracy of the detonator shells is higher;

(3) the detonator shell collecting device effectively realizes the collection of detonator shells and keeps the ordering uniformity;

(4) the control structure of the invention is convenient and fast to operate, and is beneficial to further improving the production efficiency;

(5) the first baffle, the second baffle and the third baffle effectively prevent the detonator shell from falling off in the rotating process of the collecting wheel, and are also beneficial to keeping the orderliness of the detonator shell, so that the detonator shell can smoothly and orderly reach the bottom plate for subsequent operation;

(6) the invention is simple, convenient and efficient, is convenient to operate and is convenient for further automation,

(7) the invention enables the detonator shell to be smoothly placed on the detonator shell so as to be convenient for collection.

Drawings

FIG. 1 is a schematic structural diagram of a sequencing and lifting integrated device according to the present invention;

FIG. 2 is a second schematic structural view of the sequencing and hoisting integrated device according to the present invention;

FIG. 3 is a schematic structural diagram of the detonator shell sequencing device of the present invention;

FIG. 4 is a schematic structural diagram of a lifting part of the sequencing and lifting integrated device according to the invention;

FIG. 5 is a schematic structural view of the storing device of the invention;

FIG. 6 is one of the enlarged partial views of FIG. 1;

FIG. 7 is a second enlarged view of the portion of FIG. 1;

fig. 8 is a third enlarged view of the portion of fig. 1.

6. The device comprises a vibrating disk, 7, a damping spring, 8, a rack, 9, a transition guide rail, 10, a collecting wheel, 11, a pushing device, 12, a flywheel push block, 13, a collecting wheel mounting seat, 14, a storage device, 15, a lifting chain, 17, a containing part, 18, a feeding transition block, 19, a feeding device, 20, a proximity switch, 31, a discharging guide rail, 32, a detonator shell, 33, a hopper, 34, a discharging channel, 35, a chassis, 36, a transition channel, 101, a collecting block, 102, a temporary storage cavity, 103, a rotating shaft, 121, a clamping arc, 122, a connecting part, 131, a curved surface, 141, a first baffle, 142, a second baffle, 143, a third baffle, 144, a bottom plate, 171 and an L-shaped plate.

Detailed Description

The present invention will be described in further detail with reference to examples and drawings, but the present invention is not limited to these examples.

In the description of the invention, the vibration disk 6 belongs to the prior art, and the invention sequences the disk type single detonator shells, so that the structures of the damping spring 7, the chassis 35, the vibration power device, the hopper 33 and the like are not described in more detail.

Example 1

As shown in fig. 1 to 8, the disc type single-shot detonator shell sorting device comprises a frame 8, wherein a vibrating disc 6 is arranged on the frame 8, a material outlet of the vibrating disc 6 is provided with a discharging guide rail 31, a plurality of discharging channels 34 for accommodating detonator shells are arranged on the discharging guide rail 31, and the discharging channels 34 are used for carrying the detonator shells away from the vibrating disc 6.

When the detonator shell sorting machine is used, detonator shells 32 to be sorted are placed into a hopper 33 of a vibrating disk 6, a vibrating power device drives the vibrating disk 6 to work, the vibrating power device enables the hopper 33 to vibrate in the vertical direction and drives the hopper 33 to do torsional vibration around the vertical axis of the hopper, and disordered detonator shells 32 are screened or changed in posture through a series of tracks in the ascending process and then are orderly, directionally and accurately conveyed into a discharge channel 34 of a discharge guide rail 31. Therefore, the low work efficiency of detonator shell 32 sequencing is improved, the personnel operation is greatly reduced, the potential safety hazard is reduced, and the sequencing automation degree is improved.

Preferably, the detonator shell diameter size-matched transition guide rail structure further comprises a transition guide rail 9, wherein a plurality of transition channels 36 with the width gradually narrowing from the width and finally keeping the width matched with the detonator shell diameter size are arranged on the transition guide rail 9, one end of each transition channel 36 is connected with the discharging channel 34, and the other end of each transition channel 36 extends in the direction away from the vibrating disk 6.

The transition channel 36 gradually narrows from width to width which is finally matched with the diameter of the detonator shell, so that the detonator shells 32 are guided to be arranged more orderly, and the sequenced detonator shells 32 are gathered, guided and adjusted, so that the sequencing accuracy of the detonator shells 32 is higher.

Preferably, the detonator shell temporary storage device further comprises a vertically arranged collecting wheel 10 and a collecting wheel mounting seat 13, wherein the collecting wheel 10 is mounted on the collecting wheel mounting seat 13, the collecting wheel 10 can rotate, one end, far away from the vibrating disk 6, of the discharge channel 34 is close to the collecting wheel 10, the collecting wheel 10 comprises a plurality of collecting blocks 101 distributed at intervals, the collecting blocks 101 are distributed along the circumference of the collecting wheel 10 in an annular mode, a temporary storage cavity 102 for containing a detonator shell is formed by the intervals between every two adjacent collecting blocks 101, and the discharge channel 34 is used for bringing the detonator shell into the temporary storage cavity 102.

A row of detonator shells 32 on the transition guide rail 9 sequentially enter an empty temporary storage cavity 102 of the collecting wheel 10, after the row of detonator shells 32 completely enter the temporary storage cavity 102, the collecting wheel 10 rotates for a certain angle, so that the next empty temporary storage cavity 102 of the collecting wheel 10 rotates to a set position, and then the detonator shells 32 continuously enter. This effectively enables collection of detonator shells 32, maintaining the regularity of the sequencing.

Preferably, the collecting wheel mounting seat 13 includes a curved surface 131 protruding upwards, the curved surface 131 is used for extruding the detonator shell in the temporary storage cavity 102 at the top of the curved surface 131 during the rotation of the collecting wheel 10, and the curved surface 131 is located at one side of the collecting wheel 10 in the axial direction.

The curved surface 131 functions to disengage the detonator shell 32 in the buffer chamber 102 of the collection wheel 10 from the buffer chamber 102 as it passes over the top of the curved surface 131 as the collection wheel 10 rotates. The collecting wheel 10 rotates a plurality of times, and the detonator shell 32 is extruded out of the temporary storage cavity 102 along with the curved surface 131. In actual use, the top of the curved surface 131 and the top of the collecting wheel 10 are arranged on the same horizontal line, and the detonator shell 32 is extruded from the top of the curved surface 131 when passing through the top of the collecting wheel 10. The control structure is convenient and quick to operate, convenient to further automate and beneficial to further improving the production efficiency; and is favorable for extruding the detonator shells 32 step by step, effectively keeps the regularity and prevents the disorder caused by that a plurality of detonator shells 32 leave the temporary storage cavity 102 simultaneously.

In this embodiment, a structure as shown in fig. 1 and 7 is selected, the collecting wheel further includes a flywheel push block 12, the collecting wheel 10 is connected with a rotating shaft 103, the flywheel push block 12 clamps the rotating shaft 103, the flywheel push block 12 is connected with a push device 11, the push device 11 can select an air cylinder, the air cylinder is connected with an air source and an air control device, the flywheel push block 12 includes a clamping arc 121 and a connecting portion 122, the clamping arc 121 clamps the rotating shaft 103, a piston rod of the air cylinder is connected with the connecting portion 122, the flywheel push block 12 clamps the rotating shaft 103, the push device 11 pushes the flywheel push block 12 upwards, the rotation of the collecting wheel 10 is realized through the flywheel push block 12, the collecting wheel 10 rotates for multiple times, and the detonator shell 32 is gradually extruded by the curved surface 131.

Example 2

As shown in fig. 1 to fig. 8, as a further optimization of embodiment 1, this embodiment includes all the technical features of embodiment 1, and in addition, this embodiment also includes the following technical features:

preferably, a storage device 14 is arranged outside the collecting wheel 10, and the storage device 14 is used for preventing detonator shells in the temporary storage cavity 102 from falling off in the rotating process of the collecting wheel 10 and receiving and transferring the detonator shells in the temporary storage cavity 102.

Preferably, the storing device 14 includes a first baffle 141 and a second baffle 142 which are arranged in parallel, the first baffle 141 and the second baffle 142 are respectively located at two sides of the axial direction, one end of the first baffle 141 and one end of the second baffle 142 are connected to a vertical third baffle 143, the third baffle 143 is located at one side of the collecting wheel 10 in the radial direction, the bottom ends of the first baffle 141 and the second baffle 142 are connected to a bottom plate 144, and the bottom plate 144 is located at the other side of the collecting wheel 10 in the radial direction; the first baffle 141, the second baffle 142 and the third baffle 143 are used for preventing the detonator shells in the temporary storage cavity 102 from falling off during the rotation of the collecting wheel 10, and the bottom plate 144 is used for receiving and transferring the detonator shells in the temporary storage cavity 102.

The first baffle 141, the second baffle 142 and the third baffle 143 effectively prevent the detonator shell 32 from falling off in the process of rotating along with the collecting wheel 10, and are also beneficial to keeping the orderliness of the detonator shell 32, so that the detonator shell 32 can smoothly and orderly reach the bottom plate 144 for subsequent operation.

Preferably, the vibrating tray 6 further comprises a hopper 33, and the proximity switch 20 is arranged in the hopper 33.

Set up proximity switch 20 in suitable position in hopper 33, proximity switch 20 can effectively respond to and feed back the quantity data of the inside detonator tube 32 of vibration dish 6, and this access electrical system of being convenient for, the automatic opportunity of judging the interpolation detonator tube 32 of being convenient for is convenient for further realize automated control.

Example 3

As shown in fig. 1 to fig. 8, as a further optimization of the embodiment 2, this embodiment further provides a sequencing and hoisting integrated device including the disc type single detonator shell sequencing device, and this embodiment includes all technical features of the embodiment 2, and in addition, this embodiment includes the following technical features:

the utility model provides a contain sequencing promotion integral type equipment of disc type single shot detonator tube sequencing device, still including locating the other promotion chain 15 of storage device 14, promote chain 15 slope and upwards set up, it is used for accomodating the holding part 17 of the detonator tube that gets into from storage device 14 to be equipped with a plurality of on the promotion chain 15, promote chain 15 and be used for promoting the detonator tube.

Preferably, the receiving portion 17 comprises an L-shaped plate 171, and the inner space at the intersection of the horizontal portion and the vertical portion of the L-shaped plate 171 provides a space for receiving the detonator shell entering from the bottom plate 144.

The detonator shell 32 enters the accommodating part 17 on the lifting chain 15 from the side of the storage device 14, the lifting chain 15 drives the detonator shell 32 to do lifting motion, and the inclined arrangement is favorable for keeping the detonator shell 32 to move gradually in the lifting process so as to keep the regularity; meanwhile, in the process that the L-shaped plate 171 moves to the top of the lifting chain 15 along with the lifting chain 15, the vertical part of the L-shaped plate 171 is gradually and stably changed into the horizontal direction, so that the detonator shell 32 is smoothly placed.

Preferably, a horizontally arranged feeding device 19 is arranged beside the top of the lifting chain 15, and the feeding device 19 is used for receiving detonator shells output from the top of the lifting chain 15.

The feeder 19 provides space for the detonator shell 32 to collect and carry on further operations.

In this embodiment, as a further preferable scheme, a feeding transition block 18 is arranged between the feeding device 19 and the top of the lifting chain 15, and the feeding transition block 18 is higher than the feeding device 19. After the detonator shell 32 passes through the L-shaped plate 171, the detonator shell continues to move along the feeding transition block 18 due to inertia, and then falls into the feeding device 19 from the feeding transition block 18, so that the detonator shell 32 enters the feeding device 19 more smoothly.

As described above, the present invention can be preferably realized.

The foregoing is only a preferred embodiment of the present invention, and the present invention is not limited thereto in any way, and any simple modification, equivalent replacement and improvement made to the above embodiment within the spirit and principle of the present invention still fall within the protection scope of the present invention.

Claims (7)

1. The disc type single detonator shell sequencing device is characterized by comprising a rack (8), wherein a vibrating disc (6) is arranged on the rack (8), a discharging guide rail (31) is arranged at a material outlet of the vibrating disc (6), a plurality of discharging channels (34) for accommodating detonator shells are arranged on the discharging guide rail (31), the discharging channels (34) are used for taking the detonator shells away from the vibrating disc (6), the disc type single detonator shell sequencing device also comprises a transition guide rail (9), a plurality of transition channels (36) with the width gradually narrowed from width and finally kept to be matched with the diameter size of the detonator shells are arranged on the transition guide rail (9), one end of each transition channel (36) is connected with the discharging channel (34), and the other end of each transition channel (36) extends in the direction away from the vibrating disc (6);

the detonator shell collecting device is characterized by further comprising a collecting wheel (10) and a collecting wheel mounting seat (13), wherein the collecting wheel (10) is vertically arranged on the collecting wheel mounting seat (13), the collecting wheel (10) can rotate, one end, far away from the vibrating disc (6), of a discharging channel (34) is close to the collecting wheel (10), the collecting wheel (10) comprises a plurality of collecting blocks (101) distributed at intervals, the collecting blocks (101) are distributed annularly along the circumference of the collecting wheel (10), a temporary storage cavity (102) for containing a detonator shell is formed by the intervals between every two adjacent collecting blocks (101), and the discharging channel (34) is used for bringing the detonator shell into the temporary storage cavity (102);

the collecting wheel mounting seat (13) comprises an upward convex curved surface (131), the curved surface (131) is used for extruding detonator shells in the temporary storage cavity (102) at the top of the curved surface (131) in the rotating process of the collecting wheel (10), and the curved surface (131) is positioned on one side of the collecting wheel (10) in the axial direction.

2. The disc type single shot detonator shell sequencing device of claim 1, wherein a storage device (14) is arranged outside the collection wheel (10), the storage device (14) being used for preventing detonator shells in the temporary storage cavity (102) from falling off during the rotation of the collection wheel (10) and receiving detonator shells in the transfer temporary storage cavity (102).

3. The disc type single detonator shell sequencing device of claim 2, wherein the storage device (14) comprises a first baffle (141) and a second baffle (142) which are arranged in parallel, the first baffle (141) and the second baffle (142) are respectively positioned at two sides of the axial direction, one ends of the first baffle (141) and the second baffle (142) are jointly connected with a vertical third baffle (143), the third baffle (143) is positioned at one side of the radial direction of the collecting wheel (10), the bottom ends of the first baffle (141) and the second baffle (142) are jointly connected with a bottom plate (144), and the bottom plate (144) is arranged at the other side of the radial direction of the collecting wheel (10); the first baffle plate (141), the second baffle plate (142) and the third baffle plate (143) are used for preventing detonator shells in the temporary storage cavity (102) from falling off in the rotation process of the collecting wheel (10), and the bottom plate (144) is used for receiving and transferring the detonator shells in the temporary storage cavity (102).

4. The disc-type single shot cap shell sequencing device of claim 1, wherein the vibratory disc (6) further comprises a hopper (33), and an access switch (20) is arranged in the hopper (33).

5. A sequencing and lifting integrated device comprising the disc type single detonator shell sequencing device of claim 3, further comprising a lifting chain (15) arranged beside the storage device (14), wherein the lifting chain (15) is arranged obliquely upwards, a plurality of accommodating parts (17) used for accommodating detonator shells entering from the storage device (14) are arranged on the lifting chain (15), and the lifting chain (15) is used for lifting the detonator shells.

6. Sequenced lift integrated apparatus as in claim 5 wherein the containment section (17) comprises an L-shaped plate (171), the interior space where the horizontal and vertical sections of the L-shaped plate (171) meet providing a space to receive a detonator shell entering from the bottom plate (144).

7. A sequencing and lifting integrated device according to claim 5, characterized in that a horizontally arranged feeding device (19) is arranged beside the top of the lifting chain (15), and the feeding device (19) is used for receiving detonator shells output from the top of the lifting chain (15).

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