CN215247828U - Automatic material arranging machine for nanocrystalline magnetic cores - Google Patents
Automatic material arranging machine for nanocrystalline magnetic cores Download PDFInfo
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- CN215247828U CN215247828U CN202120624907.0U CN202120624907U CN215247828U CN 215247828 U CN215247828 U CN 215247828U CN 202120624907 U CN202120624907 U CN 202120624907U CN 215247828 U CN215247828 U CN 215247828U
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Abstract
The utility model relates to a pendulum material machine technical field provides automatic pendulum material machine of nanocrystalline magnetic core, including the transport mechanism and the reason material mechanism that set gradually, reason material mechanism sets up the end at transport mechanism, has set gradually card material mechanism and has right the board on the transport mechanism, card material mechanism is used for periodic restriction magnetic core motion, it is used for adjusting the magnetic core upset to right the board, reason material mechanism includes the primary shaft, set up the end at transport mechanism perpendicularly, reason work or material rest, coaxial setting is on the primary shaft, a magnetic core is used for holding, reason work or material rest removes along the axial direction of primary shaft, a magnetic core for receiving a plurality of comes from transport mechanism. Through above-mentioned technical scheme, the problem of artifical cluster material inefficiency among the prior art has been solved.
Description
Technical Field
The utility model relates to a pendulum material machine technical field, it is specific, relate to automatic pendulum material machine of nanocrystalline magnetic core.
Background
Magnetic cores refer to a sintered magnetic metal oxide composed of a mixture of various iron oxides, generally in the shape of a ring. Still need collect the magnetic core after the magnetic core production is come out and put and transport together with the coaxial cluster, present cluster material process generally uses the manual work to put, but consuming time and wasting power, production efficiency is too low.
SUMMERY OF THE UTILITY MODEL
The utility model provides an automatic pendulum material machine of nanocrystalline magnetic core has solved the problem of artifical cluster material inefficiency among the correlation technique.
The technical scheme of the utility model as follows:
a transmission mechanism and a material arranging mechanism which are arranged in sequence, wherein the material arranging mechanism is arranged at the tail end of the transmission mechanism,
the transmission mechanism is sequentially provided with a material clamping mechanism and a righting plate, the material clamping mechanism is used for periodically limiting the movement of the magnetic core, the righting plate is used for adjusting the overturning of the magnetic core,
the material arranging mechanism comprises
A first shaft vertically arranged at the end of the transmission mechanism,
a material arranging frame coaxially arranged on the first shaft and used for accommodating the magnetic core,
the material arranging frame moves along the axial direction of the first shaft and is used for receiving a plurality of magnetic cores from the transmission mechanism.
The transmission mechanism comprises
A belt conveying table is arranged on the upper portion of the frame,
the striker plates are arranged on two sides of the conveying direction of the belt conveying table,
the guide belt is arranged on the belt conveying table and forms an included angle with the conveying direction of the belt conveying table, the striker plate and the guide belt form a first channel,
a second channel arranged on the belt conveying table and communicated with the first channel,
the conveying track is arranged at the tail end of the second channel and inclines downwards along the conveying direction, and the material arranging frame is arranged at the tail end of the conveying track.
The righting plate is arranged at one end, far away from the first channel, of the second channel, and after the magnetic core passes through the righting plate, the contact between the circular end face and the belt conveying table is adjusted to be that the circular face is in contact with the belt conveying table.
The material clamping mechanism is arranged on one side of the second channel close to one end of the first channel,
the material clamping mechanism comprises
A turntable rotatably disposed at one side of the second channel,
and the four support rods are uniformly arranged on the turntable along the radial direction, and two adjacent support rods clamp one magnetic core.
The width of the conveying track is smaller than the diameter of the magnetic core and larger than the thickness of the magnetic core.
Also comprises
A strip-shaped groove is arranged on the first shaft along the axial direction,
the material arranging frame also comprises
A bar-shaped protrusion which is in key fit with the bar-shaped groove,
the accommodating frame is provided with a plurality of partition plates, and every two adjacent partition plates form a gap for accommodating a magnetic core.
The two containing frames are distributed on the first shaft in a central symmetry way,
the first shaft drives the containing frame to rotate or the containing frame and the first shaft synchronously carry out axial movement.
The two accommodating frames are arranged on the first shaft side by side in sequence,
the clapboard is provided with a round through hole communicated with the outside,
the accommodating frame moves back and forth along the axial direction of the first shaft.
Also comprises
The workpiece penetrating rod is arranged on the outer side of the containing frame in a symmetrical mode, the workpiece penetrating rod is coaxial with the circular through hole after rotating, the containing frame moves axially along the first shaft, and the workpiece penetrating rod is inserted into the circular through hole.
The utility model discloses a theory of operation and beneficial effect do:
1. in the utility model, the transmission mechanism is used for transmitting the magnetic core forwards, the magnetic cores are arranged in a line on the transmission mechanism, the posture of the magnetic cores is turned and adjusted through the righting plate, the material clamping mechanism can be matched with the material arranging mechanism, and the magnetic core is temporarily blocked by the material clamping mechanism during the replacement of the material arranging frame; after a row is formed, subsequent material arrangement can be performed more conveniently, the posture of the magnetic core can be adjusted to increase the transmission speed of the magnetic core, and subsequent material stringing can be performed conveniently. The material arranging frame is located at the tail end of the transmission mechanism, the first shaft is perpendicular to the tail end of the transmission mechanism, and the magnetic cores fall into the material arranging frame one by one, so that coaxial arrangement is formed.
Through this scheme, realize automatic messenger's magnetic core and arrange according to the line, and the automatic adjustment position is expected the cluster material in order automatically, can practice thrift a large amount of manual operation.
Drawings
The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.
FIG. 1 is a schematic view of the structure of a belt conveying table of the present invention;
FIG. 2 is an enlarged schematic view of the straightening plate of the present invention;
FIG. 3 is a schematic view of the material clamping mechanism of the present invention;
FIG. 4 is a schematic view of the working state structure of the material clamping mechanism of the present invention;
FIG. 5 is a schematic structural view of a first embodiment of a material arranging mechanism according to the present invention;
fig. 6 is a schematic structural view of a first embodiment of the material arranging frame of the present invention;
FIG. 7 is a schematic structural view of a second embodiment of the material arranging mechanism of the present invention;
fig. 8 is a schematic structural view of a second embodiment of the material arranging frame of the present invention;
in the figure: 1-a belt conveying table, 2-a material baffle plate, 3-a guide belt, 4-a first channel, 5-a second channel, 6-a material clamping mechanism, 7-a righting plate, 8-a conveying track, 10-a first shaft, 11-a material arranging frame, 12-a rotating disc, 13-a supporting rod, 14-a strip-shaped groove, 15-a strip-shaped bulge, 16-a containing frame, 17-a partition plate, 18-a circular through hole and 19-a penetrating rod.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive work, are related to the scope of the present invention.
As shown in fig. 1 to 6, the present embodiment proposes a conveying mechanism and a material arranging mechanism, which are arranged in sequence, the material arranging mechanism is arranged at the tail end of the conveying mechanism,
the transmission mechanism is sequentially provided with a material clamping mechanism 6 and a righting plate 7, the material clamping mechanism 6 is used for periodically limiting the movement of the magnetic core, the righting plate 7 is used for adjusting the overturning of the magnetic core,
the material arranging mechanism comprises
A first shaft 10, arranged vertically at the end of the transport mechanism,
a material arranging frame 11 coaxially arranged on the first shaft 10 and used for accommodating the magnetic core,
the arranging frame 11 moves in the axial direction of the first shaft 10 for receiving a number of magnetic cores from the transport mechanism.
In this embodiment, the transmission mechanism is used for conveying the magnetic cores forwards, the magnetic cores are arranged on the transmission mechanism in a row, the postures of the magnetic cores are turned and adjusted through the righting plate 7, the material clamping mechanism 6 can be matched with the material arranging mechanism, and the magnetic cores are temporarily blocked from being transmitted through the material clamping mechanism 6 when the material arranging frame 11 is replaced; after a row is formed, subsequent material arrangement can be performed more conveniently, the posture of the magnetic core can be adjusted to increase the transmission speed of the magnetic core, and subsequent material stringing can be performed conveniently. The material arranging frame 11 is arranged at the tail end of the transmission mechanism, the first shaft 10 is perpendicular to the tail end of the transmission mechanism, and the magnetic cores fall onto the material arranging frame 11 one by one, so that coaxial arrangement is formed.
Through this scheme, realize automatic messenger's magnetic core and arrange according to the line, and the automatic adjustment position is expected the cluster material in order automatically, can practice thrift a large amount of manual operation.
Further, the transmission mechanism comprises
The belt is conveyed by the belt conveying table 1,
the striker plates 2 are arranged on two sides of the conveying direction of the belt conveying table 1,
a guide belt 3 arranged on the belt conveying table 1 and forming an included angle with the conveying direction of the belt conveying table 1, a first channel 4 is formed by the material baffle plate 2 and the guide belt 3,
a second channel 5 arranged on the belt conveying table 1 and communicated with the first channel 4,
and the conveying track 8 is arranged at the tail end of the second channel 5 and inclines downwards along the conveying direction, and the material arranging frame 11 is arranged at the tail end of the conveying track 8.
In this embodiment, belt conveying platform 1 is used for transmitting the magnetic core to the place ahead, and striker plate 2 is located belt conveying platform 1's both sides, blocks that the material falls, and guide belt 3 is an contained angle with belt conveying platform 1 for the passway of transmission magnetic core reduces, thereby makes the range that the magnetic core can be adjacent one transport forward. The magnetic core changes its posture in the second channel 5 and then slides down the conveyor track 8 into the tidying mechanism.
Further, the righting plate 7 is arranged at one end, far away from the first channel 4, of the second channel 5, and after the magnetic core passes through the righting plate 7, the circular end face is adjusted to be in contact with the belt conveying table 1 through contact of the circular end face and the belt conveying table 1, and the circumference face is adjusted to be in contact with the belt conveying table 1.
In this embodiment, the righting plate 7 and the plane of the conveying table form a variable included angle, so that the width of the channel is reduced, and one side of the magnetic core is supported to realize the posture adjustment.
Furthermore, the material clamping mechanism 6 is arranged at one side of the second channel 5 close to one end of the first channel 4,
the material clamping mechanism 6 comprises
A rotary disc 12 rotatably arranged at one side of the second channel 5,
four supporting rods 13 are uniformly arranged on the rotating disc 12 along the radial direction, and two adjacent supporting rods 13 clamp one magnetic core.
In this embodiment, the number that a reason work or material rest 11 held the magnetic core is as a set of, and card material mechanism 6 constantly rotates in a set of magnetic core transportation, and the magnetic core is stirred by two adjacent branches 13, can not block the transportation of magnetic core, and the space between two sets of can temporary stall, thereby branch 13 stops to block the transportation of the first magnetic core of second group.
Further, the width of the transfer rail 8 is smaller than the diameter of the magnetic core and larger than the thickness of the magnetic core.
In this embodiment, the transfer rail 8 is a passage after the core is attitude-adjusted, and has a small width so as to prevent the core from lying down again.
Further, the first shaft 10 is provided with a strip-shaped groove 14 along the axial direction,
the material arranging frame 11 also comprises
A bar-shaped protrusion 15, which is key-fitted with the bar-shaped groove 14,
the accommodating frame 16 comprises two accommodating frames 16, a plurality of partition plates 17 are arranged on the accommodating frame 16, and a gap is formed between every two adjacent partition plates 17 and used for accommodating one magnetic core.
In this embodiment, the bar-shaped groove 14 on the primary shaft 10 and the bar-shaped protrusion 15 on the material arranging frame 11 are mutually matched, and can be used as a guide rail to enable the material arranging frame 11 to move along the axial direction and also can be used as a rotating shaft to drive the material arranging frame 11 to rotate.
Furthermore, the two accommodating frames 16 are distributed on the first shaft 10 in a central symmetry manner,
the first shaft 10 drives the accommodating frame 16 to rotate or the accommodating frame 16 and the first shaft 10 synchronously perform axial movement.
In this embodiment, in the first embodiment, the accommodating frame 16 is at the end of the conveying track 8, the accommodating frame 16 can rotate around the first shaft 10 and can also move along the first shaft 10, when the first magnetic core falls, the magnetic core falls into a gap which is towards one end of the accommodating frame 16, then the accommodating frame 16 moves horizontally, so that the second magnetic core is towards the second gap of the accommodating frame 16, and the accommodating frame 16 moves horizontally again, and the magnetic cores are sequentially blanked until the accommodating frame 16 is full. After the first containing frame 16 is full, a motor coaxially connected with the first shaft 10 is started to drive the containing frame 16 to rotate, a material receiving box is arranged on one side of the material arranging platform, a magnetic core in the containing frame 16 falls into the material receiving box once to realize batch collection and material mixing, and meanwhile, a second material arranging frame 11 which is in central symmetry with the first containing frame 16 rotates to the tail end close to the conveying track 8 to arrange materials of a second group.
As shown in FIGS. 7 to 8, a second embodiment is proposed, comprising
Two containing racks 16 are arranged side by side in succession on the first shaft 10,
the partition 17 is provided with a circular through hole 18 communicating with the outside,
the accommodating frame 16 moves back and forth in the axial direction of the first shaft 10.
Furthermore, two penetrating rods 19 are symmetrically arranged on the outer sides of the two accommodating frames 16, the penetrating rods 19 are coaxial with the circular through holes 18 after rotating, and the penetrating rods 19 are inserted into the circular through holes 18 after the accommodating frames 16 axially move along the first shaft.
In this embodiment, two accommodating frames 16 are arranged side by side, the first shaft 10 does not need to rotate but serves as a guide rod, when the first accommodating frame 16 is full, the cylinder pushes the accommodating frame 16 to move along the first shaft 10, the second accommodating frame 16 receives a second group of magnetic cores, meanwhile, the partition plate 17 is provided with a circular through hole 18 which is communicated with the outside, so that the magnetic cores can sequentially penetrate through penetrating rods 19 on two sides of the accommodating frame 16, then the penetrating rods 19 rotate towards the direction far away from the accommodating frame 16, rotate out from a gap at the upper end of the circular through hole 18, which is communicated with the outside, take one group of magnetic cores away, rotate to the other side, then the second accommodating frame 16 is discharged and collected, and then the second accommodating frame 16 is full of magnetic cores, and the cylinder is driven to reversely move the accommodating frame 16 until the magnetic cores on the second accommodating frame 16 are sleeved on the penetrating rods 19 on the side; in this way, the material receiving device swings back and forth to receive the material and realize material stringing.
The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.
Claims (9)
1. The automatic material placing machine for the nanocrystalline magnetic core is characterized by comprising
A transmission mechanism and a material arranging mechanism which are arranged in sequence, wherein the material arranging mechanism is arranged at the tail end of the transmission mechanism,
the transmission mechanism is sequentially provided with a material clamping mechanism (6) and a righting plate (7), the material clamping mechanism (6) is used for periodically limiting the movement of the magnetic core, the righting plate (7) is used for adjusting the overturning of the magnetic core,
the material arranging mechanism comprises
A first shaft (10) arranged vertically at the end of the transport mechanism,
a material arranging frame (11) coaxially arranged on the first shaft (10) and used for accommodating a magnetic core,
the material arranging frame (11) moves along the axial direction of the first shaft (10) and is used for receiving a plurality of magnetic cores from the transmission mechanism.
2. The automatic pendulum machine of claim 1, wherein the transport mechanism comprises a mechanism that comprises a magnetic core that is substantially cylindrical in shape and is substantially cylindrical in shape
A belt conveying table (1),
the material blocking plates (2) are arranged at two sides of the conveying direction of the belt conveying table (1),
the guide belt (3) is arranged on the belt conveying table (1) and forms an included angle with the conveying direction of the belt conveying table (1), the striker plate (2) and the guide belt (3) form a first channel (4),
a second channel (5) arranged on the belt conveying table (1) and communicated with the first channel (4),
the conveying track (8) is arranged at the tail end of the second channel (5) and inclines downwards along the conveying direction, and the material arranging frame (11) is arranged at the tail end of the conveying track (8).
3. The automatic pendulum machine of nanocrystalline magnetic core according to claim 2,
the righting plate (7) is arranged at one end, far away from the first channel (4), of the second channel (5), and the magnetic core is adjusted to be in circumferential surface contact with the belt conveying table (1) through the contact of the circular end face and the belt conveying table (1) after passing through the righting plate (7).
4. The automatic swinging machine of the nanocrystalline magnetic core according to claim 2, characterized in that the material clamping mechanism (6) is arranged on one side of the second channel (5) close to one end of the first channel (4),
the material clamping mechanism (6) comprises
A rotary disc (12) which is rotatably arranged at one side of the second channel (5),
and the four support rods (13) are uniformly arranged on the rotating disc (12) along the radial direction, and one magnetic core is clamped by two adjacent support rods (13).
5. The automatic pendulum machine of nanocrystalline magnetic core according to claim 2,
the width of the conveying track (8) is smaller than the diameter of the magnetic core and larger than the thickness of the magnetic core.
6. The automatic pendulum machine of nanocrystalline magnetic core of claim 1, further comprising
A strip-shaped groove (14) is arranged on the first shaft (10) along the axial direction,
the material arranging frame (11) also comprises
A bar-shaped protrusion (15) which is in key fit with the bar-shaped groove (14),
the magnetic core accommodating frame comprises two accommodating frames (16), wherein a plurality of partition plates (17) are arranged on the accommodating frames (16), and a gap is formed between every two adjacent partition plates (17) and used for accommodating one magnetic core.
7. The automatic material arranging machine for the nanocrystalline magnetic core according to claim 6, characterized in that,
the two accommodating frames (16) are distributed on the first shaft (10) in a central symmetry way,
the first shaft (10) drives the containing frame (16) to rotate or the containing frame (16) and the first shaft (10) synchronously carry out axial movement.
8. The automatic material arranging machine for the nanocrystalline magnetic core according to claim 6, characterized in that,
the two receiving frames (16) are arranged side by side in sequence on the first shaft (10),
a circular through hole (18) communicated with the outside is arranged on the clapboard (17),
the receiving rack (16) moves back and forth in the axial direction of the first shaft (10).
9. The automatic pendulum machine of nanocrystalline magnetic core of claim 8, further comprising
The two penetrating rods (19) are symmetrically arranged on the outer sides of the two accommodating frames (16), the penetrating rods (19) are coaxial with the circular through holes (18) after rotating, and the penetrating rods (19) are inserted into the circular through holes (18) after the accommodating frames (16) axially move along the first shaft.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202120624907.0U CN215247828U (en) | 2021-03-29 | 2021-03-29 | Automatic material arranging machine for nanocrystalline magnetic cores |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202120624907.0U CN215247828U (en) | 2021-03-29 | 2021-03-29 | Automatic material arranging machine for nanocrystalline magnetic cores |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN215247828U true CN215247828U (en) | 2021-12-21 |
Family
ID=79506014
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202120624907.0U Active CN215247828U (en) | 2021-03-29 | 2021-03-29 | Automatic material arranging machine for nanocrystalline magnetic cores |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN215247828U (en) |
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2021
- 2021-03-29 CN CN202120624907.0U patent/CN215247828U/en active Active
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