CN211538595U - Unpowered bipartition ball device - Google Patents

Abstract

The utility model discloses an unpowered two-ball-dividing device, which comprises a fixed shaft, a rotating shaft arranged on the fixed shaft, a first clapboard, a second clapboard and a third clapboard which are arranged on the rotating shaft; the first partition plate is used for guiding the metal balls into the quenching bath from one side by matching with a first groove edge on one side of the blanking groove when rotating to the first position, and is also used for guiding the metal balls into the quenching bath from the other side by matching with a second groove edge on the other side of the blanking groove when rotating to the second position; the device also comprises a first limiting part and a second limiting part, wherein the first limiting part is used for preventing the second clapboard from rotating downwards so that the first clapboard stays at the first position, and the second limiting part is used for preventing the third clapboard from rotating downwards so that the first clapboard stays at the second position; when the first partition board is located at the first position and the second position, the first groove edge and the second groove edge are located on two sides of the first partition board respectively. The utility model relates to a two volleyball devices that are unpowered has not only saved the manual work, also need not extra actuating mechanism simultaneously, has saved extra energy consumption.

Description

Unpowered bipartition ball device

Technical Field

The utility model relates to an unpowered bipartition ball device.

Background

When the steel balls are prepared, the steel balls produced by the high-temperature furnace need to be guided to enter different steel ball processing mechanisms respectively because the steel balls produced by the high-temperature furnace in unit time are more in quantity and the steel ball processing mechanisms after quenching can process less steel balls in unit time.

The steel balls produced by the high-temperature furnace have the characteristics of large mass, high temperature, high density and the like, and are difficult to guide manually.

Disclosure of Invention

The utility model aims at providing a bipartition ball device that is unpowered utilizes the kinetic energy of metal ball self to divide the leading-in quenching bath of two tunnel with the metal ball, has not only saved the manual work, also need not extra actuating mechanism simultaneously.

In order to achieve the above purpose, the utility model adopts the technical scheme that:

a powerless two ball-separating device is used for guiding metal balls sliding in a blanking groove into a quenching bath in two ways, and comprises a fixed shaft, a rotating shaft which can rotate around the axis direction of the rotating shaft and is arranged on the fixed shaft, and a first partition plate, a second partition plate and a third partition plate which are sequentially arranged at intervals along the circumferential direction and are arranged on the rotating shaft;

the first partition plate is used for guiding the metal balls into the quenching bath from one side by matching with a first groove edge on one side of the blanking groove when the first partition plate rotates to a first position, and is also used for guiding the metal balls into the quenching bath from the other side by matching with a second groove edge on the other side of the blanking groove when the first partition plate rotates to a second position;

the device further comprises a first limiting part and a second limiting part, wherein the first limiting part is used for blocking the second partition plate to rotate downwards so that the first partition plate stays at the first position, and the second limiting part is used for blocking the third partition plate to rotate downwards so that the first partition plate stays at the second position;

when the first partition plate is located at the first position and the second position, the first groove edge and the second groove edge are located on two sides of the first partition plate respectively.

Preferably, the first groove edge and the third partition plate are positioned on one side of the first partition plate; the second groove edge and the second partition plate are positioned on the other side of the first partition plate.

More preferably, when the first partition board is located at the first position, the third partition board and the second limiting member are arranged at intervals; when the first partition board is located at the second position, the second partition board and the first limiting piece are arranged at intervals.

More preferably, when the first partition plate is in the first position, the third partition plate is lower than the lowest point of the blanking groove and is used for bearing the metal balls; when the first partition plate is located at the second position, the second partition plate is lower than the lowest point of the blanking groove and is used for bearing the metal balls.

Preferably, the first partition, the second partition and the third partition equally divide the circumference.

Preferably, the rotating shaft is coaxially and rotatably sleeved on the fixed shaft, and the feeding trough is equally divided by a vertical plane passing through the axial line of the rotating shaft.

Preferably, the distances between the first partition plate, the second partition plate, the third partition plate and the discharge port of the blanking groove are all smaller than the diameter of the metal ball.

Preferably, the device further comprises a blocking plate which is arranged at one end, far away from the blanking groove, of the fixing shaft and used for blocking the metal ball.

Preferably, the device further comprises a connecting shaft connected to the fixed shaft, one end of the first limiting piece is connected to the connecting shaft, and the other end of the first limiting piece is located on a rotating path of the second partition plate; one end of the second limiting part is connected to the connecting shaft, and the other end of the second limiting part is located on a rotating path of the third partition plate.

More preferably, the second partition is located on one side of the first limiting member and the second limiting member, and the third partition is located on the other side of the first limiting member and the second limiting member.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage: the utility model relates to an unpowered bipartition ball device, through setting up the first baffle that can the free rotation and have two stop positions, in two stop position departments, first baffle cooperates first groove limit and second groove limit respectively with the metal ball divide two tunnel leading-in quenching bath, this process has only utilized the kinetic energy of metal ball self, has not only saved the manual work, also need not extra actuating mechanism simultaneously, has saved extra energy consumption.

Drawings

FIG. 1 is a schematic structural diagram of the device of the present invention;

fig. 2 is a side view of the device of the present invention.

Wherein: 1. a discharging groove; 2. a metal ball; 3. a quenching bath; 4. a fixed shaft; 5. a rotating shaft; 6. a first separator; 7. a second separator; 8. a third partition plate; 9. a first slot edge; 10. a second slot edge; 11. a first limit piece; 12. a second limiting member; 13. a blocking plate; 14. and (7) connecting the shafts.

Detailed Description

The technical solution of the present invention will be further explained with reference to the accompanying drawings.

Referring to fig. 1-2, the unpowered two-ball-dividing device is used for guiding the metal balls 2 sliding down from the blanking chute 1 into the quenching bath 3 in two ways, passing through two transmission channels in the quenching bath 3, and entering two processing mechanisms respectively after quenching.

The unpowered two-ball-splitting device comprises a fixed shaft 4, a rotating shaft 5 which can rotate around the axis direction of the rotating shaft and is arranged on the fixed shaft 4, and a first partition plate 6, a second partition plate 7 and a third partition plate 8 which are sequentially arranged at intervals along the circumferential direction and are arranged on the rotating shaft 5.

In this embodiment, the first partition plate 6, the second partition plate 7, and the third partition plate 8 are equally divided into circles, that is, the included angles between every two of the three partition plates are all 120 °, and the surrounding center of the three partition plates is the axis line of the rotating shaft 5. Simultaneously, the distance between first baffle 6, second baffle 7, third baffle 8 and the 1 discharge gate of feed chute all is less than the diameter of metal ball 2, through this setting, makes metal ball 2 can fall between two baffles. The rotating shaft 5 can be coaxially and rotatably sleeved on the fixed shaft 4, the axis of the rotating shaft 5 extends along the horizontal direction, and the discharging groove 1 is equally divided by the vertical plane passing through the axis of the rotating shaft 5.

The unpowered two-ball-splitting device further comprises a connecting shaft 14 connected to the fixed shaft 4, a first limiting piece 11 with one end connected to the connecting shaft 14, and a second limiting piece 12 with one end connected to the first connecting shaft 14. The other end of the first limiting piece 11 is positioned on the rotating path of the second partition plate 7; the other end of the second limiting member 12 is located on the rotation path of the third partition 8.

In this embodiment, the connecting shaft 14 is located at one end of the fixed shaft 4 close to the discharging chute 1. The first position-limiting element 11 points to the second partition 7, and the second position-limiting element 12 points to the third partition 8. The second partition 7 is located at one side of the first limiting member 11 and the second limiting member 12, and the third partition 8 is located at the other side of the first limiting member 11 and the second limiting member 12.

The first partition 6 has two rest positions, a first position and a second position, respectively. When the first clapboard 6 is at the first position, a first groove edge 9 at one side of the blanking groove 1 and a second groove edge 10 at the other side are respectively positioned at two sides of the first clapboard 6; when the first partition 6 is in the second position, the first slot edge 9 and the second slot edge 10 are still located on both sides of the first partition 6. The first groove edge 9 and the third clapboard 8 are positioned at one side of the first clapboard 6; the second slot edge 10 and the second partition 7 are located on the other side of the first partition 6. Specifically, when the first partition 6 is in the first position, the first partition 6 is deflected from the vertical plane to the second slot edge 10, and when the first partition 6 is in the second position, the first partition 6 is deflected from the vertical plane to the first slot edge 9. Referring to fig. 1, the first partition plate 6 is located above the discharge port of the discharging chute 1, and the second partition plate 7 and the third partition plate 8 are located below the discharge port of the discharging chute 1.

When the first partition plate 6 is at the first position, the metal ball 2 is guided into the quenching bath 3 from one side by matching with the first trough edge 9 at one side of the blanking trough 1; when the first partition plate 6 is at the second position, the metal ball 2 is guided into the quenching bath 3 from the other side by matching with the second groove edge 10 at the other side of the blanking groove 1.

When the first partition board 6 is at the first position, the second partition board 7 abuts against the first limiting piece 11, the metal ball 2 enters between the first partition board 6 and the third partition board 8, the third partition board 8 is pressed down to rotate until abutting against the second limiting piece 12, the first partition board 6 is switched to the second position, and at the moment, the second partition board 7 rotates upwards to separate from the first limiting piece 11; the next metal ball 2 enters between the first partition plate 6 and the second partition plate 7, the second partition plate 7 is pressed down to rotate until abutting against the first limiting piece 11, the first partition plate 6 is switched to the first position again, and at the moment, the third partition plate 8 rotates upwards to separate from the second limiting piece 12.

When the first clapboard 6 is at the first position, the third clapboard 8 is lower than the lowest point of the blanking groove 1 and is used for bearing the metal balls 2, so that the metal balls 2 enter the quenching bath 3 from the third clapboard 8 side; when the first partition plate 6 is at the second position, the second partition plate 7 is lower than the lowest point of the blanking groove 1 and is used for bearing the metal balls 2, so that the metal balls 2 enter the quenching bath 3 from the side of the second partition plate 7. The unpowered automatic shunting of the metal ball 2 is realized.

The unpowered two-ball separating device further comprises a blocking plate 13 which is arranged at one end, far away from the blanking groove 1, of the fixing shaft 4 and used for blocking the metal balls 2. By arranging the blocking plate 13, the metal balls 2 with large kinetic energy can be prevented from directly rushing into the quenching bath 3, and can only enter the quenching bath 3 from the second partition plate 7 side or the third partition plate 8 side.

The following specifically explains the working process of this embodiment:

the first partition plate 6 is located at a first position, the metal ball 2 in the feeding chute 1 enters between the first partition plate 6 and the third partition plate 8 under the matching of the first chute edge 9 and the first partition plate 6, the third partition plate 8 is pressed downwards to rotate downwards until abutting against the second limiting part 12, the metal ball 2 enters the quenching bath 3 from the third partition plate 8 side, at the moment, the second partition plate 7 rotates upwards to separate from the first limiting part 11, and the first partition plate 6 is switched to a second position;

the next metal ball 2 in the blanking groove 1 enters between the first partition plate 6 and the second partition plate 7 under the matching of the second groove edge 10 and the first partition plate 6, the second partition plate 7 is pressed downwards to be rotated downwards to abut against the first limiting part 11, the metal ball 2 enters the quenching pool 3 from the side of the second partition plate 7, at the moment, the first partition plate 6 rotates upwards to be separated from the second limiting part 12, and the first partition plate 6 is switched to the first position.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims (10)

1. A unpowered two ball separating device is used for guiding metal balls sliding in a blanking groove into a quenching bath in two ways, and is characterized in that: the device comprises a fixed shaft, a rotating shaft which can rotate around the axis line direction of the device and is arranged on the fixed shaft, and a first clapboard, a second clapboard and a third clapboard which are sequentially arranged at intervals along the circumferential direction and are arranged on the rotating shaft;

the first partition plate is used for guiding the metal balls into the quenching bath from one side by matching with a first groove edge on one side of the blanking groove when the first partition plate rotates to a first position, and is also used for guiding the metal balls into the quenching bath from the other side by matching with a second groove edge on the other side of the blanking groove when the first partition plate rotates to a second position;

the device further comprises a first limiting part and a second limiting part, wherein the first limiting part is used for blocking the second partition plate to rotate downwards so that the first partition plate stays at the first position, and the second limiting part is used for blocking the third partition plate to rotate downwards so that the first partition plate stays at the second position;

when the first partition plate is located at the first position and the second position, the first groove edge and the second groove edge are located on two sides of the first partition plate respectively.

2. The unpowered bipartite ball device of claim 1, wherein: the first groove edge and the third clapboard are positioned on one side of the first clapboard; the second groove edge and the second partition plate are positioned on the other side of the first partition plate.

3. The unpowered bipartite ball device of claim 2, wherein: when the first partition board is located at the first position, the third partition board and the second limiting piece are arranged at intervals; when the first partition board is located at the second position, the second partition board and the first limiting piece are arranged at intervals.

4. The unpowered bipartite ball device of claim 2, wherein: when the first partition plate is located at the first position, the third partition plate is lower than the lowest point of the blanking groove and is used for bearing the metal balls; when the first partition plate is located at the second position, the second partition plate is lower than the lowest point of the blanking groove and is used for bearing the metal balls.

5. The unpowered bipartite ball device of claim 1, wherein: the first partition plate, the second partition plate and the third partition plate equally divide the circumference.

6. The unpowered bipartite ball device of claim 1, wherein: the rotating shaft can be coaxially and rotatably sleeved on the fixed shaft, and the discharging groove is equally divided by a vertical plane passing through the axial lead of the rotating shaft.

7. The unpowered bipartite ball device of claim 1, wherein: the distances between the first partition plate, the second partition plate, the third partition plate and the discharge hole of the blanking groove are all smaller than the diameter of the metal ball.

8. The unpowered bipartite ball device of claim 1, wherein: the device also comprises a blocking plate which is arranged at one end, far away from the blanking groove, of the fixed shaft and used for blocking the metal ball.

9. The unpowered bipartite ball device of claim 1, wherein: the device further comprises a connecting shaft connected to the fixed shaft, one end of the first limiting piece is connected to the connecting shaft, and the other end of the first limiting piece is located on a rotating path of the second partition plate; one end of the second limiting part is connected to the connecting shaft, and the other end of the second limiting part is located on a rotating path of the third partition plate.

10. The unpowered bipartite ball device of claim 9, wherein: the second partition board is located on one side of the first limiting part and the second limiting part, and the third partition board is located on the other side of the first limiting part and the second limiting part.

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