CN219559992U - Vibrating sintered flux impurity removing device - Google Patents

Abstract

The utility model relates to a vibrating sintered flux impurity removing device, which comprises a vibrating receiving mechanism and an impurity removing mechanism, wherein the vibrating receiving mechanism is obliquely arranged and used for receiving materials, and the impurity removing mechanism is used for removing metal impurities in the materials; the vibration receiving mechanism comprises a supporting plate which is obliquely arranged and can change the inclination angle, a vibrating plate which is arranged on the supporting plate and is parallel to the supporting plate, and baffle plates which are respectively arranged on two sides of the vibrating plate, wherein the supporting plate is connected with the vibrating plate through a plurality of springs, and a vibrator is arranged on the vibrating plate; the impurity removing mechanism comprises two groups of magnet bars positioned above the vibrating plate, and the two groups of magnet bars are arranged in an upper layer and a lower layer. The utility model can effectively remove the mixed metal impurities in the materials, and improves the product quality of the sintered flux.

Description

Vibrating sintered flux impurity removing device

Technical Field

The utility model relates to the technical field of sintered flux production, in particular to a vibrating type sintered flux impurity removing device.

Background

The sintered flux is high-quality, high-efficiency, energy-saving and environment-friendly flux. The prepared wet flux is processed into required particles, and the particles are calcined at a high temperature of 750-1000 ℃ to form fine particles. The sintered flux is produced by using a stirrer, a granulator, a rotary dryer, a lifter, a sieving machine, a crusher and other equipment, so that metal impurities such as scrap iron are particularly easy to mix, and the metal impurities easily cause rough weld marks and discontinuous weld joints when the sintered flux is used for welding, so that the welding quality is seriously affected, and therefore, an impurity removing device capable of effectively removing the metal impurities in the sintered flux particles is highly demanded.

Disclosure of Invention

The utility model provides a vibrating sintered flux impurity removing device aiming at the defects of the prior art.

The utility model is realized by the following technical scheme, and provides a vibrating sintered flux impurity removing device, which comprises a vibrating receiving mechanism and an impurity removing mechanism, wherein the vibrating receiving mechanism is obliquely arranged and used for receiving materials, and the impurity removing mechanism is used for removing metal impurities in the materials; the vibration receiving mechanism comprises a supporting plate which is obliquely arranged and can change the inclination angle, a vibrating plate which is arranged on the supporting plate and is parallel to the supporting plate, and baffle plates which are respectively arranged on two sides of the vibrating plate, wherein the supporting plate is connected with the vibrating plate through a plurality of springs, and a vibrator is arranged on the vibrating plate; the impurity removing mechanism comprises two groups of magnet bars positioned above the vibrating plate, and the two groups of magnet bars are arranged in an upper layer and a lower layer.

Preferably, the lower end of the supporting plate is hinged with the supporting frame, the upper end of the supporting plate is connected with the supporting frame through a driving mechanism, and the driving mechanism drives the upper end of the supporting plate to move so that the supporting plate rotates along the hinged position to change the inclination angle.

Preferably, the driving mechanism is two air cylinders, the two air cylinders are respectively positioned at two sides of the supporting plate, the outer cylinder of each air cylinder is hinged with the supporting frame, and the piston rod of each air cylinder is hinged with the upper end of the supporting plate. The inclination angle of the supporting plate is increased by extending the cylinder piston rod, the inclination angle of the supporting plate is decreased by shortening the cylinder piston rod, and the falling speed of the material on the vibrating plate can be adjusted by adjusting the inclination angle of the supporting plate according to the requirement.

The belt conveyor for conveying materials is arranged above the vibration receiving mechanism, the materials on the belt conveyor fall onto the vibrating plate and fall along the vibrating plate, the vibrator is started, and the vibrator drives the vibrating plate to vibrate, so that the materials on the vibrating plate shake.

Preferably, the upper magnet rod is located at the upper layer, the lower magnet rod is located at the lower layer, the upper magnet rod and the lower magnet rod are multiple, the multiple upper magnet rods are arranged in parallel and fixedly connected with the upper connecting arm, the multiple lower magnet rods are arranged in parallel and fixedly connected with the lower connecting arm, and the upper magnet rod and the lower magnet rod are arranged in a staggered mode up and down.

Preferably, the distances between the upper magnet bars and the vibrating plate are the same, and the distances between the lower magnet bars and the vibrating plate are the same.

Preferably, the upper connecting arm and the lower connecting arm are respectively positioned at the outer sides of the two baffles, an upper through hole and a lower through hole which are respectively used for the passage of the upper magnet rod and the lower magnet rod are arranged on the baffles, the upper magnet rod connecting end penetrates through the upper through hole and then is fixed with the upper connecting arm, and the lower magnet rod connecting end penetrates through the lower through hole and then is fixed with the lower connecting arm.

Preferably, the diameters of the connecting end of the upper magnet rod and the connecting end of the lower magnet rod become larger gradually, so that the upper magnet rod is conveniently clamped in the upper through hole, and the lower magnet rod is clamped in the lower through hole.

Preferably, rubber blocks are respectively fixed at the end parts of the upper magnet rod and the end parts of the lower magnet rod, when metal impurities of the upper magnet rod and the lower magnet rod need to be taken down, the upper connecting arm and the lower connecting arm are respectively pulled in the direction away from the baffle, the baffle extrudes the metal impurities on the upper magnet rod and the lower magnet rod to the end parts along with the movement of the upper magnet rod in the upper through hole and the movement of the lower magnet rod in the lower through hole, the metal impurities on the end parts are separated from the upper magnet rod and the lower magnet rod and fall onto the vibrating plate, and the metal impurities are collected in a concentrated manner, so that the metal impurities on the upper magnet rod and the lower magnet rod are cleaned in a short time.

The beneficial effects of the utility model are as follows:

1. according to the utility model, the vibrating plate enables the material to slide downwards and be shaken up, and the vibrating plate is matched with the structural arrangement of the upper magnet rod and the lower magnet rod, so that the contact probability of metal impurities in the material with the upper magnet rod and the lower magnet rod is greatly improved, the mixed metal impurities in the material can be effectively removed, and the product quality of sintered flux is improved.

2. The utility model has simple structure, can clean the adsorbed metal impurities by pulling the upper magnet rod and the lower magnet rod and matching with the baffle, saves time and labor in operation and has short shutdown cleaning time.

Drawings

FIG. 1 is a schematic elevational view of the present utility model;

FIG. 2 is a schematic diagram of another front view of the present utility model;

FIG. 3 is a schematic top view of the vibrating plate and the impurity removing mechanism of the present utility model;

FIG. 4 is a schematic view of the structure of the upper magnet bar of the present utility model;

FIG. 5 is a schematic view of the structure of the lower magnet bar of the present utility model;

FIG. 6 is a schematic elevational view of a baffle plate of the present utility model;

FIG. 7 is a schematic rear view of another baffle plate of the present utility model;

the figure shows:

1. the vibration plate comprises a supporting plate, 2, a vibration plate, 3, a baffle, 4, a spring, 5, a vibrator, 6, a supporting frame, 7, a driving mechanism, 8, an upper magnet rod, 9, a lower magnet rod, 10, an upper connecting arm, 11, a lower connecting arm, 12, an upper through hole, 13, a lower through hole, 14 and a rubber block.

Detailed Description

In order to clearly illustrate the technical characteristics of the scheme, the scheme is explained below through a specific embodiment.

As shown in fig. 1, 2 and 3, the utility model comprises a vibrating receiving mechanism which is obliquely arranged for receiving materials and a impurity removing mechanism for removing metal impurities in the materials.

The vibration receiving mechanism comprises a supporting plate 1 which is obliquely arranged and can change the inclination angle, a vibrating plate 2 which is arranged on the supporting plate 1 and is parallel to the supporting plate 1, and baffle plates 3 which are respectively arranged on two sides of the vibrating plate 2. The support plate 1 is connected to the vibration plate 2 through a plurality of springs 4, and a vibrator 5 is mounted on the vibration plate 2. The vibrator 5 adopts the prior art, and the specific structure thereof is not described herein. The springs 4 are hard springs, which can support the vibrating plate 2 and materials and meet the vibration requirement of the vibrating plate 2.

The lower extreme of backup pad 1 is articulated with support frame 6, and backup pad 1 upper end is connected with support frame 6 through actuating mechanism 7, and actuating mechanism 7 drive backup pad 1 upper end removes and makes backup pad 1 rotate along articulated department and change the inclination. In this embodiment, the driving mechanism 7 is two cylinders, the two cylinders are respectively located at two sides of the supporting plate 1, the outer cylinder of each cylinder is hinged with the supporting frame 6, and the piston rod of each cylinder is hinged with the upper end of the supporting plate 1. The inclination angle of the supporting plate 1 is increased by extending the cylinder piston rod, the inclination angle of the supporting plate 1 is decreased by shortening the cylinder piston rod, and the falling speed of the material on the vibrating plate 2 can be adjusted by adjusting the inclination angle of the supporting plate 1 according to the requirement.

The belt conveyor for conveying materials is arranged above the vibration receiving mechanism, the materials on the belt conveyor fall onto the vibrating plate 2 and fall along the vibrating plate 2, the vibrator 5 is started, and the vibrator 5 drives the vibrating plate 2 to vibrate, so that the materials on the vibrating plate 2 shake.

The impurity removing mechanism comprises two groups of magnet bars positioned above the vibrating plate 2, the two groups of magnet bars are arranged in an upper layer and a lower layer, the upper magnet bar 8 is positioned on the upper layer, the lower magnet bar 9 is positioned on the lower layer, the upper magnet bar 8 and the lower magnet bar 9 are multiple, as shown in figures 3, 4 and 5, the multiple upper magnet bars 8 are arranged in parallel and fixedly connected with the upper connecting arm 10, the multiple lower magnet bars 9 are arranged in parallel and fixedly connected with the lower connecting arm 11, and the upper magnet bars 8 and the lower magnet bars 9 are arranged in an up-down staggered mode. The distance between each upper magnet bar 8 and the vibration plate 2 is the same, and the distance between each lower magnet bar 9 and the vibration plate 2 is the same.

The upper connecting arm 10 and the lower connecting arm 11 are respectively located on the outer sides of the two baffles 3, as shown in fig. 6 and 7, an upper through hole 12 and a lower through hole 13 through which the upper magnet rod 8 and the lower magnet rod 9 pass are respectively arranged on the baffles 3, the connecting end of the upper magnet rod 8 penetrates through the upper through hole 12 and then is fixed with the upper connecting arm 10, the connecting end of the lower magnet rod 9 penetrates through the lower through hole 13 and then is fixed with the lower connecting arm 11, the diameters of the connecting end of the upper magnet rod 8 and the connecting end of the lower magnet rod 9 become larger gradually, the upper magnet rod 8 is conveniently clamped in the upper through hole 12, and the lower magnet rod 9 is clamped in the lower through hole 13. For the stabilization of the upper magnet bar 8 and the lower magnet bar 9, the upper connecting arm 10 and the baffle 3 and the lower connecting arm 11 and the baffle 3 are connected by bolts.

Rubber blocks 14 are respectively fixed at the end parts of the upper magnet rod 8 and the lower magnet rod 9. When the metal impurities on the upper magnet rod 8 and the lower magnet rod 9 need to be taken down, material conveying is suspended, the upper connecting arm 10 and the lower connecting arm 11 are pulled towards the direction away from the baffle 3 respectively, the lower magnet rod 9 moves in the lower through hole 13 along with the movement of the upper magnet rod 8 in the upper through hole 12, the baffle 3 extrudes the metal impurities on the upper magnet rod 8 and the lower magnet rod 9 to the end parts, the metal impurities on the end parts are separated from the upper magnet rod 8 and the lower magnet rod 9 and fall onto the vibrating plate 2, concentrated collection is carried out, metal impurity cleaning on the upper magnet rod 8 and the lower magnet rod 9 is completed in a short time, and time and labor are saved in metal impurity cleaning, and the process is very convenient. After the metal impurities are cleaned, the upper magnet rod 8 is inserted into the upper through hole 12 and clamped, the lower magnet rod 9 is inserted into the lower through hole 13 and clamped, and the metal impurities in the materials are adsorbed continuously.

When the vibrating and receiving device is particularly used, materials conveyed by the belt conveyor are received through the vibrating and receiving mechanism, the materials fall onto the vibrating plate 2, and the vibrating plate 2 vibrates, so that the materials are continuously rocked while falling along the vibrating plate 2 and are continuously contacted with the upper magnet rod 8 and the lower magnet rod 9, and metal impurities mixed in the materials are adsorbed on the upper magnet rod 8 and the lower magnet rod 9. The vibrating plate 2 enables the material to slide downwards and be shaken up, and is matched with the structural arrangement of the upper magnet rod 8 and the lower magnet rod 9, so that the probability of contact between metal impurities in the material and the upper magnet rod 8 and the lower magnet rod 9 is greatly improved, and the mixed metal impurities in the material can be effectively removed.

The utility model has simple structure, good effect of removing the mixed metal impurities in the materials, and can clean the adsorbed metal impurities by pulling the upper magnet rod 8, the lower magnet rod 9 and the baffle plate 3 to be matched, and the cleaning of the metal impurities adsorbed by the upper magnet rod 8 and the lower magnet rod 9 is convenient.

Of course, the above description is not limited to the above examples, and the technical features of the present utility model that are not described may be implemented by or by using the prior art, which is not described herein again; the above examples and drawings are only for illustrating the technical scheme of the present utility model and not for limiting the same, and the present utility model has been described in detail with reference to the preferred embodiments, and it should be understood by those skilled in the art that changes, modifications, additions or substitutions made by those skilled in the art without departing from the spirit of the present utility model and the scope of the appended claims.

Claims (6)

1. A vibrating sintered flux impurity removing device is characterized in that: the device comprises a vibrating receiving mechanism which is obliquely arranged and used for receiving materials and a impurity removing mechanism which is used for removing metal impurities in the materials; the vibration receiving mechanism comprises a supporting plate which is obliquely arranged and can change the inclination angle, a vibrating plate which is arranged on the supporting plate and is parallel to the supporting plate, and baffle plates which are respectively arranged on two sides of the vibrating plate, wherein the supporting plate is connected with the vibrating plate through a plurality of springs, and a vibrator is arranged on the vibrating plate; the impurity removing mechanism comprises two groups of magnet bars positioned above the vibrating plate, and the two groups of magnet bars are arranged in an upper layer and a lower layer.

2. The vibratory sintered flux impurity removal apparatus of claim 1, wherein: the lower end of the supporting plate is hinged with the supporting frame, the upper end of the supporting plate is connected with the supporting frame through a driving mechanism, and the driving mechanism drives the upper end of the supporting plate to move so that the supporting plate rotates along the hinged position to change the inclination angle.

3. The vibratory sintered flux impurity removing apparatus according to claim 2, wherein: the driving mechanism is two air cylinders, the two air cylinders are respectively positioned at two sides of the supporting plate, the outer cylinder of each air cylinder is hinged with the supporting frame, and the piston rod of each air cylinder is hinged with the upper end of the supporting plate.

4. The vibratory sintered flux impurity removal apparatus of claim 1, wherein: the upper magnet rod is located the upper strata, and the lower magnet rod is located the lower floor, and it is a plurality of with lower magnet rod to go up magnet rod, and a plurality of magnet rod parallel arrangement and be connected fixedly with last linking arm, a plurality of lower magnet rod parallel arrangement and be connected fixedly with lower linking arm, go up magnet rod and stagger the setting from top to bottom with lower magnet rod.

5. The vibratory sintered flux impurity removal apparatus of claim 4, wherein: the distances between the upper magnet bars and the vibrating plate are the same, and the distances between the lower magnet bars and the vibrating plate are the same.

6. The vibratory sintered flux impurity removal apparatus of claim 4, wherein: the upper connecting arm and the lower connecting arm are respectively positioned at the outer sides of the two baffles, an upper through hole and a lower through hole which are respectively used for the passage of the upper magnet rod and the lower magnet rod are arranged on the baffles, the upper magnet rod connecting end penetrates through the upper through hole and then is fixed with the upper connecting arm, and the lower magnet rod connecting end penetrates through the lower through hole and then is fixed with the lower connecting arm.