CN217527217U - Powder metallurgy V-arrangement agitating unit - Google Patents

Abstract

The utility model provides a powder metallurgy V-shaped stirring device, which comprises a machine base and a V-shaped stirring tank, wherein two linear rails are respectively arranged on two side walls of the V-shaped stirring tank, the two linear rails are arranged in a V-shaped clamp angle, sliding blocks are arranged on the linear rails, a sliding shaft is fixed on the sliding block of each side linear rail, and the centers of the sliding shafts of the two linear rails are concentric with each other; the outer wall of the sliding shaft is provided with a sliding groove which is arranged along the axial direction of the sliding shaft and a plurality of meshing gear rings which are arranged along the circumferential direction of the sliding shaft and are arranged at intervals along the axial direction of the sliding shaft; the two sides of the base are respectively provided with a speed reducer which is matched with the sliding grooves of the sliding shafts in an axial sliding manner and is driven by a hybrid motor to realize circumferential rotation of the sliding shafts; and the two sides of the base are also provided with lifting gears which are meshed with the meshing gear rings of the sliding shafts and used for controlling the sliding shafts to slide axially, and the lifting gears are controlled to rotate by a lifting motor. The utility model has the advantages of be convenient for go up the unloading, effectively reduce inside powder simultaneously and gather, alleviate operating personnel intensity of labour.

Description

Powder metallurgy V-arrangement agitating unit

Technical Field

The utility model relates to a agitating unit field, concretely relates to powder metallurgy V-arrangement agitating unit.

Background

The V-shaped stirrer series product is a V-shaped high-efficiency asymmetric mixer, and is suitable for mixing powder or granular materials in the industries of chemical industry, food, medicine, feed, ceramics, metallurgy and the like; the machine has reasonable and simple structure, closed operation and convenient feeding and discharging (manual or vacuum feeding) of the cylinder body made of stainless steel material, is convenient to clean and is one of basic devices of enterprises;

the existing V-shaped stirrer is often fixed in structure, materials need to be fed from a higher tank top during feeding, and operators are easy to fatigue, especially in the field of powder metallurgy, and the specific gravity of metal powder is often higher, so that the feeding of the operators is extremely difficult;

simultaneously current V-arrangement mixer often contains a discharge gate and a charge door, and the discharge gate is located V type tank bottoms department, and the charge door then is located the tank deck, owing to there is seal structure, consequently makes partial unmixed material enter into the gap between charge door and the charging lid and gathers in stirring earlier stage, and easy secondary drops and causes partial material mixing proportion to change after the stirring is accomplished, especially has the powder metallurgy occasion of this strict demand to material mixing proportion.

SUMMERY OF THE UTILITY MODEL

Based on the problem, the utility model aims to provide a powder metallurgy V-arrangement agitating unit convenient to material loading before mixing, unloading after mixing effectively reduces inside powder simultaneously and gathers, alleviates operating personnel intensity of labour.

Aiming at the problems, the following technical scheme is provided: a V-shaped stirring device for powder metallurgy comprises a base and a V-shaped stirring tank arranged on the base, wherein two side walls of the V-shaped stirring tank are respectively provided with a linear rail extending from the top of the tank to the direction of a material inlet and a material outlet at the bottom of the tank, the two linear rails are arranged in a V-shaped included angle manner, the linear rails are respectively provided with a sliding block, a sliding shaft is fixed on the sliding block of each linear rail at each side, and the centers of the sliding shafts of the two linear rails are concentric with each other; the outer wall of the sliding shaft is provided with a sliding groove which is arranged along the axial direction of the sliding shaft and a plurality of meshing gear rings which are arranged along the circumferential direction of the sliding shaft at intervals; the two sides of the base are respectively provided with a speed reducer which is matched with the sliding grooves of the sliding shafts in an axial sliding manner and is driven by a hybrid motor to realize circumferential rotation of the sliding shafts; and the two sides of the base are also provided with lifting gears which are meshed with the meshing gear rings of the sliding shafts and used for controlling the sliding shafts to slide axially, and the lifting gears are controlled to rotate by a lifting motor.

In the structure, the two linear rails arranged in a V-shaped included angle manner can drive the V-shaped stirring tank to generate lifting motion along the height direction of the V-shaped stirring tank by utilizing the synchronous axial extension and contraction of the two sliding shafts to approach or separate; when the metal powder is poured into the V-shaped stirring tank, the lifting gear is meshed with the meshing gear ring to enable the two sliding shafts to axially move close to each other, and the sliding block slides to one side of the material inlet and outlet along the line rail to enable the V-shaped stirring tank to descend; after the materials are loaded, the lifting gear is meshed with the meshing gear ring to enable the two sliding shafts to axially move away from each other, and at the moment, the sliding block slides to the side away from the material inlet and outlet along the linear rail to enable the V-shaped stirring tank to be lifted and returned to enter a stirring station; then, a speed reducer is driven by a mixing motor, and the speed reducer is used for driving a sliding shaft to rotate, so that the V-shaped stirring tank is overturned and stirred; after stirring is finished, the V-shaped stirring tank is rotated to enable the material inlet and the material outlet to face downwards, so that operators can conveniently take the mixed metal powder, the lifting gear is controlled to be meshed with the meshing toothed ring to enable the two sliding shafts to axially move to be close to each other, the sliding block slides to one side of the material inlet and the material outlet along the linear rail at the moment, the V-shaped stirring tank can be caused to ascend due to the downward state of the material inlet and the material outlet at the moment, and an enough material receiving space is provided below the material inlet and the material outlet; the sliding groove is preferably a spline groove and is matched with an internal spline of a shaft hole of an output shaft of the speed reducer, so that the speed reducer can provide circumferential torque for the sliding shaft and the sliding shaft can slide in the axial direction; the meshing gear ring is annular, so that the meshing gear ring can be meshed with the meshing gear ring on the outer wall of the sliding shaft one by one to realize axial driving when the lifting gear rotates, the meshing gear ring can rotate on the tooth surface of the lifting gear when the sliding shaft rotates in the circumferential direction, and the axial motion are not interfered with each other; the labor intensity of workers is effectively reduced, and particularly in the mixing of the hard alloy powder, the weight of the hard alloy powder is far higher than that of common metal, and the requirement on the physical ability of operators is higher.

The utility model discloses further set up to, V-arrangement agitator tank only its tank bottoms department is equipped with into discharge gate.

In the above-mentioned structure, the business turn over material mouth is equipped with the valve, through business turn over material mouth control feeding and the ejection of compact, has removed the structure that traditional top was uncapped from, effectively reduces the possibility that other tiny gaps exist in the V-arrangement agitator tank, has avoided mixing the interior powder of later stage gap to drop and has caused the inconsistent condition of mixing proportion to take place and influence the performance after carbide shaping sintering.

The utility model discloses further set up to, the reduction gear of frame both sides is worm gear reduction gear.

In the structure, the worm gear reducer has self-locking performance, can lock the position of the V-shaped stirring tank, and avoids abnormal rotation caused by unstable gravity center of the tank body of the V-shaped stirring tank after shutdown; meanwhile, the hybrid motor can be selected as a brake motor to replace a worm gear reducer.

The utility model discloses further set up to, the reduction gear of frame both sides can be alone one to one and hybrid motor power is connected, or hybrid motor of sharing provides power.

In the structure, the optimal scheme is that one hybrid motor drives two speed reducers through a transmission shaft system simultaneously, so that the consistency of the rotating speed can be ensured.

The utility model discloses further set up to, elevator motor passes through lift reducing gear box drive lifting gear and rotates.

In the structure, the lifting reduction box can reduce the speed and increase the torque of the lifting motor; the lifting motor is preferably a brake motor with a brake.

The utility model discloses further set up to, the lift reducing gear box of frame both sides can be alone one to one and lift motor power is connected, or lift motor of sharing provides power.

In the structure, the preferred scheme is that one lifting motor drives two lifting reduction boxes simultaneously through a transmission shaft system, so that the consistency of the rotating speed can be ensured.

The utility model discloses further set up to, the lift reducing gear box is worm gear reduction gear.

In the structure, the worm gear reducer has self-locking performance, and the possibility that the sliding shaft slides axially due to the self weight of the V-shaped stirring tank after the lifting motor is stopped can be avoided.

The utility model discloses further set up to, hybrid motor, elevator motor are when cooperation worm gear reduction gear, and the motor optional type is step motor or servo motor.

The utility model has the advantages that: the two linear rails arranged in a V-shaped included angle mode can drive the V-shaped stirring tank to generate lifting motion along the height direction of the V-shaped stirring tank by utilizing synchronous axial extension and retraction of the two sliding shafts to approach or separate; when the metal powder is poured into the V-shaped stirring tank, the lifting gear is meshed with the meshing gear ring to enable the two sliding shafts to axially move close to each other, and the sliding block slides to one side of the material inlet and outlet along the line rail to enable the V-shaped stirring tank to descend; after the materials are loaded, the lifting gear is meshed with the meshing gear ring to enable the two sliding shafts to axially move away from each other, and at the moment, the sliding block slides to the side away from the material inlet and outlet along the linear rail to enable the V-shaped stirring tank to be lifted and returned to enter a stirring station; then, a speed reducer is driven by a mixing motor, and the speed reducer is used for driving a sliding shaft to rotate, so that the V-shaped stirring tank is overturned and stirred; after stirring is completed, the V-shaped stirring tank is rotated to enable the material inlet and the material outlet to face downwards, so that operators can conveniently take the mixed metal powder, the lifting gear is controlled to be meshed with the meshing toothed ring to enable the two sliding shafts to axially move to be close to each other, the sliding block slides to one side of the material inlet and the material outlet along the linear rail at the moment, the V-shaped stirring tank can be caused to ascend due to the downward state of the material inlet and the material outlet at the moment, and a sufficient material receiving space is provided below the material inlet and the material outlet; the sliding groove is preferably a spline groove and is matched with an internal spline of a shaft hole of an output shaft of the speed reducer, so that the speed reducer can provide circumferential torque for the sliding shaft and the sliding shaft can slide in the axial direction; the meshing gear ring is annular, so that the meshing gear ring can be meshed with the meshing gear ring on the outer wall of the sliding shaft one by one to realize axial driving when the lifting gear rotates, the meshing gear ring can rotate on the tooth surface of the lifting gear when the sliding shaft rotates in the circumferential direction, and the axial motion are not interfered with each other; the labor intensity of workers is effectively reduced, and particularly in the mixing of the hard alloy powder, the weight of the hard alloy powder is far higher than that of common metal, and the requirement on the physical ability of operators is higher.

Drawings

Fig. 1 is the structure schematic diagram of the descending state of the tank body when the charging and discharging port of the V-shaped stirring tank is up.

Fig. 2 is the structure diagram of the reset state of the V-shaped stirring tank of the present invention.

Fig. 3 is a schematic diagram of the stirring state structure of the V-shaped stirring tank of the present invention.

Fig. 4 is the structural schematic diagram of the rising state of the tank body when the V-shaped stirring tank finishes stirring and the discharge port is downward.

Fig. 5 is an enlarged schematic view of a portion a of fig. 1 according to the present invention.

The reference numbers in the figures mean: 10-a machine base; 11-V-shaped stirring tank; 111-feeding and discharging ports; 12-wire track; 13-a slide block; 14-a slip axis; 141-a slipping groove; 142-an engaging gear ring; 15-a reducer; 16-a lifting gear; 161-a lifting motor; 162-lifting reduction gearbox.

Detailed Description

The following detailed description of the embodiments of the present invention is provided with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

Referring to fig. 1 to 5, a powder metallurgy V-shaped stirring apparatus shown in fig. 1 to 5 includes a base 10, a V-shaped stirring tank 11 disposed on the base 10, two side walls of the V-shaped stirring tank 11 are respectively provided with a linear rail 12 extending from a top of the tank to a material inlet 111 and a material outlet 111 at a bottom of the tank, the two linear rails 12 are disposed in a V-shaped included angle, the linear rail 12 is provided with a sliding block 13, the sliding block 13 of each linear rail 12 is fixed with a sliding shaft 14, and centers of the sliding shafts 14 of the two linear rails 12 are concentric; the outer wall of the sliding shaft 14 is provided with a sliding groove 141 which is arranged along the axial direction of the sliding shaft and a plurality of meshing toothed rings 142 which are arranged along the circumferential direction of the sliding shaft and are arranged at intervals along the axial direction of the sliding shaft 14; two sides of the machine base 10 are respectively provided with a speed reducer 15 which is axially matched with the sliding grooves 141 of the sliding shafts 14 in a sliding manner and is driven by a hybrid motor (not shown in the figure) to realize circumferential rotation of the sliding shafts 14; two sides of the machine base 10 are further provided with a lifting gear 16 engaged with the engaging gear rings 142 of the respective sliding shafts 14 for controlling the sliding shafts 14 to slide axially, and the lifting gear 16 is controlled to rotate by a lifting motor 161.

In the structure, the two linear rails 12 arranged in a V-shaped included angle mode can drive the V-shaped stirring tank 11 to generate lifting motion along the height direction of the V-shaped stirring tank by utilizing the synchronous axial extension and retraction of the two sliding shafts 14 to approach or separate; during feeding, the V-shaped stirring tank 11 is rotated to enable the feeding and discharging port 111 to face upwards, in order to reduce the height of the V-shaped stirring tank 11 at the moment, metal powder is convenient for workers to pour into, the lifting gear 16 is meshed with the meshing toothed ring 142 to enable the two sliding shafts 14 to axially move close to each other, and at the moment, the sliding block 13 slides towards one side of the feeding and discharging port 111 along the line rail 12 to enable the V-shaped stirring tank 11 to descend; after the material loading is finished, the lifting gear 16 is meshed with the meshing gear ring 142 to enable the two sliding shafts 14 to axially move away from each other, and at the moment, the sliding block 13 slides towards the side far away from the material inlet/outlet 111 along the linear rail 12 to enable the V-shaped stirring tank 11 to be lifted and returned to enter a stirring station; then, the speed reducer 15 is driven by the mixing motor, and the slippage shaft 14 is driven by the speed reducer 15 to rotate, so that the V-shaped stirring tank 11 is turned and stirred; after stirring is completed, the V-shaped stirring tank 11 is rotated to enable the material inlet and outlet 111 to face downwards, so that operators can conveniently take mixed metal powder, the lifting gear 16 is controlled to be meshed with the meshing toothed ring 142 to enable the two sliding shafts 14 to axially move to be close to each other, at the moment, the sliding block 13 slides towards one side of the material inlet and outlet 111 along the linear rail 12, and due to the fact that the material inlet and outlet 111 faces downwards, the V-shaped stirring tank 11 can be caused to ascend, and a sufficient material receiving space is provided below the material inlet and outlet 111; the sliding groove 141 is preferably a spline groove, and is matched with an inner spline of a shaft hole of an output shaft of the speed reducer 15, so that the speed reducer 15 can provide circumferential torque for the sliding shaft 14 and the sliding shaft 14 can slide in the axial direction; the meshing ring gear 142 is annular, so that the meshing ring gear 142 on the outer wall of the sliding shaft 14 can be meshed one by one to realize axial driving when the lifting gear 16 rotates, the meshing ring gear 142 can rotate on the tooth surface of the lifting gear 16 when the sliding shaft 14 rotates in the circumferential direction, and the axial motion are not interfered with each other; the labor intensity of workers is effectively reduced, and particularly in the mixing of the hard alloy powder, the weight of the hard alloy powder is far higher than that of common metal, so that the physical ability requirement of operators is higher.

In this embodiment, the V-shaped stirring tank 11 is provided with a material inlet and outlet 111 only at the bottom of the tank.

In the above-mentioned structure, business turn over material mouth 111 is equipped with the valve (not shown in the figure), through business turn over material mouth 111 control feeding and the ejection of compact, has removed the structure that traditional top was uncapped from, effectively reduces the possibility that other tiny gaps exist in the V-arrangement agitator tank 11, has avoided mixing later stage gap in the powder drop and has caused the inconsistent condition of mixture proportion to take place and influence the performance after the carbide shaping sintering.

In this embodiment, the reducers 15 on both sides of the machine base 10 are worm gear reducers.

In the structure, the worm gear reducer has self-locking performance, can lock the position of the V-shaped stirring tank 11, and avoids abnormal rotation caused by unstable gravity center of the tank body of the V-shaped stirring tank 11 after shutdown; meanwhile, the hybrid motor can be selected as a brake motor to replace a worm and gear reducer.

In this embodiment, the reducers 15 on both sides of the machine base 10 can be individually connected with the hybrid motor one by one, or share one hybrid motor to provide power.

In the structure, the optimal scheme is that one hybrid motor drives two speed reducers 15 through a transmission shaft system simultaneously, so that the consistency of the rotating speed can be ensured.

In this embodiment, the lifting motor 161 drives the lifting gear 16 to rotate through the lifting reduction box 162.

In the above structure, the lifting reduction box 162 can reduce the speed and increase the torque of the lifting motor 161; the lift motor 161 is preferably a brake motor with a brake.

In this embodiment, the lifting reduction boxes 162 on both sides of the machine base 10 can be individually connected with the lifting motors 161 one by one, or share one lifting motor 161 to provide power.

In the above structure, the preferred scheme is to drive two reduction gear boxes 162 through a transmission shaft system by one lifting motor 161, so as to ensure the consistency of the rotating speed.

In this embodiment, the reduction gearbox 162 is a worm gear reducer.

In the structure, the worm gear reducer has self-locking performance, and the possibility that the sliding shaft 14 slides axially due to the self weight of the V-shaped stirring tank 11 after the lifting motor 161 is stopped can be avoided.

In this embodiment, when the hybrid motor and the lifting motor 161 are matched with a worm reducer, the motor may be a stepping motor or a servo motor.

The utility model has the advantages that: through two linear rails 12 arranged in a V-shaped included angle manner, the V-shaped stirring tank 11 can be driven to generate lifting motion along the height direction of the V-shaped stirring tank by utilizing the synchronous axial stretching close or far of two sliding shafts 14; during feeding, the V-shaped stirring tank 11 is rotated to enable the feeding and discharging port 111 to face upwards, in order to reduce the height of the V-shaped stirring tank 11 at the moment, so that the metal powder is convenient for workers to pour, the lifting gear 16 is meshed with the meshing toothed ring 142 to enable the two sliding shafts 14 to axially move close to each other, and at the moment, the sliding block 13 slides towards one side of the feeding and discharging port 111 along the linear rail 12 to enable the V-shaped stirring tank 11 to descend; after the material is loaded, the lifting gear 16 is meshed with the meshing gear ring 142 to enable the two sliding shafts 14 to axially move away from each other, and at the moment, the sliding block 13 slides to the side far away from the material inlet/outlet 111 along the linear rail 12 to enable the V-shaped stirring tank 11 to be lifted and returned to enter a stirring station; then, a speed reducer 15 is driven by a mixing motor, and a sliding shaft 14 is driven by the speed reducer 15 to rotate, so that the V-shaped stirring tank 11 is turned and stirred; after stirring is completed, the V-shaped stirring tank 11 is rotated to enable the material inlet and outlet 111 to face downwards, so that operators can conveniently take mixed metal powder, the lifting gear 16 is controlled to be meshed with the meshing toothed ring 142 to enable the two sliding shafts 14 to axially move to be close to each other, at the moment, the sliding block 13 slides towards one side of the material inlet and outlet 111 along the linear rail 12, and the V-shaped stirring tank 11 can be lifted due to the downward state of the material inlet and outlet 111, so that a sufficient material receiving space is provided below the material inlet and outlet 111; the sliding groove 141 is preferably a spline groove, and is adapted to an inner spline of a shaft hole of an output shaft of the speed reducer 15, so that the speed reducer 15 can provide circumferential torque for the sliding shaft 14, and the sliding shaft 14 can slide in the axial direction; the meshing ring gear 142 is annular, so that the meshing ring gear 142 on the outer wall of the sliding shaft 14 can be meshed one by one to realize axial driving when the lifting gear 16 rotates, the meshing ring gear 142 can rotate on the tooth surface of the lifting gear 16 when the sliding shaft 14 rotates in the circumferential direction, and the axial motion are not interfered with each other; the labor intensity of workers is effectively reduced, and particularly in the mixing of the hard alloy powder, the weight of the hard alloy powder is far higher than that of common metal, and the requirement on the physical ability of operators is higher.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations of the above assumption should also be regarded as the protection scope of the present invention.

Claims (7)

1. The utility model provides a powder metallurgy V-arrangement agitating unit, includes the frame, sets up the V-arrangement agitator tank on the frame, its characterized in that: two linear rails extending from the top of the tank to the material inlet and the material outlet at the bottom of the tank are respectively arranged on two side walls of the V-shaped stirring tank, the two linear rails are arranged in a V-shaped included angle shape, sliding blocks are respectively arranged on the linear rails, a sliding shaft is fixed on each sliding block of each side linear rail, and the centers of the sliding shafts of the two linear rails are concentric; the outer wall of the sliding shaft is provided with a sliding groove which is arranged along the axial direction of the sliding shaft and a plurality of meshing gear rings which are arranged along the circumferential direction of the sliding shaft at intervals; the two sides of the base are respectively provided with a speed reducer which is matched with the sliding grooves of the sliding shafts in an axial sliding manner and is driven by a hybrid motor to realize circumferential rotation of the sliding shafts; and the two sides of the base are also provided with lifting gears which are meshed with the meshing gear rings of the sliding shafts and used for controlling the sliding shafts to slide axially, and the lifting gears are controlled to rotate by a lifting motor.

2. The powder metallurgy V-shaped stirring device according to claim 1, wherein: and the V-shaped stirring tank is provided with a material inlet and a material outlet only at the bottom of the tank.

3. The powder metallurgy V-shaped stirring device according to claim 1, wherein: the speed reducers on two sides of the base are worm and gear speed reducers.

4. A powder metallurgy V-shaped stirring apparatus according to claim 1 or 3, wherein: the speed reducers on two sides of the base can be individually connected with the hybrid motor in a one-to-one manner or share the hybrid motor to provide power.

5. The powder metallurgy V-shaped stirring device according to claim 1, wherein: the lifting motor drives the lifting gear to rotate through the lifting reduction gearbox.

6. The powder metallurgy V-shaped stirring device according to claim 5, wherein: the lifting reduction boxes on two sides of the base can be individually connected with the lifting motor in a one-to-one manner or share one lifting motor to provide power.

7. A powder metallurgy V-shaped stirring device according to claim 5 or 6, wherein: the lifting reduction gearbox is a worm gear reducer.

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