CN210681865U - Anti-blocking steel bin for limestone warehouse - Google Patents

Abstract

The utility model relates to a lime stone batching storehouse, concretely relates to prevent stifled steel storehouse for lime stone storehouse, strike the mechanism including steel storehouse body and a plurality of shaking, the steel storehouse body is installed in the lime stone storehouse, vacuole formation between steel storehouse body and the lime stone storehouse, the upper end of steel storehouse body and the lateral wall fixed connection of storage silo, the lower extreme and the unloading awl fill fixed connection of steel storehouse body, every shakes and strikes the mechanism and includes shakes and strike the unit, shake and strike the unit and include the cam pack, the cam pack includes fixed part, pars contractilis and spring, the fixed part rotates and sets up in the cavity, pars contractilis and fixed part pass through spring coupling, and pars contractilis can strike the lateral wall of steel storehouse body. When the technical scheme is adopted, the smoothness of limestone blanking can be improved.

Description

Anti-blocking steel bin for limestone warehouse

Technical Field

The utility model relates to a lime stone batching storehouse, concretely relates to prevent stifled steel storehouse for lime stone storehouse.

Background

A cement plant usually uses a limestone silo to temporarily store limestone powder and then transfers the limestone in batches to the next process. The existing limestone silo consists of a storage bin at the upper end and a feeding cone hopper at the lower end, and the limestone powder is found to be easily adhered to the side wall of the feeding cone hopper in the actual transferring process, so that the normal feeding is influenced; through analysis, the limestone is easy to form wall on the side wall of the blanking cone hopper mainly has two reasons, firstly, the limestone base is made of cement, and the limestone and the side wall of the limestone base have larger friction force and are easier to bond; secondly, the slope of unloading awl fill is less, and the lime stone is also relatively more easily adhered to on the unloading awl fill to form and connect the wall and influence the lime stone normally unloading.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a can improve smooth and easy degree of stifled steel storehouse of lime stone unloading.

In order to achieve the purpose, the technical scheme of the utility model provide a prevent stifled steel storehouse for limestone silo, strike the mechanism including steel storehouse body and a plurality of shaking, the steel storehouse body is installed in the limestone storehouse, vacuole formation between steel storehouse body and the limestone storehouse, the upper end of steel storehouse body and the lateral wall fixed connection of storage silo, the lower extreme and the unloading awl fill fixed connection of steel storehouse body, every shakes and strikes the mechanism and including shaking and strike the unit, shake and strike the unit and include the cam pack, the cam pack includes fixed part, pars contractilis and spring, the fixed part rotates and sets up in the cavity, pars contractilis and fixed part pass through spring coupling, and the pars contractilis can strike the lateral wall of steel storehouse body.

The technical effect of the scheme is as follows: by installing the steel bin body in the limestone warehouse, a cavity is formed between the steel bin body and the limestone warehouse, namely the gradient of the steel bin body is greater than that of the blanking cone hopper, and meanwhile, the inner side wall of the steel bin body is smooth, so that limestone powder is not easily adhered to the steel bin body; and be provided with the cam subassembly in the cavity, the fixed part of cam subassembly rotates the in-process, can drive the lateral wall that the pars contractilis knocked the steel storehouse body through the spring to make the vibration of steel storehouse body, thereby prevent the adhesion of limestone flour on the inside wall of steel storehouse body.

Furthermore, the vibration and knocking unit also comprises a support rod, and the fixed part is rotatably connected with the side wall of the limestone warehouse through the support rod; the cam assembly further comprises a guide rod, a concave hole is formed in the telescopic portion, the guide rod is fixedly connected with the fixing portion, the spring sleeve is arranged on the guide rod, one end of the spring is fixedly connected with the fixing portion, and the other end of the spring is fixedly connected with the bottom of the concave hole. The technical effect of the scheme is as follows: the telescopic part can be guided by the guide rod in the contact process of the telescopic part and the steel bin body, and the spring is ensured to normally stretch.

Further, the lower extreme that the unloading awl was fought is equipped with the opening, and every shakes and beats the mechanism and still includes conveyer belt and rotation unit, the rotation unit rotates and sets up in the opening part, and the rotation unit includes the dwang and fixes a plurality of rotor plates on the dwang, the dwang rotates with the lateral wall that the unloading awl was fought to be connected, bracing piece and dwang pass through the conveyer belt and are connected. The technical effect of the scheme is as follows: strike the rotor plate through limestone flour unloading in-process, can drive the dwang and rotate to drive the bracing piece through the conveyer belt and rotate, and then drive fixed part and pars contractilis and rotate, strike the steel storehouse body, practice thrift power resources more.

Further, the supporting rod and the rotating rod are coaxially fixed with gears, the conveying belt is a gear conveying belt, and the gear conveying belt is meshed with the gears. The technical effect of the scheme is as follows: the gear conveyer belt can drive bracing piece and dwang to rotate smoothly, avoids skidding.

Furthermore, the gear coaxially fixed on the rotating rod is positioned at the outer side of the blanking cone hopper. The technical effect of the scheme is as follows: the area of the rotating plate is ensured to be larger, the impact of more limestone powder can be received, and the rotating rod is ensured to normally rotate.

Furthermore, the lateral wall of the storage bin is provided with an annular groove, and the upper end of the steel bin body is positioned in the annular groove. The technical effect of the scheme is as follows: the upper end of the steel bin body is positioned in the annular groove, so that limestone powder can be prevented from being accumulated and adhered to the upper end of the steel bin body.

Furthermore, a T-shaped hole is formed in the lower end of the steel bin body. The technical effect of the scheme is as follows: after the lower end of the steel bin body is fixedly connected with the discharging cone hopper through the bolt, the head of the bolt can be located in the T-shaped hole, and the limestone powder is prevented from being blocked by the bolt.

Further, the lateral wall of steel storehouse body is equipped with annular strengthening rib. The technical effect of the scheme is as follows: on the one hand, the strength of the steel bin body can be enhanced, and on the other hand, the knocking effect of the telescopic part on the steel bin body can be improved.

Furthermore, the surface of the reinforcing rib is arc-shaped. The technical effect of the scheme is as follows: ensure the transition to be smoother after the telescopic part contacts with the reinforcing rib.

Further, still include the bearing, the bracing piece passes through the bearing with the lateral wall in limestone warehouse and rotates and be connected, the dwang passes through the bearing with the lateral wall that the unloading awl was fought and rotates and be connected. The technical effect of the scheme is as follows: ensure that bracing piece and dwang rotate smoothly, can improve the stability of rotation in-process simultaneously.

Drawings

Fig. 1 is a front cross-sectional view of an embodiment of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a view taken along line A-A of FIG. 1;

FIG. 4 is a schematic view of the cam assembly of FIG. 2.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: the device comprises a steel bin body 1, a cavity 2, a storage bin 3, a discharging cone hopper 4, a reinforcing rib 5, a supporting rod 6, a fixing part 7, a telescopic part 8, a spring 9, a concave hole 10, a guide rod 11, a conveying belt 12, a rotating rod 13, a rotating plate 14 and a gear 15.

Example 1:

example 1 is substantially as shown in figures 1 to 3: as shown in fig. 1, the anti-blocking steel silo for the limestone silo comprises a steel silo body 1 and two vibrating and knocking mechanisms, wherein the steel silo body 1 is installed in the limestone silo, and a cavity 2 is formed between the steel silo body 1 and the limestone silo. Limestone base comprises storage silo 3 and the unloading awl of lower extreme of upper end and fights 4, the inside wall of storage silo 3 is opened there is the ring channel, the upper end of steel storehouse body 1 is located the ring channel, and the inside wall fixed connection of bolt and storage silo 3 is passed through to the upper end of steel storehouse body 1, the lower extreme of steel storehouse body 1 is opened there is "T" shape hole, the bolt passes "T" shape hole will be as shown the lower extreme and the unloading awl of the steel storehouse body 1 of fig. 2 fight 4 fixed connection, the welding of the lateral wall of steel storehouse body 1 has annular strengthening rib 5, the surface of strengthening rib 5 is the arc.

As shown in fig. 2, each vibration and knocking mechanism comprises a vibration and knocking unit, the vibration and knocking unit is located in the cavity 2, the vibration and knocking unit comprises a servo motor (not shown in the figure), a support rod 6 and a cam assembly, in the embodiment, the servo motor is a mitsubishi servo motor with the model of MR-J2S-100A, a rack (not shown in the figure) is fixedly installed on the inner side wall of the storage bin 3 through bolts, and the servo motor is fixedly installed on the rack through bolts; the rear end of bracing piece 6 and servo motor's output shaft coaxial weld, the front end of bracing piece 6 passes through the bearing and rotates the setting on the inside wall of storage silo 3, and it has the blind hole to open on the inside wall of storage silo 3 promptly, the outer lane of bearing and the pore wall interference fit of blind hole, the front end of bracing piece 6 and the inner circle interference fit of bearing.

As shown in fig. 4, the cam assembly comprises a fixing part 7, a telescopic part 8 and a spring 9, a hole is formed on the fixing part 7, and after the supporting rod 6 passes through the hole, the supporting rod 6 is welded with the fixing part 7; the telescopic part 8 is provided with a concave hole 10, the fixed part 7 is welded with a guide rod 11, the spring 9 is sleeved on the guide rod 11, one end of the spring 9 is welded with the fixed part 7, the other end of the spring 9 is welded with the groove bottom of the concave hole 10, and the telescopic part 8 can strike the reinforcing rib 5 on the outer side wall of the steel bin body 1 shown in fig. 2 in the rotating process.

Example 2:

on the basis of embodiment 1, as shown in fig. 2, each vibration and knock mechanism in embodiment 2 further includes a conveyor belt 12 and a rotating unit, the lower end of the lower material cone 4 is provided with an opening, the rotating unit is rotatably disposed at the opening, the rotating unit includes a rotating rod 13 and a plurality of rotating plates 14, and the rotating plates 14 are welded to the rotating rod 13. As shown in fig. 3, the rotating rod 13 is rotatably connected with the side wall of the discharging cone hopper 4 through a bearing, the rotating rod 13 is connected with the supporting rod 6 shown in fig. 2 through a conveyor belt 12, wherein the side wall of the discharging cone hopper 4 is provided with a through hole for the conveyor belt 12 to pass through. Certainly, as shown in fig. 3, gears 15 may also be coaxially tensioned on the rotating rod 13 and the supporting rod 6, the gear 15 on the rotating rod 13 is located outside the discharging cone 4, the gear 15 on the supporting rod 6 is located in the cavity 2, the conveyor belt 12 is a gear 15 conveyor belt 12, and the gear 15 conveyor belt 12 is engaged with the rotating rod 13 and the gear 15 on the supporting rod 6.

The specific implementation process is as follows:

by installing the steel bin body 1 in the limestone silo, the gradient of the steel bin body 1 is larger than that of the blanking cone hopper 4, and limestone powder is not easy to adhere to the steel bin body 1. As shown in fig. 2, the limestone powder impacts the rotating plate 14 to rotate clockwise in the falling process, so as to drive the rotating rod 13 to rotate clockwise, and further drive the supporting rod 6 to rotate clockwise through the conveying belt 12; the bracing piece 6 clockwise turning's in-process drives fixed part 7, spring 9 and the 8 clockwise rotations of pars contractilis, strikes strengthening rib 5 (this in-process spring 9 compression) after pars contractilis 8 and the 5 contacts on the 1 lateral wall of steel storehouse body to make 1 vibrations in steel storehouse body, and then prevent the adhesion of limestone flour on the inside wall of steel storehouse body 1.

The above are merely examples of the present invention, and common general knowledge of known specific structures and characteristics in the schemes is not described herein. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several modifications and improvements can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent.

Claims (10)

1. A prevent stifled steel storehouse for limestone warehouse, its characterized in that: including steel storehouse body and a plurality of mechanism of knocking that shakes, the steel storehouse body is installed in the limestone storehouse, forms the cavity between steel storehouse body and the limestone storehouse, the upper end of steel storehouse body and the lateral wall fixed connection of storage silo, the lower extreme and the unloading awl fill fixed connection of steel storehouse body, every shakes and beats the mechanism and including shaking and strike the unit, shake and strike the unit and include the cam subassembly, the cam subassembly includes fixed part, pars contractilis and spring, the fixed part rotates and sets up in the cavity, pars contractilis passes through spring coupling with the fixed part, and pars contractilis can strike the lateral wall of steel storehouse body.

2. The anti-blocking steel silo for a limestone silo according to claim 1, characterized in that: the vibration knocking unit further comprises a supporting rod, and the fixing part is rotatably connected with the side wall of the limestone warehouse through the supporting rod; the cam assembly further comprises a guide rod, a concave hole is formed in the telescopic portion, the guide rod is fixedly connected with the fixing portion, the spring sleeve is arranged on the guide rod, one end of the spring is fixedly connected with the fixing portion, and the other end of the spring is fixedly connected with the bottom of the concave hole.

3. The anti-blocking steel silo for a limestone silo according to claim 2, characterized in that: the lower extreme that the unloading awl was fought is equipped with the opening, and every shakes and beats the mechanism and still include conveyer belt and rotation unit, the rotation unit rotates and sets up in the opening part, and the rotation unit includes the dwang and fixes a plurality of rotor plates on the dwang, the dwang rotates with the lateral wall that the unloading awl was fought to be connected, bracing piece and dwang pass through the conveyer belt and are connected.

4. The anti-blocking steel silo for a limestone silo according to claim 3, characterized in that: the coaxial gear that is fixed with on bracing piece and the dwang, the conveyer belt is gear conveyer belt, gear conveyer belt and gear engagement.

5. The anti-blocking steel silo for a limestone silo according to claim 4, characterized in that: the gear coaxially fixed on the rotating rod is positioned on the outer side of the blanking cone hopper.

6. The anti-blocking steel silo for a limestone silo according to claim 5, characterized in that: the lateral wall of the storage bin is provided with an annular groove, and the upper end of the steel bin body is positioned in the annular groove.

7. The anti-blocking steel silo for a limestone silo according to claim 6, characterized in that: the lower end of the steel bin body is provided with a T-shaped hole.

8. The anti-blocking steel silo for a limestone silo according to claim 7, characterized in that: the lateral wall of steel storehouse body is equipped with annular strengthening rib.

9. The anti-blocking steel silo for a limestone silo according to claim 8, characterized in that: the surface of the reinforcing rib is arc-shaped.

10. The anti-blocking steel silo for a limestone silo according to claim 9, characterized in that: the support rod is rotatably connected with the side wall of the limestone warehouse through a bearing, and the rotating rod is rotatably connected with the side wall of the discharging cone hopper through a bearing.

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