CN216941203U - Herringbone fly ash building block slurry discharging mechanism - Google Patents

Abstract

The utility model provides a novel herringbone fly ash block slurry blanking mechanism which is suitable for injecting materials into a long pouring groove and can be quickly leveled; specifically, the technical scheme adopted by the utility model is as follows: a herringbone fly ash building block slurry blanking mechanism comprises a slurry tank, a material distribution plate, a herringbone blanking groove, a guide rail frame, a pouring groove and a lifting platform; the material distribution plate is a 90-degree right-angle folded plate and is fixed below a discharge hole of the slurry tank through a steel bar; the vertical distance between the folded ridge of the material distributing plate and the material outlet is D, wherein D is the diameter of the material outlet; the vertical distance between the material distributing plate and the groove body of the blanking groove is greater than the maximum diameter of the hinge lug; because the maximum opening angle of the herringbone blanking groove is 90 degrees, the groove bodies of the left blanking groove and the right blanking groove are in contact, and the effect of slurry shunting can be achieved.

Description

Herringbone fly ash building block slurry discharging mechanism

Technical Field

The utility model relates to fly ash building material processing equipment, in particular to a herringbone fly ash building block slurry blanking mechanism.

Background

With the development of society and huge energy consumption, building energy conservation becomes a worldwide trend, and new requirements on novel wall materials are also provided. The fly ash building block is a light porous building material prepared by taking fly ash as a main raw material, proportionally mixing with auxiliary materials such as a gas former and the like, blending, adding water and stirring, and then performing the working procedures of pouring, standing, blank cutting, autoclaved curing and the like.

The casting groove used for casting is large in size, the length of the casting groove is about six meters generally, the common slurry tank is provided with only one vertical feed opening, long time is needed for slurry to be injected into the casting groove to flow flat, manual flattening is needed, and the production period and the labor amount of workers are increased.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems in the prior art, the utility model provides a novel herringbone fly ash block slurry blanking mechanism which is suitable for injecting materials into a long pouring groove and can be quickly leveled.

Specifically, the technical scheme adopted by the utility model is as follows:

a herringbone fly ash building block slurry blanking mechanism comprises a slurry tank, a material distribution plate, a herringbone blanking groove, a guide rail frame, a pouring groove and a lifting platform;

the material distribution plate is a 90-degree right-angle folded plate and is fixed below a discharge hole of the slurry tank through a steel bar; the vertical distance between the folded ridge of the material distributing plate and the material outlet is D, wherein D is the diameter of the material outlet; the vertical distance between the material distributing plate and the groove body of the blanking groove is greater than the maximum diameter of the hinge lug;

because the biggest opening angle of silo under the herringbone is 90, the cell body contact of two silos down about this moment can play the effect that the thick liquids shunted, along with filling thick liquids and lift platform down, the opening angle of silo under the herringbone reduces, and the cell body of two silos rotates thereupon and parts, just no longer has the function that the thick liquids shunted, consequently need set up the branch flitch alone. Meanwhile, the slurry of the building block is considered to have good fluidity, and the baffle of the discharging groove plays a role in blocking the slurry from transversely scattering, so that the protective wing baffle is not required to be added to the material distributing plate, and the width of the material distributing plate can play a sufficient flow distributing role as long as the width of the material distributing plate is larger than D. Further, in order to make the flow dividing process more controllable, it is preferable that the width of the material dividing plate is adapted to the width of the discharging chute.

The herringbone blanking groove comprises a support, a left blanking groove and a right blanking groove, and the opening angle of the herringbone blanking groove is 25-90 degrees;

the feeding trough comprises a U-shaped trough body, hinge lugs, suspension lugs and baffle plates, the width of the trough body is at least 1.5D and is not more than 2/3 of the width of the pouring trough, the baffle plates are semicircular and are welded with the side wall of the trough body into a whole, the radius of the baffle plates is equal to the height of the side wall of the trough body, the hinge lugs and the suspension lugs are both circular, the hinge lugs are arranged on two sides of the bottom of the top end of the trough body, and the suspension lugs are arranged on two sides of the bottom of the lower end of the trough body;

the support comprises a cross rod and two vertical rods vertically connected with two ends of the cross rod;

the left discharging groove and the right discharging groove are hinged with the cross rod through the hinge lugs and are fixed at the bottom of the slurry tank through the vertical rods to form a herringbone discharging groove;

the guide rail frames are composed of hanging rods and V-shaped bearings, the V-shaped bearings are arranged on transverse short shafts extending from the bottom ends of the hanging rods, through holes are formed in the top ends of the hanging rods, the four guide rail frames are symmetrically arranged at two ends of the herringbone blanking groove in a pairwise mode through cross frames penetrating through the hanging lugs;

guide rails are arranged on two sides of the pouring groove, are symmetrically arranged by taking the center line of the side surface of the pouring groove as an axis and are inclined towards two ends, and the inclination angle is 1 degree; the pouring groove is hung below the herringbone blanking groove through the guide rail and the V-shaped bearing of the guide rail frame, and meanwhile, the pouring groove is placed on the lifting platform.

The utility model adopts a herringbone blanking mechanism, the initial position is a herringbone blanking groove 90-degree angle state, building block slurry of the slurry tank is divided by a material dividing plate arranged below after a discharge port is opened, the slurry is guided to two sides of the herringbone blanking groove, the divided slurry is injected into a pouring groove, when the slurry height at the position corresponding to the tail end of the herringbone blanking groove reaches 4/5 with a preset height, a lifting platform begins to slowly descend, and simultaneously, a V-shaped bearing is driven to slide towards the middle along a guide rail, so that two arms (namely the blanking groove) of the herringbone blanking groove are close together, and the operation of uniform distribution is finished.

In order to better prevent the slurry from splashing caused by the initial fluctuation of the split flow, particularly because the material distribution plate is fixed, the fall between the material distribution plate and the discharging groove becomes larger along with the reduction of the angle of the herringbone discharging groove, and the splashing condition can be more serious, the discharging groove further comprises a splash guard which is a section of U-shaped groove and is buckled at the upper end of the discharging groove. Furthermore, the tail part of the splash-proof groove is also provided with a separation blade, and the separation blade is hinged with the tail part of the splash-proof groove.

Furthermore, the width of the material distributing plate is matched with the width of the blanking groove, so that the material distributing process is more stable.

Further, the length of the vertical rod is larger than that of the tail section of the blanking groove, and the tail section refers to a section of the blanking groove below the suspension lug.

Compared with the prior art, the utility model has the beneficial effects that: the utility model adopts the herringbone blanking mechanism, the flow distribution flow direction is simple and stable, the grouting is carried out by gradually closing from two ends to the middle, the quick grouting and the slurry leveling can be realized, the leveling time of the slurry is greatly shortened under the condition of not arranging a vibration platform, and sufficient time is provided for foaming and shaping. The feed chute basically adopts an open structure, so that the feed chute is convenient to clean. The whole structure is simple, the requirement on control precision is not high, the device is suitable for the workshop operation environment, all main components are mutually related and independent, and the maintenance is very convenient.

Drawings

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

Fig. 2 is a side view of fig. 1.

Fig. 3 is a structural schematic diagram of the material distributing plate.

Fig. 4 is a schematic structural diagram of the blanking trough.

Fig. 5 is a top view of fig. 4.

Fig. 6 is a schematic structural view of the rail bracket.

In the figure, 1-slurry tank, 2-material distributing plate, 3-herringbone blanking tank, 4-guide rail frame, 5-casting tank and 6-lifting platform.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clear, the present invention is further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

As shown in fig. 1-6, a herringbone fly ash building block slurry blanking mechanism comprises a slurry tank 1, a material distribution plate 2, a herringbone blanking groove 3, a guide rail frame 4, a pouring groove 5 and a lifting platform 6;

the material distribution plate 2 is a 90-degree right-angle folded plate, the material distribution plate 2 is fixed below a discharge port of the slurry tank 1 through a steel bar, the vertical distance between a folded ridge of the material distribution plate 2 and the discharge port below the slurry tank 1 is D, and D is the diameter of the discharge port; the vertical distance between the material distributing plate 2 and the groove body 9 of the blanking groove 7 is larger than the maximum diameter of the hinge lug 10;

the herringbone blanking groove 3 comprises a support 8 and a left blanking groove 7 and a right blanking groove 7;

the blanking groove 7 comprises a groove body 9, a hinge lug 10, a suspension lug 11 and a baffle 12, and the width of the groove body is at least 1.5D and is not more than 2/3 of the width of the casting groove 5; the baffle 12 is semicircular and has the radius equal to the height of the side wall of the tank body 9, and is welded with the side wall of the tank body 9, the hinge lugs 10 and the suspension lugs 11 are both circular rings, the hinge lugs 10 are arranged on two sides of the bottom of the top end of the tank body 9, and the suspension lugs 11 are arranged on two sides of the bottom of the lower end of the tank body 9;

the support 8 comprises a cross rod 13 and two vertical rods 14 vertically connected with two ends of the cross rod 13;

the two discharging troughs 7 are hinged with the cross rod 13 through the hinge lugs 10 and are fixed at the bottom of the slurry tank 1 through the vertical rods 14 to form a herringbone discharging trough 3;

the guide rail frames 4 are composed of hanging rods 15 and V-shaped bearings 16, the V-shaped bearings 16 are arranged on transverse short shafts extending from the bottom ends of the hanging rods 15, through holes are formed in the top ends of the hanging rods 15, the number of the guide rail frames 4 is four, and the four guide rail frames 4 are symmetrically arranged at two ends of the herringbone blanking chute 3 in pairs through transverse frames 17 penetrating through 7 hanging lugs 11;

guide rails 18 are arranged on two sides of the casting groove 5, the guide rails 18 are arranged in an axisymmetric mode by taking the center line of the side face of the casting groove 5 as an axis and are inclined towards two ends, and the inclination angle is 3 degrees; the casting trough 5 is hung below the herringbone blanking trough 3 through a guide rail 18 and a V-shaped bearing 16 of a guide rail frame 4, and meanwhile, the casting trough 5 is placed on the lifting platform 6.

Because the biggest opening angle of silo 3 is 90 under the herringbone, the cell body 9 contact of two silos 7 this moment, can play the effect that the thick liquids shunted, along with pour into thick liquids and lift platform down, the opening angle of silo 3 under the herringbone reduces, and the cell body 9 of two silos 7 rotates thereupon and parts, just no longer has the function that the thick liquids shunted, consequently need set up branch flitch 2 alone. Meanwhile, considering that the slurry of the building block has good fluidity and the baffle 12 with the blanking groove 7 plays a role in blocking the slurry from transversely scattering, the material distributing plate 2 does not need to be additionally provided with a protective wing baffle, and the width of the material distributing plate can play a sufficient flow distributing role as long as the width of the material distributing plate is larger than D. Further, in order to make the flow dividing process more controllable, it is preferable that the width of the material dividing plate 2 should be adapted to the width of the blanking groove 7.

As a further preferred embodiment of the present invention, the discharging chute 7 further comprises a splash guard, the splash guard is a section of U-shaped groove, and the U-shaped groove is buckled at the upper end of the discharging chute 7.

Furthermore, the tail part of the splash-proof slot is also provided with a separation blade, and the separation blade is hinged with the tail part of the splash-proof slot 7.

Still further, the length of the vertical rod 14 is greater than the length of the tail section of the discharging groove 7.

The above are only some of the preferred embodiments of the present invention and are not limited to the above embodiments.

Claims (3)

1. A herringbone fly ash building block slurry blanking mechanism is characterized by comprising a slurry tank, a material distribution plate, a herringbone blanking groove, a guide rail frame, a pouring groove and a lifting platform;

the material distribution plate is a 90-degree right-angle folded plate, the material distribution plate is fixed below a discharge port of the slurry tank through a steel bar, and the vertical distance between a folded ridge of the material distribution plate and the discharge port is D;

the herringbone blanking groove comprises a support, a left blanking groove and a right blanking groove, and the opening angle of the herringbone blanking groove is 25-90 degrees;

the blanking groove comprises a groove body, hinge lugs, suspension lugs and baffle plates, the width of the groove body is at least 1.5D and is not more than 2/3 of the width of the pouring groove, the baffle plates are semicircular and are welded with the side wall of the groove body into a whole, the radius of the baffle plates is equal to the height of the side wall of the groove body, the hinge lugs and the suspension lugs are both circular, the hinge lugs are arranged on two sides of the bottom of the top end of the groove body, and the suspension lugs are arranged on two sides of the bottom of the lower end of the groove body;

the support comprises a cross rod and two vertical rods vertically connected with two ends of the cross rod;

the two discharging troughs are hinged with the cross rods through the hinge lugs and fixed at the bottom of the slurry tank through the vertical rods to form herringbone discharging troughs;

the guide rail frames are composed of hanging rods and V-shaped bearings, the V-shaped bearings are arranged on transverse short shafts extending from the bottom ends of the hanging rods, through holes are formed in the top ends of the hanging rods, the four guide rail frames are symmetrically arranged at two ends of the herringbone blanking groove in a pairwise mode through cross frames penetrating through the hanging lugs;

guide rails are arranged on two sides of the pouring groove, are symmetrically arranged by taking the center line of the side surface of the pouring groove as an axis and are inclined towards two ends, and the inclination angle is 1 degree; the pouring groove is hung below the herringbone blanking groove through the guide rail and the V-shaped bearing of the guide rail frame, and meanwhile, the pouring groove is placed on the lifting platform;

the vertical distance between the material distributing plate and the groove body of the blanking groove is larger than the maximum diameter of the hinged lug.

2. The herringbone fly ash block slurry blanking mechanism of claim 1, which is characterized in that: the blanking trough further comprises a splash guard which is a section of U-shaped groove and is buckled at the upper end of the blanking trough.

3. The herringbone fly ash block slurry blanking mechanism of claim 1, which is characterized in that: the length of the vertical rod is greater than that of the tail section of the discharging groove.

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