CN113979057B

CN113979057B - Shunt direct-casting device

Info

Publication number: CN113979057B
Application number: CN202111108056.5A
Authority: CN
Inventors: 卢世昌; 白轩徽; 伍梅山
Original assignee: Liuzhou Yinuoshi Intelligent Equipment Co ltd; Guangzhou Yinuoshi Intelligent Equipment Co ltd
Current assignee: Liuzhou Yinuoshi Intelligent Equipment Co ltd; Guangzhou Yinuoshi Intelligent Equipment Co ltd
Priority date: 2021-09-22
Filing date: 2021-09-22
Publication date: 2024-04-12
Anticipated expiration: 2041-09-22
Also published as: CN113979057A

Abstract

The invention discloses a shunt direct-casting device. The invention comprises a split-flow double-throw device, wherein the split-flow double-throw device is provided with two double-throw discharge ports, and is characterized in that: the device comprises a mounting frame, wherein the rear part of the mounting frame is connected with a shunt double-throw device, the front part of the mounting frame is connected with a transverse moving frame device, a travelling trolley mechanism is arranged on the transverse moving frame device, the travelling trolley mechanism is connected with a direct-throw blanking device, and the direct-throw blanking device is connected with a bag shaping device; and a gate mechanism is arranged at the double-throw discharging hole. According to the invention, through the arrangement of the direct-feeding blanking device with a very simple structure, the posture of a loading vehicle of materials (mainly bag materials such as cement bags) can be effectively controlled, and the materials can be well piled up.

Description

Shunt direct-casting device

Technical Field

The invention relates to the technical field of feeding devices, in particular to a split-flow direct-feeding device.

Background

Based on the shortcoming of old-fashioned car loader in bags: the problem of loading inefficiency, the material in bags goods damage rate is higher and easy stifled package, I have designed new product: a bagged feeding car loader (application number: 202021080373.1) with a feeder capable of entering a carriage, mainly aiming at feeding a cement bag; a split-flow double-throw device (application number: 202120358888.1) of a loader mainly aims at material split-flow.

The use of kinetic energy to transport cement bags into the car is now on the market, however, the bag arrangement and grouping is limited. The car loading requirements of the bagged cement truck carriage with different widths, no tailgate carriage, side barrier refitted carriage, high guardrail carriage and the like are difficult to adapt, and the products cannot ensure that bags are delivered in place, so that the problem of poor bag delivery posture exists. Because the cement powder is a flexible substance, various states exist in the automatic feeding process, the bag is thrown by utilizing the repeated falling and packing device, the requirement on the coordination of the mutual actions of all the parts is high, the bag is easy to be blocked during conveying, and the manual intervention for processing the materials is difficult for the blocked bag. If the above problem uses a mechanism to push each packet in place, the whole stack is used for throwing the packets, the height of the packets is reduced, and although the arrangement posture of the packets is good, the mechanism is very complex in structure, the failure rate of the mechanism is high, and the mechanism is still unacceptable to customers.

For the above reasons, customers have higher demands on the throw of bags from a bag loader. Aiming at the demands of customers, a feeder with a shunt direct-casting device is newly designed on the basis of a bagged car loader, and the feeder is different from the existing car loader in structure and principle, so that the complex problem is simplified, the structure is very simple, and the feeder has a great breakthrough compared with the existing products.

Disclosure of Invention

The invention aims to provide a split-flow direct-casting device. According to the invention, through the arrangement of the direct-feeding blanking device with a very simple structure, the posture of a loading vehicle of materials (mainly bag materials such as cement bags) can be effectively controlled, and the materials can be well piled up.

The invention adopts the following technical scheme to realize the aim of the invention:

the utility model provides a reposition of redundant personnel direct-injection device, includes reposition of redundant personnel double-injection device, and reposition of redundant personnel double-injection device has two double-injection discharge gate, its characterized in that: the device comprises a mounting frame, wherein the rear part of the mounting frame is connected with a shunt double-throw device, the front part of the mounting frame is connected with a transverse moving frame device, a travelling trolley mechanism is arranged on the transverse moving frame device, the travelling trolley mechanism is connected with a direct-throw blanking device, and the direct-throw blanking device is connected with a bag shaping device; and a gate mechanism is arranged at the double-throw discharging hole.

In the shunt direct-casting device, the gate mechanism comprises a gate, and the gate is connected with a gate driving mechanism.

In the shunt direct-casting device, the travelling trolley mechanism comprises a mounting plate, and a composite bearing assembly, a travelling motor component, a rotating motor component and a sensor plate are arranged on the mounting plate.

In the shunt direct-casting device, the package shaping device comprises a shaping assembly, wherein the bottom of the shaping assembly is connected with a turning plate through a hinge, the turning plate is connected with a turning plate cylinder, and the turning plate cylinder is connected with a guide device.

In the shunt direct-casting device, the direct-casting blanking device comprises a frame assembly, a feed inlet is formed in one side wall of the frame assembly, a guide plate is arranged at the lower part of the feed inlet, an adjustable baffle is arranged at the upper part of the feed inlet, and a connection adjusting device is arranged on the adjustable baffle; and a discharge hole is formed in the lower portion of the frame assembly.

In the shunt direct-casting device, a frame feeding guide plate is arranged on the top plate of the frame assembly upwards at the upper part of the feeding hole.

In the shunt direct-casting device, the adjustable baffle comprises a feeding guide section, a blanking guide section and a discharging guide section.

In the shunt direct-casting device, the feeding guide section of the adjustable baffle is connected with the inner wall of the top plate of the frame assembly; the middle part of the blanking guide section is positioned at the discharge hole; the lower part of the discharging guide section is arranged in the bag shaping device.

In the shunt direct-casting device, a rotary gear is arranged at the top of the frame assembly and is connected with the travelling trolley mechanism.

In the shunt direct-casting device, a sealing plate is arranged at the bottom of the frame assembly and is connected with the bag shaping device.

The beneficial effects are that:

the invention provides a direct-casting blanking device, materials (mainly referred to as bag materials, such as cement bags) sent out from a conveyor belt of a split-flow double-casting device at a certain speed enter the direct-casting blanking device in a 'casting' mode, the posture of the materials is effectively adjusted under the action of gravity through a structure of a guide plate and an adjustable baffle plate, the posture of loading the materials is ensured, the materials can be put in place in a 'straightening' posture, the materials are shaped and fall into bags through a frame structure (shaping assembly), and orderly stacking of the materials is ensured.

Compared with the existing equipment, the special structure (the guide plate and the adjustable baffle) for realizing the technical purpose is very simple, the new casting and gravity working principle is used for controlling the material posture to cast the bag, and the bag is further shaped and falls after the material is cast in the bag posture is ensured. The invention not only simplifies the existing complex technology for solving the bag-throwing gesture by a new structure and a new principle, but also has extremely low failure rate compared with the direct-throwing blanking structure.

Drawings

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

FIG. 2 is a schematic elevational view of the present invention;

FIG. 3 is a schematic top view of the present invention;

FIG. 4 is a schematic structural view of a direct-throw blanking device;

FIG. 5 is a schematic diagram I of the state of the material package entering the direct-throw blanking device and the package shaping device;

FIG. 6 is a second schematic diagram of the state of the package entering the direct-throw blanking device and the package shaping device;

FIG. 7 is a schematic structural view of a travelling carriage mechanism;

fig. 8 is a schematic structural view of the packet shaping device.

The marks in the drawings are:

1-frame assembly, 2-feed inlet, 3-guide plate, 4-adjustable baffle, 5-discharge outlet, 6-frame feed guide plate, 7-rotary gear, 8-shrouding, 9-feed guide section, 10-blanking guide section, 11-discharge guide section, 12-adjusting device, 13-material package, 14-package shaping device, 15-shunt double-throw device, 16-mounting rack, 17-sideslip frame device, 18-walking trolley mechanism, 19-direct throw blanking device, 20-gate mechanism, 21-gate, 22-gate driving mechanism, 23-mounting plate, 24-composite bearing assembly, 25-walking motor component, 26-rotary motor component, 27-sensor board, 28-shaping assembly, 29-hinge, 30-turning plate, 31-turning plate cylinder, 32-guiding device.

A is a package projection track, and B is a gravity descent track.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

In the description of the present invention, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Examples. The split-flow direct-casting device is shown in fig. 1-8, and comprises a split-flow double-casting device 15, wherein the split-flow double-casting device 15 is provided with two double-casting discharge ports, the split-flow direct-casting device comprises a mounting frame 16, the rear part of the mounting frame 16 is connected with the split-flow double-casting device 15, the front part of the mounting frame 16 is connected with a traversing frame device 17, a travelling trolley mechanism 18 is arranged on the traversing frame device 17, the travelling trolley mechanism 18 is connected with a direct-casting blanking device 19, and the direct-casting blanking device 19 is connected with a bag shaping device 14; the double-throw discharging port is provided with a gate mechanism 20. The mounting frame 16 is preferably H-section steel.

The invention adds a direct-casting blanking device 19 above the background technology. When the inclined conveyor belt conveys the materials to the belt of the bag control mechanism, the materials are output at set time and enter the split double-throw device 15, the split double-throw device 15 detects incoming material signals (signals and control are realized through a conventional control system such as a PLC), and the material channel is switched through the air cylinder switch control splitter plate so as to receive the next bag of materials. After the materials enter the channel, the materials are respectively put into the two bag shaping devices 14 through the direct-feeding blanking device 19. The two bag shaping devices 14 are respectively driven independently with the two travelling trolley mechanisms 18 for linear travelling and rotation of the vertical bag-to-horizontal bag. After walking to the position appointed by the program, the two ladle shaping devices 14 are respectively charged and loaded, so that the loading efficiency is improved.

Preferably, the main body of the feeder provided with the device is 3.02 meters wide, and the two bag shaping devices can transversely move for 2.8 meters, so that the loading requirement of trucks with the width of not more than 2.8 meters in the carriage on the market is met. The height of the bag shaping device is 0.6 meter, so that the bag shaping device can be inserted into a carriage to reduce the feeding height, and the phenomenon of bag breaking caused by too high feeding outside a carriage baffle plate is avoided.

The shutter mechanism 20 includes a shutter 21, and the shutter 21 is connected to a shutter driving mechanism 22. The shutter drive mechanism 22 is preferably a cylinder. Two gates 21 are arranged at the double-throw discharging hole, and a gate driving mechanism 22 can control the opening and closing of the gates 21, so as to control whether the materials on the conveying belt of the split double-throw device 15 enter the direct-throw blanking device 19.

The travelling trolley mechanism 18 comprises a mounting plate 23, and a composite bearing assembly 24, a travelling motor component 25, a rotating motor component 26 and a sensor plate 27 are arranged on the mounting plate 23. The function of the sensor board 27 is, among other things, to mount a laser ranging sensor for vehicle gauge size detection. The detection content mainly comprises the length, width, height and various characteristic dimensions of the vehicle.

The bag shaping device 14 comprises a shaping assembly 28, wherein the bottom of the shaping assembly 28 is connected with a turning plate 30 through a hinge 29, the turning plate 30 is connected with a turning plate cylinder 31, and the turning plate cylinder 31 is connected with a guide device 32.

The direct-casting blanking device 19 comprises a frame assembly 1, a feed inlet 2 is formed in one side wall of the frame assembly 1, a guide plate 3 is arranged at the lower part of the feed inlet 2, an adjustable baffle 4 is arranged at the upper part of the feed inlet 2, and a connection adjusting device 12 is arranged on the adjustable baffle 4; the lower part of the frame assembly 1 is provided with a discharge hole 5. The guiding plate 3 and the adjustable baffle 4 guide the material bag 13 to enter and then form a projection, as shown in fig. 5; the bale 13 then undergoes a natural gravity descent under the action of the adjustable baffle 4, as shown in fig. 6.

The top plate of the frame assembly 1 is upwards provided with a frame feeding guide plate 6 at the upper part of the feeding hole 2. The feed guide plate 6 guides the bale 13 to better enter the feed inlet 2.

The adjustable baffle 4 comprises a feeding guide section 9, a blanking guide section 10 and a discharging guide section 11. The feeding guide section 9 of the adjustable baffle 4 is connected with the inner wall of the top plate of the frame assembly 1; the middle part of the blanking guide section 10 is positioned at the discharge hole 2; the lower part of the discharge guide section 11 is arranged in the ladle shaping device 14.

The feeding guide section 9 and the guide plate 3 guide incoming materials to be thrown preliminarily according to a preset track, the material bag 13 falls down according to the preset track after being further guided by the blanking guide section 10, as shown in fig. 5, one end of the material bag 13 falls onto the discharging guide section 11, and under the action of gravity, the material bag 13 can only turn down and fall down, as shown in fig. 6.

The top of the frame assembly 1 is provided with a rotary gear 7, and the rotary gear 7 is connected with a travelling trolley mechanism 18.

The bottom of the frame assembly 1 is provided with a sealing plate 8, and the sealing plate 8 is connected with a bag shaping device 14.

Further, in actual operation, the following steps are:

(1) the device is connected with an inclined conveying belt, and the conveying belt on a platform of a host manufacturer conveys materials to the inclined conveying belt of the bagged truck loader. The materials respectively enter the boxcar through four parts of a diversion double-throw device 15, a travelling trolley mechanism 18, a direct-throw blanking device 19 and a bag shaping device 14 of the feeder. The conveyer belt of the diversion belt device 15 can carry out stepless speed regulation according to different material characteristics so as to ensure the in-place ladle throwing of the next flow; the lifting device is connected with the lifting device of the loading machine through the H-shaped steel connected with the two sides, so that the lifting and the forward and backward walking of the device are realized.

The split double throw device 15 detects the incoming material signal and closes this channel by the cylinder and opens the other channel to receive the next packet of material. The first material is fed along the guide plate and through the belt conveyor gate mechanism 20. If the packet shaping device 14 receives the information from the origin position, the cylinder of the gate mechanism 20 is opened, and the material enters the direct-casting blanking device 19; the other channel material is the same as the above principle, and the high-efficiency diversion feeding work of the material is completed. The cylinder operation after receiving the information from the package shaping device 14 to the origin position is detected by a proximity switch sensor arranged below the traversing frame device 17, after the feeder reaches the receiving position (origin position), the proximity switch sensor obtains a signal, the signal is reflected to an upper system, then the upper system signals a double-electric control electromagnetic valve of a gate cylinder, and the valve core drives the cylinder to act after switching the gas path.

(2) After passing through the gate 21, the material is flushed onto the adjustable baffle 4 (the adjustable baffle 4 swings within a certain range of angles through the adjusting device 12, so as to ensure that the bag is thrown in place) along the guide plate 3 of the direct throwing blanking device 19 by the obtained kinetic energy, and the throwing schematic diagram is shown in fig. 5 in detail; the bag then does work by gravity, and is tipped over into the bag shaping device to complete the throwing and bag falling process, and the gravity drop schematic diagram is shown in fig. 6.

(3) The traveling trolley mechanism 18 is in butt joint with the direct-casting blanking device 19, and the composite bearing assembly 24 is arranged in a C-shaped guide rail of the transverse moving frame device 17 and is used for bearing and guiding (ensuring the motion track of the traveling trolley) of the moving part; the walking motor part 25 adopts a servo motor group to drive a gear, and drives the mounting plate to transversely move to a programmed position through a rack; the rotating motor part 26 adopts a servo motor group to drive a gear, and drives the direct-casting blanking device 19 and the bag shaping device 14 to rotate to a programmed position.

(4) The bag shaping device 14 is assembled with the direct-casting blanking device 19 integrally and is hung at the central position of the travelling trolley mechanism 18. When the bag is tipped over to the inner frame of the bag shaping device 14, the bag adjusts the posture by its own weight; after receiving the signal, the flap cylinder 31 extends out the piston rod of the flap cylinder 31. The two side guide rods (guide devices 32) are used for restraining, so that the two side turning plates 30 are ensured to be opened synchronously, and the bags are put in the programmed bag arranging positions.

In the above process, after the split-flow double-throw device 15 splits, materials are circularly conveyed out from two positions in sequence, and two groups of corresponding travelling trolley mechanisms 18, direct-throw blanking devices 19 and package shaping devices 14 are also arranged, so that the materials are sequentially thrown from the two package shaping devices 14 for loading after the direct-throw blanking devices 19 control the postures, and the loading efficiency is improved.

The preferred technical parameters of the invention are as follows:

TABLE 1 technical parameters and Performance indicators of split Belt apparatus

Table 2-technical parameters and performance index of the ladle shaping device and the gate mechanism:

name and specification	Technical parameter requirements
		Cylinder	63*200
Output thrust	170kgf
		Push-out time	0.3s

TABLE 3 technical parameters and Performance indicators of 1-running Trolley mechanism

Name of the name	Specification of specification	Parameters (parameters)
			Walking servoMotor with a motor housing	Power and torque	1kw
Speed reducer	Reduction ratio	5～7
			Gear wheel	Modulus and number of teeth	M＝3、z＝19
Travel time	Every 500mm	0.33s

Table 3-2-technical parameters and Performance indicators of the travelling bogie mechanism

Name of the name	Specification of specification	Parameters (parameters)
			Rotary servo motor	Power and torque	0.75kw
Speed reducer	Reduction ratio	10
			Gear wheel	Modulus and number of teeth	M＝3、z＝19
Time	Rotated 90 degrees	0.3s

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims

1. The utility model provides a reposition of redundant personnel direct-injection device, includes reposition of redundant personnel double-injection device (15), and reposition of redundant personnel double-injection device (15) have two double-injection discharge gate, its characterized in that: the device comprises a mounting frame (16), wherein the rear part of the mounting frame (16) is connected with a split-flow double-throw device (15), the front part of the mounting frame (16) is connected with a transverse moving frame device (17), a travelling trolley mechanism (18) is arranged on the transverse moving frame device (17), the travelling trolley mechanism (18) is connected with a direct-throw blanking device (19), and the direct-throw blanking device (19) is connected with a bag shaping device (14); a gate mechanism (20) is arranged at the double-throw discharging hole;

the direct-feeding blanking device (19) comprises a frame assembly (1), a feed inlet (2) is formed in one side wall of the frame assembly (1), a guide plate (3) is arranged at the lower part of the feed inlet (2), an adjustable baffle (4) is arranged at the upper part of the feed inlet (2), and a connection adjusting device (12) is arranged on the adjustable baffle (4); a discharge hole (5) is formed in the lower part of the frame assembly (1); the material bag enters from the feeding hole (2), forms a projection under the guidance of the guide plate (3) and the adjustable baffle (4), and then naturally descends under the action of the adjustable baffle (4); the adjustable baffle (4) can be adjusted to swing through the adjusting device (12) so as to ensure that the adjustable baffle is thrown into a preset track;

a top plate of the frame assembly (1) is upwards provided with a frame feeding guide plate (6) at the upper part of the feeding port (2); the feeding guide plate (6) guides the material bag (13) to smoothly enter the feeding port (2);

the adjustable baffle (4) comprises a feeding guide section (9), a blanking guide section (10) and a discharging guide section (11); the feeding guide section (9) of the adjustable baffle plate (4) is connected with the inner wall of the top plate of the frame assembly (1); the middle part of the blanking guide section (10) is positioned at the discharge hole (5); the lower part of the discharging guide section (11) is arranged in the bag shaping device (14); the feeding guide section (9) and the guide plate (3) guide the material package to be thrown according to a preset track, the material package (13) falls down according to the preset track after being further guided by the blanking guide section (10), one end of the material package falls onto the discharging guide section (11), then the material package does work by means of self gravity, and the material package is tipped into the package shaping device (14) to finish the throwing and package falling process.

2. The split direct-casting device according to claim 1, wherein: the gate mechanism (20) comprises a gate (21), and the gate (21) is connected with a gate driving mechanism (22).

3. The split direct-casting device according to claim 1, wherein: the travelling trolley mechanism (18) comprises a mounting plate (23), and a composite bearing assembly (24), a travelling motor component (25), a rotating motor component (26) and a sensor plate (27) are arranged on the mounting plate (23).

4. The split direct-casting device according to claim 1, wherein: the bag shaping device (14) comprises a shaping assembly (28), wherein the bottom of the shaping assembly (28) is connected with a turning plate (30) through a hinge (29), the turning plate (30) is connected with a turning plate cylinder (31), and the turning plate cylinder (31) is connected with a guide device (32).

5. The split direct-casting device according to claim 1, wherein: the top of the frame assembly (1) is provided with a rotary gear (7), and the rotary gear (7) is connected with a travelling trolley mechanism (18).

6. The split direct-casting device according to claim 1, wherein: the bottom of the frame component (1) is provided with a sealing plate (8), and the sealing plate (8) is connected with a bag shaping device (14).