CN109910220B - Forming machine for household appliance inner container - Google Patents

Abstract

The invention discloses a forming machine for a household appliance inner container, which comprises a feeding station, a heating station and a forming station, wherein the feeding station, the heating station and the forming station are linearly arranged, and are connected through a conveying device to form a forming assembly line, so that a plate sequentially passes through the heating station and the forming station through the conveying device at the feeding station; the forming station comprises a forming assembly and a cutting assembly, and the plate is cured in the forming station sequentially through the forming assembly and trimmed through the cutting assembly; one side that the shaping station is close to the heating station is equipped with the feed inlet, and one side that shaping station and feed inlet are relative is equipped with the discharge gate, and the transportation subassembly that is used for taking out the sheet material of machine-shaping is installed to the department at the discharge gate in the shaping station. The invention can reduce the labor intensity of operators, improve the automation degree of equipment and simultaneously improve the forming efficiency.

Description

Forming machine for household appliance inner container

Technical Field

The invention relates to a forming machine, in particular to a forming machine for an inner container of a household appliance.

Background

With the arrival of a new industrial age, society emphasizes the reduction of labor intensity, the improvement of equipment automation and the influence of industry on environment. At present, most of domestic existing household appliance inner container forming machines are old, low in production efficiency, low in automation degree, high in technical dependence on workers, low in automation degree of foaming lines owned by manufacturers and incapable of well performing automatic production.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides the forming machine for the household appliance inner container, which can reduce the labor intensity of operators, improve the automation degree of equipment and simultaneously improve the forming efficiency.

The technical scheme adopted by the invention for solving the technical problems is as follows: a forming machine for a household appliance inner container comprises a feeding station, a heating station and a forming station, wherein the feeding station, the heating station and the forming station are linearly arranged, and are connected into a forming assembly line through a conveying device, so that a plate sequentially passes through the heating station and the forming station through the conveying device at the feeding station;

the forming station comprises a forming assembly and a cutting assembly, and the plate is cured sequentially through the forming assembly in the forming station and trimmed through the cutting assembly;

the shaping station is close to one side of heating the station is equipped with the feed inlet, the shaping station with one side that the feed inlet is relative is equipped with the discharge gate, the shaping station is in discharge gate department installs and is used for taking out machine-shaping the transportation subassembly of sheet material.

Optionally, the cutting assembly and the forming assembly are respectively arranged at two sides of the forming station;

the cutting assembly comprises a cutting platform and a cutting knife group, the cutting knife group is arranged above the cutting platform and matched with the cutting platform, the cutting knife group is driven to reciprocate up and down by a driving assembly, and the driving assembly is fixedly arranged at the position of the cutting station.

Optionally, the cutting platform is mounted at the cutting station by a support assembly.

Optionally, the supporting component includes cylindrical barrel, locates first transmission shaft in the barrel, with second transmission shaft, the drive that first transmission shaft transmission is connected the first servo motor of second transmission shaft, cutting platform's bottom central point put be equipped with the collet that first transmission shaft top transmission is connected, and the collet with the top of barrel is rotated and is connected, first servo motor's output is equipped with and is used for detecting the angle sensor of the output corner of first servo motor output.

Optionally, a plurality of bearings matched with the first transmission shaft are fixedly installed in the cylinder, and the bottom of the first transmission shaft is arranged in the cylinder;

the bottom of the cylinder is provided with a through hole matched with the second transmission shaft, the axis of the through hole is distributed along the radial direction of the cylinder, one section of the second transmission shaft is inserted into the cylinder through the through hole and is in transmission connection with the bottom of the first transmission shaft, and the other end of the second transmission shaft is in transmission fit with the first servo motor;

the first transmission shaft and the second transmission shaft are perpendicular to each other.

Optionally, a plurality of annular check rings are further fixedly mounted in the cylinder body, a plurality of check blocks matched with the check rings are fixedly mounted on the shaft body of the first transmission shaft, the central angle of each check ring is 270 degrees, a groove matched with the head of each check block is formed in the end portion of each check ring, and the depth of each groove is consistent with the thickness or width of each check block.

Optionally, the transfer assembly comprises a linear moving pair, an air cylinder assembly is mounted on the linear moving pair, the output end of the air cylinder assembly faces vertically downwards, and a negative pressure manipulator is fixedly mounted at the output end of the air cylinder assembly.

Optionally, the feeding station includes a first feeding station and a second feeding station, an annular guide rail is installed on one side of the heating station away from the forming station, and the first feeding station and the second feeding station are installed on the annular guide rail.

Optionally, the transportation device includes a first transportation system, a second transportation system, and a third transportation system, the first transportation system is disposed between the feeding station and the heating station, and between the heating station and the forming station, the second transportation system and the third transportation system are disposed on one side of the forming station away from the heating station, and the second transportation system and the third transportation system are distributed in an up-and-down manner;

the discharge gate is including being first discharge gate and the second discharge gate that the following formula distributes, wherein, first discharge gate with the second conveying system is connected, the second discharge gate with the third conveying system is connected.

Optionally, the third transportation system is located below the second transportation system, and a cutting mechanism is provided at an end of the third transportation system.

By adopting the technical scheme, the invention has the following beneficial effects in the forming process:

1. according to the invention, the cutting assembly is arranged in the forming station, and the edge cutting treatment is carried out on the just-formed plate, so that the labor intensity of manual cutting is reduced, the automation degree of equipment is improved, and the forming efficiency of the equipment can be improved;

2. when the cutting assembly is installed, the cutting assembly is installed in the forming station, so that residual heat remains in the plate when the plate is cut, the cutting knife set can be ensured to cut the plate easily during cutting, meanwhile, scraps generated during cutting can be reduced, and the cutting efficiency of the plate is improved;

3. the cutting platform is supported by the supporting assembly, and the supporting assembly also has a rotating effect, so that the cutting direction of the plate can be changed by rotating the supporting assembly, and the cutting precision of the cutting assembly on the plate is improved;

4. the two discharge ports are arranged at the forming station and are respectively used for conveying out formed plates and waste materials generated after trimming, and the waste materials are broken through the breaking mechanism, so that the recovery efficiency of the waste materials is improved;

5. the double-feeding-station automatic feeding device adopts the double feeding stations, when one feeding station is used, the other feeding station can wait for the next feeding operation, when the plate material of the previous feeding station is used up, the plate material on the next feeding station can be directly taken for use in a seamless mode, and the continuity of feeding work is guaranteed.

Drawings

FIG. 1 is a schematic structural view of the present invention;

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

FIG. 3 is a schematic view of the construction of the cutting blade assembly of the present invention;

FIG. 4 is a schematic structural view of the drive assembly of the present invention;

FIG. 5 is a schematic structural view of the support assembly of the present invention;

FIG. 6 is a schematic view of the construction of the retainer ring of the present invention;

FIG. 7 is a schematic view of the position relationship between the retainer ring and the stopper according to the present invention;

FIG. 8 is a schematic structural view of a transfer module of the present invention;

fig. 9 is a schematic structural view of the cutting platform of the present invention.

Detailed Description

The present application will be described in further detail with reference to the following drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the relevant invention and not restrictive of the invention. It should be noted that, for convenience of description, only the portions related to the present invention are shown in the drawings.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

As shown in fig. 1, the invention discloses a forming machine for a liner of a household appliance, which comprises a feeding station 1, a heating station 2 and a forming station 3, wherein the feeding station 1, the heating station 2 and the forming station 3 are linearly arranged, the feeding station 1, the heating station 2 and the forming station 3 are connected into a forming assembly line through a conveying device 5, a plate raw material is carried to the heating station 2 through the conveying device 5 at the feeding station 1 for heating, and the heated plate raw material is carried to the forming station 3 through the conveying device 5 for forming.

In this embodiment, as shown in fig. 2, the forming station 3 includes a forming component 4 and a cutting component 6, the forming component 4 and the cutting component 6 can be installed in the forming box 303, and the forming component 4 may be a component in existing equipment. Therefore, the forming box body 303 is divided into a left part and a right part, the left part and the right part are respectively used for installing the forming component 4 and the cutting component 6, the left part and the right part are divided by taking the moving direction of the forming assembly line as a reference, namely, the left part of the forming box body 303 is one side close to the heating station 2, the right part of the forming box body 303 is one side opposite to the left part, after the plate materials are cured by the forming component 4 in the forming station 3 in sequence, the plate materials are pushed into the cutting component 6 through a moving push plate of the forming component 4, and then the edge cutting is carried out through the cutting component 6.

In this embodiment, a feeding hole 301 is formed in one side of the forming station 3 close to the heating station 2, a discharging hole 302 is formed in one side of the forming station 3 opposite to the feeding hole 301, and a transfer assembly 7 for taking out the sheet to be processed and formed is installed at the discharging hole 302 of the forming station 3, so that the feeding hole 301 and the discharging hole 302 are respectively formed in the left side and the right side of the forming box 303, and the transfer assembly 7 is formed in the right side of the forming box 303.

In the present embodiment, as shown in fig. 3, the cutting assembly 6 includes a cutting platform 601 and a cutter set 602, and the cutter set 602 is disposed above the cutting platform 601 and cooperates with the cutting platform 601 to trim the sheet material. The cutter assembly 602 is driven by a driving assembly 603 to reciprocate up and down, the driving assembly 603 is fixedly installed at the position of the cutting station 3, and the cutting platform 601 is installed at the position of the cutting station 3 through a supporting assembly 604.

As shown in fig. 4, the cutter set 602 includes a pair of cutting blades 6021 and a fixing plate 6022 for mounting the cutting blades 6021, wherein the cutting blades 6021 are uniformly distributed on both sides of the bottom of the fixing plate 6022, the pair of cutting blades 6021 are arranged in parallel, and the distance between the pair of cutting blades 6021 is adapted to the required size of the sheet.

As shown in fig. 5, the driving assembly 603 includes a second servo motor 6031, a driving rod 6032 and a cam assembly 6033, the second servo motor 6031 and the cam assembly 6033 are installed at the top position of the mold box 303, and the cam assembly 6033 is driven by the second servo motor 6031 to rotate, while the driving rod 6032 is vertically arranged, and the top end of the driving rod 6032 is in transmission connection with the cam assembly 3033, the bottom end of the driving rod 6032 penetrates into the interior of the mold box 303 and is fixedly connected with the top center position of the fixing plate 6022, and the driving rod 6032 realizes up-and-down movement through the cam assembly 6033. In addition, a circle of baffle 6034 protruding along the radial direction of the driving rod 6032 can be fixed at the position, close to the top, of the driving rod 6032, and a return spring 6035 is arranged between the baffle 6034 and the top of the forming box 303, so that the baffle 6034 can be timely reset after the edge of the cutting knife group 602 is cut.

As shown in fig. 6, the supporting assembly 604 includes a cylindrical barrel 6041, a first transmission shaft 6042 disposed in the barrel 6041, a second transmission shaft 6043 in transmission connection with the first transmission shaft 6042, and a first servo motor 6044 driving the second transmission shaft 6043, wherein a bottom center of the cutting platform 601 is provided with a bottom bracket 6045 in transmission connection with the top of the first transmission shaft 6042, the bottom bracket 6045 is rotatably connected with the top of the barrel 6041, and an output end of the first servo motor 6044 is provided with an angle sensor 6046 for detecting an output angle of the output end of the first servo motor 6044. Through the output of first servo motor 6044, accessible first transmission shaft 6042, second transmission shaft 6043 drive cutting platform 601 rotate, realize adjusting the side cut direction of sheet material.

In this embodiment, fixed mounting has a plurality of bearings 6047 with first transmission shaft 6042 complex in the barrel 6041, and in barrel 6041 was located to first transmission shaft 6042's bottom, barrel 6041's bottom has and cooperates the perforation with second transmission shaft 6043, the radial distribution of barrel 6041 is followed to the fenestrate axis, one section of second transmission shaft 6043 inserts in barrel 6041 through the perforation, and be connected with first transmission shaft 6042's bottom transmission, second transmission shaft 6043's the other end and the transmission cooperation of first servo motor 6044, mutually perpendicular between first transmission shaft 6042 and the second transmission shaft 6043.

As shown in fig. 6 and 7, a plurality of annular check rings 6048 are fixedly mounted in the cylinder 6041, a shaft body of the first transmission shaft 6042 is fixedly provided with a check block 6049 matched with the check rings 6048, the central angle of the check ring 6048 is 270 °, the setting is adopted, the rotation angle of the cutting platform 601 can be limited to 90 °, other excessive angle rotation is omitted, simplicity and easiness in implementation are realized, the trimming precision is improved, in addition, in order to eliminate the influence of the thickness of the check block 6049 on the rotation angle, a groove matched with the head of the check block 6049 can be arranged at the end part of the check ring 6048, the depth of the groove is consistent with the thickness or width of the check block 6049, after the rotation is carried out for 90 °, the head of the check block 6049 is just clamped in the groove, the outer side surface of the check block 6049 is just level with the end face of the check ring.

Through the technical scheme, this embodiment is at the in-process of implementing, because install cutting assembly 6 in shaping station 3, therefore can cut edge to just fashioned sheet material and handle, the intensity of labour of manual cutting has been reduced, the degree of automation of equipment has been improved simultaneously, and then can improve the shaping efficiency of equipment, and, install cutting assembly 6 in shaping station 3, the adjustment has been made on the cutting opportunity to the sheet material, therefore when cutting the sheet material, compare when cutting edge to the sheet material in prior art, the residual temperature still persists in the sheet material, thereby can guarantee that cutting knife tackle 602 can cut the sheet material more easily when the cutting, the piece that produces when can also reducing the cutting simultaneously, the cutting efficiency to the sheet material has been improved.

In this embodiment, as shown in fig. 8, the transfer assembly 7 includes a linear moving pair 701, a cylinder assembly 702 is installed on the linear moving pair 701, an output end of the cylinder assembly 702 is vertically downward, and a negative pressure manipulator 703 is fixedly installed at an output end of the cylinder assembly 702, during transfer, the negative pressure manipulator 703 first moves to the forming box 303 through the linear moving pair 701, then the negative pressure manipulator 703 is driven to descend by the cylinder assembly 702, and after the negative pressure manipulator 703 descends to a proper position, a negative pressure is generated at an execution end of the negative pressure manipulator 703 by a negative pressure assembly (not shown in the figure), so as to suck the sheet material, and then the sheet material is taken out of the forming box 303.

In this embodiment, as shown in fig. 1, the feeding station 1 includes a first feeding station 101 and a second feeding station 102, a linear guide 103 is installed on one side of the heating station 2 away from the forming station 3, the first feeding station 101 and the second feeding station 102 are installed on the linear guide 103, and a double feeding station is adopted, in an initial state, the first feeding station 101 is connected with the transportation device 5, when the sheet material in the first feeding station 101 is used up, the sheet material in the second feeding station 102 can be directly and seamlessly taken for use, so that the continuity of feeding work is ensured.

In this embodiment, as shown in fig. 1 and 2, the transportation device 5 includes a first transportation system 501, a second transportation system 502, and a third transportation system 503, the first transportation system 501 is disposed between the loading station 1 and the heating station 2, and between the heating station 2 and the forming station 3, the second transportation system 502 and the third transportation system 503 are disposed on a side of the forming station 3 away from the heating station 2, and the second transportation system 502 and the third transportation system 503 are distributed in a vertical manner. The discharging port 302 includes a first discharging port 3021 and a second discharging port 3022 distributed in an up-and-down manner, wherein the first discharging port 3021 is connected to the second transportation system 502, and the second discharging port 3022 is connected to the third transportation system 503. The first transportation system 501, the second transportation system 502, and the third transportation system 503 may be the same as those of the currently used production line transportation module, and are not described herein again.

In this embodiment, the third transportation system 503 is located below the second transportation system 502, and the end of the third transportation system 503 is provided with a cutting mechanism 8, by which the waste material can be cut off by the cutting mechanism 8, so that the size of the waste material is reduced, thereby facilitating the collection of the waste material. Specifically, the breaking mechanism 8 includes a driving device and a cutting device, and the cutting device has the same structure as the cutting knife group 602 in the cutting assembly 6, except that the cutting blade in the breaking mechanism 8 has at least 4 pieces, and the driving device of the breaking mechanism 8 is also the same as the structure of the driving assembly 603 in the cutting assembly 6, and will not be described herein again. Thus, as shown in fig. 9, a circle of material leakage openings 605 distributed in a square shape is provided on the cutting platform 601, the trimmed waste material is leaked to the third transportation system 503 through the material leakage openings 605, and the second transportation system 502 is equal to the cutting platform 601 in height.

It should be noted that, in the specific implementation process of the present invention, corresponding sensors need to be installed at each motion node to cooperate with a control system of the whole machine, so as to achieve the purpose of accurate control, and the selection and installation of the sensors are already skilled in the art and will not be described herein again.

The above description is only a preferred embodiment of the application and is illustrative of the principles of the technology employed. It will be appreciated by a person skilled in the art that the scope of the invention as referred to in the present application is not limited to the embodiments with a specific combination of the above-mentioned features, but also covers other embodiments with any combination of the above-mentioned features or their equivalents without departing from the inventive concept. For example, the above features may be replaced with (but not limited to) features having similar functions disclosed in the present application.

Other technical features than those described in the specification are known to those skilled in the art, and are not described herein in detail in order to highlight the innovative features of the present invention.

Claims (5)

1. A forming machine for a household appliance inner container is characterized by comprising a feeding station (1), a heating station (2) and a forming station (3), wherein the feeding station (1), the heating station (2) and the forming station (3) are linearly arranged, and the feeding station (1), the heating station (2) and the forming station (3) are connected through a conveying device (5) to form a forming assembly line, so that a plate passes through the heating station (2) and the forming station (3) in sequence at the feeding station (1) through the conveying device (5);

the forming station (3) comprises a forming assembly (4) and a cutting assembly (6), the plate materials are sequentially solidified through the forming assembly (4) in the forming station (3), and trimming is carried out through the cutting assembly (6);

a feeding hole (301) is formed in one side, close to the heating station (2), of the forming station (3), a discharging hole (302) is formed in one side, opposite to the feeding hole (301), of the forming station (3), and a transferring assembly (7) used for taking out the processed and formed plate is installed at the discharging hole (302) of the forming station (3);

the cutting assembly (6) and the forming assembly (4) are respectively arranged on two sides of the forming station (3); the cutting assembly (6) comprises a cutting platform (601) and a cutting knife set (602), the cutting knife set (602) is arranged above the cutting platform (601) and matched with the cutting platform (601), the cutting knife set (602) is driven by a driving assembly (603) to reciprocate up and down, and the driving assembly (603) is fixedly arranged at the position of the cutting station (3); the cutting platform (602) is mounted at the cutting station (3) by a support assembly (604);

the supporting assembly (604) comprises a cylindrical barrel (6041), a first transmission shaft (6042) arranged in the barrel (6041), a second transmission shaft (6043) in transmission connection with the first transmission shaft (6042), and a first servo motor (6044) for driving the second transmission shaft (6043), wherein a bottom support (6045) in transmission connection with the top of the first transmission shaft (6042) is arranged at the center of the bottom of the cutting platform (602), the bottom support (6045) is in rotation connection with the top of the barrel (6041), and an angle sensor (6046) for detecting an output rotation angle of the output end of the first servo motor (6044) is arranged at the output end of the first servo motor (6044);

a plurality of bearings (6047) matched with the first transmission shaft (6042) are fixedly arranged in the cylinder body (6041), and the bottom of the first transmission shaft (6042) is arranged in the cylinder body (6041); the bottom of the cylinder (6041) is provided with a through hole matched with the second transmission shaft (6043), the axis of the through hole is distributed along the radial direction of the cylinder (6041), one section of the second transmission shaft (6043) is inserted into the cylinder (6041) through the through hole and is in transmission connection with the bottom of the first transmission shaft (6042), and the other end of the second transmission shaft (6043) is in transmission fit with the first servo motor (6044); the first transmission shaft (6042) and the second transmission shaft (6043) are perpendicular to each other;

still fixed mounting has a plurality of annular retaining rings (6048) in barrel (6041), the axle body fixed mounting of first transmission shaft (6042) has with a plurality of retaining ring (6048) complex dog (6049), the central angle of retaining ring (6048) is 270, and the tip of retaining ring (6048) be equipped with the recess of dog (6049) head adaptation, the recess depth with the thickness or the width of dog (6049) are unanimous.

2. The forming machine for the household appliance inner container as claimed in claim 1, wherein the transfer assembly (7) comprises a linear moving pair (701), a cylinder assembly (702) is installed on the linear moving pair (701), an output end of the cylinder assembly (702) faces vertically downwards, and a negative pressure manipulator (703) is fixedly installed at an output end of the cylinder assembly (702).

3. The forming machine for the household appliance inner container as claimed in claim 2, wherein the feeding station (1) comprises a first feeding station (101) and a second feeding station (102), a circular guide rail (103) is installed on one side, away from the forming station (3), of the heating station (2), and the first feeding station (101) and the second feeding station (102) are installed on the circular guide rail (103).

4. The forming machine for the household appliance inner container as claimed in claim 3, wherein the transporting device (5) comprises a first transporting system (501), a second transporting system (502) and a third transporting system (503), the first transporting system (501) is arranged between the loading station (1) and the heating station (2) and between the heating station (2) and the forming station (3), the second transporting system (502) and the third transporting system (503) are arranged on one side of the forming station (3) far away from the heating station (2), and the second transporting system (502) and the third transporting system (503) are distributed in an up-and-down manner;

the discharging port (302) comprises a first discharging port (3021) and a second discharging port (3022) which are distributed in an up-and-down manner, wherein the first discharging port (3021) is connected with the second transportation system (502), and the second discharging port (3022) is connected with the third transportation system (503).

5. The machine for forming household appliance liners according to claim 4, wherein the third transport system (503) is located below the second transport system (502), and the end of the third transport system (503) is provided with a cutting mechanism (8).

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