CN114560300B

CN114560300B - High-efficient spring receiving device

Info

Publication number: CN114560300B
Application number: CN202210214461.3A
Authority: CN
Inventors: 郭祥飞
Original assignee: Foshan Qilin Bed Machinery Co ltd
Current assignee: Foshan Qilin Bed Machinery Co ltd
Priority date: 2022-03-07
Filing date: 2022-03-07
Publication date: 2022-11-08
Anticipated expiration: 2042-03-07
Also published as: CN114560300A

Abstract

The invention provides a high-efficiency spring receiving device which comprises a high-efficiency receiving mechanism, wherein the high-efficiency receiving mechanism is arranged corresponding to a conveying mechanism and is used for transferring a spring to be processed to the conveying mechanism, the high-efficiency receiving mechanism comprises a conveying pipe and a material protecting block, the structure is simple, the material protecting block is in sliding connection with the conveying pipe, a conveying cavity in the conveying pipe and a cavity in the material protecting block are used for conveying the spring to be processed, the speed of the spring to be processed falling into the conveying mechanism can be increased, the material protecting block moves upwards along with the falling of the spring to be processed, the spring to be processed can be limited through a matching hole in the material protecting block, and the spring to be processed can be prevented from falling in the transferring process.

Description

High-efficient spring receiving device

Technical Field

The invention relates to the technical field of spring processing, in particular to an efficient spring receiving device.

Background

The spring is a widely used elastic component, take the spring that is used for sofa, mattress as an example, at present, the spring in the relevant spring production facility is usually directly rolled up the shaping through the spring coiling device, heat treatment after configuration conveyor shifts it to pushing away in spring device and welding set, but roll up fashioned spring and need just can fall on the predetermined position of conveyer belt through corresponding transfer device or pipeline, refer to utility model patent CN 201922143547-the spring device that falls of spring machine in bags, this spring shifts the structure comparatively complicated, and shift speed is slow, refer to utility model patent CN 20646933-a pneumatic pipe conveyor who is used for conveying spring, this spring shifts simple structure, nevertheless can't carry on spacingly to the spring, lead to the spring easily to take place to empty the phenomenon.

Disclosure of Invention

The invention provides a high-efficiency spring receiving device, which is used for solving any technical problem in the problems that the spring transfer structure is complex and the transfer speed is slow in the spring falling device of the bag-type spring machine in the reference utility model patent CN201922143547, and the spring transfer structure is simple in the pneumatic pipeline conveying device for conveying the spring, but the spring cannot be limited, so that the spring is prone to toppling.

In order to solve the technical problem, the invention discloses an efficient spring receiving device which comprises an efficient receiving mechanism, wherein the efficient receiving mechanism is arranged corresponding to a conveying mechanism and used for transferring a spring to be processed to the conveying mechanism, the efficient receiving mechanism comprises a conveying pipe and a material protecting block, the material protecting block is connected with the conveying pipe in a sliding mode, and a conveying cavity in the conveying pipe and a cavity in the material protecting block are used for conveying the spring to be processed.

Preferably, the number of the conveying pipes and the material protection blocks is one or any one of a plurality of the conveying pipes and the material protection blocks, the conveying pipes correspond to the material protection blocks one by one, and the inlet ends of the material protection blocks are connected with the outlet ends of the conveying pipes in a sliding mode in the vertical direction.

Preferably, conveying mechanism includes the transfer frame, be equipped with the conveyer belt in the transfer frame, the conveyer belt bottom is provided with a plurality of magnets, and the conveyer belt conveys through a plurality of conveyer belt wheels, the outside fixed mounting that high-efficient receiving mechanism one side was kept away from to the transfer frame has driving motor, driving motor and its conveyer belt fixed connection who corresponds the side.

Preferably, the exit end of the material protecting block corresponds to the arrangement of the conveyor belt, the conveying pipe is communicated with an air inlet block, a guide plate is arranged at the communication position of the conveying pipe and the air inlet block, the air inlet block is communicated with an air inlet pipe, and the air inlet pipe is connected with a gas booster pump.

Preferably, the front side and the rear side of the protecting block are symmetrically provided with guide blocks, guide grooves in the guide blocks are in sliding connection with guide posts fixedly arranged on the conveying frame, the protecting blocks are connected through a connecting piece, and the connecting piece is connected with any one of a motor or a driving cylinder.

Preferably, the cavity of the guard block comprises a matching hole and a matching groove, the matching hole is in sliding connection with the outlet end of the conveying pipe, and the conveying cavity, the matching hole and the matching groove in the conveying pipe are sequentially communicated.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

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

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

FIG. 3 is an enlarged schematic view of the high-efficiency receiving mechanism of the invention;

FIG. 4 is a schematic view of the internal structure of the high-efficiency receiving mechanism of the invention;

FIG. 5 is a schematic view of the cooling apparatus of the present invention;

fig. 6 is a schematic view of a buffer block connection structure according to the present invention.

In the figure: 1. a protective block; 101. a guide block; 102. a guide groove; 103. a guide post; 104. a connecting member; 105. a mating hole; 106. a mating groove; 2. a conveying mechanism; 201. a transfer frame; 202. a conveyor belt; 203. a drive motor; 3. the high-efficiency material receiving mechanism; 301. a delivery tube; 302. an air inlet block; 303. an air inlet pipe; 304. a baffle; 4. an exhaust shell; 401. an exhaust fan; 402. an exhaust port; 5. cooling the shell; 501. an air intake; 502. a first cavity; 503. a second cavity; 504. a third groove; 6. an air inlet housing; 601. rotating a first shaft; 602. a first condenser pipe; 603. an air inlet cavity; 604. an air outlet cavity; 605. a filter screen; 7. a power shell; 701. a first motor; 702. a first bevel gear; 703. a second bevel gear; 704. a second rotating shaft; 705. a second spiral pipe; 706. a first belt pulley; 707. a second belt pulley; 708. a belt; 709. a double-headed motor; 710. a third rotating shaft; 711. a movable block; 712. a second spring; 713. a buffer block; 7131. a buffer tank; 714. blocking; 715. a power cavity; 8. a second motor; 801. a seventh rotating shaft; 802. a third bevel gear; 803. a fourth bevel gear; 804. a second rotating shaft; 805. a blade.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

In addition, the descriptions related to the first, the second, etc. in the present invention are only used for description purposes, do not particularly refer to an order or sequence, and do not limit the present invention, but only distinguish components or operations described in the same technical terms, and are not understood to indicate or imply relative importance or implicitly indicate the number of indicated technical features. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions and technical features between various embodiments can be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not be within the protection scope of the present invention.

The invention provides the following examples

Example 1

The embodiment of the invention provides an efficient spring receiving device, which comprises an efficient receiving mechanism 3, wherein the efficient receiving mechanism 3 is arranged corresponding to a conveying mechanism 2, the efficient receiving mechanism 3 is used for transferring a spring to be processed to the conveying mechanism 2, the efficient receiving mechanism 3 comprises a conveying pipe 301 and a material protecting block 1, the material protecting block 1 is connected with the conveying pipe 301 in a sliding mode, and a conveying cavity in the conveying pipe 301 and a cavity in the material protecting block 1 are used for conveying the spring to be processed.

The number of the conveying pipes 301 and the material protection blocks 1 is any one or a plurality of conveying pipes 301 and the material protection blocks 1 are in one-to-one correspondence, and the inlet ends of the material protection blocks 1 are connected with the outlet ends of the conveying pipes 301 in a sliding mode in the vertical direction.

The beneficial effects of the above technical scheme are:

the high-efficiency material receiving mechanism 3 is connected with a preset position corresponding to the position of the conveying mechanism 2 where the spring to be treated falls, the conveying pipe 301 and the material protecting block 1 in the high-efficiency material receiving mechanism 3 transfer the spring to be treated to the target position of the conveying mechanism 2, the diameter of a conveying cavity in the conveying pipe 301 and the diameter of a cavity in the material protecting block 1 are both larger than the diameter of the spring to be treated, the spring to be treated can be accommodated and passed through, by arranging the material protecting block 1, the material protecting block 1 moves upwards along with the falling of the spring to be treated, the spring to be treated can be limited by the cavity in the material protecting block 1, the falling of the spring to be treated is prevented, the spring to be treated falls into the conveying mechanism 2 through the material protecting block 1 and the conveying pipe 301, the speed of the spring to be treated falling into the conveying mechanism 2 can be increased, the conveying mechanism 2 conveys the spring to be treated to the next station, and the steps are repeated, through setting up conveying pipe 301 and protecting piece 1, with utility model patent CN 201922143547-open-close type transfer mechanism contrast simple structure among the spring device that falls of bagged spring machine, it is fast to shift pending spring, with utility model patent CN 201420646933-a full open type transfer structure contrast among the pneumatic pipeline conveyor for conveying spring can avoid the spring to empty, the spring device that falls of referring to utility model patent CN 201922143547-bagged spring machine has been solved, this spring shifts the structure comparatively complicacy, and shift rate is slow, refer to utility model patent CN 201420646933-a pneumatic pipeline conveyor for conveying spring, this spring shifts simple structure, nevertheless can't carry on spacingly to the spring, lead to the spring to take place any item technical problem in the problem of empting the phenomenon.

Example 2

On the basis of the above embodiment 1, as shown in fig. 1 to 4, the conveying mechanism 2 includes a conveying frame 201, a conveying belt 202 is arranged in the conveying frame 201, a plurality of magnets are arranged at the bottom of the conveying belt 202, the conveying belt 202 is conveyed by a plurality of conveying belt wheels, a driving motor 203 is fixedly mounted on the outside of one side of the conveying frame 201 away from the high-efficiency receiving mechanism 3, and the driving motor 203 is fixedly connected with the conveying belt wheels on the corresponding side;

the outlet end of the protecting block 1 is arranged corresponding to the conveyor belt 202, the conveying pipe 301 is communicated with an air inlet block 302, a guide plate 304 is arranged at the communication position of the conveying pipe 301 and the air inlet block 302, the air inlet block 302 is communicated with an air inlet pipe 303, and the air inlet pipe 303 is connected with a gas booster pump;

the front side and the rear side of the protecting block 1 are symmetrically provided with guide blocks 101, guide grooves 102 on the guide blocks 101 are in sliding connection with guide posts 103 fixedly arranged on a conveying frame 201, a plurality of protecting blocks 1 are connected through connecting pieces 104, and the connecting pieces 104 are connected with any one of motors or driving cylinders;

the cavity of the protecting block 1 comprises a matching hole 105 and a matching groove 106, the matching hole 105 is connected with the outlet end of the conveying pipe 301 in a sliding mode, and the conveying cavity, the matching hole 105 and the matching groove 106 in the conveying pipe 301 are communicated in sequence.

The beneficial effects of the above technical scheme are:

when a spring to be processed is transferred, a gas booster pump connected with a gas inlet pipe 303 is started, high-pressure gas enters the gas inlet pipe 303, a guide plate 304 in a gas inlet block 302 plays a role in guiding the direction of the high-pressure gas, so that the direction of gas flow in a conveying pipe 301 flows from an inlet end to an outlet end, negative pressure is formed at the inlet end of the conveying pipe 301, the spring to be processed is sucked into the conveying pipe 301, a material protection block 1 is arranged at the outlet end of the conveying pipe 301, when the spring to be processed flows to the outlet end of the conveying pipe 301, a driving cylinder drives a connecting piece 104 to move upwards, the connecting piece 104 drives the guide block 101 to move upwards, so that the material protection block 1 moves upwards, the guide groove 102 and a guide post 103 are matched to guide the movement of the guide block 101, the material protection block 1 moves upwards, the spring to be processed can be limited through a matching hole 105, the spring to be processed is prevented from falling down in the conveying belt 202, the spring to be processed is prevented from falling down through the matching groove 106, the spring to be processed directly falls into the conveying mechanism 2 through the matching hole 106, and the diameter of the spring to be processed is increased, and the spring to be processed can be more than the diameter of the spring to be processed when the spring to be processed falls into the matching groove 105.

Example 3

On the basis of embodiment 1, as shown in fig. 5 to 6, the present invention further includes a cooling device, the cooling device is matched with the conveying mechanism 2, and the cooling device includes:

the cooling device comprises a cooling shell 5, wherein an air inlet 501 is formed in the middle of the upper end of the cooling shell 5 in a vertically penetrating manner, a third groove 504 is formed in the middle of the lower end of the cooling shell 5 in a front-back penetrating manner, the air inlet 501 is communicated with the third groove 504, the conveying mechanism 2 penetrates through the third grooves 504, a first cavity 502 is formed in the left end of the cooling shell 5, and a second cavity 503 is formed in the left end of the cooling shell 5;

the air inlet shell 6 is fixedly arranged inside the third groove 504, an air inlet cavity 603 is formed in the upper end inside the air inlet shell 6, an air outlet cavity 604 is formed in the lower end inside the air inlet shell 6, the air inlet 501, the air inlet cavity 603 and the air outlet cavity 604 are sequentially communicated from top to bottom, a filter screen 605 is arranged at an outlet below the air outlet cavity 604 and corresponds to the upper end of the conveying mechanism 2, a first condensing pipe 602 is arranged inside the air inlet cavity 603, the first condensing pipe 602 is fixedly connected with a first rotating shaft 601, and the first rotating shaft 601 penetrates through the air inlet shell 6, enters the second cavity 503 and is rotatably connected with the cooling shell 5 and the air inlet shell 6;

the power shell 7 is fixedly arranged between the left end and the right end of the middle part of the air inlet shell 6, a power cavity 715 is arranged in the power shell 7, a first motor 701 is fixedly arranged at the top end of the power cavity 715, the first motor 701 is fixedly connected with a first bevel gear 702 through a motor shaft, second bevel gears 703 are symmetrically arranged on the left side and the right side of the first bevel gear 702, the second bevel gears 703 are fixedly connected with a second rotating shaft 704, the second rotating shaft 704 penetrates through the power shell 7 and the air inlet shell 6 to enter the second cavity 503 and is fixedly connected with a first belt pulley 706, the first belt pulley 706 is fixedly connected with a second belt pulley 707 through a belt 708, and the second belt pulley 707 is fixedly connected with the first rotating shaft 601;

the double-end motor 709 is fixedly arranged between the front end and the rear end of the middle part of the power shell 7, three rotating shafts 710 are symmetrically arranged on the left side and the right side of the double-end motor 709, the three rotating shafts 710 are fixedly connected with a movable block 711, the movable block 711 is fixedly connected with a second spring 712, the second spring 712 is fixedly arranged at one end, far away from the double-end motor 709, of the buffer groove 7131, the buffer groove 7131 is fixedly arranged at one end, close to the double-end motor 709, of the buffer block 713, and the movable block 711 is in sliding connection with the buffer groove 7131;

the second motor 8 is fixedly arranged in the first cavity 502, the second motor 8 is fixedly connected with a seventh rotating shaft 801, the seventh rotating shaft 801 penetrates through the cooling shell 5 and the power shell 7 to enter the power cavity 715, a plurality of third bevel gears 802 are uniformly arranged on the seventh rotating shaft 801 in the power cavity 715 at intervals, the third bevel gears 802 are meshed with fourth bevel gears 803, the fourth bevel gears 803 are fixedly connected with an eighth rotating shaft 804, the eighth rotating shaft 804 penetrates through the power shell 7 to enter the air outlet cavity 604, and a plurality of blades 805 are uniformly arranged on the side end of the eighth rotating shaft 804 in the air outlet cavity 604 in the circumferential direction;

exhaust shell 4, exhaust shell 4 symmetry sets up both ends about three 504 of recess, the lower extreme of exhaust shell 4 is equipped with gas vent 402, the export orientation of gas vent 402 the both sides end about conveying mechanism 2, the inside exhaust fan 401 that is equipped with of gas vent 402, the middle part of exhaust shell 4 is equipped with sprue 714, sprue 714 with run through exhaust shell 4 buffer block 713 eccentric connection, the upside of sprue 714 is equipped with condenser pipe two 705, condenser pipe two 705 with two 704 fixed connection in the axis of rotation, the upper end export of exhaust shell 4 runs through cooling shell 5 and external intercommunication.

The beneficial effects of the above technical scheme are:

when the spring to be processed which is formed by coiling the spring coiling device and is subjected to heat treatment is transferred into the spring pushing device and the welding device through the conveying device, the cooling is carried out in the conveying process of the spring to be processed, so that the cooling effect of the spring to be processed is improved, the next process of the spring to be processed is facilitated, and the production efficiency of a spring production line is improved, when the spring to be processed is cooled, the motor 701 is started to drive the bevel gear 702 to rotate, so that the bevel gear 703 rotates, the condensation pipe 705 rotates through the rotating shaft two 704, the rotating shaft two 704 simultaneously drives the belt pulley 706 to rotate, the belt pulley 706 drives the belt pulley two 707 to rotate through the belt 708, the belt pulley two 707 drives the condensation pipe one 602 to rotate through the rotating shaft four 601, air firstly enters the air inlet cavity 603 from the air inlet hole 501, and the air passes through the condensation pipe one 602 to achieve the cooling purpose, the first condenser pipe 602 rotates to increase the contact area with air, so as to increase the cooling effect of air, the air enters the air outlet cavity 604 through the front side and the rear side of the power shell 7 after being cooled, the motor II 8 is started to drive the rotating shaft seven 801 to rotate, the bevel gear III 802 rotates, the bevel gear IV 803 rotates to drive the blades 805 to rotate through the rotating shaft eight 804, the cooled air is conveniently blown out through the filter screen 605, the lower outlet of the air outlet cavity 604 corresponds to the upper end of the conveying mechanism 2, so that the cooled air can cool the springs to be treated on the conveying mechanism 2, the purpose of heat exchange is achieved, the air cooled by the exhaust fan 401 can be discharged into the exhaust shell 4, a certain amount of heat exchange can also be carried out on the side ends of the springs to be treated, the double-head motor 709 is started after the heat exchanged air enters the exhaust shell 4, the buffer block 713 can be driven to rotate, the movable block 711 and the second spring 712 are arranged in the buffer block 713 in a sliding mode, the rotation process of the buffer block 713 is kept stable under the elastic action of the spring 712, the buffer block 713 drives the blocking block 714 which is eccentrically connected with the buffer block to rotate, the air after heat exchange is cooled and discharged to the outside through the second condensing pipe 705 by the exhaust shell 4, an air inlet and exhaust circulation process is completed, the phenomenon that the temperature of the air which is discharged from the outside is too high to enable the temperature of the air near the cooling device to be too high is avoided by arranging the second condensing pipe 705, and the working environment of an operator is poor.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, it is intended that all such modifications and variations of the invention be covered by the claims and their equivalents

Within the scope of the same technology, it is intended that the present invention encompass such changes and modifications.

Claims

1. The utility model provides a high-efficient spring receiving device which characterized in that: the high-efficiency material receiving mechanism comprises a high-efficiency material receiving mechanism (3), wherein the high-efficiency material receiving mechanism (3) is arranged corresponding to a conveying mechanism (2), the high-efficiency material receiving mechanism (3) is used for transferring a spring to be processed to the conveying mechanism (2), the high-efficiency material receiving mechanism (3) comprises a conveying pipe (301) and a material protecting block (1), the material protecting block (1) is connected with the conveying pipe (301) in a sliding mode, and a conveying cavity in the conveying pipe (301) and a cavity in the material protecting block (1) are used for conveying the spring to be processed;

the cavity of the protecting block (1) comprises a matching hole (105) and a matching groove (106), the matching hole (105) is connected with the outlet end of the conveying pipe (301) in a sliding mode, the conveying cavity in the conveying pipe (301), the matching hole (105) and the matching groove (106) are communicated in sequence, and the diameter of the matching groove (106) is larger than that of the matching hole (105);

the number of the conveying pipes (301) and the number of the material protecting blocks (1) are any one or more, the conveying pipes (301) correspond to the material protecting blocks (1) one by one, and the inlet ends of the material protecting blocks (1) are connected with the outlet ends of the conveying pipes (301) in a sliding mode in the vertical direction;

the conveying mechanism (2) comprises a conveying frame (201), a conveying belt (202) is arranged in the conveying frame (201), a plurality of magnets are arranged at the bottom of the conveying belt (202), the conveying belt (202) is conveyed through a plurality of conveying belt wheels, a driving motor (203) is fixedly installed on the outer portion of one side, away from the high-efficiency material receiving mechanism (3), of the conveying frame (201), and the driving motor (203) is fixedly connected with the conveying belt wheels on the corresponding side;

the front side and the back side of the protecting block (1) are symmetrically provided with guide blocks (101), a guide groove (102) on the guide blocks (101) is in sliding connection with a guide post (103) fixedly arranged on a conveying frame (201), the protecting blocks (1) are connected through a connecting piece (104), and the connecting piece (104) is connected with a motor or any one of driving cylinders.

2. The efficient spring receiving device according to claim 1, characterized in that: the exit end of protecting material piece (1) with conveyer belt (202) correspond the setting, conveying pipe (301) intercommunication has air inlet block (302), and the intercommunication department of conveying pipe (301) and air inlet block (302) is equipped with guide plate (304), air inlet block (302) and intake pipe (303) intercommunication, intake pipe (303) are connected with the gas booster pump.