CN111948359B

CN111948359B - Safety rapid detection equipment for chronic disease food therapy

Info

Publication number: CN111948359B
Application number: CN202010813410.3A
Authority: CN
Inventors: 张晓峰; 樊剑鸣; 芦鑫; 王伟东; 唐宇君; 管孝贤; 张志会
Original assignee: Zhengzhou University
Current assignee: Zhengzhou University
Priority date: 2020-08-13
Filing date: 2020-08-13
Publication date: 2022-09-16
Anticipated expiration: 2040-08-13
Also published as: CN111948359A

Abstract

The invention discloses safe and rapid detection equipment for chronic food therapy, which comprises a feeding assembly and a detection assembly, wherein the feeding assembly can continuously feed for the detection assembly, the feeding assembly comprises a feeding plate, a feeding and discharging assembly, an oscillation shaking assembly and a rotation driving assembly, the feeding plate is arranged at an oscillation end of the oscillation shaking assembly by adopting an installation plate, the oscillation shaking assembly is arranged on an installation table, and the rotation driving assembly is also arranged on the installation table and used for driving the feeding plate to rotate quantitatively; the feeding and discharging assemblies are arrayed on the outer circumference of the feeding plate and used for receiving the delivery of food containers, and after oscillation, the food containers are driven by the rotation driving assembly to be sequentially conveyed to the feeding end of the detection assembly, so that the detection efficiency of the detection assembly is improved.

Description

Safe rapid detection equipment for chronic disease food therapy

Technical Field

The invention relates to the technical field of food detection, in particular to safe and rapid detection equipment for chronic disease food therapy.

Background

In the prevention and improvement of chronic diseases, comprehensive interventions including rational diet therapy, exercise in proper amount, and alcohol restriction for smoking cessation are often required.

The reasonable food therapy comprises eating chronic disease food therapy food, and the chronic disease food therapy food can leave a factory after being checked layer by layer in the production process and meeting the qualified standard, wherein the food therapy food comprises the steps of detecting the components of the food, detecting microorganisms in the food and the like;

however, the existing detection equipment has low detection efficiency and accuracy, and the investigation and analysis find that the causes of the problems comprise poor connection of feeding and detection, and sedimentation and accumulation of the required detection objects before detection due to long-time standing.

Therefore, there is a need to provide a safe and rapid detection device for chronic disease food, so as to solve the problems in the background art.

Disclosure of Invention

In order to achieve the purpose, the invention provides the following technical scheme: a safe and rapid detection device for chronic disease food therapy comprises a feeding assembly and a detection assembly, wherein the feeding assembly can continuously feed the detection assembly,

the feeding assembly comprises a feeding disc, a feeding and discharging assembly, an oscillation shaking assembly and a rotation driving assembly, wherein the feeding disc is arranged at an oscillation end of the oscillation shaking assembly by adopting an installation plate, the oscillation shaking assembly is arranged on an installation table, and the rotation driving assembly is also arranged on the installation table and used for driving the feeding disc to rotate quantitatively;

the feeding and discharging assemblies are arrayed on the outer circumference of the feeding tray and used for receiving the delivery of food containers, and after oscillation, the food containers are driven by the rotary driving assembly to be sequentially fed to the feeding end of the detection assembly.

Further, as preferred, the detection assembly includes conveyer belt, direction claw, infrared counter and detector, wherein, the conveyer belt sets up on testing platform for receive the food container who comes from the feeding subassembly, still be fixed with direction claw, infrared counter and detector from a left side to the right side on the testing platform in proper order, and, the food container after the detector detects conveys out next station from the discharge end of conveyer belt.

Preferably, the feeding and discharging assembly comprises clamping bins, a first push rod and a second push rod, wherein the clamping bins are circumferentially arrayed and fixed on the outer circumference of the feeding plate, the clamping bins are groove-shaped and used for placing food containers, the first push rod is fixed below the clamping bins, and the output end of the first push rod can extend into the clamping bins in a sliding manner so as to eject the food containers;

a second push rod corresponding to the clamping bin is embedded in the feeding plate and can extend when the push rod upwards ejects out of the food container, so that the food container is pushed out; or when the food container is positioned in the clamping bin, the second push rod can be stretched and contracted in a short time, so that the radial oscillation of the food container is realized.

Further, preferably, the rotation driving assembly comprises an outer rotating shaft, an inner rotating shaft, a first synchronous pulley, a second synchronous pulley and a stepping motor, wherein the outer rotating shaft is rotatably arranged in the mounting table, the outer rotating shaft is of a cavity structure, the inner rotating shaft is connected in the outer rotating shaft in a non-rotatable manner and can slide relatively by adopting an elastic connecting piece, and a mounting plate is coaxially fixed on the inner rotating shaft;

the outer circumference of the outer rotating shaft is coaxially fixed with a first synchronous belt wheel, the first synchronous belt wheel is in transmission connection with a second synchronous belt wheel through a belt, the second synchronous belt wheel is coaxially fixed at the output end of a stepping motor, and the stepping motor is fixed on a motor plate.

Further, as preferred, the bottom of mounting panel still is provided with the runner, the runner is stirred the oscillation end contact of subassembly with the oscillation to feed back the oscillation to the mounting panel when providing rotation guide for the mounting panel.

Preferably, the elastic connecting member includes a plurality of limiting sliders and a buffer spring, wherein the limiting sliders are circumferentially arrayed outside the inner rotating shaft, the limiting sliders are further arranged in sliding grooves formed in a cavity of the outer rotating shaft in a limiting manner, and the bottom of the inner rotating shaft is connected with the outer rotating shaft through the buffer spring.

Preferably, a damping sleeve is coaxially fixed at the upper end of the inner rotating shaft, and the damping sleeve is slidably arranged in the cavity of the outer rotating shaft.

Further, as preferred, the oscillation homogenizing assembly comprises an oscillation seat, an oscillation ring table, an inner ring seat, an outer ring seat and a first oscillation spring, wherein the oscillation seat is arranged on the mounting table in a manner that the oscillation driving piece can oscillate up and down, a through groove is formed in the middle of the oscillation seat and is used for enabling the outer rotating shaft to pass through the through groove, an annular groove is further formed in the oscillation seat, the inner ring seat is attached to the inner circumference of the annular groove, the outer ring seat is attached to the outer circumference of the annular groove, the oscillation ring table is arranged between the inner ring seat and the outer ring seat in a manner that the inner ring seat and the outer ring seat can slide up and down, and a plurality of groups of first oscillation springs are arranged between the oscillation ring table and the oscillation seat.

Further, as preferred, the oscillation driving part comprises oscillators and second oscillation springs, wherein the oscillators are fixed on the mounting table, the oscillators are linear oscillators, oscillation ends of the linear oscillators are fixedly connected with the oscillation seat, and a plurality of groups of second oscillation springs are distributed between the oscillation seat and the mounting table.

Further, as preferred, still include the controller, the controller is continuous with step motor, oscillator, push rod one, push rod two, infrared counter and detector electrical property respectively.

Compared with the prior art, the invention provides safe and rapid detection equipment for chronic disease food therapy, which has the following beneficial effects:

in this equipment, be provided with the feed subassembly, it can use the pivoted mode to last as the determine module feed, wherein, last pivoted in-process at the feed table, the oscillation homogenizes the subassembly and can drive the feed table and the business turn over material subassembly on it and carry out the axial oscillation, its axial oscillation includes when going up unloading, the change of its self weight, arouse the oscillation that the feed table used the oscillation seat as the benchmark, and the oscillation of going on by oscillator drive oscillation seat, and, the business turn over material subassembly can also provide radial oscillation for food container, thereby carrying out incessant pay-off in-process, the abundant oscillation that realizes the fluid food in the food container homogenizes, the detection in the later stage of being convenient for, holistic detection efficiency has been improved.

Drawings

FIG. 1 is a schematic perspective view of a safety and rapid detection device for chronic food therapy;

FIG. 2 is a schematic plan view of a safety and rapid detection device for chronic food therapy;

FIG. 3 is a schematic structural diagram of a feeding assembly in the safety and rapid detection device for chronic food therapy;

FIG. 4 is a schematic structural diagram of a discharging assembly in the safety rapid detection device for chronic disease food therapy;

in the figure: 1. a feeding assembly; 2. a detection component; 3. a feed tray; 4. mounting a plate; 5. a feeding and discharging component; 6. oscillating the homogenizing assembly; 7. a mounting table; 8. a rotation drive assembly; 9. a conveyor belt; 10. a guide claw; 11. an infrared counter; 12. a detector; 13. a food container; 14. a rotating wheel; (ii) a 51. Clamping the bin; 52. a first push rod; 53. a second push rod; 61. an oscillating base; 62. oscillating the ring table; 63. an inner ring seat; 64. an outer ring seat; 65. a first oscillating spring; 66. an oscillator; 67. a second oscillating spring; 81. an outer rotating shaft; 82. an inner rotating shaft; 83. a limiting sliding seat; 84. a synchronous belt wheel I; 85. a second synchronous belt wheel; 86. a stepping motor.

Detailed Description

Referring to fig. 1 to 4, in an embodiment of the present invention, a safety and fast detection apparatus for chronic disease food therapy includes a feeding assembly 1 and a detection assembly 2, wherein the feeding assembly 1 can continuously feed the detection assembly 2,

the feeding assembly 1 comprises a feeding tray 3, a feeding and discharging assembly 5, an oscillation shaking assembly 6 and a rotation driving assembly 8, wherein the feeding tray 3 is arranged at an oscillation end of the oscillation shaking assembly 6 by adopting a mounting plate 4, the oscillation shaking assembly 6 is arranged on a mounting table 7, and the rotation driving assembly 8 is further arranged on the mounting table 7 and used for driving the feeding tray 3 to rotate quantitatively;

a plurality of feeding and discharging assemblies 5 are arrayed on the outer circumference of the feeding tray 3 and used for receiving the delivery of food containers 13, and after oscillation, the food containers 13 are sequentially conveyed to the feeding end of the detection assembly 2 by being driven by the rotary driving assembly 8.

In this embodiment, as shown in fig. 1 and 2, the detection assembly 2 includes a conveyor belt 9, a guide claw 10, an infrared counter 11, and a detector 12, wherein the conveyor belt 9 is disposed on the detection platform and is configured to receive a food container 13 from the feeding assembly 1, the detection platform is further sequentially fixed with the guide claw 10, the infrared counter 11, and the detector 12 from left to right, and the food container 13 detected by the detector 12 is conveyed out of a next station from a discharge end of the conveyor belt 9, wherein the guide claw 10 is two claw bodies with a certain gap, the food container 13 falling on the conveyor belt 9 can pass through the claw bodies, and the claw bodies can centralize and guide the food container 13.

In this embodiment, as shown in fig. 4, the feeding and discharging assembly 5 includes a plurality of clamping bins 51, a first pushing rod 52 and a second pushing rod 53, wherein a plurality of the clamping bins 51 are circumferentially arrayed and fixed on the outer circumference of the feeding tray 3, the clamping bins 51 are groove-shaped and used for placing the food containers 13, the first pushing rod 52 is fixed below the clamping bins 51, and the output end of the first pushing rod 52 can slidably extend into the clamping bins 51 so as to eject the food containers 13;

a second push rod 53 corresponding to the clamping bin 51 is embedded in the feeding tray 3, and the second push rod 53 can stretch when the first push rod 52 pushes out the food container 13 upwards so as to push out the food container 13 and enable the food container 13 to fall on the conveyor belt 9; alternatively, the second push rod 53 can be extended and retracted shortly when the food container 13 is located in the clamping chamber 51, so that a radial oscillation of the food container 13 is achieved.

In this embodiment, as shown in fig. 3, the rotation driving assembly 8 includes an outer rotating shaft 81, an inner rotating shaft 82, a first synchronous pulley 84, a second synchronous pulley 85 and a stepping motor 86, wherein the outer rotating shaft 81 is rotatably disposed in the mounting table 7, the outer rotating shaft 81 is a cavity structure, an inner rotating shaft 82 is connected to the inner rotating shaft 81 in a non-rotatable manner and can slide relatively by using an elastic connecting member, and the mounting plate 4 is coaxially fixed on the inner rotating shaft 82;

a first synchronous pulley 84 is coaxially fixed on the outer circumference of the outer rotating shaft 81, the first synchronous pulley 84 is in transmission connection with a second synchronous pulley 85 by a belt, the second synchronous pulley 85 is coaxially fixed at the output end of a stepping motor 86, the stepping motor 86 is fixed on a motor plate, the outer rotating shaft 81 and the inner rotating shaft 82 can be driven to rotate by the stepping motor 86, so that the feeding tray 3 is driven to rotate, and a plurality of food containers 13 on the feeding tray 3 are all allowed to move to one side close to the conveying belt 9.

In a preferred embodiment, the bottom of the mounting plate 4 is further provided with a rotating wheel 14, and the rotating wheel 14 is in contact with the oscillation end of the oscillation homogenizing assembly 6, so that the oscillation is fed back to the mounting plate 4 while providing a rotation guide for the mounting plate 4.

In a preferred embodiment, the elastic connection member includes a plurality of limiting sliders 83 and a buffer spring, wherein the limiting sliders 83 are circumferentially arrayed outside the inner rotating shaft 82, the limiting sliders 83 are slidably disposed in sliding grooves formed in a cavity of the outer rotating shaft 81, and the bottom of the inner rotating shaft 82 is connected to the outer rotating shaft 81 by the buffer spring.

In a preferred embodiment, a damping sleeve is coaxially fixed to the upper end of the inner rotating shaft 82, and the damping sleeve is slidably disposed in the cavity of the outer rotating shaft 81 to reduce radial runout of the inner rotating shaft 82.

In this embodiment, as shown in fig. 3, the oscillating and homogenizing assembly 6 includes an oscillating base 61, an oscillating ring platform 62, an inner ring base 63, an outer ring base 64, and an oscillating spring one 65, wherein the oscillating base 61 is disposed on the mounting table 7 in a manner that an oscillating driving member can oscillate up and down, a through groove is disposed in the middle of the oscillating base 61 for allowing an outer rotating shaft 81 to pass therethrough, an annular groove is further disposed on the oscillating base 61, the inner ring base 63 is attached to the inner circumference of the annular groove, the outer ring base 64 is attached to the outer circumference of the annular groove, the oscillating ring platform 62 is disposed between the inner ring base 63 and the outer ring base 64 in a manner that the inner ring base can slide up and down, and a plurality of groups of oscillating springs one 65 are disposed between the oscillating ring platform 62 and the oscillating base 61.

In this embodiment, the oscillation driving member includes oscillators 66 and two oscillation springs 67, wherein a plurality of oscillators 66 are fixed on the mounting table 7, the oscillators 66 are linear oscillators, oscillation ends of the oscillators 66 are fixedly connected with the oscillation base 61, a plurality of groups of two oscillation springs 67 are further arranged between the oscillation base 61 and the mounting table 7, and the feeding tray 3 and the food containers 13 thereon oscillate up and down simultaneously under the driving of the oscillators 66.

In this embodiment, the device further includes a controller, and the controller is electrically connected to the stepping motor 86, the oscillator 66, the first push rod 52, the second push rod 53, the infrared counter 11, and the detector 12, respectively.

When the automatic food container pushing device is specifically implemented, the stepping motor 86 is started through the controller, the stepping motor 86 drives the feeding tray 3 to rotate, feeding is sequentially carried out in the feeding and discharging assembly 5 on the feeding tray 3 in a manual or mechanical arm mode on the left side, in addition, the oscillator 66 is started through the controller, under the driving of the oscillator 66, the feeding tray 3 and the food containers 13 on the feeding tray 3 simultaneously oscillate up and down, when the food containers 13 on the feeding tray 3 are positioned right above the conveying belt 9, the corresponding food containers 13 can be pushed to the conveying belt 9 through the matching of the first push rod and the second push rod, then the food containers 13 sequentially move to the position below the detector 12 through the guide claws 10 and the infrared counter 11 to be detected, and after the detection, the food containers are moved to the next station from the discharging end of the conveying belt 9.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention are equivalent to or changed within the technical scope of the present invention.

Claims

1. A safe and rapid detection device for chronic disease food therapy comprises a feeding assembly (1) and a detection assembly (2), wherein the feeding assembly (1) can continuously feed the detection assembly (2),

the method is characterized in that: the feeding assembly (1) comprises a feeding disc (3), a feeding and discharging assembly (5), an oscillation shaking assembly (6) and a rotation driving assembly (8), wherein the feeding disc (3) is arranged at an oscillation end of the oscillation shaking assembly (6) through a mounting plate (4), the oscillation shaking assembly (6) is arranged on a mounting table (7), and the rotation driving assembly (8) is further arranged on the mounting table (7) and used for driving the feeding disc (3) to rotate quantitatively;

a plurality of feeding and discharging assemblies (5) are arrayed on the outer circumference of the feeding tray (3) and used for receiving the delivery of food containers (13), and after oscillation, the food containers (13) are driven by the rotary driving assembly (8) to be sequentially fed to the feeding end of the detection assembly (2);

the rotation driving assembly (8) comprises an outer rotating shaft (81), an inner rotating shaft (82), a synchronous pulley I (84), a synchronous pulley II (85) and a stepping motor (86), wherein the outer rotating shaft (81) is rotatably arranged in the mounting table (7), the outer rotating shaft (81) is of a cavity structure, the inner rotating shaft (82) is connected in a non-rotatable mode and can slide relatively through an elastic connecting piece, and the mounting plate (4) is coaxially fixed on the inner rotating shaft (82);

a first synchronous pulley (84) is coaxially fixed on the outer circumference of the outer rotating shaft (81), the first synchronous pulley (84) is in transmission connection with a second synchronous pulley (85) through a belt, the second synchronous pulley (85) is coaxially fixed at the output end of a stepping motor (86), and the stepping motor (86) is fixed on a motor plate;

the bottom of the mounting plate (4) is also provided with a rotating wheel (14), and the rotating wheel (14) is in contact with the oscillation end of the oscillation shaking component (6), so that the oscillation is fed back to the mounting plate (4) while the rotation guide is provided for the mounting plate (4);

the elastic connecting piece comprises limiting sliding seats (83) and buffer springs, wherein the limiting sliding seats (83) are circumferentially arrayed outside the inner rotating shaft (82), the limiting sliding seats (83) are further arranged in sliding grooves formed in a cavity of the outer rotating shaft (81) in a limiting sliding mode, and the bottom of the inner rotating shaft (82) is connected with the outer rotating shaft (81) through the buffer springs;

the oscillation shaking component (6) comprises an oscillation seat (61), an oscillation ring platform (62), an inner ring seat (63), an outer ring seat (64) and an oscillation spring I (65), wherein the oscillation seat (61) is arranged on the mounting table (7) in an oscillation driving piece capable of oscillating up and down, a through groove is formed in the middle of the oscillation seat (61) and used for enabling an outer rotating shaft (81) to pass through the through groove, an annular groove is further formed in the oscillation seat (61), the inner ring seat (63) is attached to the inner circumference of the annular groove, the outer ring seat (64) is attached to the outer circumference of the annular groove, the oscillation ring platform (62) is arranged between the inner ring seat (63) and the outer ring seat (64) in a vertically sliding mode, and a plurality of groups of oscillation spring I (65) are arranged between the oscillation ring platform (62) and the oscillation seat (61);

the oscillating driving piece comprises an oscillator (66) and two oscillating springs (67), wherein the oscillator (66) is fixed on the mounting table (7), the oscillator (66) is a linear oscillator, the oscillating end of the linear oscillator is fixedly connected with the oscillating base (61), and a plurality of groups of two oscillating springs (67) are arranged between the oscillating base (61) and the mounting table (7).

2. The apparatus for safely and rapidly detecting chronic food therapy according to claim 1, wherein: detection component (2) include conveyer belt (9), direction claw (10), infrared counter (11) and detector (12), wherein, conveyer belt (9) set up on detecting platform for receive food container (13) from feeding component (1), still be fixed with direction claw (10), infrared counter (11) and detector (12) from a left side to the right side on the detecting platform in proper order, and, food container (13) after detector (12) detected, the delivery end from conveyer belt (9) conveys out next station.

3. The apparatus for safely and rapidly detecting chronic food therapy according to claim 1, wherein: the feeding and discharging assembly (5) comprises clamping bins (51), a first push rod (52) and a second push rod (53), wherein a plurality of clamping bins (51) are fixed on the outer circumference of the feeding tray (3) in a circumferential array, the clamping bins (51) are groove-shaped and used for placing food containers (13), the first push rod (52) is fixed below the clamping bins (51), and the output end of the first push rod (52) can extend into the clamping bins (51) in a sliding mode so as to eject the food containers (13);

a second push rod (53) corresponding to the clamping bin (51) is further embedded into the feeding tray (3), and the second push rod (53) can extend when the first push rod (52) pushes the food container (13) upwards so as to push the food container (13); or when the food container (13) is positioned in the clamping bin (51), the second push rod (53) can perform short stretching, so that the radial oscillation of the food container (13) is realized.

4. The apparatus for safely and rapidly detecting chronic food therapy according to claim 1, wherein: and a damping sleeve is coaxially fixed at the upper end of the inner rotating shaft (82), and is arranged in a cavity of the outer rotating shaft (81) in a sliding manner.

5. The apparatus for safely and rapidly detecting chronic food therapy according to claim 1, wherein: the device is characterized by further comprising a controller, wherein the controller is electrically connected with the stepping motor (86), the oscillator (66), the first push rod (52), the second push rod (53), the infrared counter (11) and the detector (12) respectively.