CN219238462U - Online sampling device of milk - Google Patents

Abstract

The utility model discloses a milk on-line sampling device.A bracket is vertically arranged on one side of a conveyor belt; the support is in an inverted L shape, and one end of the support is parallel to one side surface of the conveyor belt and connected with the conveyor belt through bolts; the other end of the bracket is positioned right above the conveyor belt; the infrared sensing device is arranged at one end of the bracket above the conveyor belt; an infrared diffuse reflection type photoelectric sensing probe is arranged at the bottom end of the infrared sensing device; the photoelectric sensing probe is opposite to the top surface of the conveyor belt; an air cylinder is arranged on one side of the bracket parallel to the conveyor belt; the cylinder is vertical to the bracket; the piston end of the air cylinder penetrates through the bracket; the piston end of the cylinder is positioned on the upper side of the conveyor belt; the conveyor belt is provided with a guide plate at the other side opposite to the air cylinder; a collecting tray is arranged below the bottom end of the material guide plate; the control box is arranged at one side of the collecting tray; the infrared sensing device is connected with the control box through an electric signal, and the utility model can automatically collect samples at regular time, the regular collection time is adjustable, the labor intensity of workers is reduced, and the cost is saved.

Description

Online sampling device of milk

Technical Field

The utility model relates to the technical field of milk production line equipment, in particular to a milk online sampling device.

Background

At present, with the development of science and technology, the requirements on the degree of automation of factory equipment are higher and higher as the living standard is improved; in the milk production process, the boxed milk needs to be subjected to spot check in the production line, original equipment adopts manual sample taking from the production line, but the speed of movement of the boxed milk on the conveying belt is higher, certain difficulty and discontinuity exist in the operation of taking, other products are easy to knock down, operators are required to take every other certain time in the production process, the degree of automation of the existing equipment is lower, improvement is required, and automatic sample extraction is realized.

Disclosure of Invention

The utility model aims to provide an on-line milk sampling device so as to solve the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the milk online sampling device comprises a conveyor belt, a collecting tray, a bracket, an infrared sensing device, an air cylinder, a control box and a material guide plate; the conveyor belt is strip-shaped; a bracket is vertically arranged on one side of the conveyor belt; the support is in an inverted L shape, and one end of the support is parallel to one side surface of the conveyor belt and connected with the conveyor belt through bolts; the other end of the bracket is positioned right above the conveyor belt; the infrared sensing device is arranged at one end of the bracket above the conveyor belt; an infrared diffuse reflection type photoelectric sensing probe is arranged at the bottom end of the infrared sensing device; the photoelectric sensing probe is opposite to the top surface of the conveyor belt; an air cylinder is arranged on one side of the bracket parallel to the conveyor belt; the air cylinder is perpendicular to the bracket; the piston end of the cylinder penetrates through the bracket; the piston end of the cylinder is positioned on the upper side of the conveyor belt; the conveyor belt is provided with a guide plate at the other side opposite to the air cylinder; a collecting tray is arranged below the bottom end of the material guide plate; the control box is arranged at one side of the collecting tray; the infrared sensing device is in electrical signal connection with the control box; the electric induction probe and the air cylinder are on the same vertical plane.

Preferably, the cylinder barrel of the cylinder is provided with two gas electric control valves, and the gas electric control valves are connected with a gas pressure communicating pipe; the two air pressure communicating pipes are arranged, one air pressure communicating pipe is communicated with the side wall of the cylinder barrel of the cylinder far away from the piston, the other air pressure communicating pipe is communicated with the side wall of the cylinder barrel of the piston end of the cylinder, and the two air pressure communicating pipes are positioned on the same side of the bracket; the two gas electric control valves respectively control the on-off of the gas supply of the stretching and shrinking cavity of the cylinder.

Preferably, a singlechip and a time relay are arranged in the control box; the singlechip is electrically connected with the time relay, the infrared sensing device and the gas electric control valve.

Preferably, two sides above the conveyor belt are respectively provided with a stop lever; the stop lever is provided with a notch at a position opposite to the cylinder.

Preferably, the upper side of the material guide plate is parallel to the side surface of the conveyor belt; the lower side of the guide plate is inclined to the lower side of the conveyor belt; the lower side of the guide plate forms an included angle of 40-60 degrees with the side surface of the conveyor belt; two sides above the guide plate are provided with fixed continuous shifts; the other end of the fixed connecting plate is connected with the side face of the conveyor belt through bolts.

Compared with the prior art, the utility model has the beneficial effects that: the utility model can automatically collect samples at regular time, the regular collection time is adjustable, the labor intensity of workers is reduced, and the cost is saved; the type of the singlechip can be 80C51, the time relay can be in a delay and timing dual-purpose type, the type of the time relay is H3Y, the type of the gas electric control valve can be Q25DC-L20, the type of the infrared sensing device can be XZY, and the photoelectric switch can be scanned by hands; when the box-packed milk collecting device is used, the photoelectric sensing probe of the infrared sensing device moves on the conveyor belt, the photoelectric sensing probe of the infrared sensing device is opposite to the box-packed milk, an induction electric signal triggered by the box-packed milk is transmitted to the singlechip, after a certain time, the time relay sends an electric signal to the singlechip, the singlechip simultaneously receives the electric signal fed by the time relay and the electric signal of the infrared sensing device, and after the photoelectric sensing probe is on the same vertical plane with the air cylinder, the box-packed milk is opposite to the piston of the air cylinder, the singlechip firstly controls a gas electric control valve to be connected, the air cylinder receives external air pressure and stretches out, the air cylinder piston ejects the box-packed milk out of the conveyor belt, the box-packed milk is limited by the guide plate and slides down to the collecting tray, so that box-packed milk is collected, then the singlechip controls the other gas electric control valve to be connected, the air cylinder piston is retracted, and the continuous stretching out of the air cylinder piston can be realized through adjusting the on-off time of the two gas electric control valves of the singlechip control switch, so that continuous collection of the box-packed milk is realized.

Drawings

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

FIG. 2 is an oblique view of the present utility model;

fig. 3 is a schematic view of a portion of an infrared sensing device according to the present utility model.

In the figure: 1. a conveyor belt; 2. a collection tray; 3. a bracket; 4. an infrared sensing device; 5. a cylinder; 6. a control box; 7. a material guide plate; 8. a stop lever; 9. and fixing the connecting plate.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-3, the present utility model provides a technical solution: the milk online sampling device comprises a conveyor belt 1, a collecting tray 2, a bracket 3, an infrared sensing device 4, a cylinder 5, a control box 6 and a material guide plate 7; the conveyor belt 1 is strip-shaped; a bracket 3 is vertically arranged on one side of the conveyor belt 1; the support 3 is in an inverted L shape, and one end of the support 3 is parallel to one side surface of the conveyor belt 1 and is connected with the conveyor belt through bolts; the other end of the bracket 3 is positioned right above the conveyor belt 1; the infrared induction device 4 is arranged at one end of the bracket 3 above the conveyor belt 1; an infrared diffuse reflection type photoelectric sensing probe is arranged at the bottom end of the infrared sensing device 4; the photoelectric sensing probe is opposite to the top surface of the conveyor belt 1; an air cylinder 5 is arranged on one side of the bracket 3 parallel to the conveyor belt 1; the cylinder 5 is perpendicular to the bracket 3; the piston end of the cylinder 5 passes through the bracket 3; the piston end of the cylinder 5 is positioned on the upper side of the conveyor belt 1; the conveyor belt 1 is provided with a material guide plate 7 at the other side opposite to the air cylinder 5; a collecting tray 2 is arranged below the bottom end of the material guide plate 7; the control box 6 is arranged at one side of the collecting tray 2; the infrared sensing device 4 is in electrical signal connection with the control box 6; the photoelectric sensing probe and the cylinder 5 are on the same vertical plane.

Further, two gas electric control valves are arranged on the cylinder barrel of the air cylinder 5, and an air pressure communicating pipe is connected to the gas electric control valves; the two air pressure communicating pipes are arranged, one air pressure communicating pipe is communicated with the side wall of the cylinder barrel of the air cylinder 5 far away from the piston, the other air pressure communicating pipe is communicated with the side wall of the cylinder barrel of the air cylinder 5 near the piston end, and the two air pressure communicating pipes are positioned on the same side of the bracket 3; the two gas electric control valves respectively control the on-off of the air supply of the stretching and shrinking cavity of the air cylinder 5.

Further, a singlechip and a time relay are arranged in the control box 6; the singlechip is electrically connected with the time relay, the infrared sensing device 4 and the gas electric control valve.

Furthermore, two sides above the conveyor belt 1 are respectively provided with a stop lever 8; the stop lever 8 is provided with a notch at a position opposite to the cylinder 5.

Further, the upper side of the material guiding plate 7 is parallel to the side surface of the conveyor belt 1; the lower side of the material guide plate 7 is inclined to the lower side of the conveyor belt 1; the lower side of the material guide plate 7 forms an included angle of 40-60 degrees with the side surface of the conveyor belt 1; two sides above the guide plate 7 are provided with fixed continuous shifts; the other end of the fixed connecting plate 9 is connected with the side surface of the conveyor belt 1 through bolts.

When the utility model is implemented, the boxed milk moves on the conveyor belt 1, the photoelectric sensing probe of the infrared sensing device 4 is opposite to the boxed milk, and an induced electric signal triggered by the boxed milk is transmitted to the singlechip, when a certain time is required, the time relay sends out an electric signal to the singlechip, and after the singlechip receives the electric signal given by the time relay and the electric signal of the infrared sensing device 4, the photoelectric sensing probe is on the same vertical plane with the air cylinder 5, at the moment, the boxed milk is opposite to the piston of the air cylinder 5, the singlechip firstly controls a gas electric control valve to be connected, the air cylinder 5 receives external air pressure and stretches out, the air cylinder 5 piston ejects the boxed milk out of the conveyor belt 1, the boxed milk is limited by the guide plate 7 and slides down on the collecting tray 2, so that the boxed milk is collected, and then the singlechip controls the other gas electric control valve to be connected, and the piston of the air cylinder 5 is retracted, so that the continuous stretching out of the piston of the air cylinder 5 is realized by adjusting the on-off time of the two gas electric control valves of the singlechip; the utility model can automatically collect samples at regular time, the regular collection time is adjustable, the labor intensity of workers is reduced, and the cost is saved.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. Milk on-line sampling device, its characterized in that: comprises a conveyor belt (1), a collecting tray (2), a bracket (3), an infrared sensing device (4), an air cylinder (5), a control box (6) and a material guide plate (7); the conveyor belt (1) is strip-shaped; a bracket (3) is vertically arranged on one side of the conveyor belt (1); the support (3) is in an inverted L shape, and one end of the support (3) is parallel to one side surface of the conveyor belt (1) and connected with the conveyor belt through bolts; the other end of the bracket (3) is positioned right above the conveyor belt (1); the infrared induction device (4) is arranged at one end of the bracket (3) above the conveyor belt (1); an infrared diffuse reflection type photoelectric sensing probe is arranged at the bottom end of the infrared sensing device (4); the photoelectric sensing probe is opposite to the top surface of the conveyor belt (1); an air cylinder (5) is arranged on one side of the bracket (3) parallel to the conveyor belt (1); the cylinder (5) is perpendicular to the bracket (3); the piston end of the cylinder (5) passes through the bracket (3); the piston end of the air cylinder (5) is positioned on the upper side of the conveyor belt (1); the conveyor belt (1) is provided with a material guide plate (7) at the other side opposite to the air cylinder (5); a collecting tray (2) is arranged below the bottom end of the material guide plate (7); the control box (6) is arranged at one side of the collecting tray (2); the infrared sensing device (4) is in electrical signal connection with the control box (6); the photoelectric sensing probe and the air cylinder (5) are arranged on the same vertical plane.

2. The milk on-line sampling device of claim 1, wherein: two gas electric control valves are arranged on the cylinder barrel of the air cylinder (5), and an air pressure communicating pipe is connected to the gas electric control valves; the two air pressure communicating pipes are arranged, one air pressure communicating pipe is communicated with the side wall of the cylinder barrel of the air cylinder (5) far away from the piston, the other air pressure communicating pipe is communicated with the side wall of the cylinder barrel of the air cylinder (5) near the piston end, and the two air pressure communicating pipes are positioned on the same side of the bracket (3); the two gas electric control valves respectively control the on-off of the gas supply of the extension and contraction cavity of the cylinder (5).

3. An on-line milk sampling apparatus according to claim 2, wherein: a singlechip and a time relay are arranged in the control box (6); the singlechip is electrically connected with the time relay, the infrared sensing device (4) and the gas electric control valve.

4. The milk on-line sampling device of claim 1, wherein: two sides above the conveyor belt (1) are respectively provided with a stop lever (8); the stop lever (8) is provided with a notch at a position opposite to the air cylinder (5).

5. The milk on-line sampling device of claim 1, wherein: the upper side of the material guide plate (7) is parallel to the side surface of the conveyor belt (1); the lower side of the material guide plate (7) is inclined to the lower side of the conveyor belt (1); the lower side of the material guide plate (7) forms an included angle of 40-60 degrees with the side surface of the conveyor belt (1); two sides above the material guide plate (7) are provided with fixed connecting plates; the other end of the fixed connecting plate (9) is connected with the side surface of the conveyor belt (1) through bolts.

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