CN215296827U - Particle transportation process's online sampling device - Google Patents

Abstract

The utility model discloses a particle transportation's online sampling device, including the material case, be used for breathing in with follow the material case extract material and blow with carry away the main drive source of material and locate the process between material case and the main drive source and get the material subassembly, be equipped with the main input pipeline of connecting the two between material case and the main drive source input, the process is got the material subassembly and is included the vice driving source that can breathe in with follow the material case extraction material, vice driving source input and material case intercommunication, vice driving source output is connected with the material collection structure of collecting the material in order to supply the inspection, be equipped with the backflow structure that can lead back the material to main input pipeline between material collection structure and the main input pipeline. The utility model has the advantages of simple structure, low cost, sampling at any time in the particle production process and simple and convenient use.

Description

Particle transportation process's online sampling device

Technical Field

The utility model relates to a particle detection device technical field especially relates to a particle transportation process's online sampling device.

Background

The density and other quality data of the actual foaming product and the difference between the expected set value need to be grasped in real time in the conveying process of the foaming particles, and the difference is fed back to the program for real-time correction, so that the yield is improved. The existing sampling method for detecting the foaming particles is to sample the finished product after a period of time. The sample obtained in this way is not an instant sample, and cannot reflect the quality of the product currently being produced, and the expected value of the current production can only be controlled and corrected according to the quality condition of the finished product in the previous batch, which is not beneficial to instantly mastering the product quality.

The present invention is made based on such a situation.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the defects of the prior art and providing the on-line sampling device which has simple structure, low cost, can sample at any time in the particle production process and is simple and convenient to use.

The utility model discloses a realize through following technical scheme:

the utility model provides a particle course's online sampling device, includes the material case, is used for breathing in with follow the material case extraction material and blow in order to carry away the main drive source of material and locate the process between material case and the main drive source and get the material subassembly, be equipped with the main input pipeline of connecting the two between material case and the main drive source input, the process is got the material subassembly and is breathed in order to follow the vice drive source of material case extraction material, vice drive source input and material case intercommunication, vice drive source output is connected with the material collection structure of collecting the material in order to supply the inspection, be equipped with the backflow structure that can lead back the material to main input pipeline between material collection structure and the main input pipeline.

According to the online sampling device for the particle conveying process, an auxiliary input pipeline is arranged between the input end of the auxiliary driving source and the material box, an auxiliary output pipeline is arranged at the output end of the auxiliary driving source, and the material collecting structure comprises a material receiving funnel which is arranged below the far-end opening of the auxiliary output pipeline and used for receiving and taking materials.

According to the on-line sampling device for the particle conveying process, the opening at the far end of the auxiliary output pipeline is provided with the air discharging cylinder for discharging wind power and enabling materials to fall.

According to the above on-line sampling device for the particle conveying process, the air discharge barrel is in a cylindrical shape with a hollow side wall in the vertical direction.

The device for on-line sampling of particle delivery process as described above, wherein the backflow structure comprises a backflow pipeline connected between the receiving hopper and the main input pipeline.

According to the on-line sampling device for the particle conveying process, the return pipeline is provided with the return valve for closing or opening the return pipeline.

According to the on-line sampling device for the particle conveying process, the main driving source and the auxiliary driving source are fans which can be used for material conveying.

According to the on-line sampling device for the particle conveying process, the output end of the main driving source is connected with the main output pipeline for conveying materials.

Compared with the prior art, the utility model discloses there is following advantage:

1. the utility model discloses in, in particle material production process, the main drive source is taken out the particle from the feed box and is driven the particle and flow along main input pipeline. And the accessory drive source then extracts the particle of small part from the material case and carries the material collection structure as the sample, supplies to detect the use, during the detection directly from the material collect the structure sample can, simplify the sample work, the convenience obtains real-time sample in process of production. The redundant sample is drained to the main input pipeline by the backflow structure, and particles in the backflow structure can be automatically sucked due to the fact that the flow speed in the main input pipeline is high and the pressure is low, so that the redundant sample is recycled, waste is reduced, and cost is saved.

2. An air discharging barrel is arranged at the opening at the far end of the auxiliary output pipeline, and the air discharging barrel is in a cylindrical shape with a hollow side wall in the vertical direction. I.e. the side wall of the discharge duct is provided with a mesh which allows the passage of wind but not the passage of particles. Since the particles are blown out of the secondary output duct, they carry wind. In order to avoid impact and escape under the influence of particle conveying wind power, an air discharge barrel is arranged at the opening at the far end of the auxiliary output pipeline. The conveying wind firstly overflows from the meshes on the side wall of the wind discharging cylinder when reaching the wind discharging cylinder, and the particles slowly fall into the material receiving hopper.

3. The backflow structure comprises a backflow pipeline connected between the material receiving funnel and the main input pipeline. The backflow pipeline is connected with the main input pipeline, and due to the fact that suction exists in the main input pipeline, particles in the backflow pipeline can be sucked, redundant particles in the material receiving funnel can be sucked away into the main input pipeline to be recycled, and waste of resources is reduced.

Drawings

The following detailed description of embodiments of the present invention is provided with reference to the accompanying drawings, in which:

fig. 1 is a first perspective view of the present invention;

fig. 2 is a schematic perspective view of the present invention.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings and the detailed description.

An online sampling device for a particle conveying process as shown in fig. 1 to 2 comprises a material tank 1, a main driving source 2 used for sucking to extract materials from the material tank 1 and blowing to convey the materials, and a process material taking assembly arranged between the material tank 1 and the main driving source 2, wherein a main input pipeline 21 used for connecting the material tank 1 and the main driving source 2 is arranged between the input ends of the main driving source 2, the process material taking assembly comprises an auxiliary driving source 3 capable of sucking to extract the materials from the material tank 1, the input end of the auxiliary driving source 3 is communicated with the material tank 1, the output end of the auxiliary driving source 3 is connected with a material collecting structure used for collecting the materials for inspection, and a backflow structure capable of guiding the materials back to the main input pipeline 21 is arranged between the material collecting structure and the main input pipeline 21. The utility model discloses in, in particle material production process, main driving source 2 takes out the particle from material case 1 and drives the particle and flow along main input pipeline 21. And the auxiliary driving source 3 extracts a small part of particles from the material box 1 and conveys the particles to the material collecting structure as a sample for detection, and the detection is directly performed by sampling from the material collecting structure, so that the sampling work is simplified, and a real-time sample is conveniently obtained in the production process. The redundant sample is drained to the main input pipeline 21 by the backflow structure, and particles in the backflow structure can be automatically sucked due to the fact that the flow speed in the main input pipeline 21 is high and the pressure is low, so that the redundant sample is recycled, waste is reduced, and cost is saved.

More specifically, the main driving source 2 and the auxiliary driving source 3 are both fans which can be used for material conveying, and both draw air from the input end and blow air from the output end. The efficiency of conveying particles is high.

More specifically, be equipped with vice input pipeline 4 between vice driving source 3 input and the material case 1, the 3 output of vice driving source is equipped with vice output pipeline 5, the material is collected the structure and is used for connecing the material funnel 51 of connecing of getting the material including establishing in vice output pipeline 5 distal end opening below. That is, the particles are extracted from the material box 1 by the auxiliary driving source 3 and sucked into the auxiliary input pipeline 4, then the particles are blown out from the auxiliary output pipeline 5 by the auxiliary driving source 3, the particles fall into the material receiving funnel 51 from the far end opening of the auxiliary output pipeline 5, and sampling personnel can sample from the material receiving funnel 51, so that the sampling is simple and rapid.

Preferably, the far end of the auxiliary output pipeline 5 and the receiving hopper 51 are arranged in the sound insulation room and are separated from other equipment, sampling personnel do not need to be checked, and the harm of machine noise to the sampling personnel can be reduced.

More specifically, the opening at the far end of the secondary output pipeline 5 is provided with a wind discharging cylinder 52 for discharging wind power and enabling materials to fall. More specifically, the air discharge duct 52 is a tube shape with a hollow side wall in the vertical direction, that is, the side wall of the air discharge duct 52 is provided with meshes which allow air to pass through but do not allow particles to pass through. As the particles are blown out of the secondary output duct 5, they carry wind with them. In order to avoid impact and escape under the influence of the wind force of particle transportation, a wind discharge cylinder 52 is arranged at the opening at the far end of the secondary output pipeline 5. The conveying wind will first overflow from the side wall mesh in the wind discharge cylinder 52, and the particles will slowly fall into the receiving hopper 51.

More specifically, the return structure comprises a return duct 6 connected between the receiving hopper 51 and the main input duct 21. The return pipeline 6 is connected with the main input pipeline 21, particles in the return pipeline 6 can be sucked in due to the suction of the main input pipeline 21, redundant particles in the material receiving funnel 51 can be sucked away into the main input pipeline 21 to be recycled, and the waste of resources is reduced.

More specifically, the return pipe 6 is provided with a return valve 61 for closing or opening the return pipe 6. When the backflow is needed, the backflow valve 61 is opened, and the sampling is prevented from being influenced.

More specifically, the output end of the main driving source 2 is connected with a main output pipeline 22 for conveying away materials. The particles are sucked from the material tank 1 into the main drive source 2 and then blown out by the main drive source 2 to the main output duct 22 to be conveyed to the next process.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (8)

1. An online sampling device of particle transportation process which characterized in that: including material case (1), be arranged in order to breathe in with follow material case (1) extraction material and blow in order to carry away main drive source (2) of material and locate the process between material case (1) and main drive source (2) and get the material subassembly, be equipped with between material case (1) and the main drive source (2) input and connect main input pipeline (21) of the two, the process is got the material subassembly and is drawn vice drive source (3) of material in order to follow material case (1) including breathing in, vice drive source (3) input and material case (1) intercommunication, vice drive source (3) output is connected with collects the material and collects the structure in order to supply the material of inspection, be equipped with the backflow structure that can lead back main input pipeline (21) with the material between material collection structure and main input pipeline (21).

2. An on-line sampling device for particle delivery processes according to claim 1, wherein: be equipped with vice input pipeline (4) between vice driving source (3) input and material case (1), vice driving source (3) output is equipped with vice output pipeline (5), the material is collected the structure and is used for connecing the material funnel (51) of getting the material including establishing in vice output pipeline (5) distal end opening below.

3. An on-line sampling device for particle delivery processes according to claim 2, wherein: an air discharge barrel (52) used for discharging wind power and enabling materials to fall is arranged at the opening at the far end of the auxiliary output pipeline (5).

4. An on-line sampling device for particle delivery processes according to claim 3, wherein: the air discharge barrel (52) is in a cylindrical shape with a hollow side wall in the vertical direction.

5. An on-line sampling device for particle delivery processes according to claim 2, wherein: the backflow structure comprises a backflow pipeline (6) connected between the receiving hopper (51) and the main input pipeline (21).

6. An on-line sampling device for particle delivery processes according to claim 5, wherein: and a return valve (61) for closing or opening the return pipeline (6) is arranged on the return pipeline (6).

7. An on-line sampling device for particle delivery processes according to claim 1, wherein: the main driving source (2) and the auxiliary driving source (3) are fans which can be used for material conveying.

8. An on-line sampling device for particle delivery processes according to claim 1, wherein: the output end of the main driving source (2) is connected with a main output pipeline (22) for conveying materials.

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