CN216160490U - Automatic sampling device for building material radioactivity detection - Google Patents

Abstract

The utility model discloses an automatic sampling device for building material radioactivity detection, and belongs to the technical field of automatic sampling. Building materials radioactivity detects autoinjection device, including mount table, check out test set, still include: the cylinder is fixedly connected to the mounting table; the storage box is fixedly connected to the mounting table through a fixed side plate, the fixed side plate is fixedly connected to two sides of the bottom of the storage box, and a gap is reserved between the storage box and the mounting table; according to the utility model, multiple groups of building material samples are uniformly placed in the material storage box, then the building material samples are pushed to enter the conveyor belt one by using the air cylinder, the complexity caused by manual placement can be reduced by placing the multiple groups of building material samples, the placement operation is simplified, manual work does not need to stay beside equipment for a long time, and the building material samples are jacked up by the push plate, so that the speed of pushing the building material samples to the conveyor belt is increased, and the detection efficiency is improved.

Description

Automatic sampling device for building material radioactivity detection

Technical Field

The utility model relates to the technical field of automatic sampling, in particular to an automatic sampling device for building material radioactivity detection.

Background

Radioactivity detection of building material products is an important index for quality control of the building material products, and relates to health and safety of people, and building material radioactivity detection equipment is very important detection equipment for quality inspection mechanisms and building material product manufacturing enterprises;

during the radioactivity detection of the building materials, most of the building material samples are manually placed below detection equipment for detection, the manual placement operation is complicated, and personnel are required to be beside the equipment together, so that the personnel are influenced to perform other operations; the manual placement efficiency is low when the batch detection is carried out, and the detection efficiency is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems that the manual placement operation is complicated, and personnel are required to be beside the equipment together, so that the personnel are influenced to perform other operations; the manual placement efficiency is low when the batch detection is carried out, and the detection efficiency is influenced.

In order to achieve the purpose, the utility model adopts the following technical scheme:

building materials radioactivity detects autoinjection device, including mount table, check out test set, still include: the cylinder is fixedly connected to the mounting table; the storage box is fixedly connected to the mounting platform through a fixed side plate, the fixed side plate is fixedly connected to two sides of the bottom of the storage box, a gap is reserved between the storage box and the mounting platform, and a building material sample is placed in the storage box; the mounting box is fixedly connected to one end of the telescopic end of the air cylinder, and the mounting box is horizontal to the building material sample; the push plate is fixedly connected in the mounting box through a spring; the baffle is fixedly connected to one side, close to the cylinder, of the bottom of the storage box, the push plate is located below the baffle, and the push plate is tightly attached to the bottom surface of the baffle; the conveying belt is arranged on the other side of the storage box, and the detection equipment is located above the conveying belt.

In order to facilitate pushing of the building material sample, the distance between the bottom surface of the storage box and the mounting platform is preferably greater than the thickness of the building material sample.

In order to facilitate pushing the building material sample and prevent the mounting box from abutting against the adjacent building material sample, preferably, the thickness of the mounting box is smaller than that of the building material sample.

In order to reduce the hard friction between the side surface of the push plate and the building material sample, furthermore, two ends of the push plate are downward arc-shaped.

In order to reduce the friction between the push plate and the baffle plate and between the building material samples and the friction between the building material samples and the mounting table, further, the embedded rolling connection of the upper surface of the push plate is provided with a second ball, the second ball is attached to the bottom surface of the baffle plate, the embedded rolling connection of the mounting table is provided with a first ball, and the first ball is positioned below the material storage box.

Compared with the prior art, the utility model provides an automatic sampling device for building material radioactivity detection, which has the following beneficial effects:

1. this building materials radioactivity detects autoinjection device places the time of artifical placing in the material storage box through once treating the building materials sample that the multiunit was waited to detect, utilizes the cylinder flexible, and the average speed is pushed the building materials sample to the conveyer belt on, need not the manual work and guards by equipment, and the building materials sample of multiunit can improve detection efficiency simultaneously.

The device has the advantages that the plurality of groups of building material samples are uniformly placed in the storage box, then the building material samples are pushed to enter the conveyor belt one by using the air cylinder, the complexity caused by manual placement can be reduced by placing the plurality of groups of building material samples, the placement operation is simplified, the manual work does not need to stay beside the equipment for a long time, the building material samples are jacked up by the push plate, the speed of pushing the building material samples to the conveyor belt is increased, and the detection efficiency is improved.

Drawings

Fig. 1 is a schematic perspective view of an automatic sampling device for building material radioactivity detection according to the present invention;

FIG. 2 is a schematic perspective view of an automatic sampling device for building material radioactivity detection according to the present invention;

FIG. 3 is a third schematic view of a three-dimensional structure of the automatic sampling device for detecting building material radioactivity, provided by the utility model;

FIG. 4 is a schematic diagram of a right-view three-dimensional structure of the automatic sampling device for detecting building material radioactivity, which is provided by the utility model;

FIG. 5 is a schematic structural diagram of an automatic sampling device for building material radioactivity detection shown in FIG. 2A;

FIG. 6 is a schematic structural diagram of a building material radioactivity detection automatic sample injection device B in FIG. 3 according to the present invention;

FIG. 7 is a schematic structural diagram of a sample auto-feeder for building material radioactivity detection shown in FIG. 6;

fig. 8 is a schematic structural view of a building material radioactivity detection automatic sample injection device D in fig. 4 according to the present invention.

In the figure: 1. a material storage box; 10. a first ball bearing; 101. a baffle plate; 102. building material samples; 103. fixing the side plate; 2. an installation table; 201. a cylinder; 202. mounting a box; 203. pushing the plate; 2031. a second ball bearing; 204. a spring; 3. a conveyor belt; 4. and (5) detecting the equipment.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1:

referring to fig. 1-8, the automatic sampling device for building material radioactivity detection comprises a mounting platform 2 and a detection device 4, and further comprises: the cylinder 201 is fixedly connected to the mounting table 2; the storage box 1 is fixedly connected to the mounting table 2 through a fixed side plate 103, the fixed side plate 103 is fixedly connected to two sides of the bottom of the storage box 1, one end, far away from the storage box 1, of the fixed side plate 103 is fixed to the mounting table 2, a gap is reserved between the storage box 1 and the mounting table 2, and a building material sample 102 is placed in the storage box 1; the mounting box 202 is fixedly connected to one end of the telescopic end of the air cylinder 201, and the mounting box 202 is horizontal to the building material sample 102; the push plate 203 is fixedly connected in the mounting box 202 through a spring 204, one end of the spring 204 is fixed at the bottom of the push plate 203, the other end of the spring 204 is fixed in the mounting box 202, the upper end of the mounting box 202 is in an open shape, and the push plate 203 slides in the mounting box 202; the baffle 101 is fixedly connected to one side, close to the cylinder 201, of the bottom of the storage box 1, the push plate 203 is located below the baffle 101, and the push plate 203 is tightly attached to the bottom surface of the baffle 101; the conveyor belt 3 is arranged at the other side of the material storage box 1, the detection equipment 4 is positioned above the conveyor belt 3, and the detection equipment 4 is erected above the conveyor belt 3 through a support and is used for detecting the building material sample 102 moving on the conveyor belt 3; the distance between the bottom surface of the storage box 1 and the mounting platform 2 is larger than the thickness of the building material sample 102;

the cylinder 201 and the conveyor belt 3 are electrically connected with external control equipment, and the external control equipment can adjust the time of each expansion and contraction of the cylinder 201;

placing a plurality of groups of building material samples 102 to be detected in a storage box 1, stacking the plurality of groups of building material samples 102 in the storage box 1, wherein the shape of the storage box 1 is the same as that of the building material samples 102, and the building material samples 102 slide in the storage box 1;

the building material sample 102 at the bottommost layer is attached to the upper surface of the mounting table 2; starting the conveyor belt 3 and the detection equipment 4, then starting the cylinder 201, wherein the telescopic end of the cylinder 201 pushes the mounting box 202 to approach to the storage box 1, then one end of the mounting box 202 abuts against the building material sample 102 on the bottommost layer, and pushes the building material sample 102 to approach to the conveyor belt 3, when the mounting box 202 pushes the building material sample 102 to approach to the conveyor belt 3, under the action of rotation of the conveyor belt 3, the building material sample 102 falls on the conveyor belt 3, and the conveyor belt 3 brings the building material sample 102 to the lower part of the detection equipment 4 for detection;

the fixed baffle 101 can enable a gap to be reserved between the material storage box 1 and the mounting platform 2, and in addition, the fixed baffle 101 can provide a guiding effect for the building material sample 102 when the mounting box 202 pushes the building material sample 102, so that the building material sample 102 is prevented from inclining before entering the conveyor belt 3;

when one end of the mounting box 202 pushes the building material samples 102 to move, in order to reduce the friction force between the building material sample 102 at the bottom layer and the adjacent building material sample 102 at the upper layer, the push plate 203 can lift the building material sample 102 above the building material sample 102 at the bottom layer, so that a certain gap is left between the two groups of building material samples 102, the air cylinder 201 can push the building material sample 102 at the bottom layer onto the conveyor belt 3 more quickly, and the detection efficiency is improved;

when the building material sample 102 is pushed onto the conveyor 3, the telescopic end of the cylinder 201 drives the mounting box 202 to retract.

Example 2:

referring to fig. 1 to 8, an automatic sampling device for building material radioactivity detection is substantially the same as in example 1, and further comprises: the thickness of the mounting box 202 is less than the thickness of the building material sample 102;

the distance between the baffle 101 and the mounting platform 2 is smaller than the thickness of the building material sample 102, and after the thickness of the mounting box 202 is smaller than the thickness of the building material sample 102, the building material sample 102 can be pushed more conveniently, and the upper end of the mounting box 202 can be prevented from abutting against another group of building material samples 102, so that the building material sample 102 at the bottommost layer can not be pushed to move to the conveyor belt 3.

Example 3:

referring to fig. 1-2, the automatic sampling device for building material radioactivity detection is substantially the same as in example 1, and further comprises: the two ends of the push plate 203 are downward arc-shaped;

it can be more convenient for the pusher 203 to jack up a group of building material samples 102 adjacent to the bottommost building material sample 102.

Example 4:

referring to fig. 7-8, the automatic sampling device for building material radioactivity detection is substantially the same as in example 1, and further comprises: the upper surface of the push plate 203 is internally embedded with a second ball 2031 in a rolling way, the second ball 2031 is attached to the bottom surface of the baffle 101, the mounting table 2 is internally embedded with a first ball 10 in a rolling way, and the first ball 10 is positioned below the material storage box 1;

the second ball 2031 can reduce the friction between the second ball and the baffle 101, reduce the friction between the building material sample 102 attached to the push plate 203, and reduce the abrasion to the building material sample 102;

the first ball 10 can reduce the friction force with the mounting table 2 and reduce the abrasion when being pushed by the mounting box 202, so that the building material sample 102 can be quickly pushed onto the conveyor belt 3, and the detection efficiency is improved.

According to the utility model, multiple groups of building material samples 102 are uniformly placed in the storage box 1, then the air cylinders 201 are used for pushing the building material samples 102 to enter the conveyor belt 3 one by one, the complexity caused by manual placement can be reduced by placing the multiple groups of building material samples 102, the placement operation is simplified, manual work does not need to stay beside the equipment for a long time, the building material samples 102 are jacked up through the push plate 203, the speed of pushing the building material samples 102 to the conveyor belt 3 is increased, and the detection efficiency is improved.

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 equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (5)

1. Building materials radioactivity detection autoinjection device, including mount table (2), check out test set (4), its characterized in that still includes:

the cylinder (201) is fixedly connected to the mounting table (2);

the storage box (1) is fixedly connected to the mounting table (2) through a fixed side plate (103), the fixed side plate (103) is fixedly connected to two sides of the bottom of the storage box (1), a gap is reserved between the storage box (1) and the mounting table (2), and a building material sample (102) is placed in the storage box (1);

the mounting box (202) is fixedly connected to one end of the telescopic end of the air cylinder (201), and the mounting box (202) is horizontal to the building material sample (102);

the push plate (203) is fixedly connected in the mounting box (202) through a spring (204);

the baffle (101) is fixedly connected to one side, close to the cylinder (201), of the bottom of the storage box (1), the push plate (203) is located below the baffle (101), and the push plate (203) is tightly attached to the bottom surface of the baffle (101);

the conveying belt (3) is arranged on the other side of the storage box (1), and the detection equipment (4) is located above the conveying belt (3).

2. A building material radioactivity detecting autoinjection device according to claim 1, wherein a distance between a bottom surface of the storage bin (1) and the mounting platform (2) is greater than a thickness of the building material sample (102).

3. The building material radioactivity detection autosampler device of claim 1, wherein the thickness of the mounting box (202) is less than the thickness of the building material sample (102).

4. A building material radioactivity detection automatic sample introduction device according to claim 3, wherein both ends of the push plate (203) are downward arc-shaped.

5. The building material radioactivity detection automatic sampling device of claim 4, wherein a second ball (2031) is embedded and connected in a rolling mode on the upper surface of the push plate (203), the second ball (2031) is attached to the bottom surface of the baffle plate (101), a first ball (10) is embedded and connected in a rolling mode on the mounting table (2), and the first ball (10) is located below the material storage box (1).

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