CN111198229A - Novel ceramic plate sound insulation performance test equipment - Google Patents

Abstract

The invention discloses a novel ceramic plate sound insulation performance testing device, which comprises a detection box, wherein a detection cavity is arranged in the detection box, a first decibel instrument is arranged in the detection cavity, a sound source cavity positioned on the upper side of the detection cavity is arranged in the detection box, the sound source cavity is communicated with the detection cavity through a through hole, a sound production module is arranged in the sound source cavity, a ceramic plate positioned on the upper side of the through hole is placed on the bottom wall of the sound source cavity, a clamping mechanism used for fixing the ceramic plate is arranged in the sound source cavity, and a second decibel instrument is arranged in the sound source cavity. The accuracy of the test result is ensured.

Description

Novel ceramic plate sound insulation performance test equipment

Technical Field

The invention relates to the technical field of sound insulation performance detection, in particular to novel ceramic plate sound insulation performance testing equipment.

Background

With the development of the technology, the novel ceramic material gradually replaces the traditional heat-insulating and sound-insulating material, the ceramic material has the advantages of good sound-insulating effect and strong heat-insulating property, and a plurality of factors influencing the quality of the ceramic plate exist in the production process of the ceramic plate, so that the ceramic plate needs to be detected after the production of the ceramic plate is finished.

Disclosure of Invention

The invention provides novel ceramic plate sound insulation performance testing equipment, which overcomes the problems.

The invention is realized by the following technical scheme.

A novel ceramic plate sound insulation performance testing device comprises a detection box, wherein a detection cavity is arranged in the detection box, a first scallop instrument is arranged in the detection cavity, a sound source cavity is arranged on the upper side of the detection cavity in the detection box, the sound source cavity is communicated with the detection cavity through a through hole, a sound production module is arranged in the sound source cavity, a ceramic plate arranged on the upper side of the through hole is placed on the bottom wall of the sound source cavity, a clamping mechanism used for fixing the ceramic plate is arranged in the sound source cavity, a second scallop instrument is arranged in the sound source cavity, valve mechanisms are arranged in the left inner wall and the right inner wall of the sound source cavity, a feeding mechanism is arranged on the left side of the detection box, a support plate is fixedly arranged on the front end face and the rear end face of the detection box, an electric guide rail is fixedly arranged on the opposite end face of the support plate, a slide block is arranged on, front and back the fixed transport plate that is equipped with of the relative one end of first electric telescopic handle, front and back the constant head tank that runs through about being equipped with in the relative terminal surface of transport plate around the fixed connecting plate that is equipped with of slider upside, the terminal surface is fixed to be equipped with second electric telescopic handle under the connecting plate, the fixed backup pad that is equipped with of second electric telescopic handle lower extreme, end-face mounting has electric chuck under the backup pad, the backup pad downside is equipped with the bin, be equipped with the storage chamber that makes progress the open-ended in the bin, after the detection the ceramic plate is placed in corresponding according to the testing result store in the.

Furthermore, the feeding mechanism comprises a feeding plate fixedly arranged on the left end face of the detection box, a conveying belt penetrates through the upper side of the feeding plate, the conveying belt is used for conveying the ceramic plates, an air cylinder positioned on the left side of the conveying belt is fixedly arranged on the upper end face of the feeding plate, and a pushing plate used for pushing the ceramic plates into the sound source cavity is fixedly arranged at the right end of a piston rod on the right side of the air cylinder.

Further, the valve mechanism comprises valve cavities which are bilaterally symmetrical and are arranged in the inner wall of the sound source cavity in a left-right penetrating mode, a storage cavity is arranged in the top wall of the valve cavity, a second electric guide rail is fixedly arranged on the rear wall of the storage cavity, and valve plates used for opening and closing the valve cavities are installed on the front portion and the rear portion of the second electric guide rail.

Furthermore, the clamping mechanism comprises fixed plates which are symmetrically and fixedly arranged on the bottom wall of the sound source cavity in a front-back mode, opposite end faces of the front fixed plate and the back fixed plate are provided with spring grooves with opposite openings, clamping plates are arranged in the spring grooves in a sliding mode, electromagnets are fixedly arranged on the top walls of the spring grooves, jacking springs are connected between the clamping plates and the top walls of the spring grooves, the clamping plates clamp the ceramic plates under the action of the jacking springs, and the electromagnets are started to enable the clamping plates to ascend.

Further, sound source chamber roof is fixed and is equipped with third electric telescopic handle, sound production module installation with third electric telescopic handle downside starts third electric telescopic handle adjustment sound production module with distance between the ceramic plate.

Furthermore, a limiting plate is arranged in the sound source cavity and fixedly connected with the right valve plate.

The invention has the beneficial effects that: the invention can carry out batch detection on the sound insulation performance of the ceramic plates and classify the ceramic plates according to the sound insulation performance of each ceramic plate.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

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

FIG. 2 is a schematic view of the structure at A-A in FIG. 1;

FIG. 3 is a schematic view of a right cross-sectional view of the rear fixing plate of FIG. 1;

fig. 4 is a schematic diagram of the structure at B in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The novel ceramic plate sound insulation performance test equipment disclosed by the accompanying drawings 1-4 mainly comprises a detection box 10, wherein a detection cavity 11 is arranged in the detection box 10, a first decibel analyzer 12 is arranged in the detection cavity 11, a sound source cavity 37 positioned on the upper side of the detection cavity 11 is arranged in the detection box 10, the sound source cavity 37 is communicated with the detection cavity 11 through a through hole 13, a sound production module 29 is arranged in the sound source cavity 37, a ceramic plate 14 positioned on the upper side of the through hole 13 is placed on the bottom wall of the sound source cavity 37, a clamping mechanism 62 for fixing the ceramic plate 14 is arranged in the sound source cavity 37, a second decibel analyzer 28 is arranged in the sound source cavity 37, valve mechanisms 61 are arranged in the left inner wall and the right inner wall of the sound source cavity 37, a feeding mechanism 60 is arranged on the left side of the detection box 10, a supporting plate 19 is fixedly arranged on the front end face and the rear end faces of the detection box 10, an electric guide rail 20, front and back slider 39 is installed to the relative one side of backup pad 19, front and back first electric telescopic handle 38 is installed to the relative one side of slider 39, front and back the fixed transport plate 21 that is equipped with of the relative one end of first electric telescopic handle 38, front and back the constant head tank 15 that runs through about being equipped with in the relative terminal surface of transport plate 21, front and back the fixed connecting plate 25 that is equipped with of slider 39 upside, the fixed second electric telescopic handle 26 that is equipped with of terminal surface under the connecting plate 25, the fixed backup pad 23 that is equipped with of second electric telescopic handle 26 lower extreme, electric suction cup 22 is installed to terminal surface under the backup pad 23, the 19 downside of backup pad is equipped with bin 17, be equipped with upwards open-ended storage chamber 16 in bin 17, after the detection ceramic plate 14 place in.

Advantageously, the feeding mechanism 60 includes a feeding plate 35 fixedly disposed on the left end surface of the detecting box 10, a conveying belt 36 passes through the feeding plate 35, the conveying belt 36 is used for conveying the ceramic plate 14, an air cylinder 34 is fixedly disposed on the upper end surface of the feeding plate 35 and located on the left side of the conveying belt 36, and a pushing plate 33 is fixedly disposed at the right end of the piston rod on the right side of the air cylinder 34 and used for pushing the ceramic plate 14 into the sound source cavity 37.

Beneficially, the valve mechanism 61 includes a valve cavity 40 which is arranged in the inner wall of the sound source cavity 37 in a bilateral symmetry manner and penetrates left and right, a storage cavity 45 is arranged in the top wall of the valve cavity 40, a second electric guide rail 50 is fixedly arranged on the rear wall of the storage cavity 45, and a valve plate 41 for opening and closing the valve cavity 40 is mounted on the front and rear of the second electric guide rail 50.

Advantageously, the clamping mechanism 62 includes a fixed plate 30 fixed to the bottom wall of the sound source chamber 37 in a front-back symmetrical manner, opposite end faces of the front and back fixed plates 30 are provided with spring grooves 42 with opposite openings, a clamping plate 31 is slidably disposed in the spring grooves 42, an electromagnet 44 is fixedly disposed on the top wall of the spring groove 42, a pressing spring 43 is connected between the clamping plate 31 and the top wall of the spring groove 42, the clamping plate 31 clamps the ceramic plate 14 under the action of the pressing spring 43, and the electromagnet 44 is activated to lift the clamping plate 31.

Advantageously, a third electric telescopic rod 27 is fixedly arranged on the top wall of the sound source cavity 37, the sound production module 29 is mounted on the lower side of the third electric telescopic rod 27, and the third electric telescopic rod 27 is actuated to adjust the distance between the sound production module 29 and the ceramic plate 14.

Advantageously, a stop plate 46 is arranged in the sound source chamber 37, and the stop plate 46 is fixedly connected to the right side valve plate 41.

The working steps are as follows: the conveyor belt 36 conveys the ceramic plate 14 to the right of the push plate 33;

the second left electric guide rail 50 is started to enable the left valve plate 41 to be accommodated in the accommodating cavity 45, the air cylinder 34 is started to enable the pushing plate 33 to push the ceramic plate 14 to move rightwards, the electromagnet 44 is started to enable the clamping plate 31 to move upwards, the pushing plate 33 pushes the ceramic plate 14 to abut against the limiting plate 46 and then stops, and the air cylinder 34 is started to enable the pushing plate 33 to return;

the left valve plate 41 descends to seal the left valve cavity 40, the electromagnet 44 is closed, the clamping plate 31 clamps the ceramic plate 14 under the action of the jacking spring 43, the second decibel meter 28 detects that no other sound exists in the sound source cavity 37, the sound production module 29 starts sound production, and the first decibel meter 12 detects the sound decibel in the detection cavity 11, so that the sound insulation effect of the ceramic plate 14 is detected;

after the detection is finished, the left valve plate 41 and the right valve plate 41 are lifted, the limiting plate 46 is lifted, the air cylinder 34 is started, the pushing plate 33 pushes the ceramic plate 14 in the sound source cavity 37 rightwards, and the ceramic plate 14 moves to the positioning groove 15;

electric guide rail 20 starts to make transport plate 21 move to the right, and transport plate 21 drives ceramic plate 14 and moves to corresponding storage chamber 16 upside, and second electric telescopic handle 26 starts to make electric suction cup 22 descend and adsorb on ceramic plate 14, and first electric telescopic handle 38 starts to make transport plate 21 keep away from each other around, and electric suction cup 22 drives ceramic plate 14 and descends and store in storage chamber 16.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides a novel ceramic plate sound insulation capability test equipment, includes the detection case, be equipped with in the detection case and detect the chamber, be equipped with first branch shellfish appearance in the detection chamber, be equipped with in the detection case and be located detect the sound source chamber of chamber upside, the sound source chamber with detect through hole intercommunication between the chamber, be equipped with sound production module in the sound source chamber, sound source chamber diapire has been placed and is located the ceramic plate of through hole upside, be equipped with in the sound source chamber be used for with the fixed clamping mechanism of ceramic plate, its characterized in that: the acoustic source cavity is internally provided with a second shellfish analyzer, the left and right inner walls of the acoustic source cavity are internally provided with a valve mechanism, the left side of the detection box is provided with a feeding mechanism, the front and back end surfaces of the detection box are fixedly provided with supporting plates, the opposite end surfaces of the front and back supporting plates are fixedly provided with electric guide rails, the opposite sides of the front and back supporting plates are provided with sliding blocks, the opposite sides of the front and back sliding blocks are provided with first electric telescopic rods, the opposite ends of the front and back electric telescopic rods are fixedly provided with conveying plates, the opposite end surfaces of the front and back conveying plates are provided with left and right through positioning grooves, the upper sides of the front and back sliding blocks are fixedly provided with connecting plates, the lower end surfaces of the connecting plates are fixedly provided with second electric telescopic rods, the lower ends of the second electric telescopic rods, and the ceramic plate after detection is placed in the corresponding storage cavity to be stored according to the detection result.

2. The novel ceramic plate sound insulation performance test device according to claim 1, characterized in that: the feeding mechanism comprises a feeding plate fixedly arranged on the left end face of the detection box, a conveying belt penetrates through the upper side of the feeding plate and is used for conveying the ceramic plates, an air cylinder positioned on the left side of the conveying belt is fixedly arranged on the upper end face of the feeding plate, and a pushing plate used for pushing the ceramic plates into the sound source cavity is fixedly arranged at the right end of a piston rod on the right side of the air cylinder.

3. The novel ceramic plate sound insulation performance test device according to claim 1, characterized in that: the valve mechanism comprises a valve cavity which is bilaterally symmetrical and is arranged in the sound source cavity inner wall in a left-right penetrating mode, a storage cavity is arranged in the top wall of the valve cavity, a second electric guide rail is fixedly arranged on the rear wall of the storage cavity, and a valve plate used for opening and sealing the valve cavity is arranged around the second electric guide rail.

4. The novel ceramic plate sound insulation performance test device according to claim 1, characterized in that: the clamping mechanism comprises a fixed plate which is symmetrically and fixedly arranged on the bottom wall of the sound source cavity in a front-back mode, opposite end faces of the front fixed plate and the back fixed plate are provided with spring grooves with opposite openings, clamping plates are arranged in the spring grooves in a sliding mode, electromagnets are fixedly arranged on the top walls of the spring grooves, jacking springs are connected between the clamping plates and the top walls of the spring grooves, the ceramic plates are clamped by the clamping plates under the action of the jacking springs, and the clamping plates can ascend when the electromagnets are started.

5. The novel ceramic plate sound insulation performance test device according to claim 1, characterized in that: the sound source chamber roof is fixedly provided with a third electric telescopic handle, the sound production module is installed on the lower side of the third electric telescopic handle and is started to adjust the sound production module and the distance between the ceramic plates.

6. The novel ceramic plate sound insulation performance test device according to claim 3, characterized in that: and a limiting plate is arranged in the sound source cavity and is fixedly connected with the right valve plate.

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