阅读说明：本技术 一种检测模组壳体上的开孔方法 (Method for detecting hole on module shell ) 是由 王伟 于 2019-03-06 设计创作，主要内容包括：本发明涉及电子设备生产领域,特别涉及一种检测模组壳体上的开孔方法,包括如下步骤：根据预先提供的检测模块的最大检测流量值和空气分子的扩散速度,计算开设于检测模组的壳体上的至少一个透气孔的开孔总面积,使通过各透气孔的总流量值等于检测模块的最大检测流量值；根据计算得到的开孔总面积,计算各透气孔的开孔孔径；根据计算得出的各透气孔的开孔孔径,在壳体上与检测模块相对的位置,开设至少一个透气孔。根据开孔总面积计算开孔尺寸,进行开孔。即空气分子在自由扩散时通过透气孔进入检测模组,空气进入的流量等于最大流量检测值,使得检测模块可以检测气体参数的同时以最高的效率进行工作,提升了检测模块的工作效率。(The invention relates to the field of electronic equipment production, in particular to a method for detecting holes on a module shell, which comprises the following steps: calculating the total area of the opening of at least one air hole formed in the shell of the detection module according to the maximum detection flow value of the detection module and the diffusion speed of the air molecules, which are provided in advance, so that the total flow value passing through each air hole is equal to the maximum detection flow value of the detection module; calculating the pore diameter of each air hole according to the total pore area obtained by calculation; and opening at least one air hole on the shell at a position opposite to the detection module according to the calculated hole opening aperture of each air hole. And (4) calculating the size of the opening according to the total area of the opening, and opening the opening. Air molecule gets into through the bleeder vent when free diffusion promptly and detects the module, and the flow that the air got into equals the maximum flow detection value for work with the highest efficiency when detection module can detect gas parameter, promoted detection module's work efficiency.)

1. A method for detecting holes on a module shell is characterized by comprising the following steps:

calculating the total area of the opening of at least one air hole formed in the shell of the detection module according to the maximum detection flow value of the detection module and the diffusion speed of air molecules, which are provided in advance, so that the total flow value passing through each air hole is equal to the maximum detection flow value of the detection module;

calculating the pore diameter of each air hole according to the total pore area obtained by calculation;

and opening at least one air hole on the shell at a position opposite to the detection module according to the calculated hole opening aperture of each air hole.

2. The method for detecting the opening of the module shell as claimed in claim 1, wherein the step of calculating the opening diameter of each vent hole according to the total opening area obtained by calculation specifically comprises the following steps:

predetermining the number of the air holes;

and calculating the pore diameter of each air hole according to the air permeable area and the number of the air holes.

3. The method as claimed in claim 2, wherein the number of the air holes is greater than 1, and the diameter of each air hole is the same.

4. The method for detecting the holes on the module shell as claimed in claim 3, wherein in the step of calculating the hole diameter of each vent hole according to the vent area and the number of vent holes, the method specifically comprises:

dividing the total area of each opening obtained by calculation by the number of the air holes, and calculating the opening area of each air hole;

and calculating the opening aperture of the single air hole according to the calculated opening area of the single air hole.

5. The method of claim 1, wherein the housing comprises: the air-permeable shell comprises a shell body with mounting holes and a protection plate used for being mounted on the mounting holes of the shell body, wherein each air hole is formed in the protection plate.

6. The method for forming the hole on the detection module casing according to claim 5, wherein the step of forming at least one vent hole on the casing at a position corresponding to the detection module according to the calculated hole diameter of each vent hole specifically comprises the steps of:

arranging each air hole at the position of the protection plate corresponding to the detection module according to the calculated hole diameter of each air hole;

installing the protection plate in the installation hole of the shell body.

7. The method for forming the hole in the detection module casing according to claim 5, wherein the step of forming at least one vent hole in the casing at a position corresponding to the detection module according to the calculated hole diameter of each vent hole comprises the following steps:

forming air holes in the positions, corresponding to the detection module, of the protection plate according to the hole opening diameters of the air holes obtained through calculation; the cross section area of the air holes is equal to the total area of the openings;

installing the protection plate in the installation hole of the shell body.

Technical Field

The invention relates to the field of electronic equipment production, in particular to a method for detecting holes on a module shell.

Background

A gas sensor is a device that converts information such as the composition, concentration, etc. of a gas into information that can be utilized by persons, instruments, computers, etc., and is generally classified as a chemical sensor.

The detection module is a packaging part which packages the gas sensor, when the gas sensor works, the gas sensor needs to be communicated with air, the detection module needs to be provided with air holes, the size of the air holes has strict requirements, if the size of the air holes is too small, the flow of air entering the detection module is too small, and the detection effect and the detection efficiency of the gas sensor are greatly influenced; if the size of bleeder vent is too big for get into the air flow rate that detects in the module at the excessive speed, lead to gas sensor's testing result inaccurate, so the size that the bleeder vent was seted up needs very accurate, just can guarantee gas sensor's detection precision.

Disclosure of Invention

The invention aims to provide a hole opening method on a detection module shell, so that the flow value of air entering a detection module is equal to the maximum detection flow value of the detection module, and a gas sensor works at the highest efficiency.

In order to solve the above technical problem, an embodiment of the present invention provides a method for detecting a hole on a module housing, including the following steps: calculating the total area of the opening of at least one air hole formed in the shell of the detection module according to the maximum detection flow value of the detection module and the diffusion speed of air molecules, which are provided in advance, so that the total flow value passing through each air hole is equal to the maximum detection flow value of the detection module; calculating the pore diameter of each air hole according to the total pore area obtained by calculation; and opening at least one air hole on the shell at a position opposite to the detection module according to the calculated hole opening aperture of each air hole.

Compared with the prior art, the method and the device have the advantages that the total opening area is calculated through the maximum flow detection value of the detection module and the diffusion speed of the molecules, the diffusion speed of the air molecules multiplied by the total opening area is equal to the maximum flow detection value, and then the size of the opening is calculated through the total opening area to open the opening. Air molecule gets into through the bleeder vent when free diffusion promptly and detects the module, and the flow that the air got into equals the maximum flow detection value for work with the highest efficiency when detection module can detect gas parameter, promoted detection module's work efficiency.

In addition, the step of calculating the aperture of each vent hole according to the total aperture area obtained by calculation specifically includes the following steps:

predetermining the number of the air holes;

and calculating the pore diameter of each air hole according to the air permeable area and the number of the air holes.

In addition, the number of the air holes is more than 1, and the apertures of the air holes arranged on the shell are the same.

In addition, in the step of calculating the aperture of each air hole according to the air permeable area and the number of the air holes, the method specifically comprises the following steps:

dividing the total area of each opening obtained by calculation by the number of the air holes, and calculating the opening area of each air hole;

and calculating the opening aperture of the single air hole according to the calculated opening area of the single air hole.

In addition, the housing includes: the air-permeable shell comprises a shell body with mounting holes and a protection plate used for being mounted on the mounting holes of the shell body, wherein each air hole is formed in the protection plate.

In addition, according to the calculated hole opening aperture of each air hole, in the step of opening at least one air hole on the shell at the position corresponding to the detection module, the method specifically comprises the following steps:

arranging each air hole at the position of the protection plate corresponding to the detection module according to the calculated hole diameter of each air hole;

installing the protection plate in the installation hole of the shell body.

In addition, according to the calculated hole opening aperture of each air hole, in the step of opening at least one air hole on the shell at the position corresponding to the detection module, the method specifically comprises the following steps:

forming air holes in the positions, corresponding to the detection module, of the protection plate according to the hole opening diameters of the air holes obtained through calculation; the cross section area of the air holes is equal to the total area of the openings;

installing the protection plate in the installation hole of the shell body.

Drawings

One or more embodiments are illustrated by way of example in the accompanying drawings, which correspond to the figures in which like reference numerals refer to similar elements and which are not to scale unless otherwise specified.

FIG. 1 is a flow chart of a method for forming openings in a detection module according to a first embodiment;

FIG. 2 is a flowchart of a method of opening holes in a detection module according to a second embodiment;

FIG. 3 is a top view of a detection module in a first embodiment;

FIG. 4 is a cross-sectional view of a detection module in a first embodiment;

FIG. 5 is a top view of a detection module in a second embodiment;

fig. 6 is a sectional view of a detection module in the second embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail below with reference to the accompanying drawings. However, it will be appreciated by those of ordinary skill in the art that numerous technical details are set forth in order to provide a better understanding of the present application in various embodiments of the present invention. However, the technical solution claimed in the present application can be implemented without these technical details and various changes and modifications based on the following embodiments.

The invention relates to a hole opening method on a detection module shell, which is applied to a detection module, wherein the detection module is arranged in the detection module and is used for contacting with air and acquiring parameter information of specific gas in the air. Set up the bleeder vent on the detection module casing and can make the air admission detection module, detection module in the detection module contacts with the parameter information of the air that gets into from the bleeder vent in order to test specific gas.

As shown in fig. 1, 3 and 4, the method for forming the hole in the detection module includes the following steps:

1100. calculating the total opening area of at least one air hole 2 arranged on the shell 1 of the detection module according to the maximum detection flow value of the detection module 3 and the diffusion speed of the air molecules, which are provided in advance, so that the total flow value passing through each air hole 2 is equal to the maximum detection flow value of the detection module 3; the maximum detection flow value of the detection module 3 is divided by the diffusion speed of air molecules to obtain the cross-sectional area of the air entering the detection module 3, namely the total area of the openings, so that the flow of the air entering the detection module through all the air holes 2 is equal to the maximum detection flow value, and the maximum detection flow is the maximum air flow of the parameter of the specific gas in the air which can be normally detected by the detection module 3.

1200. Calculating the pore diameter of each air hole 2 according to the total pore area obtained by calculation; the calculated area of each air hole 2 is equal to the total area of the opening, namely, when air enters the detection module 3 through each air hole 2, the sum of the areas of the air holes 2 is equal to the total area of the opening, the air enters the detection module 3 through the total area of the opening, namely, the flow value of the air entering the detection module is the maximum detection flow value.

1300. And at least one air hole 2 is formed in the position, corresponding to the detection module 3, of the shell 1 according to the calculated hole opening aperture of each air hole 2. One or more air holes 2 are formed, and the processing is convenient because one air hole 2 is formed; set up a plurality of bleeder vents 2 and can disperse the air that gets into the detection module group for air and detection module 3 fully contact, guarantee detection efficiency.

It should be noted that, in step 120, the method specifically includes:

1210. the number of the vent holes 2 is predetermined; the number of the ventilation holes 2 is predetermined and is determined according to the area of the side of the detection module 3 contacting with air.

1220. And calculating the pore diameter of each air hole 2 according to the air permeable area and the number of the air holes 2.

Meanwhile, in this embodiment, the aperture of each vent hole 2 is the same, and step 1220 includes:

1221. dividing the total area of each opening obtained by calculation by the number of the air holes 2, and calculating the opening area of each single air hole 2; the aperture of each air hole 2 is the same, that is, the cross-sectional area of each air hole 2 is the same, and each air hole 2 equally divides the total area of the opening, that is, the opening area of each air hole 2 can be obtained by dividing the total area of the opening by the number of the openings.

1222. And calculating the opening aperture of the single air hole 2 according to the calculated opening area of the single air hole 2. The hole opening aperture of the air holes 2 can be obtained through a circle area calculation formula, and the user can be helped to select a punching tool with a proper size by knowing the hole opening aperture of the air holes 2.

It should be noted that, in the detection module of the present embodiment, the housing 1 includes: casing body 11, be used for installing protection plate 12 on casing body 11, seted up mounting hole 111 on casing body 11, protection plate 12 fixes and realizes the installation on casing body 11 in mounting hole 111.

In the present embodiment, the number of the ventilation holes 2 is 4, but of course, the number of the ventilation holes 2 may be other than 1, and the present embodiment only takes 4 ventilation holes 2 as an example, and is not particularly limited.

Step 1300 specifically includes:

1310. and arranging the air holes 2 at the positions of the protection plate 12 corresponding to the detection module 3 according to the calculated hole diameters of the air holes 2. The air holes 2 are opposite to the detection module 3, so that air can directly contact with the detection module 3 when entering the detection module from the air holes 2, and the detection efficiency of specific gas in the air is improved.

1320. The shielding plate 12 is mounted in the mounting hole 111 of the housing body 11.

Meanwhile, a plurality of detection modules 3 can be packaged in the detection module 3, and according to the steps of the method, the air holes 2 are sequentially formed in the shell 1 at positions corresponding to the detection modules 3, so that the detection modules 3 can work at the maximum efficiency.

A second embodiment of the present invention relates to a method for detecting a hole in a module housing, as shown in fig. 2, 5 and 6, comprising the steps of:

2100. calculating the total opening area of at least one air hole 2 arranged on the shell 1 of the detection module according to the maximum detection flow value of the detection module 3 and the diffusion speed of the air molecules, which are provided in advance, so that the total flow value passing through each air hole 2 is equal to the maximum detection flow value of the detection module 3; the maximum detection flow value of the detection module 3 is divided by the diffusion speed of air molecules to obtain the cross-sectional area of the air entering the detection module 3, namely the total area of the openings, so that the flow of the air entering the detection module through all the air holes 2 is equal to the maximum detection flow value, and the maximum detection flow is the maximum air flow of the parameter of the specific gas in the air which can be normally detected by the detection module 3.

2200. Calculating the pore diameter of the air holes 2 according to the total pore area obtained by calculation; the calculated area of each air hole 2 is equal to the total area of the opening, namely, when air enters the detection module 3 through each air hole 2, the sum of the areas of the air holes 2 is equal to the total area of the opening, the air enters the detection module 3 through the total area of the opening, namely, the flow value of the air entering the detection module is the maximum detection flow value.

2300. According to the calculated hole opening aperture of each air hole 2, one air hole 2 is formed in the position, opposite to the detection module 3, of the shell 1.

It should be noted that, in the detection module of the present embodiment, the housing 1 includes: casing body 11, be used for installing protection plate 12 on casing body 11, seted up mounting hole 111 on casing body 11, protection plate 12 fixes and realizes the installation on casing body 11 in mounting hole 111.

In the present embodiment, the number of the openings of the ventilation holes 2 is 1. Step 2300 specifically comprises:

2310. and arranging the air holes 2 at the positions of the protection plate 12 corresponding to the detection module 3 according to the calculated hole diameters of the air holes 2. The air holes 2 are opposite to the detection module 3, so that air can directly contact with the detection module 3 when entering the detection module from the air holes 2, and the detection efficiency of specific gas in the air is improved.

2320. The shielding plate 12 is mounted in the mounting hole 111 of the housing body 11.

It will be understood by those of ordinary skill in the art that the foregoing embodiments are specific examples for carrying out the invention, and that various changes in form and details may be made therein without departing from the spirit and scope of the invention in practice.