CN218956832U - Water logging sensor module test piece substrate - Google Patents

Abstract

The utility model discloses a water logging sensor module test piece substrate, and mainly relates to a water logging sensor module test piece protection substrate. Comprises a protective shell (1) and a chip seat (2); the protective shell (1) covers the water sensor module test piece (29) from the top; a through hole (3) is formed above the protective shell (1), and the test end of the water immersion sensor test piece protrudes out of the through hole (3); the protective shell (1) is fixed on the chip seat (2). The utility model has the beneficial effects that: the pressure applied by the binding band can be borne, and the pressure can not be applied to the test piece of the immersion sensor module to cause the compression damage or the slight bending damage of the test piece of the immersion sensor module, so that the normal blood seepage information acquisition of the test piece of the immersion sensor module is ensured.

Description

Water logging sensor module test piece substrate

Technical Field

The utility model relates to the field of water logging sensor module test piece protection base materials, in particular to a water logging sensor module test piece base material.

Background

The statements in this section merely provide background information related to the present disclosure and may not necessarily constitute prior art.

After the wound of the wounded is hemostatic and bandaged, if the hemostatic treatment is not good, bleeding can occur, and the hemostatic treatment needs to be carried out again and then the wound needs to be bandaged again. However, in the case of many wounded persons and few medical staff, tens of wounded persons need to be serviced by each medical care. It is not possible to have great effort and time to check the wound treatment of the wounded person. There is a need for a bleeding alarm device for use in a batch of wounded persons for bleeding alarms during medical treatment. In links such as on-site first aid, early treatment and post-delivery of wounded, the contradiction between the pressure of the batch wounded treatment and the relative lack of sanitary resources is alleviated, the treatment efficiency is improved, and the number of the casualties is reduced.

The wound is stained with red on the binding band auxiliary material after the blood seepage, and along with the continuous blood seepage, the stained red area of the binding band auxiliary material can be increased, and the greater the blood seepage speed is, the faster the stained red area can be increased. If the blood permeation alarm device is required to be designed, detection and alarm are required to be carried out from the blood permeation area and the blood permeation rate. The cost for monitoring the blood permeation area and the blood permeation rate by adopting a visual sensor such as a camera is high, factors such as the fixation of the camera and the volume of the whole alarm device can be considered and designed, and the two factors are difficult problems. And monitoring of the blood permeation rate by visual sensors has not been achieved by simple techniques. Therefore, the technical scheme of blood permeation alarming by devices similar to visual sensors and the like is difficult to realize, and therefore, the technical scheme is abandoned.

A solution that is different from the visual sensor, is low-cost, simple in construction, and well-suited is needed. The water immersion sensor is a sensor capable of detecting the wetting of water or blood, can well reflect the blood leakage or not, and can give an alarm for blood leakage by using the water immersion sensor technology, so that the alarm information is more accurate. But also can observe the blood permeation state and the blood permeation rate, and is better applied to the war time requirement. Accordingly, a blood permeation alarm device as shown in fig. 5 and 8 of the accompanying drawings of the specification is developed, which comprises a placement yarn, a water immersion sensor module and a signal arrangement module; the specification arrangement is equipped with a plurality of equal area's sensor and places the district on placing the subsides yarn, places the subsides yarn setting on a ventilative subsides cloth. The breathable patch provided with the placement patch is bound to the bleeding wound through binding band auxiliary materials. Each sensor placing area is internally provided with a water logging sensor module, the placing paste yarn is thinner and has good blood seepage and water seepage characteristics, and the placing paste yarn is mainly used for placing the water logging sensor module on the ventilation paste cloth, and the water logging sensor module is in signal transmission connection with the signal arrangement module; the water logging sensor module detects the blood seepage signal and then transmits the blood seepage signal to the signal arrangement module, and the signal arrangement module carries out signal processing.

The signal arrangement module comprises a blood permeation recording module, a reset button, a blood permeation time recording module and a positioning module; wherein the blood seepage recording module comprises a blood seepage area calculating module; the blood seepage area calculation module obtains the blood seepage area according to the number of the water logging sensor modules which are detected by calculation, the area of each sensor placement area is set to be an expansion value of a unit, and the blood seepage area is reflected by the number of the expansion values; the blood seepage recording module further comprises a blood seepage coordinate recording module; a coordinate system is formed by a plurality of sensor placement areas with equal areas, each sensor placement area is used as a coordinate point, and a water immersion sensor module for detecting water immersion signals performs coordinate recording through a blood permeation coordinate recording module; the coordinate position of the water immersion sensor module for detecting the water immersion signal is obtained, so that a blood seepage area can be obtained, and all the blood seepage areas are integrated to form a blood seepage area position image; and calculating the blood seepage area. The zeroing reset button is used for zeroing the original area of the bound blood immediately after the binding is finished, and the blood permeation time recording module records the time point of each water immersion sensor module detecting the water immersion signal and the time period timing after the zeroing reset button zeroing. After the binding is finished, a nursing staff presses a reset button for zeroing, so that the area of an original sensor placement area for binding blood seepage immediately after the binding is finished is zeroed; the water immersion sensor module in the sensor placement area without blood leakage monitors whether water immersion signals exist in real time, if the water immersion signals are expressed as newly added blood leakage areas, the coordinates of each newly added blood leakage area and the number of the diffusion values after superposition of all the newly added blood leakage areas are recorded through the blood leakage area calculation module; and the bleeding time recording module records the time point of each water immersion sensor module detecting the water immersion signal in real time and counts the time period after the zero-resetting treatment of the zero-resetting button. The signal arrangement module is used for obtaining the blood permeation speed value in unit time, namely the blood permeation area expansion rate, through extracting the data of the blood permeation value of the blood permeation area calculation module and the time data of the blood permeation time recording module; when the blood seepage area expansion rate is calculated to reach an alarm value or when the data of the blood seepage expansion value reaches the alarm value, the signal transmitting module transmits a blood seepage information signal to the signal receiving module, and the blood seepage alarm module alarms. Audio and light source alarms can expose the wounded location, increasing the risk. The conception mode is a vibration mode, and the positioning module is used for rapidly positioning the position of the patient with blood seepage, so that the position of the wounded can be rapidly positioned by a hygienist in the mass transfer process.

In the use, place the ventilative subsides cloth of water logging sensor module and wrap to ooze blood wound department through wrapping the bandage auxiliary material, wrap the bandage auxiliary material and wrap very tightly, receive the pressure influence of wrapping the bandage auxiliary material and make local or individual water logging sensor module pressurized damage easily, if use when oozing blood wound department at four limbs moreover, place the ventilative subsides cloth of water logging sensor module and wrap into an arc that suits with four limbs, more easily make water logging sensor module test piece take place slight bending pressurized damage. There is a need for a protective substrate that protects a water sensor module test strip from compression.

The foregoing is a brief description of a blood permeation alarm device, and will be described in detail in the detailed description of the utility model when the water immersion sensor module test piece base material of the present utility model is specifically used.

Disclosure of Invention

The utility model aims to provide a water immersion sensor module test piece substrate which can bear the pressure brought by a binding band, and the pressure can not be applied to the immersion sensor module test piece to cause compression damage or slight bending damage of the compression, so that the normal blood seepage information acquisition of the immersion sensor module test piece is ensured.

The utility model aims to achieve the aim, and the aim is achieved by the following technical scheme:

the water immersion sensor module tests a test piece substrate, and comprises a protective shell and a chip seat; the shape and the size of the protective casing are adapted to those of the water sensor module test piece, the protective casing covers the water sensor module test piece from the top, and the water sensor module test piece cannot loosen in the protective casing. And be equipped with the through-hole above protective housing, the test end of water logging sensor test piece stretches out from the through-hole to guarantee that the test end that stretches out can normally acquire the ooze blood signal. The protective casing is fixed on the chip seat, and the water logging sensor module test piece wraps up the protection through protective casing and chip seat.

The mounting and fixing modes of the protective shell and the chip seat are as follows: the side part of the protective shell is provided with an elastic sheet, and the side edge of the notch of the chip seat is provided with a limit groove; the elastic sheet is arranged in the limiting groove and is limited and fixed. For more stable protection: the lowest part of the elastic sheet is provided with a clamping foot, and the bottom of the limiting groove is provided with a clamping groove; after the elastic sheet slides down to the lowest end along the limiting groove, the clamping foot is sprung into the clamping groove to limit.

The side wall of the protective shell is provided with a first dismounting groove, and the chip seat is provided with a second dismounting groove corresponding to the first dismounting groove; a prying slot is formed between the first dismounting groove and the second dismounting groove after the protective shell is stably arranged on the chip seat. The tool is inserted into the prying slot to conveniently detach the protective shell from the chip seat.

And the chip seat is provided with a wiring hole, and a signal wire connected with the water logging sensor module test piece passes through the wiring hole.

Compared with the prior art, the utility model has the beneficial effects that:

the protective housing and the chip seat wrap up the water logging sensor module test piece, place the ventilative subsides cloth of water logging sensor module test piece and receive the binder auxiliary material to wrap up very tight pressure, make protective housing and chip seat can bear the pressure that the binder brought to make this pressure can not exert and cause its pressurized damage or pressurized slight crooked damage to the water logging sensor module test piece, and water logging sensor's test end stretches out from the through-hole of protective housing top moreover, can not influence the normal use of water logging sensor module test piece, guarantee the normal blood leakage information acquisition of water logging sensor module test piece.

Drawings

FIG. 1 is a schematic three-dimensional structure of the present utility model.

Fig. 2 is a schematic three-dimensional structure and a partial enlarged view of a chip carrier according to the present utility model.

Fig. 3 is a state diagram of the present utility model after the protective housing and the chip carrier are mounted.

FIG. 4 is a schematic view of the structure of the water sensor module test piece covered by the protective housing in the present utility model.

FIG. 5 is a graph of the blood permeation alarm device of the present utility model.

FIG. 6 is a graph of the diffusion values of the blood permeation coordinates of FIG. 5 over a period of time for permeation in accordance with the present utility model.

FIG. 7 is a graphical representation of the calibration of the blood permeation time paths of the present utility model for each of the blood permeation coordinate positions of FIG. 6 over a blood permeation time period.

Fig. 8 is a schematic structural block diagram of the present utility model.

Fig. 9 is an illustration of the bleed area of different levels of the band at the bleed wound.

FIG. 10 is a cross-sectional view and partial enlarged view of the view of FIG. 5 a in accordance with the present utility model.

The reference numbers shown in the drawings:

1. a protective housing; 2. a chip holder; 3. a through hole; 4. a spring plate; 5. a limit groove; 6. a clamping foot; 7. a clamping groove; 8. a first dismounting groove; 9. a second dismounting groove; 10. prying open the slit; 11. a wiring hole; 12. placing a paste yarn; 13. a signal arrangement module; 14. a signal acquisition module; 15. a sensor placement area; 16. breathable sticking cloth; 17. binding up the binding band; 18. a thin gauze; 19. a sponge layer; 20. a groove; 21. a bleeding recording module; 22. a reset button for return to zero; 23. a bleeding time recording module; 24. a positioning module; 25. a blood seepage area calculation module; 26. a signal transmitting module; 27. a signal receiving module; 28. a blood seepage alarm module; 29. a water immersion sensor module test piece; 30. and a bleeding coordinate recording module.

Detailed Description

The utility model will be further illustrated with reference to specific examples. It is to be understood that these examples are illustrative of the present utility model and are not intended to limit the scope of the present utility model. Further, it will be understood that various changes or modifications may be made by those skilled in the art after reading the teachings of the utility model, and such equivalents are intended to fall within the scope of the utility model as defined herein.

The utility model relates to a water immersion sensor module test piece substrate, as shown in figure 1 of the specification attached hereto, a main body structure comprises a protective shell 1 and a chip seat 2; the shape and size of the protective case 1 are adapted to the shape of the water sensor module test piece 29, which is set to be square in the present embodiment, because the water sensor module test piece 29 of the blood permeation alarming device is square, but the shape is not limited, and if the test piece is shaped to be other, the protective case 1 and the chip carrier 2 are also adapted to be changed to be other shapes.

As shown in fig. 4 of the drawings, the protective casing 1 covers the water sensor module test piece 29 from the top, and the water sensor module test piece 29 is not loosened within the protective casing 1. And be equipped with through-hole 3 in protective housing 1 top, the test end of water logging sensor test piece stretches out from through-hole 3 to guarantee that the test end that stretches out can normally acquire the ooze blood signal. The protective casing 1 is fixed on the chip carrier 2, and the water immersion sensor module test piece 29 is wrapped and protected by the protective casing 1 and the chip carrier 2.

As shown in fig. 1 of the drawings, the mounting and fixing modes of the protective housing 1 and the chip seat 2 are as follows: the side part of the protective shell 1 is provided with an elastic sheet 4, the elastic sheet 4 has elastic deformation capacity of being pressed, bent and deformed, and the side edge of the notch of the chip seat 2 is provided with a limit groove 5; the elastic sheet 4 is pressed by the pressure of the side wall of the limit groove 5 in the limit groove 5 to elastically deform, and the protective shell 1 is stably arranged in the limit groove 5 to be limited and fixed under the action of deformation elasticity.

Furthermore, for more stable protection: the lowest part of the elastic sheet 4 is provided with a clamping foot 6, as shown in figure 2 of the specification attached drawings, and the bottom of the limit groove 5 is provided with a clamping groove 7; after the elastic sheet 4 slides downwards to the lowest end along the limiting groove 5, the clamping pin 6 is sprung into the clamping groove 7 for limiting, so that the protective shell 1 is stably arranged in the limiting groove 5 for limiting and fixing.

As shown in fig. 3 of the specification and the drawings, a first dismounting groove 8 is formed in the side wall of the protective shell 1, and a second dismounting groove 9 corresponding to the first dismounting groove 8 is formed in the chip seat 2; after the protective shell 1 is stably installed on the chip seat 2, a prying seam 10 is formed between the first dismounting groove 8 and the second dismounting groove 9. The tool is inserted into the prying slot 10 to conveniently detach the protective casing 1 from the chip seat 2, so that the broken water sensor module test piece 29 can be conveniently replaced.

Finally, the chip holder 2 is provided with a wiring hole 11, and a signal wire connected with the water sensor module test piece 29 passes through the wiring hole 11.

The using method comprises the following steps:

the protective casing 1 and the chip seat 2 wrap the water immersion sensor module test piece 29, the ventilation patch 16 for placing the water immersion sensor module test piece 29 is subjected to the tight pressure of the binding band 17 auxiliary materials binding, so that the protective casing 1 and the chip seat 2 can bear the pressure brought by the binding band 17, the pressure can not be applied to the water immersion sensor module test piece to cause the pressure damage or the slight bending damage of the pressure, and the test end of the water immersion sensor protrudes out of the through hole 3 above the protective casing 1, so that the normal use of the water immersion sensor module test piece 29 is not influenced, and the normal blood seepage information acquisition of the water immersion sensor module test piece is ensured.

The blood seepage alarm device for the technical background is attached as follows:

as shown in fig. 5 and 10 of the drawings of the specification, the blood seepage alarm device comprises a placement yarn 12, a water immersion sensor module and a signal arrangement module 13; the plurality of water logging sensor modules form a signal acquisition module 14, a plurality of sensor placement areas 15 with equal areas are arranged on the placement patch 12 in a specification arrangement mode, each sensor placement area 15 is a square area, the water logging sensor module test piece base material is arranged in the sensor placement area 15, and all square areas form a whole blood seepage monitoring area. The placement patch 12 is disposed on a ventilation patch 16, the water immersion sensor module is a test chip, i.e. a water immersion sensor module test piece 29, the ventilation patch 16 is used as a base material for placing a base material of the water immersion sensor module test piece, and the placement patch 12 is attached to the surface of the water immersion sensor module test piece 29.

The plurality of water sensor module test pieces 29 are arranged on the surface of the breathable adhesive cloth 16 in an array manner, one water sensor module test piece 29 is arranged in each sensor placing area 15, the array arrangement ensures the regular arrangement of the plurality of water sensor module test pieces 29, the regular arrangement can be used as the basis for coordinate calibration of each water sensor module test piece 29, the water sensor module test pieces 29 are arranged in a rectangular array manner, and the arrangement manner is visual and not easy to mix as shown in the figure 5 of the specification.

The breathable patch 16 provided with the placement patch 12 is wrapped at the blood-permeable wound by a wrapping strap 17, and 1-2 layers of straps are arranged between the breathable patch 16 and the blood-permeable wound, so that 1-2 layers of straps are arranged in front of the water-immersed sensor module and the blood-permeable wound, and the water-immersed sensor module can be permeated only by the blood after the blood-permeable patch is permeated by the 1-2 layers of straps and the placement patch 12 is thinner, so that the purpose of using the breathable patch is as follows: the wound which is just hemostatic and wrapped is still slightly permeated, the 1-2 layers of binding belts are used for absorbing a small amount of blood, if the blood permeation is not serious, only a small amount of blood which is permeated into the 1-2 layers of binding belts is sensed by the water immersion sensor modules so as not to meet the alarm requirement, if the blood permeation alarm device is directly contacted with a blood permeation wound, the plurality of water immersion sensor modules are soaked by the blood which is just permeated, the number of the original diffusion water permeation sensor modules before zero clearing is increased, and the blood permeation alarm area of the blood permeation alarm device after zero clearing is reduced. More clearly, as shown in fig. 9 of the drawings of the specification, because the smaller the area of the seepage wetting area of one layer of the binding belt is, the larger the area of the seepage wetting area of one layer of the binding belt is, namely the smaller the area of the seepage wetting area of the binding belt from the first layer of binding belt to the third layer of binding belt is, in order to reduce the test area of the seepage alarm device and the number of used water sensor modules, the manufacturing cost is reduced, and the seepage alarm device is placed between the first layer of binding belt and the second layer of binding belt or between the second layer of binding belt and the third layer of binding belt when in use.

The water logging sensor modules are connected with the signal arrangement module 13 in a signal transmission mode, the water logging sensor modules detect blood seepage signals and then transmit the blood seepage signals to the signal arrangement module 13, and the signal arrangement module 13 performs signal processing.

As shown in figure 9 of the drawings in the specification, the breathable sticking cloth 16 is divided into three layers, namely a thin gauze 18, a sponge layer 19 and a thin gauze 18; the gauze 18 on both sides is used for wrapping the sponge layer 19, and the sponge layer 19 is soft and has certain thickness, is used for the wiring of signal line, i.e. the signal line that water logging sensor module test piece 29 and oozes blood alarm device and is connected is hidden to locate the sponge layer 19. The sponge layer 19 is provided with a groove 20 which is matched with the substrate of the water immersion sensor module test piece in an array manner; the water sensor module test strip substrate is positioned in the recess 20 so that the water sensor module test strip substrate is positioned so as not to move irregularly.

The signal arrangement module 13 comprises a blood permeation recording module 21, a return-to-zero reset button 22, a blood permeation time recording module 23 and a positioning module 24;

wherein the blood permeation recording module 21 comprises a blood permeation area calculation module 25; the blood permeation area calculation module 25 obtains the blood permeation area according to the number of the water immersion sensor modules with the water immersion signals detected, the area of each sensor placement area 15 is set to be an expansion value of one unit, and the blood permeation area is reflected by the number of the expansion values, as shown in figure 5 of the specification; the blood seepage recording module 21 further comprises a blood seepage coordinate recording module 30, a coordinate system is formed by a plurality of sensor placement areas 15 with equal areas, each sensor placement area 15 is used as a coordinate point, and the coordinate recording is carried out by the water immersion sensor module which detects water immersion signals through the blood seepage coordinate recording module 30, as shown in figure 5 of the specification; the coordinate position of the water immersion sensor module for detecting the water immersion signal is obtained, so that a blood seepage area can be obtained, and all the blood seepage areas are integrated to form a blood seepage area position image; and calculating the blood seepage area.

The zeroing reset button 22 is used for zeroing the original area of the bandaged blood after the bandaging is completed, as shown in fig. 6 of the specification, the diffusion values of the k4, k5, k6, L5 and L6 coordinate positions are zeroed, and the diffusion values are the original diffusion values. The bleeding time recording module 23 records the time point when each water immersion sensor module detects the water immersion signal (as shown in fig. 6 of the specification, the soaking time point is recorded after each diffusion coordinate after zeroing is soaked), and the time period after zeroing of the zeroing reset button 22 is counted (as shown in fig. 6 of the specification, the diffusion value is counted cumulatively in each unit time period or total time period after zeroing). After the binding is finished, a nursing staff presses a reset button 22 for resetting the area of the original sensor placement area 15 for binding blood seepage immediately after the binding is finished; the water immersion sensor module in the sensor placement area 15 without blood leakage monitors whether water immersion signals exist in real time, if the water immersion signals are expressed as newly added blood leakage areas, the coordinates of each newly added blood leakage area and the number of the diffusion values after superposition of all the newly added blood leakage areas are recorded through the blood leakage area calculation module 25; and the bleeding time recording module 23 records in real time the point in time when each of the water logging sensor modules detects the water logging signal and the time period timer from the zero-resetting process of the zero-resetting button 22. The signal arrangement module 13 extracts the diffusion value data of the blood diffusion area calculation module 25 and the time data of the blood diffusion time recording module 23 so as to calculate and obtain the blood diffusion speed value in unit time, namely the diffusion rate of the blood diffusion area; when the blood permeation area expansion rate calculation reaches an alarm value or when the data of the blood permeation expansion value reaches the alarm value, the signal transmitting module 26 transmits a blood permeation information signal to the signal receiving module 27, and the blood permeation alarm module 28 alarms. And a blood permeation sequence path diagram (shown in figure 7 of the specification) and a blood permeation sequence simulation diagram (namely a diagram in which all blood permeation coordinate points are lightened on a display coordinate one by one according to a time sequence) can be formed according to the blood permeation time sequence of each coordinate position, so that the blood permeation process in the whole blood permeation time period can be intuitively seen, and the analysis of nursing staff is facilitated.

The information of the patient with the blood permeation alarm is displayed on a display screen arranged on the blood permeation alarm, and the blood permeation coordinates recorded by the blood permeation coordinate recording module 30 are displayed in a coordinate system image on the display screen (as shown in the figure 5 coordinate diagram of the attached drawing); the display screen is also used for displaying blood seepage area calculation and result display, blood seepage area expansion rate calculation and result display, and each blood seepage coordinate is used for displaying a blood seepage time point; positioning module 24 is used for positioning the position of the patient where blood seepage occurs; the display screen also displays the position location and navigation of the patient suffering from blood seepage. The display screen is provided with a switch key and an information switching key; different information is displayed on the display screen by controlling the information switching keys.

The signal arrangement module 13 extracts the diffusion value data of the blood diffusion area calculation module 25 and the time data of the blood diffusion time recording module 23 so as to calculate and obtain the blood diffusion speed value in unit time, namely the diffusion rate of the blood diffusion area;

the blood permeation area expansion rate includes total blood permeation rate S and total blood permeation rate ST in the interval, as shown in the table of figure 6 of the attached drawing:

total blood permeation rate stotal=25/(t1+t2+t3+t4+t5+t6+t7+t8);

interval blood permeation rate ST:

ST1＝5/T1；ST2＝4/T2；ST3＝4/T3；ST4＝3/T4；ST5＝4/T5；ST6＝2/T6；ST7＝2/T7；

ST18＝1/T8；

when the blood permeation area expansion rate calculation reaches the alarm value (the total blood permeation rate S reaches the alarm value, or the interval blood permeation rate ST reaches the alarm value), the signal transmitting module 26 transmits a blood permeation information signal to the signal receiving module 27, and the blood permeation alarm module 28 alarms. Through the dual alarm mode, thereby safer, wherein one alarm mode can also report to the police after the inefficacy another alarm mode.

Or when the total of the diffusion value data reaches the alarm value (in fig. 6 of the specification, the total of the diffusion value reaches 25, if the alarm value is 50, the alarm is also given after the total of the diffusion value reaches 50, but the diffusion speed is slow, but the diffusion is still in the blood), the signal transmitting module 26 transmits the diffusion information signal to the signal receiving module 27, and the diffusion alarm module 28 gives an alarm.

The information of the blood permeation alarm patient is displayed on the display screen, a blood permeation sequence route diagram (shown as figure 7 of the specification) and a blood permeation sequence simulation diagram (namely, the diagrams of all blood permeation coordinate points which are lighted on the display coordinates one by one in a screen according to the time sequence are sequentially formed according to the blood permeation time of each coordinate position, namely, the diagrams of j4, L4, m5, m6, k7, j5, j6, i6, j7, i5, i4, h4, L7, h5, k3, j3, i3, L3, m4, m7, n6, g4, g5 and n7 in the display coordinates are sequentially lighted one by one, so that the blood permeation process in the whole blood permeation time period can be intuitively seen, and the analysis of nursing staff is facilitated.

Claims (5)

1. The water logging sensor module test piece substrate, its characterized in that: comprises a protective shell (1) and a chip seat (2); the protective shell (1) covers the water sensor module test piece (29) from the top;

a through hole (3) is formed above the protective shell (1), and the test end of the water immersion sensor module test piece protrudes out of the through hole (3);

the protective shell (1) is fixed on the chip seat (2).

2. The water sensor module test strip substrate of claim 1, wherein: the side of the protective shell (1) is provided with an elastic sheet (4), and the side of the notch of the chip seat (2) is provided with a limit groove (5);

the elastic sheet (4) is arranged in the limiting groove (5) in a limiting and fixing mode.

3. The water sensor module test strip substrate of claim 2, wherein: the lowest part of the elastic sheet (4) is provided with a clamping foot (6), and the bottom of the limit groove (5) is provided with a clamping groove (7);

after the elastic sheet (4) slides down to the lowest end along the limiting groove (5), the clamping pin (6) is sprung into the clamping groove (7) to limit.

4. The water sensor module test strip substrate of claim 3, wherein: the side wall of the protective shell (1) is provided with a first dismounting groove (8), and the chip seat (2) is provided with a second dismounting groove (9) corresponding to the first dismounting groove (8);

a prying seam (10) is formed between the first dismounting groove (8) and the second dismounting groove (9) after the protective shell (1) is stably arranged on the chip seat (2).

5. The water sensor module test strip substrate of claim 1, wherein: and the chip seat (2) is provided with a wiring hole (11).

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