CN211856443U - Electrochemical hydrogen sulfide sensor - Google Patents

Abstract

The utility model discloses an electrochemistry hydrogen sulfide sensor, including having the casing that can dismantle the top cap, set up the inlet port that the gas feed body got into on the top cap of casing, the bottom of casing has the reservoir, the reservoir top is equipped with the backup pad that covers above that, the backup pad has porous structure, stack gradually by inlet port to reservoir direction in the casing and be equipped with working electrode, reference electrode and counter electrode, the storage has electrolyte in the reservoir, be equipped with imbibition material three in the reservoir, imbibition material three is the structure of reel form, be equipped with imbibition material one between working electrode and the reference electrode, be equipped with imbibition material two between reference electrode and the counter electrode, the bottom of casing is equipped with respectively with working electrode, the pin of reference electrode and counter electrode connection, be equipped with O type circle between working electrode and the casing top. The sensor is not interfered by impurity gas, has good selectivity, and has simple structure, small manufacturing difficulty and low cost.

Description

Electrochemical hydrogen sulfide sensor

Technical Field

The utility model relates to an electrochemistry hydrogen sulfide sensor belongs to electrochemistry sensor technical field.

Background

Hydrogen sulfide (chemical formula H)₂S) is a colorless and toxic gas with the odor of smelly eggs, and high-concentration hydrogen sulfide often exists in the closed environment of factories, oil fields and sewers, so that the survival and health of people are seriously threatened, and the hydrogen sulfide gas needs to be strictly monitored. There are various sensors for detecting hydrogen sulfide, such as an electrochemical type, a semiconductor type, a catalytic combustion type, an optical fiber type, and the like. Among them, the electrochemical hydrogen sulfide sensor has become a mainstream sensor for detecting hydrogen sulfide gas due to its fast response time, high sensitivity, stable output signal, good reproducibility, no need of heating, low power consumption and good linearity, and is widely applied to related monitoring device equipment, and mainly used for detecting parts per million (ppm) concentration level hydrogen sulfide gas.

In the environment where hydrogen sulfide sensors monitor usage, other interfering gases, such as carbon monoxide (CO), hydrogen (H) are often present₂) Sulfur dioxide (SO)₂) Nitrogen monoxide (NO), nitrogen dioxide (NO)₂) Chlorine (Cl)₂) Ammonia (NH)₃) Hydrogen Cyanide (HCN), vinyl chloride and the like, which can react at the working electrode of the electrochemical hydrogen sulfide sensor, so that the instrument generates false alarm or delays alarm, and seriously threatens the life safety of people.

To reduce false alarms or delay alarm situations, the following 4 technical approaches are generally taken to enhance the selectivity of electrochemical gas sensors:

1. the use of a suitable working electrode catalyst, but catalyst materials generally respond to a certain class of gaseous species, has limitations in this approach;

2. a physical or chemical filter is placed inside the sensor to filter interfering gases. When the physical filter is fully adsorbed or the chemical filter is completely reacted, the filter is invalid, and the selection range of the filter is limited, so that the method has certain limitation;

3. an intermediate electrolyte system is selected in which the relevant components of the electrolyte react only with the target gas, thereby increasing the selectivity of the sensor. However, the method is generally complex, and the electrolyte has capacity limitation and belongs to a consumable electrolyte, so that the effective service life of the sensor is limited;

4. and selecting the potential of the sensor. The activation energy of the electrochemical reaction is mainly influenced by the electric field strength at the 'electrode/solution' interface, the optimal reaction potentials of different gases are different, and the selection of the potential can improve the selectivity of the sensor. Typically, a sensor will also respond to a certain class of gaseous species at a certain potential.

In addition, the sensor electrode generally adopts a noble metal catalyst, and the noble metal is expensive and has limited reserves. On the other hand, the production process of the sensor electrode is complicated, including catalyst preparation, slurry mixing, film coating, sintering and the like, the electrochemical hydrogen sulfide sensor comprises 3 electrode plates including a working electrode, a reference electrode and a counter electrode, each electrode plate is manufactured according to the process flow, corner waste materials exist in the electrode plate manufacturing process, and a large amount of labor and financial resources are consumed. Therefore, in order to reduce the manufacturing cost of the sensor, a new technique for reducing the amount of noble metal used must be sought in every aspect.

Therefore, there is a need for a CO, H resistant₂、SO₂、NO、NO₂And the electrochemical hydrogen sulfide sensor has low manufacturing cost and small difficulty due to the interference of various gases.

Disclosure of Invention

For overcoming the not enough of prior art, the utility model provides an electrochemistry hydrogen sulfide sensor, it does not receive gaseous interference of impurity, has good selectivity to simple structure, the manufacturing degree of difficulty are little, with low costs.

In order to realize the above-mentioned purpose, the utility model discloses an electrochemistry hydrogen sulfide sensor, including having the casing that can dismantle the top cap, set up the inlet port that the gas got into on the top cap of casing, the bottom of casing has the reservoir, the reservoir top is equipped with the backup pad that covers above that, the backup pad has porous structure, it is equipped with working electrode to stack gradually by inlet port to reservoir direction in the casing, reference electrode and counter electrode, store electrolyte in the reservoir, be equipped with imbibition material three in the reservoir, imbibition material three is the structure of reel form, be equipped with imbibition material one between working electrode and the reference electrode, be equipped with imbibition material two between reference electrode and the counter electrode, the bottom of casing be equipped with respectively with working electrode, reference electrode and counter electrode connected's pin, be equipped with O type circle between working electrode and the.

Furthermore, the shell is of a hollow cylindrical structure, the working electrode is of a disc-shaped structure, the counter electrode is of a circular ring-shaped structure with the outer diameter being the same as the diameter of the working electrode, and the reference electrode is of a disc-shaped structure with the diameter being the same as the inner diameter of the counter electrode.

Further, the working electrode, the reference electrode and the counter electrode are gas diffusion electrodes made of the same material, and the working electrode, the reference electrode and the counter electrode are made of the same batch.

Further, the reference electrode and the counter electrode are a disk and a ring formed by cutting out the same disk-shaped electrode in a concentric manner.

Further, the gas diffusion electrode comprises a diffusion layer and a catalytic layer coated thereon, the diffusion layer is a porous polymer membrane, and the catalytic layer comprises a catalyst material and a binder mixture coated on the diffusion layer.

Furthermore, the catalyst material adopts one or a plurality of random combinations of platinum, ruthenium, iridium, gold, rhodium and palladium, and the binder adopts polytetrafluoroethylene emulsion.

Further, the catalyst material adopts a platinum-ruthenium black catalyst, and the molar ratio of platinum to ruthenium in the platinum-ruthenium black catalyst is 1:1-1: 3.

Further, the catalyst material adopts a carbon-supported/blended platinum-ruthenium black catalyst, and the platinum-ruthenium black loading/blending amount in the carbon-supported/blended platinum-ruthenium black catalyst is 5-40%.

Further, the electrolyte is a sulfuric acid solution with the concentration of 3M-12M.

The utility model also provides a preparation method of electrochemistry hydrogen sulfide sensor, including following step:

s1: adding catalyst material into activated carbon powder, uniformly mixing, adding a binder, and magnetically stirring for 40-60 h to prepare electrode slurry;

s2: coating the electrode slurry on the diffusion layer by using a silk screen, spraying, dripping or scraper, and drying at 55-65 ℃ for 24h to obtain an electrode;

s3: punching two disk-shaped electrodes by using a punch, wherein one disk-shaped electrode is used as a working electrode, the other disk-shaped electrode is used for cutting a small disk-shaped electrode from the center position of the other disk-shaped electrode by using the punch as a reference electrode, and the cut concentric circular ring-shaped electrode is used as a counter electrode;

s4: assembling, namely filling a liquid storage tank with a liquid absorption material III, installing a supporting plate, sequentially filling a counter electrode, a liquid absorption material II, a reference electrode, a liquid absorption material I and a working electrode into the shell, injecting electrolyte, filling an O-shaped ring, and sealing the shell by using a top cover to finish assembling;

s5: the sensitivity and immunity of the sensor are tested.

The utility model discloses an electrochemistry hydrogen sulfide sensor does not receive gaseous interference of impurity, has good selectivity to simple structure, the manufacturing degree of difficulty is little, with low costs.

Drawings

The invention will be further described and illustrated with reference to the accompanying drawings.

Fig. 1 is a cross-sectional view of an electrochemical hydrogen sulfide sensor according to a preferred embodiment of the present invention.

Reference numerals: 1. a housing; 2. a working electrode; 3. a reference electrode; 4. a counter electrode; 5. liquid absorbing material I; 6. Liquid absorption material II; 7. liquid absorption material III; 8. a support plate; 9. an air inlet; 10. a liquid storage tank; 11. a pin; 12. And an O-shaped ring.

Detailed Description

The technical solution of the present invention will be more clearly and completely explained by the description of the preferred embodiments of the present invention with reference to the accompanying drawings.

As shown in fig. 1, the electrochemical hydrogen sulfide sensor according to the preferred embodiment of the present invention includes a housing 1 having a detachable top cover, the housing 1 is a hollow cylinder structure, the housing 1 can be a standard component, such as a 4-series electrochemical gas sensor, and the inner diameter of the housing is 20 mm. The housing 1 is selected from engineering plastic materials inert to the target gases and electrolytes and may be formed from materials including, but not limited to, ABS, PE, PPO, PP, or any combination or blend thereof, with ABS plastic being used in this embodiment.

As shown in fig. 1, an air inlet 9 for air to enter is formed on the top cover of the housing 1, the aperture of the air inlet 9 is determined by the measurement sensitivity of the electrochemical hydrogen sulfide sensor, the aperture of the air inlet 9 may be 1mm to 6mm, preferably 2mm to 3mm, and the aperture of the air inlet 9 in this embodiment is 3 mm.

As shown in fig. 1, the bottom of the housing 1 has a reservoir 10, and the reservoir 10 stores therein an electrolyte, which may be any conventional aqueous acidic electrolyte, such as sulfuric acid, phosphoric acid, or neutral ion solution or any combination thereof, preferably a sulfuric acid solution with a concentration of 3M to 12M, and in this embodiment, a 9M sulfuric acid solution is used.

As shown in fig. 1, a supporting plate 8 is disposed on the top of the liquid storage tank 10 to cover the liquid storage tank, and a working electrode 2, a reference electrode 3 and a counter electrode 4 are sequentially stacked in the housing 1 from an air inlet 9 to the liquid storage tank 10. The support plate 8 has a porous structure, and the porous support plate 8 can facilitate the movement of the electrolyte in the housing 1, so that the electrolyte can contact the working electrode 2, the reference electrode 3 and the counter electrode 4, thereby providing sufficient electrolyte for the gas-generating electrochemical reaction. In consideration of cost, the support plate 8 is made of the same material as the shell 1 and is molded by die sinking together with the shell 1, and the support plate 8 provides support for the working electrode 2, the reference electrode 3 and the counter electrode 4, so that the internal stress of the sensor is consistent.

As shown in fig. 1, the bottom of the case 1 is provided with 3 pins 11 connected to the working electrode 2, the reference electrode 3 and the counter electrode 4, respectively, for communication with an external circuit, thereby outputting a sensor signal to the external circuit.

As shown in fig. 1, a first liquid absorbing material 5 is provided between the working electrode 2 and the reference electrode 3, a second liquid absorbing material 6 is provided between the reference electrode 3 and the counter electrode 4, a third liquid absorbing material 7 is provided in the reservoir 10, the third liquid absorbing material 7 is in a roll structure, and the first liquid absorbing material 5, the second liquid absorbing material 6 and the third liquid absorbing material 7 are made of glass fiber cotton or viscose non-woven fabric, and may be any suitable material known in the art. The first liquid absorption material 5 and the second liquid absorption material 6 can effectively avoid short circuit caused by physical contact among the working electrode 2, the reference electrode 3 and the counter electrode 4, and have strong liquid absorption capacity, so that sufficient electrolyte is provided for electrochemical reaction, and the liquid absorption material is also used as an electrolyte retaining layer, and the service life of the sensor can be effectively prolonged. The third liquid absorbing material 7 in the liquid storage tank 10 can limit the mobility of the electrolyte, so that the leakage of the electrolyte is avoided to a certain extent, and the use and the transportation of the sensor are facilitated. In addition, the electrochemical hydrogen sulfide sensor generally uses an acidic electrolyte, such as 9M sulfuric acid in the present embodiment, and in a high humidity environment, the electrolyte absorbs water from the environment and causes a volume increase, easily causing electrolyte leakage. And a liquid absorbing material III 7 is placed in the liquid storage tank 10, and when the environmental humidity is high, the liquid absorbing material III 7 can absorb excessive moisture and store the moisture in the liquid storage tank 10, so that the electrolyte cannot leak out of the sensor due to pressure formed by moisture absorption.

As shown in fig. 1, an O-ring 12 is provided between the working electrode 2 and the top cover of the housing 1. The O-ring 12 serves two functions: on one hand, the O-shaped ring 12 provides environmental sealing for the internal electrode of the electrochemical hydrogen sulfide sensor; on the other hand, when pressure exists, the O-shaped ring 12 deforms to provide buffering protection for internal elements of the electrochemical hydrogen sulfide sensor.

As shown in fig. 1, the working electrode 2 has a disk-like structure, the counter electrode 4 has an annular structure having an outer diameter equal to the diameter of the working electrode 2, and the reference electrode 3 has a disk-like structure having a diameter equal to the inner diameter of the counter electrode 4. The working electrode 2, the reference electrode 3 and the counter electrode 4 are gas diffusion electrodes made of the same material, and the working electrode 2, the reference electrode 3 and the counter electrode 4 are made of the same batch, so that the difference among the electrodes can be reduced, and the stability of the sensor is improved. In order to reduce the manufacturing cost, the reference electrode 3 and the counter electrode 4 are a disk and a ring formed by cutting out the same disk-shaped electrode in a concentric manner. The working electrode 2 in this example is 18mm in diameter, the reference electrode 3 is 6mm in diameter and the counter electrode 4 is 18mm 6mm in size.

The gas diffusion electrode comprised a diffusion layer and a catalytic layer coated thereon, the diffusion layer was a porous polymer membrane, in this example a polytetrafluoroethylene membrane manufactured by the company ZITEX, with a thickness of 0.02 mm. The catalytic layer comprises a mixture of a catalyst material coated on the diffusion layer and a binder, the binder being polytetrafluoroethylene emulsion manufactured by DuPont.

The catalyst material is one or any combination of platinum, ruthenium, iridium, gold, rhodium and palladium, the catalyst material in the embodiment is a platinum-ruthenium black catalyst, and the molar ratio of platinum to ruthenium in the platinum-ruthenium black catalyst is 1: 1. Platinum has a good adsorption effect on hydrogen sulfide gas and high catalytic activity, so platinum is generally used as an electrochemical hydrogen sulfide sensor catalyst. Ruthenium is an additional catalyst, and the sensitivity of gases such as carbon monoxide can be suppressed. The catalyst which has no catalytic activity to gases except the target gas or has lower catalytic activity than the target gas is added into the gas diffusion electrode, so that the selectivity of the electrochemical hydrogen sulfide sensor can be effectively improved. Ruthenium is added into the Pt catalyst according to the molar ratio of 1:1 of platinum to ruthenium, so that the selectivity of the sensor to hydrogen sulfide gas is greatly improved, and the sensor is hardly interfered by other gases. And a platinum-ruthenium black catalyst may also be supported/blended on the carbon material in an amount of 25%. The addition of the carbon material can further inhibit the response of the gas diffusion electrode to the interfering gas, reduce the material cost of the gas diffusion electrode, and increase the conductivity of the gas diffusion electrode. The carbon material can be Vulcan XC-72 activated carbon, Vulcan XC-72R activated carbon, R330 and the like, and the Vulcan XC-72 activated carbon powder is specifically adopted in the embodiment.

The utility model discloses an electrochemistry hydrogen sulfide sensor's theory of operation is:

when the target hydrogen sulfide gas enters the sensor through the air inlet hole 9, the target hydrogen sulfide gas is adsorbed at the working electrode 2 and reacts with the following electrochemical reaction:

working electrode 2: h₂S+4H₂O→H₂SO₄+8H⁺+8e (1)

On the other hand, at the counter electrode 4, O₂The following chemical reactions take place:

the counter electrode 4: o is₂+8H⁺+8e→4H₂O (2)

The reference electrode 3 does not participate in the electrochemical reaction, is combined with an external electronic voltage stabilizing circuit, and plays a role of an electric reference point to maintain the potential of the working electrode 2.

On the whole, under the action of the electrolyte solution, reactions (1) and (2) proceed simultaneously, corresponding to the following overall reactions taking place inside the sensor:

and (3) total reaction: h₂S+2O₂→H₂SO₄(3)。

The utility model discloses a preparation method of electrochemistry hydrogen sulfide sensor of preferred embodiment, including following step:

s1: taking 0.5g of platinum ruthenium black, adding 2g of activated carbon powder, uniformly mixing, adding polytetrafluoroethylene emulsion, and magnetically stirring for 48 hours to prepare electrode slurry;

s2: coating the electrode slurry on a polytetrafluoroethylene membrane by using a wire rod, and drying at 60 ℃ for 24 hours to prepare an electrode;

s3: punching two 18 mm-diameter disk-shaped electrodes by using a punch, wherein one disk-shaped electrode is used as a working electrode 2, the other disk-shaped electrode is used as a reference electrode 3 by cutting a small disk-shaped electrode from the center of the circular hollow cutting head with the diameter of 6mm, and the cut concentric circular ring-shaped electrode is used as a counter electrode 4;

s4: assembling, namely filling a liquid storage tank 10 with a liquid absorption material III 7, installing a supporting plate 8, sequentially filling a counter electrode 4, a liquid absorption material II 6, a reference electrode 3, a liquid absorption material I5 and a working electrode 2 into a shell 1, injecting 9M sulfuric acid solution, filling an O-shaped ring 12, and completing the assembling after the shell 1 is sealed by a top cover;

s5: the sensitivity and immunity of the sensor are tested.

In step S5, the test method of the electrochemical hydrogen sulfide sensor is as follows: 50ppmH was passed through₂S gas, response time T90 was measured to be 25 seconds, baseline 0.00uA, and sensitivity 1 uA/ppm. The electrochemical hydrogen sulfide sensor was then exposed to air for 5 minutes followed by exposure to other gases for 5 minutes. Table 1 shows the results of the present example for CO and H₂、SO₂、NO、NO₂And other interference values of the gas.

Table 1:

as can be seen from Table 1, CO and SO₂、NO、NO₂、Cl₂Electrochemical H of the same gas pair of the examples₂The S sensors are completely free of cross interference. In addition, the electrochemistry H₂The S sensor also has a service life of 2-3 years.

The utility model discloses an electrochemistry hydrogen sulfide sensor not only response time is fast, and the baseline is stable, and sensitivity is high, simple structure moreover, and it is little to make the degree of difficulty, low in manufacturing cost has excellent sensitivity and accuracy, does not receive CO, SO₂、 NO、NO₂、Cl₂And the gas interference is equal, and the selectivity to the hydrogen sulfide gas is good. The method is suitable for production process control, safety detection and environmental monitoring in industries such as chemical plants, sewage treatment, fertilizer production, pharmacy, paper mills, petroleum gas production, electroplating treatment and the like.

The above detailed description merely describes the preferred embodiments of the present invention and does not limit the scope of the present invention. Without departing from the design concept and spirit scope of the present invention, the ordinary skilled in the art should belong to the protection scope of the present invention according to the present invention provides the text description and drawings to the various modifications, replacements and improvements made by the technical solution of the present invention. The scope of protection of the present invention is determined by the claims.

Claims (6)

1. An electrochemical hydrogen sulfide sensor comprising a housing having a removable top cover, an air inlet hole for air to enter is arranged on the top cover of the shell, a liquid storage tank is arranged at the bottom of the shell, the top of the liquid storage tank is provided with a support plate covered on the liquid storage tank, the support plate is provided with a porous structure, a working electrode, a reference electrode and a counter electrode are sequentially stacked in the shell from the air inlet to the liquid storage tank, electrolyte is stored in the liquid storage tank, a liquid absorbing material III is arranged in the liquid storage tank, the liquid absorbing material III is of a reel-shaped structure, a first liquid absorption material is arranged between the working electrode and the reference electrode, a second liquid absorption material is arranged between the reference electrode and the counter electrode, pins connected with the working electrode, the reference electrode and the counter electrode are arranged at the bottom of the shell, and an O-shaped ring is arranged between the working electrode and the top cover of the shell.

2. The electrochemical hydrogen sulfide sensor of claim 1 wherein the housing is a hollow cylindrical structure, the working electrode is a disk-like structure, the counter electrode is a ring-like structure having an outer diameter equal to the diameter of the working electrode, and the reference electrode is a disk-like structure having a diameter equal to the inner diameter of the counter electrode.

3. An electrochemical hydrogen sulfide sensor according to claim 2 wherein the working electrode, reference electrode and counter electrode are gas diffusion electrodes of the same material and the working electrode, reference electrode and counter electrode are made from the same batch.

4. An electrochemical hydrogen sulfide sensor as claimed in claim 3 wherein the reference electrode and the counter electrode are disks and rings cut from the same disk electrode in concentric circles.

5. An electrochemical hydrogen sulfide sensor as claimed in claim 3 wherein the gas diffusion electrode comprises a diffusion layer and a catalytic layer coated thereon, the diffusion layer being a porous polymer membrane.

6. An electrochemical hydrogen sulfide sensor according to claim 1, wherein the electrolyte is a sulfuric acid solution having a concentration of 3M to 12M.

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