CN219002600U - Biological enzyme atomizing deodorizing machine - Google Patents

Abstract

The utility model discloses a biological enzyme atomization deodorizing machine, which is characterized in that: comprises an air mixing box (1), an atomizer (2) and a fan (3); an air inlet pipe (4) and an air outlet pipe (5) are arranged on the air mixing box (1); biological enzyme liquid (M) can be added into the gas mixing box (1); the atomizer (2) is arranged in the gas mixing box (1), and the atomizer (2) is used for atomizing the biological enzyme liquid (M) in the gas mixing box (1) to form biological enzyme mist; the fan (3) is arranged on the air inlet pipe (4) or the air outlet pipe (5) and is used for pumping air into the air mixing box (1) through the air inlet pipe (4) and discharging the air from the air outlet pipe (5) after mixing the air with the biological enzyme mist. The utility model can be used for efficiently removing odor or peculiar smell from the odor in the odor source room and has the advantages of thorough deodorization, low energy consumption, low running power, low maintenance cost and the like.

Description

Biological enzyme atomizing deodorizing machine

Technical Field

The utility model relates to a biological enzyme atomization deodorizing machine.

Background

At present, the method is applied to public areas with relatively dense people flow, including schools, enterprises and public institutions, markets, hotels, office buildings, stations, airports, yards and the like. The odor treatment method for the odor comprises the following steps:

(1) The odor is covered by the fragrance by adopting the fragrance spraying deodorization, so that the harm of odor molecules is not truly disinfected, and the odor is only suitable for temporary odor masking in a narrow space; masking odor without treating odor;

(2) The method has the advantages that the fresh air system is installed, all-weather air exchange is carried out on the place where the odor source occurs, the construction cost or the transformation cost is high, and the energy consumption is high; the problems of high construction/transformation cost and high operation cost when deodorizing without deodorizing and deodorizing;

(3) The method has the advantages that the odor source cleaning frequency is increased, the odor source is cleaned and flushed in real time, labor cost is greatly increased, the odor source can be diffused in different degrees, meanwhile, the bottom surface is wet and slippery due to frequent cleaning, and the risk of wrestling is brought: the human body induction technology is added to clean the odor source transmitting place in real time, the method causes waste of a large amount of water resources, and most of the odor sources generated immediately can be cleaned, but the odor sources cannot be thoroughly eliminated, and the problems of high maintenance cost, large water consumption, high operation cost and the like are solved.

The existing biological enzyme atomization deodorizing machine (such as a centrifugal machine of a biological enzyme atomization deodorizing air purifying integrated machine of a published patent CN206139005U is externally arranged on a dosing tank) has the following problems: because the existing atomizer is arranged outside the medicine chest, the biological enzyme fog generated by the atomizer can only be discharged to be deodorized after contacting with the odor source, and the odor cannot be pumped into a narrow space to be mixed, so that the problem that the deodorizing efficiency is low due to incapability of realizing circulation, repeated decomposition and full contact exists.

Disclosure of Invention

In order to solve one or more of the above-mentioned problems in the prior art, the present utility model provides a bio-enzyme atomizing deodorizing machine.

In order to achieve the above purpose, the utility model provides a biological enzyme atomization deodorizing machine, which is characterized in that: comprises an air mixing box, an atomizer and a fan; an air inlet pipe and an air outlet pipe are arranged on the air mixing box; biological enzyme liquid can be added into the gas mixing box; the atomizer is arranged in the gas mixing box and is used for atomizing the biological enzyme liquid in the gas mixing box to form biological enzyme mist; the fan is arranged on the air inlet pipe or the air outlet pipe and is used for pumping air into the air mixing box through the air inlet pipe and discharging the air from the air outlet pipe after mixing the air with the biological enzyme mist.

By adopting the scheme, when the air inlet pipe is used, the air inlet pipe can be used for absorbing the indoor air (with built-in installation) or the outdoor air (with external installation) of the odor source, and the atomizer atomizes the biological enzyme liquid in the gas mixing box to form biological enzyme fog; the fan is used for pumping air into the air mixing box through the air inlet pipe and then discharging mixed gas from the air outlet pipe after mixing the air with biological enzyme mist, and an outlet of the air outlet pipe is positioned in a smell source chamber or a designated area (a smell source concentration position); the mixed gas discharged from the outlet of the air outlet pipe contains a large amount of biological enzymes, and then is diffused into a smell source room or a designated area (a smell source concentration position) to carry out biological decomposition with fatty acid, indoxylum, hydrogen sulfide, sulfhydryl matrix, ammonia and the like (smell molecules) in the smell, so that the odor is effectively eliminated.

When the inlet of the air inlet pipe is internally installed, the air (odor) in the odor source chamber is absorbed, so that the air containing odor molecules can be sucked into the air mixing box for mixing, and the air can be circularly and repeatedly decomposed and fully contacted, and the deodorizing efficiency can be greatly improved.

In addition, as the atomizer is internally arranged in the gas mixing box, the biological enzyme mist generated by the atomizer is filled in a narrow space in the gas mixing box; so that the air pumped into the path in the air mixing box can be quickly mixed with the biological enzyme mist generated in the atomizer in a short time and then discharged.

In addition, the atomizer is arranged in the air mixing box and is used as a whole, so that the assembly and the disassembly are more convenient; and because a certain amount of biological enzyme liquid is stored in the gas mixing box, the biological enzyme mist generated by the atomizer is filled in the gas mixing box, and the air and the biological enzyme mist are mixed in the gas mixing box, the structure is compact, the multifunctional device is integrated, the layout is optimized, the simplification and the compactness are realized, and the cost is lower.

The fan is arranged on the air inlet pipe or the air outlet pipe instead of being arranged (or integrated) on the air mixing box, and the fan and the air mixing box are combined to cause very large appearance, so that the space is easily insufficient, the position is limited, and the fan is very troublesome. The technical scheme can be used for flexibly assembling, splicing and moving the air inlet pipe or the air outlet pipe according to the layout characteristics, positions and directions of the air inlet pipe or the air outlet pipe, so that the installation position of the fan is basically not limited.

The technical scheme is equivalent to the existing deodorizing equipment, and has the advantages of thorough deodorizing, low energy consumption, low running power, low maintenance cost and the like.

Further, an air inlet and an air outlet are formed in the air mixing box; the air inlet pipe is connected with the air inlet; the air outlet pipe is connected with the air outlet; the air inlet and the air outlet are higher than the air outlet of the atomizer, and the air inlet and the air outlet are distributed on two sides of the air outlet of the atomizer. The air enters one side of the air mixing box from the air inlet, is mixed with the biological enzyme mist through the upper part of the air outlet of the atomizer, and then can be discharged from the air outlet at the other side of the air mixing box, so that the air can be better mixed with the biological enzyme mist when passing through the air mixing box.

Further, a baffle plate is vertically arranged in the gas mixing box; the baffle plate is positioned in the middle between the air outlet of the atomizer and the air outlet; the upper end of the baffle plate is fixed and sealed with the top cover of the gas mixing box; the lower end of the baffle plate is equal to or close to the air outlet of the atomizer in height. Because part of air entering the top of the air mixing box is directly discharged from the air outlet (especially, the air speed or the air quantity is obvious when the air speed or the air quantity is too large), the problem of no mixing or poor mixing with the biological enzyme mist exists. Under the action of the baffle plate, the air entering the top of the air mixing box cannot be directly discharged along the upper edge from the air outlet, but can be deflected downwards and then mixed with the biological enzyme mist, and then can be discharged from the air outlet.

Further, a liquid level sensor is arranged in the gas mixing box and is used for detecting the liquid level of the biological enzyme liquid in the gas mixing box; the gas mixing box is connected with an external liquid storage box pipeline through a liquid supplementing pump; the liquid replenishing pump can pump the biological enzyme liquid in the external liquid storage tank into the gas mixing tank for replenishing liquid. When the liquid level sensor detects a liquid level low-level threshold value of the biological enzyme liquid in the gas mixing tank, the liquid supplementing pump can be controlled to work through the control system, and the biological enzyme liquid in the external liquid storage tank is pumped into the gas mixing tank to automatically supplement liquid.

Preferably, the atomizer is a nano atomizer or an ultrasonic atomizer. The nanometer atomizer or the ultrasonic atomizer can generate tiny fog, and the atomization is more uniform, so that the mixing effect of microorganisms and air is improved, and the use amount of the microorganisms is reduced.

Preferably, the liquid level sensor adopts a double-floating ball liquid level switch.

Preferably, the fan adopts a diagonal flow pipeline fan. The diagonal flow pipeline fan has the characteristics of high efficiency, energy conservation, low noise, convenience in assembly and the like.

Preferably, the air inlet pipe or/and the air outlet pipe adopts a deformable pipe. And the bending deformation is convenient for layout and pipe running.

The utility model has the beneficial effects that:

the utility model can be used for efficiently removing odor or peculiar smell from the odor in the odor source room, and has the advantages of thorough deodorization, low energy consumption, low running power, low maintenance cost and the like;

secondly, the atomizer is internally arranged in the gas mixing box, and the biological enzyme mist generated by the atomizer is filled in a narrow space in the gas mixing box; so that the air pumped into the path in the air mixing box can be quickly mixed with the biological enzyme mist generated in the atomizer in a short time and then discharged;

thirdly, the atomizer is arranged in the air mixing box and is used as a whole, so that the assembly and the disassembly are more convenient; the gas mixing box stores a certain amount of biological enzyme liquid, meanwhile, the biological enzyme mist generated by the atomizer is filled in the gas mixing box, and meanwhile, the air and the biological enzyme mist are mixed in the gas mixing box, so that the gas mixing box has a compact structure, integrates multiple functions, optimizes the layout, simplifies the realization, is small and has lower cost;

fourth, the present utility model is characterized in that the fan is installed on the air inlet pipe or the air outlet pipe instead of being arranged (or integrated) on the air mixing box, and the fan and the air mixing box are combined to form a very large appearance, so that the space is easily insufficient, the position is limited, and the fan is very troublesome. According to the technical scheme, the air inlet pipe or the air outlet pipe can be flexibly assembled, spliced and moved according to the site according to the layout characteristics, the positions and the directions of the air inlet pipe or the air outlet pipe, so that the installation position of the fan is basically not limited;

fifthly, the air entering the top of the air mixing box can not be directly discharged along the upper edge from the air outlet under the action of the baffle plate, but can be discharged from the air outlet after being mixed with the biological enzyme mist after being deflected downwards, so that partial air entering the top of the air mixing box can be prevented from being directly discharged from the air outlet (particularly, the problem is particularly obvious when the wind speed or the wind quantity is too large), and the problem that the air and the biological enzyme mist are not mixed or are not mixed is effectively solved;

sixthly, when the liquid level sensor detects a low level threshold value of the biological enzyme liquid in the gas mixing tank, the liquid supplementing pump can be controlled to work through the control system, and the biological enzyme liquid in the external liquid storage tank is pumped into the gas mixing tank to automatically supplement liquid;

seventh, the atomizer adopts a nano atomizer or an ultrasonic atomizer. The nanometer atomizer or the ultrasonic atomizer can generate tiny fog, and the atomization is more uniform, so that the mixing effect of microorganisms and air is improved, and the use amount of the microorganisms is reduced.

Drawings

FIG. 1 is a perspective view of a bio-enzyme atomizing deodorizing machine according to the present utility model (with its air mix tank cut away).

Fig. 2 is an enlarged view at a in fig. 1.

FIG. 3 is a perspective view (looking in the other direction) of a bio-enzyme atomizing deodorizing machine according to the present utility model.

Detailed Description

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings:

examples: referring to fig. 1-3, a biological enzyme atomization deodorizing machine comprises an air mixing box 1, an atomizer 2 and a fan 3.

Referring to fig. 2, a bio-enzyme liquid M (i.e., a mixed liquid of one or more bio-enzymes and water) may be added to the gas mixing tank 1.

Referring to fig. 2, a liquid level sensor 6 is disposed in the gas mixing tank 1, and the liquid level sensor 6 is used for detecting the liquid level of the biological enzyme liquid in the gas mixing tank 1.

Referring to fig. 3, the gas mixing tank 1 is connected with an external liquid storage tank 8 through a liquid supplementing pump 7 in a pipeline manner; the liquid replenishing pump 7 can pump the biological enzyme liquid in the external liquid storage tank 8 into the gas mixing tank 1 to replenish liquid.

In combination with fig. 2 and 3, the air-mixing tank 1 is provided with a liquid supplementing port 1-4, a liquid outlet of the liquid supplementing pump 7 is connected with the liquid supplementing port 1-4 through a first hose, and a liquid inlet of the liquid supplementing pump 7 is connected with the liquid storage tank 8 through a second hose.

The external reservoir 8 stores a large amount of bio-enzyme liquid.

Specifically, the liquid level sensor 6 and the liquid replenishment pump 7 are connected to a PLC (programmable controller).

When the liquid level sensor 6 detects the low level threshold value of the biological enzyme liquid in the gas mixing tank 1, the liquid supplementing pump 7 can be controlled by the control system to start working, and the biological enzyme liquid in the external liquid storage tank 8 is pumped into the gas mixing tank 1 to automatically supplement liquid; and when the liquid level sensor 6 detects that the liquid level of the biological enzyme liquid in the gas mixing tank 1 reaches a high threshold value, the control system can control the liquid supplementing pump 7 to stop working.

Referring to fig. 3, the external tank 8 may be installed at a low level while the air mix tank 1 may be installed at a high level. When the internal quantity of the external liquid storage tank 8 is small, the liquid storage tank can be manually added at a low position, and the operation is more convenient.

Preferably, the liquid level sensor 6 adopts a double-floating ball liquid level switch.

An air inlet pipe 4 and an air outlet pipe 5 are arranged on the air mixing box 1.

Referring to fig. 2, specifically, an air inlet 1-1 and an air outlet 1-2 are arranged on the air mixing box 1; the air inlet pipe 4 is connected with the air inlet 1-1; the air outlet pipe 5 is connected with the air outlet 1-2.

Preferably, the air inlet pipe 4 and/or the air outlet pipe 5 are/is deformable or bendable pipes. And the bending deformation is convenient for layout and pipe running.

Specifically, the air inlet pipe 4 and/or the air outlet pipe 5 may be made of soft materials, soft air pipes, corrugated hoses, or the like.

Referring to fig. 2, in particular, the atomizer 2 is installed inside the gas mixing tank 1, and the atomizer 2 is used for atomizing the bio-enzyme liquid M in the gas mixing tank 1 to form a bio-enzyme mist.

Preferably, the atomizer 2 is a nano atomizer or an ultrasonic atomizer. The nanometer atomizer or the ultrasonic atomizer can generate tiny fog, and the atomization is more uniform, so that the mixing effect of microorganisms and air is improved, and the use amount of the microorganisms is reduced.

Referring to fig. 2, specifically, the air inlet 1-1 and the air outlet 1-2 are higher than the air outlet of the atomizer 2, and the air inlet 1-1 and the air outlet 1-2 are distributed on two sides of the air outlet of the atomizer 2. The air enters into one side of the air mixing box 1 from the air inlet 1-1, passes through the upper part of the air outlet of the atomizer 2 and is mixed with the biological enzyme mist, and then can be discharged from the air outlet 1-2 at the other side of the air mixing box 1, so that the air can be better mixed with the biological enzyme mist when passing through the air mixing box 1.

Referring to fig. 2, the fan 3 may be disposed on the air inlet pipe 4 or the air outlet pipe 5, and is configured to pump air into the air mixing box 1 through the air inlet pipe 4, mix with the bio-enzyme mist, and then discharge the air from the air outlet pipe 5.

In this embodiment, the fan 3 is mounted on the air inlet pipe 4.

Preferably, the fan 3 is a diagonal flow pipeline fan. The diagonal flow pipeline fan has the characteristics of high efficiency, energy conservation, low noise, convenience in assembly and the like.

When the utility model is used, the air inlet pipe 4 can be used for absorbing the indoor air of the odor source and is internally installed or the outdoor air is externally installed.

Referring to fig. 2, in operation, the atomizer 2 atomizes the bio-enzyme liquid (M) in the gas mixing tank 1 to form a bio-enzyme mist; the fan 3 is used for pumping air into the air mixing box 1 through the air inlet pipe 4 and then discharging mixed gas from the air outlet pipe 5 after mixing the air with biological enzyme mist, and the outlet of the air outlet pipe 5 is positioned in a smell source chamber or a designated area (a smell source concentration position); the mixed gas discharged from the outlet of the air outlet pipe 5 contains a large amount of biological enzymes, and then is diffused into the odor source chamber or a designated area (the odor source concentration position) to carry out biological decomposition with fatty acid, indoxylum, hydrogen sulfide, mercapto substrate, ammonia and the like (odor molecules) in the odor, thereby realizing effective odor elimination.

When the inlet of the air inlet pipe is internally installed, the air (odor) in the odor source chamber is absorbed, so that the air containing odor molecules can be sucked into the air mixing box 1 for mixing, and the air can be circularly and repeatedly decomposed and fully contacted, and the deodorizing efficiency can be greatly improved.

Referring to fig. 2, in addition, since the atomizer 2 is internally installed in the gas mixing tank 1, the bio-enzyme mist generated by the atomizer 2 is filled in a narrow space in the gas mixing tank 1; so that the air drawn into the path in the air mixing box 1 can be quickly mixed with the biological enzyme mist generated in the atomizer 2 in a short time and then discharged.

Referring to fig. 2, in addition, the atomizer 2 is built in the air mixing box 1 and is a whole, so that the assembly and disassembly are more convenient; and because a certain amount of biological enzyme liquid is stored in the gas mixing box 1, simultaneously the biological enzyme mist generated by the atomizer 2 is filled in the gas mixing box 1, and simultaneously the air and the biological enzyme mist are mixed in the gas mixing box 1, the structure is compact, the multifunctional device is integrated, the layout is optimized, the simplification and the smallness are realized, and the cost is lower.

Referring to fig. 1, the fan 3 is installed on the air inlet pipe 4 or the air outlet pipe 5, instead of being arranged (or integrated) on the air mixing box 1, and the fan 3 and the air mixing box 1 are combined to form a very large appearance, so that the space is easily insufficient, the position is limited, and the operation is very troublesome. According to the technical scheme, the air inlet pipe 4 or the air outlet pipe 5 can be flexibly assembled, spliced and moved according to the site according to the layout characteristics, the positions and the directions of the air inlet pipe 4 or the air outlet pipe 5, so that the installation position of the fan 3 is basically not limited.

Referring to fig. 2, in addition, baffles 1-3 are vertically arranged in the gas mixing tank 1; the baffle plate 1-3 is positioned in the middle between the air outlet of the atomizer 2 and the air outlet 1-2; the upper end of the baffle plate 1-3 is fixed and sealed with the top cover of the gas mixing box 1; the lower ends of the baffle plates 1-3 are equal to the air outlet of the atomizer 2 in height. The partial air entering the inner top of the air mixing box 1 is directly discharged from the air outlet 1-2, especially when the air speed or the air quantity is too large, and the problem of no or poor mixing with the biological enzyme mist is caused. Under the action of the baffle plate 1-3, the air entering the inner top of the air mixing box 1 cannot be directly discharged along the upper edge from the air outlet 1-2, but can be deflected downwards and then mixed with the biological enzyme mist, and then can be discharged from the air outlet 1-2.

Referring to fig. 3, a control cabinet 9 is additionally installed on the outer wall of the air mixing box 1. A PLC (controller), a time relay, a circuit switch, and the like are installed in the control cabinet 9. Meanwhile, the device can work in cooperation with a human body sensor, an odor sensor and the like. The following modes of operation may be employed in operation:

as a first mode of operation: the deodorization operation can be started for three minutes each time (namely, the fan and the atomizer work simultaneously), then the deodorization operation is started again at intervals of 10 minutes after the machine is stopped, and the deodorization operation belongs to an interval starting mode.

As a second mode of operation: when the human body sensor detects a human body signal, the deodorizing operation is started (namely, the fan and the atomizer work simultaneously) until the deodorizing operation is stopped after the human body signal disappears and then the deodorizing operation is continued for 3 minutes.

As a third mode of operation: when the odor sensor detects that the odor molecular value reaches a set threshold value, the deodorization operation is started (namely, the fan and the atomizer work simultaneously), and when the detected odor molecular value is smaller than the threshold value, the deodorization operation is stopped.

The foregoing describes in detail preferred embodiments of the present utility model. It should be understood that numerous modifications and variations can be made in accordance with the concepts of the utility model by one of ordinary skill in the art without undue burden. Therefore, all technical solutions which can be obtained by logic analysis, reasoning or limited experiments based on the prior art by the person skilled in the art according to the inventive concept shall be within the scope of protection defined by the claims.

Claims (8)

1. A biological enzyme atomizing deodorizing machine is characterized in that: comprises an air mixing box (1), an atomizer (2) and a fan (3);

an air inlet pipe (4) and an air outlet pipe (5) are arranged on the air mixing box (1);

biological enzyme liquid (M) can be added into the gas mixing box (1);

the atomizer (2) is arranged in the gas mixing box (1), and the atomizer (2) is used for atomizing the biological enzyme liquid (M) in the gas mixing box (1) to form biological enzyme mist;

the fan (3) is arranged on the air inlet pipe (4) or the air outlet pipe (5) and is used for pumping air into the air mixing box (1) through the air inlet pipe (4) and discharging the air from the air outlet pipe (5) after mixing the air with the biological enzyme mist.

2. A bio-enzyme mist deodorizing machine as set forth in claim 1, wherein: an air inlet (1-1) and an air outlet (1-2) are arranged on the air mixing box (1); the air inlet pipe (4) is connected with the air inlet (1-1); the air outlet pipe (5) is connected with the air outlet (1-2);

the air inlet (1-1) and the air outlet (1-2) are higher than the air outlet of the atomizer (2); the air inlet (1-1) and the air outlet (1-2) are distributed on two sides of the air outlet of the atomizer (2).

3. A bio-enzyme mist deodorizing machine as set forth in claim 2, wherein: baffle plates (1-3) are vertically arranged in the gas mixing box (1);

the baffle plate (1-3) is positioned in the middle between the air outlet of the atomizer (2) and the air outlet (1-2);

the upper end of the baffle plate (1-3) is fixed and sealed with the top cover of the gas mixing box (1); the lower ends of the baffle plates (1-3) are equal to or close to the air outlet of the atomizer (2).

4. A bio-enzyme mist deodorizing machine as set forth in claim 1, wherein: a liquid level sensor (6) is arranged in the gas mixing box (1), and the liquid level sensor (6) is used for detecting the liquid level of the biological enzyme liquid in the gas mixing box (1);

the air mixing box (1) is connected with an external liquid storage box (8) through a liquid supplementing pump (7) through a pipeline; the liquid supplementing pump (7) can pump the biological enzyme liquid in the external liquid storage tank (8) into the gas mixing tank (1) for supplementing liquid.

5. A bio-enzyme mist deodorizing machine as set forth in claim 1, wherein: the atomizer (2) adopts a nano atomizer or an ultrasonic atomizer.

6. The bio-enzyme atomizing deodorizing machine according to claim 4, wherein: the liquid level sensor (6) adopts a double-floating ball liquid level switch.

7. A bio-enzyme mist deodorizing machine as set forth in claim 1, wherein: the fan (3) adopts an inclined flow pipeline fan.

8. A bio-enzyme mist deodorizing machine as set forth in any one of claims 1 to 3, wherein: the air inlet pipe (4) and/or the air outlet pipe (5) are/is deformable pipes.

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