CN211716847U - Indoor gas environment purifying equipment - Google Patents

Abstract

The utility model discloses an indoor gas environment purifying device, which comprises a chassis, wherein four corners of the chassis are connected with a moving mechanism, the chassis is provided with an air supply mechanism and a plurality of purifying mechanisms, the air supply mechanism and the purifying mechanisms are connected through a straight pipe, the purifying mechanisms are connected through a straight pipe and a bent pipe, and the purifying mechanism at the tail end is connected with an exhaust port; the utility model discloses an equipment can make equipment do the omnidirectional and remove through moving mechanism, can ensure equipment simultaneously and pass smoothly on the topography that has step or barrier, and this can ensure equipment does the gas purification at no dead angle to the whole house in real time, improves purifying effect and efficiency, can also shift to and pollute more serious region and do special purification. The equipment adopts the design of firstly heating and then adsorbing, so that the use efficiency and the adsorption rate of adsorbate are greatly improved, on one hand, high-flux pollutants can be treated, and on the other hand, pollutants with complicated components can be treated.

Description

Indoor gas environment purifying equipment

Technical Field

The utility model relates to a clarification plant technical field specifically is an indoor gaseous environment clarification plant.

Background

The indoor organic waste gas mainly comes from decoration and self emission of indoor materials, and is characterized by large quantity, large fluctuation of organic matter content, combustibility, certain toxicity, and malodor, and great harm to human health and environmental safety. The treatment method of organic waste gas can be divided into two categories: the first is a recovery method, which mainly separates volatile organic compounds by physical methods, such as selective adsorbents, selective permeable membranes and the like at a certain temperature and pressure, and mainly comprises activated carbon adsorption, pressure swing adsorption, condensation, a biofilm method and the like; the second elimination method is mainly to convert organic matters into water and carbon dioxide by chemical or biological reaction with light, heat, catalyst, microorganism and the like, and mainly comprises a thermal oxidation method, a delphinium combustion method, a biological oxidation method, a corona plasma decomposition method, a light decomposition method and the like.

However, most of the existing indoor purification equipment devices have the following problems: (1) most indoor gas purification equipment can only be fixedly installed at a certain specific position in a room, on one hand, the whole room cannot be subjected to overall gas purification, so that the purification effect is poor, the purification efficiency is low, and on the other hand, the specific purification of certain areas with serious pollution under decoration conditions cannot be performed; (2) most of the existing equipment only adopts a common adsorption mode for purification, and because the emission amount of pollutants is large in the first place and the pollutants are complex in the second place under decoration conditions, the adsorption rate of the common adsorption mode and the use efficiency of adsorbates are low; (3) the common fault of the existing indoor purification device is that only small-particle dust and pollutants are purified, and large-particle dust is not preliminarily purified and separated before the purification device, so that the purification efficiency of equipment and consumables is low.

Therefore, based on the above-mentioned defect, in clarification plant technical field, still there is research and modified demand to neotype indoor gaseous environment clarification plant, and this is also a research focus and the focus in this field at present, more is the utility model discloses the starting point and the power that can accomplish are located.

SUMMERY OF THE UTILITY MODEL

Problem to prior art existence, the utility model aims to provide an indoor gaseous atmosphere clarification plant.

In order to achieve the above object, the utility model provides a following technical scheme:

indoor gas environment purification equipment comprises a chassis, wherein four corners of the chassis are connected with moving mechanisms, the chassis is provided with an air supply mechanism and a plurality of purification mechanisms, the air supply mechanism and the purification mechanisms are connected through straight pipes, the purification mechanisms are connected through straight pipes and bent pipes, and the purification mechanism at the tail end is connected with an exhaust port;

the purification mechanism comprises a box body II, a material machine, a support rod I, a recovery box, a duckbill array II, a support rod II and a fan array; the material machine is arranged at the top of the second box body, the lower end of one side of the second box body is connected with the recycling box through the supporting rod, the recycling box is provided with a duckbilled array II close to one side of the second box body, the lower end of the other side of the second box body is provided with a fan array through the supporting rod II, and a catalytic mechanism is arranged inside the second box body.

Preferably, the moving mechanism comprises a lifter, a lifting column, a rotary joint, a frame, a rotary shaft, a Y-shaped rod, a wheel and a battery; the lift sets up on the chassis, and the lift post sets up on the lift, and the lift post lower extreme is connected with the swivel, and the swivel lower extreme is provided with the frame, and the pivot setting is on the frame, and Y shape pole nested the setting is in the pivot, and Y shape pole both ends are connected with the wheel, and the battery setting is in the chassis bottom.

Preferably, the air supply mechanism comprises an air box, a first connecting rod, an exhaust fan, a first pipeline, a first sealing door, a first duckbill array, a first box body, a heating rod, an electric wire, a motor, a second pipeline and a second sealing door; one side of the air box is provided with a plurality of exhaust fans through a first connecting rod, the other side of the air box is provided with a first box body, one side of the first box body, which is close to the air box, is provided with a first pipeline, the outer side of the first pipeline is provided with a first sealing door, a first duckbill array is arranged inside the first pipeline, a plurality of heating rods are arranged in the first box body, the heating rods are connected with a motor located at the top of the first box body through electric wires, one side of the first box body, which is far away.

Preferably, the catalytic mechanism comprises a sliding rail, a sliding sleeve, a bottom plate, a second connecting rod, an L-shaped panel and a hole; the sliding rails are respectively arranged on two sides inside the box body II, the sliding sleeve is arranged on the sliding rails in a sliding mode, the bottom plate is fixedly connected with the lower end of the sliding sleeve, two ends of the L-shaped panel are connected with the sliding sleeve through the connecting rod II, and the L-shaped panel is provided with a plurality of holes.

Preferably, the number of the L-shaped panels is more than four, and each L-shaped panel is arranged in a stepped mode.

Preferably, a catalyst is arranged in the material machine.

Preferably, the second tank body is connected with the second pipeline through a straight pipe.

Compared with the prior art, the beneficial effects of the utility model are as follows:

(1) the utility model discloses an equipment can make equipment do the omnidirectional and remove through moving mechanism, can ensure equipment simultaneously and pass smoothly on the topography that has step or barrier, and this can ensure equipment does the gas purification at no dead angle to the whole house in real time, improves purifying effect and efficiency, can also shift to and pollute more serious region and do special purification.

(2) The utility model discloses an equipment adopts the absorbent design of earlier intensification back for the availability factor and the adsorption efficiency of adsorbate are improved by a wide margin, can handle the high flux pollutant on the one hand, and on the other hand can handle the pollutant that the component is numerous and diverse.

(3) The utility model discloses an equipment adopts big before, little purification separation design, separates the air current with large granule dust preliminary separation earlier for the purification efficiency of equipment and consumptive material obtains the guarantee in follow-up purification operation.

Drawings

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

FIG. 2 is a schematic structural view of the chassis and the moving mechanism of the present invention;

fig. 3 is a schematic structural diagram of the air supply mechanism of the present invention;

FIG. 4 is a schematic structural view of the air supply mechanism of the present invention;

FIG. 5 is a schematic structural view of the purifying mechanism of the present invention;

FIG. 6 is a schematic structural view of the purifying mechanism and the catalyzing mechanism of the present invention;

FIG. 7 is a schematic structural view of a straight pipe and a bent pipe according to the present invention;

wherein: the device comprises a chassis 1, a lifter 101, a lifting column 102, a rotary joint 103, a frame 104, a rotating shaft 105, a Y-shaped rod 106, wheels 107, a battery 108, a bellows 2, a first connecting rod 201, a suction fan 202, a first pipeline 3, a first sealing door 301, a first duckbill array 302, a first box body 303, a heating rod 304, an electric wire 305, a motor 306, a second pipeline 307, a second sealing door 308, a straight pipe 4, a second box body 5, a material machine 501, a first supporting rod 502, a recycling box 503, a second duckbill array 504, a second supporting rod 505, a fan array 506, a sliding rail 507, a sliding sleeve 508, a bottom plate 509, a second connecting rod 5010, an L-shaped panel 5011, a hole 5012, an elbow 6 and an.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-7, an indoor gas environment purifying apparatus comprises a chassis 1, wherein four corners of the chassis 1 are connected with moving mechanisms, an air supply mechanism and a plurality of purifying mechanisms are arranged on the chassis 1, the air supply mechanism and the purifying mechanisms are connected through a straight pipe 4, the purifying mechanisms are connected through a straight pipe 4 and a bent pipe 6, and the purifying mechanism at the tail end is connected with an exhaust port 7;

the purification mechanism comprises a second box body 5, a material machine 501, a first support rod 502, a recycling box 503, a second duckbill array 504, a second support rod 505 and a fan array 506; the feeding machine 501 is arranged at the top of the second box body 5, the lower end of one side of the second box body 5 is connected with a recycling box 503 through a first supporting rod 502, the recycling box 503 is provided with a second duckbilled array 504 close to one side of the second box body 5, the lower end of the other side of the second box body 5 is provided with a fan array 506 through a second supporting rod 505, and a catalytic mechanism is arranged inside the second box body 5. A catalyst is arranged in the material machine 501. The second box body 5 is connected with a second pipeline 307 through a straight pipe 4.

The moving mechanism comprises a lifter 101, a lifting column 102, a rotary joint 103, a frame 104, a rotating shaft 105, a Y-shaped rod 106, a wheel 107 and a battery 108; the lifting machine 101 is arranged on the chassis 1, the lifting column 102 is arranged on the lifting machine 101, the lower end of the lifting column 102 is connected with a rotary joint 103, the lower end of the rotary joint 103 is provided with a frame 104, a rotary shaft 105 is arranged on the frame 104, a Y-shaped rod 106 is embedded on the rotary shaft 105, two ends of the Y-shaped rod 106 are connected with wheels 107, and a battery 108 is arranged at the bottom of the chassis 1.

The air supply mechanism comprises an air box 2, a first connecting rod 201, an extraction fan 202, a first pipeline 3, a first sealing door 301, a first duckbill array 302, a first box body 303, a heating rod 304, an electric wire 305, a motor 306, a second pipeline 307 and a second sealing door 308; 2 one side of bellows is provided with a plurality of extraction fan 202 through connecting rod 201, 2 opposite sides of bellows are provided with box 303, box 303 is close to 2 one side of bellows and is provided with pipeline 3, the pipeline 3 outside is provided with sealing door 301, pipeline 3 inside is provided with duckbilled array 302, be provided with a plurality of heating rod 304 in the box 303, heating rod 304 passes through electric wire 305 and is connected with the motor 306 that is located box 303 top, box 303 is kept away from 2 one side of bellows and is provided with pipeline two 307, the pipeline two 307 outside is provided with sealing door two 308.

The catalytic mechanism comprises a sliding rail 507, a sliding sleeve 508, a bottom plate 509, a second connecting rod 5010, an L-shaped panel 5011 and a hole 5012; the sliding rails 507 are respectively arranged on two sides of the interior of the second box body 5, the sliding sleeve 508 is arranged on the sliding rails 507 in a sliding mode, the bottom plate 509 is fixedly connected with the lower end of the sliding sleeve 508, two ends of the L-shaped panel 5011 are connected with the sliding sleeve 508 through the second connecting rod 5010, and a plurality of holes 5012 are formed in the L-shaped panel 5011. The number of the L-shaped panels 5011 is more than four, and each L-shaped panel 5011 is arranged in a stepped mode.

The utility model discloses the working process does: the position of the lifting column 102 on the lifter 101 is controlled to achieve the purpose of controlling the height of the chassis 1, and further control the overall working height of the equipment, wherein the equipment can be controlled to advance and turn by adjusting the rotating angle of the rotating joint 103, the equipment can be controlled to move by the wheel 107, when a step or a lower obstacle is encountered, the Y-shaped rod 106 is controlled to rotate around the rotating shaft 105, so that the equipment can move across or climb over, the battery 108 supplies energy to the overall working of the equipment, and the energy supply pipeline is buried in the equipment. The external turbid airflow is sucked into the wind box 2 through the suction fan 202 and is further conveyed into the pipeline one 3, and then enters the box body one 303 to be processed, wherein the amount of the entering airflow is controlled through the opening and closing of the sealing door one 301, the duckbill array one 302 can initially block and separate large-particle dust in the airflow, the airflow entering the box body one 303 is subjected to heating processing through the heating rod 304, and the heating rod 304 is powered through the motor 306 and the electric wire 305 in sequence. After the heating is completed, the second sealing door 308 is opened, so that high-temperature airflow enters the straight pipe 4 along the second pipeline 307 and further flows into the second box body 5, activated carbon materials are thrown downwards through the material machine 501, the activated carbon materials respectively fall on the L-shaped panel 5011 and are evenly paved, and small-particle dust entrained in the high-temperature airflow is absorbed when the high-temperature airflow passes through the activated carbon materials, and the absorption reaction is more sufficient because the airflow is at high temperature. The holes 5012 can ensure smooth airflow. When the absorption of the activated carbon material reaches saturation, the control sliding sleeve 508 moves downwards on the sliding rail 507, on one hand, the bottom plate 509 is driven to move downwards, and on the other hand, the L-shaped panel 5011 is driven to move downwards to leave the second box body 5. The L-shaped panel 5011 carries the saturated activated carbon materials to move to one side of the second support rod 505, the fan array 506 is started to generate strong wind, the strong wind blows the activated carbon materials into the recycling bin 503 to be recycled, and the second duckbill array 504 can ensure that the recycling process can be completed to the maximum extent. The cleaned gas in the second box 5 is transported along the elbow 6 to the exhaust 7 to be exhausted.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an indoor gaseous environment clarification plant, includes chassis (1), its characterized in that: the four corners of the chassis (1) are connected with moving mechanisms, the chassis (1) is provided with an air supply mechanism and a plurality of purification mechanisms, the air supply mechanism and the purification mechanisms are connected through straight pipes (4), the purification mechanisms are connected through the straight pipes (4) and bent pipes (6), and the purification mechanism at the tail end is connected with an exhaust port (7);

the purification mechanism comprises a box body II (5), a material machine (501), a support rod I (502), a recovery box (503), a duckbill array II (504), a support rod II (505) and a fan array (506); the feeding machine (501) is arranged at the top of the second box body (5), the lower end of one side of the second box body (5) is connected with a recycling box (503) through a first supporting rod (502), the recycling box (503) is provided with a second duckbilled array (504) close to one side of the second box body (5), the lower end of the other side of the second box body (5) is provided with a fan array (506) through a second supporting rod (505), and a catalysis mechanism is arranged inside the second box body (5).

2. An indoor gaseous environment purification apparatus according to claim 1, wherein: the moving mechanism comprises a lifter (101), a lifting column (102), a rotary joint (103), a frame (104), a rotating shaft (105), a Y-shaped rod (106), a wheel (107) and a battery (108); the lifting machine is characterized in that the lifting machine (101) is arranged on the chassis (1), the lifting column (102) is arranged on the lifting machine (101), the lower end of the lifting column (102) is connected with a rotary joint (103), the lower end of the rotary joint (103) is provided with a frame (104), a rotary shaft (105) is arranged on the frame (104), a Y-shaped rod (106) is arranged on the rotary shaft (105) in a sleeved mode, the two ends of the Y-shaped rod (106) are connected with wheels (107), and a battery (108) is arranged at the bottom of the chassis (1).

3. An indoor gaseous environment purification apparatus according to claim 2, wherein: the air supply mechanism comprises an air box (2), a first connecting rod (201), an exhaust fan (202), a first pipeline (3), a first sealing door (301), a first duckbill array (302), a first box body (303), a heating rod (304), an electric wire (305), a motor (306), a second pipeline (307) and a second sealing door (308); one side of the air box (2) is provided with a plurality of exhaust fans (202) through a first connecting rod (201), the other side of the air box (2) is provided with a first box body (303), the first box body (303) is provided with a first pipeline (3) close to one side of the air box (2), the outer side of the first pipeline (3) is provided with a first sealing door (301), the first pipeline (3) is internally provided with a first duckbilled array (302), the first box body (303) is internally provided with a plurality of heating rods (304), the heating rods (304) are connected with a motor (306) located at the top of the first box body (303) through electric wires (305), one side of the first box body (303) far away from the air box (2) is provided with a second pipeline (307).

4. An indoor gaseous environment purification apparatus according to claim 3, wherein: the catalytic mechanism comprises a sliding rail (507), a sliding sleeve (508), a bottom plate (509), a second connecting rod (5010), an L-shaped panel (5011) and a hole (5012); slide rail (507) set up respectively in box two (5) inside both sides, and sliding sleeve (508) slide to set up on slide rail (507), bottom plate (509) and sliding sleeve (508) lower extreme fixed connection, and L shape panel (5011) both ends are passed through connecting rod two (5010) and are connected with sliding sleeve (508), are provided with a plurality of holes (5012) on L shape panel (5011).

5. An indoor gaseous environment purification apparatus according to claim 4, wherein: the number of the L-shaped panels (5011) is more than four, and each L-shaped panel (5011) is arranged in a stepped mode.

6. An indoor gaseous environment purification apparatus as claimed in any one of claims 1 to 5, wherein: a catalyst is arranged in the material machine (501).

7. An indoor gaseous environment purification apparatus as claimed in any one of claims 1 to 5, wherein: and the second box body (5) is connected with the second pipeline (307) through a straight pipe (4).

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