CN217685635U - High-efficient intelligent ventilation system processing apparatus in laboratory - Google Patents

Abstract

The utility model discloses a high-efficient intelligent ventilation system processing apparatus in laboratory, including air intake and filtering component, air intake left side fixedly connected with chuck, and the gomphosis of chuck top is connected with the baffle, the right-hand fan that is provided with of baffle, and the right-hand ventilation pipe that is provided with of air intake fan for filtered air filtering component sets up inside the ventilation pipe, the draw-in groove has been seted up to ventilation pipe inner wall below, and is provided with the detector above the ventilation pipe, the detector top is provided with the backward flow subassembly that is used for backflow air, ventilation pipe below symmetry fixedly connected with spring, and the inboard fixedly connected with fixture block of spring, filtering component includes shell, filter plate, adsorbed layer, sterile layer and purification layer, fixedly connected with filter plate in the shell, the right-hand fixedly connected with sterile layer of adsorbed layer. The utility model discloses a cooperation between each partial part for the device can carry out filtration purification relapse to the air, and it is indoor to discharge again after the air reaches the standard.

Description

High-efficient intelligent ventilation system processing apparatus in laboratory

Technical Field

The utility model relates to a laboratory new trend technical field specifically is a high-efficient intelligent ventilation system processing apparatus in laboratory.

Background

The fresh air system is a set of independent air processing system consisting of an air supply system and an air exhaust system and is divided into a pipeline type fresh air system and a pipeline-free fresh air system. The pipeline type fresh air system is composed of a fresh air fan and pipeline accessories, fresh air is sent indoors by special equipment on one side of the closed room, and then is discharged outdoors by the special equipment on the other side of the closed room, and a fresh air flowing field can be formed indoors, so that the requirement of indoor fresh air ventilation is met.

The laboratory new trend filtration system device that has now on the market is with the direct suction of outside air, then directly discharges to indoor after simply filtering inspiratory air, can make substandard air influence people's healthy, and for this reason, we provide a high-efficient intelligent ventilation system processing apparatus in laboratory.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient intelligent ventilation system processing apparatus in laboratory to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a high-efficient intelligent ventilation system processing apparatus in laboratory, includes air intake and filtering component, air intake left side fixedly connected with chuck, and the gomphosis of chuck top is connected with the baffle, the right-hand fan that is provided with of baffle, and the right-hand ventilation pipe that is provided with of fan, be used for filtered air filtering component sets up inside the ventilation pipe, the draw-in groove has been seted up to ventilation pipe inner wall below, and is provided with the detector above the ventilation pipe, the detector top is provided with the backward flow subassembly that is used for backflow air, ventilation pipe below symmetry fixedly connected with spring, and the inboard fixedly connected with fixture block of spring, filtering component includes shell, filter plate, adsorbed layer, sterile layer and purification layer, fixedly connected with filter plate in the shell, and the right-hand adsorbed layer that is provided with of filter plate, the right-hand fixedly connected with sterile layer of adsorbed layer, and the right-hand purification layer that is provided with of sterile layer.

Preferably, the backward flow subassembly includes back flow, check valve, telescopic link, baffle, connecting rod, fixed pin, spout, commentaries on classics board and pivot, the inside left end fixedly connected with check valve of back flow, and the inside right-hand member fixedly connected with telescopic link of back flow, the telescopic link outside is provided with the baffle, and telescopic link below fixedly connected with connecting rod, the connecting rod below is provided with the fixed pin, and the fixed pin front and back bilateral symmetry has seted up the spout, fixed pin below fixedly connected with changes the board, and changes board right-hand member fixedly connected with pivot.

Preferably, the left end of the return pipe is communicated with the inside of the ventilation pipe through a one-way valve, and the right end of the return pipe penetrates through the upper part of the ventilation pipe and is communicated with the inside of the ventilation pipe.

Preferably, the baffle is fixedly connected with the return pipe, and the baffle is tightly attached to the telescopic rod.

Preferably, the connecting rod passes through the telescopic link and constitutes elevation structure with the back flow, and the connecting rod passes through the spout and constitutes sliding construction with the fixed pin, change the board and constitute rotating-structure through pivot and back flow, and change the board and closely laminate through draw-in groove and ventilation pipe.

Preferably, the partition board forms a sliding structure with the air inlet through the chuck, and the air inlet fan is fixedly connected with the air inlet.

Preferably, the adsorption layer is fixedly connected with the shell, the purification layer is fixedly connected with the shell, the shell is slidably connected with the ventilation pipe, and the shell is embedded with the clamping block.

The utility model provides a high-efficient intelligent ventilation system processing apparatus in laboratory possesses following beneficial effect: the high-efficiency intelligent ventilation system processing device for the laboratory can repeatedly filter and purify air through the matching of parts of each part until the air reaches the standard and is discharged into the room;

1. the utility model discloses a setting of baffle makes when the device operates, the air inlet fan can inhale the air intake with the outside air and insufflate in the ventilation pipe again, when the air passes through the baffle, the baffle can be isolated with the dust of granule great in the air, avoids dust to cause the influence to the operation of air inlet fan, and because baffle and chuck gomphosis, make the baffle that can relax change and clear up, also can guarantee the steadiness of baffle installation simultaneously;

2. the utility model discloses a setting of filtering component, make when the air current passes through filtering component, the suspended solid in the air can be filtered by the filter plate, then harmful component in the air can be adsorbed by the adsorbed layer, the bacterium killing layer can kill the bacterium that the adsorbed layer adsorbs, when the air passes through the purification layer, the peculiar smell in the air can be got rid of to the purification layer, when filtering component installs in the ventilation pipe, the spring can cooperate the fixture block to fix filtering component firm on the ventilation pipe, and when needing to change filtering component, only need to push the fixture block to both sides can dismantle filtering component;

3. the utility model discloses a setting of backward flow subassembly, make when the air current is through the detector, if detector inspection air quality is unqualified, then the telescopic link promotes the connecting rod downwards, it rotates to drive the commentaries on classics board through spout and fixed pin, commentaries on classics board cooperation draw-in groove seals the vent pipe, the air can only be followed the back flow right-hand member and is got into the back flow, the rethread check valve gets back to in the vent pipe, purify through filter assembly once more, it is qualified until the air quality, then the telescopic link returns back and contracts, seal the back flow right-hand member, the air flows from the vent pipe right-hand member, discharge to indoor, and can the single check valve separation at this in-process air, can't get into the back flow.

Drawings

Fig. 1 is a schematic sectional front view of the present invention;

FIG. 2 is a schematic cross-sectional front view of the reflow module of the present invention;

fig. 3 is a schematic view of the three-dimensional structure of the air inlet of the present invention.

In the figure: 1. an air inlet; 2. a chuck; 3. a partition plate; 4. a fan inlet; 5. a vent pipe; 6. a filter assembly; 601. a housing; 602. filtering the plate; 603. an adsorption layer; 604. a sterilization layer; 605. a purification layer; 7. a card slot; 8. a detector; 9. a reflow assembly; 901. a return pipe; 902. a one-way valve; 903. a telescopic rod; 904. a baffle plate; 905. a connecting rod; 906. a fixing pin; 907. a chute; 908. rotating the plate; 909. a rotating shaft; 10. a spring; 11. and (6) clamping blocks.

Detailed Description

As shown in fig. 1, fig. 2 and fig. 3, a high-efficient intelligent ventilation system processing apparatus in laboratory, including air intake 1 and filter assembly 6, air intake 1 left side fixedly connected with chuck 2, and 2 top gomphosis of chuck are connected with baffle 3, the right-hand fan 4 that is provided with of baffle 3, and the right-hand ventilation pipe 5 that is provided with of air intake fan 4, filter assembly 6 for filtered air sets up inside ventilation pipe 5, draw-in groove 7 has been seted up to ventilation pipe 5 inner wall below, and ventilation pipe 5 top is provided with detector 8, detector 8 top is provided with the backward flow subassembly 9 that is used for the backflow air, ventilation pipe 5 below symmetry fixedly connected with spring 10, and the inboard fixedly connected with fixture block 11 of spring 10, baffle 3 passes through chuck 2 and air intake 1 constitution sliding construction, and air intake fan 4 and air intake 1 fixed connection, through the setting of baffle 3, make when the apparatus operates, air intake fan 4 can inhale air intake 1 into ventilation pipe 5 with the external air again, when the air passes through baffle 3, baffle 3 can be isolated with the great dust of granule in the air, avoid causing the operation influence to the gomphosis 4, and because baffle 3 can be changed easily, make the baffle 3 also can carry out the clearance simultaneously with the installation stability of the clearance.

As shown in fig. 1, the filter assembly 6 includes a housing 601, a filter plate 602, an adsorption layer 603, a sterilization layer 604 and a purification layer 605, the filter plate 602 is fixedly connected in the housing 601, the adsorption layer 603 is arranged on the right of the filter plate 602, the sterilization layer 604 is fixedly connected on the right of the adsorption layer 603, the purification layer 605 is arranged on the right of the sterilization layer 604, the adsorption layer 603 is fixedly connected with the housing 601, the purification layer 605 is fixedly connected with the housing 601, the housing 601 is slidably connected with the ventilation pipe 5, and the housing 601 is embedded with the fixture block 11, by the arrangement of the filter assembly 6, when air flows through the filter assembly 6, suspended matters in the air are filtered by the filter plate 602, harmful components in the air are adsorbed by the adsorption layer 603, the sterilization layer 604 kills bacteria adsorbed by the adsorption layer 603, when the air flows through the purification layer 605, the purification layer 605 can remove peculiar smell in the air, when the filter assembly 6 is installed in the ventilation pipe 5, the spring 10 can be matched with the fixture block 11 to fix the filter assembly 6 on the ventilation pipe 5 stably, and when the filter assembly 6 needs to be replaced, and the filter assembly 6 can be detached only by pushing the fixture block 11 to both sides.

As shown in fig. 1 and fig. 2, the backflow component 9 includes a backflow pipe 901, a check valve 902, a telescopic rod 903, a baffle 904, a connecting rod 905, a fixing pin 906, a sliding slot 907, a rotating plate 908 and a rotating shaft 909, the check valve 902 is fixedly connected to the left end inside the backflow pipe 901, the telescopic rod 903 is fixedly connected to the right end inside the backflow pipe 901, the baffle 904 is disposed outside the telescopic rod 903, the connecting rod 905 is fixedly connected to the lower portion of the telescopic rod 903, the fixing pin 906 is disposed below the connecting rod 905, the sliding slots 907 are symmetrically disposed on the front and rear sides of the fixing pin 906, the rotating plate 908 is fixedly connected to the lower portion of the fixing pin 906, the rotating shaft 909 is fixedly connected to the right end of the rotating plate 908, the left end of the backflow pipe 901 is communicated with the inside of the ventilation pipe 5 through the check valve 902, the right end of the backflow pipe 901 penetrates through the upper portion of the ventilation pipe 5 to be communicated with the inside of the ventilation pipe 5, the baffle 904 is fixedly connected with the backflow pipe 901, and the baffle 904 is tightly attached to the backflow pipe 903, the connecting rod 905 forms a lifting structure with the return pipe 901 through the telescopic rod 903, the connecting rod 905 forms a sliding structure with the fixed pin 906 through the sliding groove 907, the rotating plate 908 forms a rotating structure with the return pipe 901 through the rotating shaft 909, the rotating plate 908 is tightly attached to the ventilation pipe 5 through the clamping groove 7, through the arrangement of the return assembly 9, when air flows through the detector 8, if the air quality is detected by the detector 8 to be unqualified, the telescopic rod 903 pushes the connecting rod 905 downwards, the rotating plate 908 is driven to rotate through the sliding groove 907 and the fixed pin 906, the rotating plate 908 is matched with the clamping groove 7 to seal the ventilation pipe 5, air can only enter the return pipe 901 from the right end of the return pipe 901 and then returns to the ventilation pipe 5 through the one-way valve 902 to be purified again until the air quality is qualified, then the telescopic rod 903 retracts to seal the right end of the return pipe 901, the air flows out from the right end of the ventilation pipe 5 and is discharged to the indoor, and in the process, air is blocked by the one-way valve 902 and cannot enter the return pipe 901.

In conclusion, this high-efficient intelligent ventilation system processing apparatus in laboratory, during the use, at first according to the structure shown in fig. 1, fig. 2 and fig. 3, start into fan 4, air intake fan 4 inhales the air intake 1 in with the external air and blows into ventilation pipe 5 again, when air passes through baffle 3, baffle 3 isolates the dust that the granule is great in the air, avoid dust to cause the influence to the operation of air intake fan 4, and because baffle 3 and chuck 2 gomphosis, make can be light change and clear up baffle 3, can also guarantee the steadiness of baffle 3 installation simultaneously, when air current passes through straining subassembly 6, suspended solid in the air can be filtered by filter plate 602, then harmful component in the air can be adsorbed by adsorption layer 603, sterilization layer 604 can kill the bacterium that adsorption layer 603 adsorbs, when air passes through purification layer 605, purification layer 605 can get rid of the peculiar smell in the air, when the filter assembly 6 is installed in the ventilation pipe 5, the spring 10 can be matched with the fixture block 11 to firmly fix the filter assembly 6 on the ventilation pipe 5, and when the filter assembly 6 needs to be replaced, the filter assembly 6 can be disassembled only by pushing the fixture block 11 towards two sides, when air flows through the detector 8, if the air quality is not qualified through the detection of the detector 8, the telescopic rod 903 pushes the connecting rod 905 downwards, the rotating plate 908 is driven to rotate by the chute 907 and the fixing pin 906, the ventilating pipe 5 is sealed by the rotating plate 908 matched with the clamping groove 7, air can only enter the return pipe 901 from the right end of the return pipe 901, then returns to the ventilation pipe 5 through the one-way valve 902, is purified again through the filter assembly 6 until the air quality is qualified, then the telescopic rod 903 retracts to seal the right end of the return pipe 901, the air flows out from the right end of the ventilation pipe 5 and is discharged to the indoor, and the air can be blocked 902 by the one-way valve in the process, cannot enter the return pipe 901.

Claims (7)

1. A laboratory high-efficiency intelligent ventilation system processing device, which comprises an air inlet (1) and a filter assembly (6), it is characterized in that the left side of the air inlet (1) is fixedly connected with a chuck (2), a partition plate (3) is embedded and connected above the chuck (2), a fan (4) is arranged at the right of the partition plate (3), a ventilation pipe (5) is arranged at the right of the fan (4), the filter assembly (6) for filtering air is arranged inside the ventilation pipe (5), a clamping groove (7) is arranged below the inner wall of the ventilation pipe (5), a detector (8) is arranged above the ventilation pipe (5), a backflow component (9) for backflow air is arranged above the detector (8), springs (10) are symmetrically and fixedly connected below the ventilation pipe (5), and the inner side of the spring (10) is fixedly connected with a fixture block (11), the filter component (6) comprises a shell (601), a filter plate (602), an adsorption layer (603), a sterilization layer (604) and a purification layer (605), the filter plate (602) is fixedly connected in the shell (601), and the right side of the filter plate (602) is provided with an adsorption layer (603), the right side of the adsorption layer (603) is fixedly connected with a sterilization layer (604), and the right side of the sterilization layer (604) is provided with a purification layer (605).

2. The device for processing the laboratory high-efficiency intelligent ventilation system according to claim 1, wherein the backflow component (9) comprises a backflow pipe (901), a one-way valve (902), a telescopic rod (903), a baffle (904), a connecting rod (905), a fixing pin (906), a sliding chute (907), a rotating plate (908) and a rotating shaft (909), the one-way valve (902) is fixedly connected to the left end inside the backflow pipe (901), the telescopic rod (903) is fixedly connected to the right end inside the backflow pipe (901), the baffle (904) is arranged on the outer side of the telescopic rod (903), the connecting rod (905) is fixedly connected to the lower portion of the telescopic rod (903), the fixing pin (906) is arranged below the connecting rod (905), the sliding chutes (907) are symmetrically formed in the front and rear sides of the fixing pin (906), the rotating plate (908) is fixedly connected to the lower portion of the fixing pin (906), and the rotating shaft (909) is fixedly connected to the right end of the rotating plate (908).

3. The processing device for the laboratory high-efficiency intelligent ventilating system according to claim 2, wherein the left end of the return pipe (901) is communicated with the inside of the ventilating pipe (5) through a one-way valve (902), and the right end of the return pipe (901) is communicated with the inside of the ventilating pipe (5) through the upper part of the ventilating pipe (5).

4. The processing device of the laboratory high-efficiency intelligent ventilation system as claimed in claim 2, wherein the baffle plate (904) is fixedly connected with the return pipe (901), and the baffle plate (904) is tightly attached to the telescopic rod (903).

5. The processing device of the laboratory high-efficiency intelligent ventilation system as claimed in claim 2, wherein the connecting rod (905) and the return pipe (901) form a lifting structure through a telescopic rod (903), the connecting rod (905) and the fixing pin (906) form a sliding structure through a sliding chute (907), the rotating plate (908) and the return pipe (901) form a rotating structure through a rotating shaft (909), and the rotating plate (908) is tightly attached to the ventilation pipe (5) through a clamping groove (7).

6. The processing device of the laboratory high-efficiency intelligent ventilation system as claimed in claim 1, wherein the partition plate (3) and the air inlet (1) form a sliding structure through the chuck (2), and the air inlet fan (4) is fixedly connected with the air inlet (1).

7. The laboratory high-efficiency intelligent ventilation system processing device as claimed in claim 1, wherein the adsorption layer (603) is fixedly connected with the housing (601), the purification layer (605) is fixedly connected with the housing (601), the housing (601) is slidably connected with the ventilation pipe (5), and the housing (601) is embedded with the fixture block (11).

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