CN216093509U - Disinfectant production is with ration accuse material device - Google Patents

Abstract

The utility model relates to the technical field of disinfectant production, in particular to a quantitative material control device for disinfectant production. According to the utility model, disinfectant is added into the square through pipe from the feed inlet, the disinfectant enters the upper part of the closed plate through the plurality of filter bags and the two gaps and floats up the floating plate, at the moment, the two rotating plates are inclined and the two rotating blocks are parallel, then the side plate on one side of the two rotating plates is pulled when the floating plate moves to the upper part of the square through pipe, the two rotating plates rotate oppositely and are arranged in parallel to seal the top end of the square through pipe, the two rotating plates rotate to drive the two vertical rods to move downwards, the bayonets of the two vertical rods are clamped by the adjacent clamping blocks, and the two support plates on the two rotating blocks are pushed by the two vertical rods to rotate oppositely, so that the bottom end of the square through pipe is smooth, and the disinfectant is filtered and then quantitatively flows out of the barrel body.

Description

Disinfectant production is with ration accuse material device

Technical Field

The utility model relates to the technical field of disinfectant production, in particular to a quantitative material control device for disinfectant production.

Background

Most of the disinfectant is liquid, in the actual production process, different concentrations can be generated according to different requirements, for example, common seventy-five percent ethanol disinfectant, ninety-five percent ethanol disinfectant and other disinfectant with various concentrations can be mixed through proportioning in general production, and then disinfectant with the same concentration is generated.

SUMMERY OF THE UTILITY MODEL

In order to overcome the technical problems, the utility model aims to provide a quantitative material control device for disinfectant production, disinfectant is added into a square through pipe from a feed inlet, the disinfectant enters the upper part of a sealing plate through a plurality of filter bags and floats upwards through two gaps, at the moment, two rotating plates are inclined and two rotating blocks are parallel, then a side plate on one side of the two rotating plates is pulled when the floating plate moves to the upper part of the square through pipe, the two rotating plates rotate oppositely and are arranged in parallel to seal the top end of the square through pipe, the two rotating plates rotate to drive two vertical rods to move downwards, bayonets of the two vertical rods are clamped by adjacent clamping blocks, support plates on the two rotating blocks are pushed by the two vertical rods to enable the two support plates to rotate oppositely, so that the bottom end of the square through pipe is smooth, and the disinfectant is filtered and then quantitatively flows out of a barrel body.

The purpose of the utility model can be realized by the following technical scheme:

a quantitative material control device for disinfectant production comprises a barrel body, wherein a feed inlet is formed in the center of the top end of the barrel body, a barrel cover is screwed at the bottom end of the barrel body, a discharge outlet is formed in the center of the barrel cover, a square through pipe is fixedly connected below the feed inlet on the inner top surface of the barrel body, the bottom end of the square through pipe is positioned on the top surface of the barrel cover, rectangular holes are formed in the top end and the bottom end of two opposite side walls of the square through pipe, an opening and closing mechanism for controlling the opening and closing of the top end and the bottom end of the square through pipe is arranged between the two rectangular holes on the same side wall of the square through pipe, a sealing plate is sleeved at the bottom end of the square through pipe in a sliding manner, two extension springs are symmetrically and fixedly connected to the top surface of the sealing plate, floating plates are fixedly connected to the top ends of the two extension springs, notches are formed in the two opposite side walls of the square through pipe and positioned above the floating plates, and clamping mechanisms for fixing the adjacent opening and closing mechanisms are arranged in the two notches, the inside a plurality of filter bags that are located breach top fixedly connected with of square tube, through with the antiseptic solution through the feed inlet add the square tube inside, square tube bottom this moment is sealed by two operating mechanism, and the top is opened, then the antiseptic solution filters through a plurality of filter bags and gets into inside the staving through the breach, be located the closure plate top, the antiseptic solution utilizes buoyancy to hold up the kickboard, the tensile extension spring of kickboard, then treat that the kickboard drives two operating mechanism and makes the square tube top seal when the kickboard floats to the square tube top, the bottom is opened, then make the inside antiseptic solution ration of staving follow two breachs and locate the outflow from square tube bottom, thereby make the antiseptic solution through filtering then ration outflow staving, then screw down the bung again, wash the staving with the antiseptic solution that clear water and utilize the staving inside to store up, be convenient for clear up the staving.

Further, the method comprises the following steps: the opening and closing mechanism comprises a rotating plate, the rotating plate is positioned at the top end of the square through pipe, the top end of one side of the rotating plate and the bottom end of the other side of the rotating plate are fixedly connected with side plates, the bottom end of the rotating plate is rotatably connected with the bottom end of an adjacent rectangular groove through a rotating shaft, two ends of the rotating shaft are movably sleeved with torsional springs, one end of each torsional spring is fixedly connected with the end part of the adjacent rotating shaft, the other end of each torsional spring is fixedly connected with the side wall of the adjacent rectangular groove, a rotating block is arranged at the bottom end of the square through pipe, a support plate is fixedly connected with the top end of one side of the rotating block, the top end of the rotating block is rotatably connected with the top end of the adjacent rectangular hole, a vertical rod is arranged in the square through pipe, one end of the vertical rod is rotatably connected with one end of the side plate of the other side of the rotating plate, the other end of the vertical rod is rotatably connected with one end of the support plate at one side of the rotating block, one side of the vertical rod is provided with a bayonet, and the bayonet is movably clamped with an adjacent clamping mechanism, the disinfectant enters the upper part of the closed plate through the two gaps, then the disinfectant is added to enable the floating plate to float, at the moment, the rotating plates on the two opening and closing mechanisms are in an inclined state, a space is generated between the side plates at the bottom ends of the other sides of the two rotating plates, the aperture of the feeding hole is smaller than the width of the space, so that the disinfectant can pass through the top end of the square pipe and can not flow into the barrel body, the two rotating blocks are parallel, the support plates at one sides of the two rotating blocks are arranged in parallel, so that the two support plates seal the bottom end of the square pipe, then the floating plate moves to the upper part of the square pipe, the floating plate pulls the side plates at one sides of the two rotating plates to enable the two rotating plates to rotate in opposite directions and to be arranged in parallel, at the moment, the side plates at the other sides of the two rotating plates are arranged in parallel and seal the top end of the square pipe, meanwhile, the two rotating plates drive the two vertical rods to move downwards, so that the bayonets on the two vertical rods are clamped on the adjacent clamping and fixing mechanisms, the support plates on the two rotating blocks are pushed open by the two vertical rods, the two support plates rotate in a back-to-back mode, so that the bottom end of the square pipe is smooth, the disinfectant in the barrel body is quantified and then flows out of the barrel body, the floating plate is pulled back to reset by the descending disinfectant horizontal plane and the stretching spring, the floating plate stirs the two clamping and fixing mechanisms when resetting, bayonets on the two vertical rods are separated from the adjacent clamping and fixing mechanisms, and then the two rotating plates automatically reset under the action of the torsion spring.

Further, the method comprises the following steps: the length of the vertical rods is larger than the distance between the two rectangular holes in the same side wall of the square through pipe, so that when the side plates on the other sides of the two rotating plates are parallel, the two vertical rods can enable the supporting plates on the two rotating blocks to rotate back to back due to the length, the two supporting plates are opened, and the bottom end of the square through pipe is opened.

Further, the method comprises the following steps: the diameter of the floating plate is smaller than the inner diameter of the barrel body, so that disinfectant flowing out of the gap can flow downwards from the edge of the floating plate and flow to the upper part of the closing plate.

Further, the method comprises the following steps: the diameter of the sealing plate is equal to the inner diameter of the barrel body, so that disinfectant cannot leak from the sealing plate, and disinfectant in the barrel body is completely positioned above the sealing plate.

Further, the method comprises the following steps: the inner side wall of the barrel body is fixedly connected with a limiting ring above the sealing plate, so that the sealing plate is prevented from moving excessively due to the fact that the sealing plate is stirred by the block structures on the other sides of the two rotating blocks, and the moving distance of the sealing plate is limited.

Further, the method comprises the following steps: the clamping mechanism comprises clamping blocks, the positions of the middle parts of the clamping blocks, which are close to one ends, are rotatably connected inside the notches through rotating shafts, the other ends of the bottom surfaces of the clamping blocks are fixedly connected with rebound springs, the other ends of the rebound springs are fixedly connected to the inner wall of the square through pipe, the other ends of the clamping blocks are movably clamped inside the adjacent bayonets, when the floating plate moves upwards, the floating plate stirs the two clamping blocks, one ends of the two clamping blocks rotate upwards to bend the two rebound springs, then when the two vertical rods move downwards, the bayonets on the two vertical rods clamp the other ends of the clamping blocks, then liquid flows out of the two notches, and then the floating plate descends, the torsional springs on the two rotating plates can reset the two rotating plates, but the two rotating plates cannot reset due to the fact that the two rebound springs are pulled, until the floating plate stirs the two clamping blocks through the self weight, the tensile force of the two tensile springs and the adsorption force with the water surface, make two fixture blocks stretch adjacent resilience spring, make two vertical poles break away from the fixture block, then two rotor plates reset, make square-tube top open once more, the bottom is closed once more.

Further, the method comprises the following steps: the vertical rods on the two opening and closing mechanisms penetrate through the filter bags and are fixedly connected with the filter bags, so that the filter bags can be turned over when the vertical rods move, impurities are shaken, and disinfectant possibly stored in the vertical rods flows down.

The utility model has the beneficial effects that:

disinfectant is added into the square through a feed port, the disinfectant enters the upper part of the closed plate through the two gaps, then the disinfectant is added to enable the floating plate to float, at the moment, the rotating plates on the two opening and closing mechanisms are in an inclined state, the disinfectant can pass through the top end of the square through pipe and can not flow into the barrel body, the two rotating blocks are parallel, the two supporting plates seal the bottom end of the square through pipe, then the floating plate is moved to the upper part of the square through pipe, the floating plate pulls the side plates on one side of the two rotating plates, the two rotating plates rotate oppositely and are arranged in parallel, at the moment, the side plates on the other sides of the two rotating plates are distributed in parallel and seal the top end of the square through pipe, simultaneously, the two rotating plates drive the two vertical rods to move downwards when rotating, the bayonet on the two vertical rods are clamped on adjacent clamping blocks, the two vertical rods push the supporting plates on the two rotating blocks, the two supporting plates rotate oppositely, and accordingly the bottom end of the square through pipe is unblocked, at the moment, the disinfectant in the barrel body is quantified and then flows out of the barrel body, so that the disinfectant is filtered and then quantitatively flows out of the barrel body.

Drawings

The utility model will be further described with reference to the accompanying drawings.

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

FIG. 2 is a schematic view of the inner structure of the barrel body according to the present invention;

FIG. 3 is an enlarged partial view of the utility model at A;

FIG. 4 is a schematic view of the bottom end structure of the square tube of the present invention;

FIG. 5 is a schematic cross-sectional view of the inside of the barrel body according to the present invention;

FIG. 6 is an enlarged partial view of the utility model at B;

FIG. 7 is a schematic view of a bayonet configuration according to the present invention;

FIG. 8 is a schematic view of the construction of the rotating plate according to the present invention;

fig. 9 is a schematic view of the structure of the turning block in the present invention.

In the figure: 100. a barrel body; 110. a limiting ring; 200. a square through pipe; 201. a notch; 210. a closing plate; 220. a floating plate; 230. an extension spring; 300. an opening and closing mechanism; 310. a rotating plate; 320. rotating the block; 330. a vertical rod; 400. a clamping mechanism; 410. a clamping block; 420. a rebound spring; 500. and (5) filtering the bags.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-9, a quantitative material control device for disinfectant production comprises a barrel 100, a feed inlet is disposed at the center of the top end of the barrel 100, a barrel cover is screwed at the bottom end of the barrel 100, a discharge outlet is disposed at the center of the barrel cover, a square tube 200 is fixedly connected to the top surface of the barrel 100 below the feed inlet, the bottom end of the square tube 200 is disposed at the top surface of the barrel cover, rectangular holes are disposed at the top and bottom ends of two opposite side walls of the square tube 200, an opening and closing mechanism 300 for opening and closing the top and bottom ends of the square tube 200 is disposed between two rectangular holes disposed at the same side wall of the square tube 200, a sealing plate 210 is slidably sleeved at the bottom end of the square tube 200, two extension springs 230 are symmetrically and fixedly connected to the top surface of the sealing plate 210, a floating plate 220 is fixedly connected to the top ends of the two extension springs 230, and a gap 201 is disposed above the floating plate 220 on two opposite side walls of the square tube 200, the clamping and fixing mechanisms 400 for fixing the adjacent opening and closing mechanisms 300 are arranged in the two gaps 201, a plurality of filter bags 500 are fixedly connected to the inner part of the square tube 200 above the gaps 201, disinfectant is added into the square tube 200 through a feed inlet, the bottom end of the square tube 200 is closed by the two opening and closing mechanisms 300 at the moment, the top end of the square tube is opened, the disinfectant is filtered through the filter bags 500 and enters the barrel body 100 through the gaps 201 and is positioned above the closing plate 210, the disinfectant lifts up the floating plate 220 by buoyancy, the floating plate 220 stretches the tension spring 230, the floating plate 220 drives the two opening and closing mechanisms 300 to close the top end and open the bottom end of the square tube 200 when the floating plate 220 floats to the top end of the square tube 200, then the disinfectant in the barrel body 100 quantitatively flows out from the bottom ends of the square tube 200 through the two gaps 201, so that the disinfectant quantitatively flows out of the barrel body 100 after being filtered, and then the barrel cover is screwed down, the tub 100 is flushed with clean water and disinfectant stored inside the tub 100, so that the tub 100 is conveniently cleaned.

The opening and closing mechanism 300 comprises a rotating plate 310, the rotating plate 310 is positioned at the top end of the square through pipe 200, the top end of one side of the rotating plate 310 and the bottom end of the other side of the rotating plate 310 are fixedly connected with side plates, the bottom end of the rotating plate 310 is rotatably connected with the bottom end of an adjacent rectangular groove through a rotating shaft, both ends of the rotating shaft are movably sleeved with torsion springs, one end of each of the two torsion springs is fixedly connected with the end part of the adjacent rotating shaft, the other end of each of the two torsion springs is fixedly connected with the side wall of the adjacent rectangular groove, the bottom end of the square through pipe 200 is provided with a rotating block 320, the top end of one side of the rotating block 320 is rotatably connected with the top end of the adjacent rectangular hole, a vertical rod 330 is arranged in the square through pipe 200, one end of the vertical rod 330 is rotatably connected with one end of the side plate of the other side of the rotating plate 310, the other end of the rotating block 320 is rotatably connected with one end of the support plate, one side of the vertical rod 330 is provided with a bayonet, and the bayonet is movably clamped with the adjacent clamping mechanism 400, disinfectant enters the upper part of the closing plate 210 through the two notches 201, then the disinfectant is added to enable the floating plate 220 to float, at the moment, the rotating plates 310 on the two opening and closing mechanisms 300 are in an inclined state, a space is generated between the side plates at the bottom ends of the other sides of the two rotating plates 310, the aperture of the feeding hole is smaller than the width of the space, so that the disinfectant can pass through the top end of the square pipe 200 and can not flow into the barrel body 100, the two rotating blocks 320 are parallel, the support plates at one sides of the two rotating blocks 320 are arranged in parallel, so that the two support plates close the bottom end of the square pipe 200, then the floating plate 220 moves to the upper part of the square pipe 200, the floating plate 220 pulls the side plates at one sides of the two rotating plates 310 to enable the two rotating plates 310 to rotate oppositely and be arranged in parallel, at the moment, the side plates at the other sides of the two rotating plates 310 are arranged in parallel and close the top end of the square pipe 200, and simultaneously the two rotating plates 310 drive the two vertical rods 330 to move downwards when rotating plates 310 rotate, the bayonets on the two vertical rods 330 are clamped on the adjacent clamping mechanisms 400, the two vertical rods 330 push open the support plates on the two rotating blocks 320, the two support plates rotate oppositely, so that the bottom end of the square tube 200 is smooth, the disinfectant in the barrel body 100 is quantified and then flows out of the barrel body 100, the floating plate 220 is pulled back to reset by the descending disinfectant horizontal plane and the stretching spring 230, the floating plate 220 stirs the two clamping mechanisms 400 when resetting, the bayonets of the two vertical rods 330 are separated from the adjacent clamping mechanisms 400, and then the two rotating plates 310 automatically reset under the action of the torsion spring.

The length of the vertical rod 330 is greater than the distance between the two rectangular holes on the same side wall of the square through pipe 200, so that when the side plates on the other sides of the two rotating plates 310 are parallel, the two vertical rods 330 can enable the support plates on the two rotating blocks 320 to rotate away from each other due to the length, so that the two support plates are opened, and the bottom end of the square through pipe 200 is opened; the diameter of the floating plate 220 is smaller than the inner diameter of the barrel body 100, so that the disinfectant flowing out of the gap 201 can flow downwards from the edge of the floating plate 220 and flow to the upper part of the closing plate 210; the diameter of the closing plate 210 is equal to the inner diameter of the barrel body 100, so that disinfectant cannot leak from the closing plate 210, and disinfectant in the barrel body 100 is completely positioned above the closing plate 210; the limiting ring 110 is fixedly connected to the inner side wall of the barrel 100 above the closing plate 210, so that the closing plate 210 is prevented from moving excessively due to shifting of the closing plate 210 by the block-shaped structure on the other side of the two rotating blocks 320, and the moving distance of the closing plate 210 is limited; the fastening mechanism 400 includes a fastening block 410, a position near one end of the middle of the fastening block 410 is rotatably connected to the inside of the notch 201 through a rotating shaft, the other end of the bottom surface of the fastening block 410 is fixedly connected with a resilient spring 420, the other end of the resilient spring 420 is fixedly connected to the inner wall of the square tube 200, and the other end of the fastening block 410 is movably fastened to the inside of the adjacent notch, when the floating plate 220 moves upwards, the floating plate 220 pulls the two fastening blocks 410, so that one end of each of the two fastening blocks 410 rotates upwards, so that the two resilient springs 420 bend, then when the two vertical rods 330 move downwards, the notches on the two vertical rods 330 clamp the other end of the fastening block 410, and then the liquid flows out from the two notches 201, the floating plate 220 descends, the torsion springs on the two rotating plates 310 can reset, but the two rotating plates 310 cannot reset because the two resilient springs 420 pull, until the floating plate 220 pulls the two fastening blocks 410 by the self weight, the pulling force of the two extension springs 230 and the adsorption force of the water surface, the two fixture blocks 410 stretch the adjacent rebound springs 420, so that the two vertical rods 330 are separated from the fixture blocks 410, and then the two rotating plates 310 are reset, so that the top ends of the square tubes 200 are opened again, and the bottom ends of the square tubes are closed again; the vertical rods 330 on the two opening and closing mechanisms 300 penetrate through the filter bags 500 and are fixedly connected with the filter bags 500, so that the filter bags 500 can be turned over by the vertical rods 330 during movement, impurities can shake, and disinfectant possibly accumulated in the filter bags can flow down.

The working principle is as follows: when the sterilizing device is used, sterilizing liquid is added into the square through pipe 200 through the feed port, the rotating plates 310 on the two opening and closing mechanisms 300 are in an inclined state, a space is formed between the side plates at the bottom ends of the other sides of the two rotating plates 310, so that the sterilizing liquid passes through, the support plates at one sides of the two rotating blocks 320 are arranged in parallel, so that the two support plates close the bottom end of the square through pipe 200, then the sterilizing liquid is filtered by the filter bags 500 and flows to the floating plate 220 through the two gaps 201, then the sterilizing liquid is left from the floating plate 220 to enter the barrel body 100 and is positioned above the closing plate 210, then the sterilizing liquid is continuously added to enable the floating plate 220 to float upwards, when the floating plate 220 moves to the upper side of the square through pipe 200, the two fixture blocks 410 of the floating plate 220 are stirred, one ends of the two fixture blocks 410 are enabled to rotate upwards, so that the two rebound springs 420 are bent, then the floating plate 220 continuously ascends to pull the side plates at one sides of the two rotating plates 310, so that the two rotating plates 310 rotate oppositely and are arranged in parallel, at this time, the side plate at the other side of the two rotating plates 310 is distributed in parallel and seals the top end of the square tube 200, and simultaneously the two rotating plates 310 drive the two vertical rods 330 to move downwards when rotating, so that the bayonets on the two vertical rods 330 block the other ends of the adjacent clamping blocks 410, and then the liquid flows out from the two gaps 201, the two vertical rods 330 prop the support plates on the two rotating blocks 320, so that the two support plates rotate oppositely, so that the bottom end of the square tube 200 is unblocked, and the two rotating blocks 320 can make the block-shaped bulges at the other side of the two rotating blocks 320 to make the closing plate 210 ascend, so that the closing plate 210 props against the limiting ring 110, and simultaneously the vertical rods 330 can turn over the filter bags 500 when moving, so that impurities shake, so that the disinfection liquid possibly accumulated inside can flow down, and then after the liquid flows out of the barrel from the bottom end of the square tube 200 through the two gaps 201, the inside of the barrel 100 can retain part of the disinfection liquid, and then the floating plate 220 descends along with the descending of the horizontal plane of the disinfection liquid inside the barrel 100, the torsion springs on the two rotating plates 310 can reset the two rotating plates 310, but the two rotating plates 310 cannot be reset due to the pulling of the two rebound springs 420, until the floating plate 220 shifts the two fixture blocks 410 under the self weight, the pulling force of the two extension springs 230 and the adsorption force with the water surface, the two fixture blocks 410 stretch the adjacent rebound springs 420, the two vertical rods 330 are separated from the fixture blocks 410, then the two rotating plates 310 reset, the top ends of the square through pipes 200 are opened again, and the bottom ends of the square through pipes are closed again;

when the barrel body 100 needs to be cleaned, the barrel cover can be directly unscrewed, then the sealing plate 210 is taken down, the disinfectant stored in the barrel body 100 is utilized, and a water gun is matched to be used for flushing the interior of the barrel body 100 and the interior of the square through pipe 200, so that the interior of the barrel body 100 and the interior of the rear through pipe 200 can be flushed and disinfected.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is illustrative and explanatory only and is not intended to be exhaustive or to limit the utility model to the precise embodiments described, and various modifications, additions, and substitutions may be made by those skilled in the art without departing from the scope of the utility model as defined in the following claims.

Claims (8)

1. A quantitative material control device for disinfectant production comprises a barrel body (100) and is characterized in that a feed inlet is formed in the center of the top end of the barrel body (100), a barrel cover is screwed at the bottom end of the barrel body (100), a discharge outlet is formed in the center of the barrel cover, a square through pipe (200) is fixedly connected below the feed inlet on the inner top surface of the barrel body (100), the bottom end of the square through pipe (200) is located on the top surface of the barrel cover, rectangular holes are formed in the top end and the bottom end of two opposite side walls of the square through pipe (200), an opening and closing mechanism (300) for controlling the opening and closing of the top end and the bottom end of the square through pipe (200) is arranged between the two rectangular holes in the same side wall of the square through pipe (200), a sealing plate (210) is sleeved at the bottom end of the square through pipe in a sliding mode, two extension springs (230) are symmetrically and fixedly connected to the top surface of the sealing plate (210), and a floating plate (220) is fixedly connected to the top ends of the two extension springs (230), the square through pipe is characterized in that notches (201) are formed in the two opposite side walls of the square through pipe (200) and located above the floating plate (220), clamping and fixing mechanisms (400) used for fixing adjacent opening and closing mechanisms (300) are arranged in the two notches (201), and a plurality of filter bags (500) are fixedly connected to the upper portions of the notches (201) in the square through pipe (200).

2. The quantitative material control device for disinfectant production according to claim 1, wherein the open-close mechanism (300) comprises a rotating plate (310), the rotating plate (310) is located at the top end of the square tube (200), the top end of one side of the rotating plate (310) and the bottom end of the other side of the rotating plate are both fixedly connected with side plates, the bottom end of the rotating plate (310) is rotatably connected to the bottom end of the adjacent rectangular groove through a rotating shaft, torsion springs are movably sleeved at both ends of the rotating shaft, one end of each torsion spring is fixedly connected to the end part of the adjacent rotating shaft, the other end of each torsion spring is fixedly connected to the side wall of the adjacent rectangular groove, a rotating block (320) is arranged at the bottom end of the square tube (200), a support plate is fixedly connected to the top end of one side of the rotating block (320), the top end of the rotating block (320) is rotatably connected to the top end of the adjacent rectangular hole, a vertical rod (330) is arranged inside the square tube (200), one end of the vertical rod (330) is rotatably connected with one end of a side plate at the other side of the rotating plate (310), the other end of the vertical rod is rotatably connected with one end of a support plate at one side of the rotating block (320), one side of the vertical rod (330) is provided with a bayonet, and the bayonet is movably clamped with the adjacent clamping mechanism (400).

3. A quantitative control device for disinfectant production according to claim 2, wherein the length of the vertical rod (330) is greater than the distance between two rectangular holes on the same side wall of the square tube (200).

4. A quantitative control device for disinfectant production, according to claim 1, characterized in that said floating plate (220) has a diameter smaller than the inner diameter of the barrel body (100).

5. A dosing and control device for disinfectant production according to claim 1, characterized in that said closing plate (210) has a diameter equal to the internal diameter of the tub (100).

6. The quantitative material control device for disinfectant production according to claim 1, wherein the inner sidewall of the barrel body (100) is fixedly connected with a spacing ring (110) above the closing plate (210).

7. The quantitative material control device for disinfectant production as claimed in claim 2, wherein said clamping mechanism (400) comprises a clamping block (410), the middle portion of said clamping block (410) is connected to the inside of the notch (201) through a rotating shaft, the position near one end of the middle portion of the clamping block (410) is connected to the inside of the notch (201) in a rotating manner, the other end of the bottom surface of the clamping block (410) is fixedly connected to a rebound spring (420), the other end of the rebound spring (420) is fixedly connected to the inner wall of the square tube (200), and the other end of the clamping block (410) is movably clamped to the inside of the adjacent notch.

8. The quantitative material control device for disinfectant production according to claim 1, wherein the vertical rods (330) of the two opening and closing mechanisms (300) penetrate through the plurality of filter bags (500) and are fixedly connected with the plurality of filter bags (500).

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