CN111825194A - Acidity detection processing apparatus of acid pollution water source - Google Patents

Abstract

The invention discloses an acidity detection processing device of an acidic polluted water source, which comprises a detection processing shell, a working cavity is arranged in the detection processing shell, a reaction container is fixedly arranged on the inner wall of the rear side of the working cavity, the reaction vessel is internally provided with a reaction cavity, the reaction cavity is internally provided with a liquid level control assembly, the liquid level control assembly comprises a linkage through hole which is arranged on the inner wall of the right side of the reaction cavity and communicated with the working cavity, and two linkage sliding chutes which are symmetrically arranged on the inner wall of the right side of the reaction cavity up and down relative to the linkage through hole, the invention can automatically control the amount of sewage entering the reaction cavity and the amount of saturated sodium carbonate solution entering the reaction cavity according to the liquid level in the reaction cavity, therefore, the precision of data in each detection process is guaranteed, the whole detection process can be automatically completed, the possibility of direct contact of experimenters is reduced, and the potential safety hazard of acid sewage to experimenters is reduced.

Description

Acidity detection processing apparatus of acid pollution water source

Technical Field

The invention relates to the technical field of polluted water source detection, in particular to an acidity detection processing device for an acidic polluted water source.

Background

Acidic wastewater is the most common wastewater in all industrial wastewater, and if discharged without recycling and necessary treatment, it will severely corrode pipelines, channels and hydraulic structures. However, the acidity of different water sources is different, and before a large amount of acidic sewage is treated, sampling is often required to detect the acidity, and the usage amount of a neutralizer is determined. Generally, the detection is carried out in a manual mode, but the manual mode not only means that a laboratory technician is likely to directly contact the acidic sewage and has certain potential safety hazard, but also the manual mode often has larger errors.

Disclosure of Invention

The invention aims to provide an acidity detection and treatment device for an acidic polluted water source, which is used for overcoming the defects in the prior art.

The acidity detection processing device for the acidic polluted water source comprises a detection processing shell, wherein a working cavity is arranged in the detection processing shell, a reaction container is fixedly arranged on the inner wall of the rear side of the working cavity, a reaction cavity is arranged in the reaction container, a liquid level control assembly is arranged in the reaction cavity, the liquid level control assembly comprises a linkage through hole which is arranged on the inner wall of the right side of the reaction cavity and communicated with the working cavity, two linkage sliding chutes which are vertically and symmetrically arranged on the inner wall of the right side of the reaction cavity relative to the linkage through hole, a sliding plate which is slidably connected with the linkage sliding chutes and extends into the linkage through hole, a first spring which is connected with the sliding plate and one end of the linkage sliding chute, which is far away from the symmetric center, a floating block which is fixedly arranged at the lower end of an upper sliding plate and fixedly connected with the upper end of a lower, still be equipped with waste water and get into the subassembly in the work chamber, still be equipped with detection components in the work chamber.

Preferably, a motor is fixedly arranged on the inner wall of the lower side of the working cavity, and a first transmission shaft which extends upwards to the inner wall of the upper side of the working cavity is connected to the upper end of the motor in a power mode.

Preferably, the inner wall of the lower side of the reaction cavity is provided with a sealing plug.

Wherein, the liquid level control component also comprises a power supply which is fixedly arranged at the right end of the reaction vessel, an electric wire is connected between the positive electrode contact of the power supply and the floating block, an auxiliary electromagnet is fixedly arranged on the inner wall of the left side of the working chamber, an electric wire is connected between the positive electrode contact of the auxiliary electromagnet and the lower end contact of the resistor, an electric wire is connected between the negative electrode contact of the power supply and the negative electrode contact of the auxiliary electromagnet, a rotating shaft support which extends rightwards is fixedly arranged on the inner wall of the left side of the working chamber, the rotating shaft support is rotationally connected with the first transmission shaft, the left end of the reaction vessel is provided with a horizontal sliding support which is positioned at the upper side of the rotating shaft support and can slide up and down, a through hole which is through up and down is arranged in the horizontal sliding support, the first transmission shaft is positioned in the through hole, a, a second spring is connected between the sliding magnetic support and the main electromagnet, a second transmission shaft which extends leftwards and rightwards is rotatably connected to the sliding magnetic support, a first bevel gear is fixedly arranged on the second transmission shaft which is positioned on the left side of the sliding magnetic support, a linkage magnetic support which can slide upwards and downwards and is positioned on the lower side of the auxiliary electromagnet is arranged on the inner wall of the left side of the working cavity, a third spring is connected between the linkage magnetic support and the rotating shaft support, a connecting support which is fixedly connected with the upper end of the horizontal sliding support is fixedly arranged at the right end of the linkage magnetic support, a third transmission shaft which extends upwards and downwards and is connected with a spline of the first transmission shaft is rotatably connected to the connecting support, a second bevel gear which can be meshed with the first bevel gear is fixedly arranged on the third transmission shaft which is positioned on the upper side of the connecting support, and a driving friction wheel is fixedly arranged on the first transmission shaft which is positioned between the horizontal sliding, rotate on the pivot support to be connected with and be located the fourth transmission shaft that first transmission shaft right side and mountain extend is located pivot support upside the pivot support on set firmly with the driven friction pulley of initiative friction pulley friction connection, be equipped with in the horizontal slip support and be located the perforating hole right side and with the communicating cooperation groove of working chamber, cooperation inslot wall sliding connection has downwardly extending to the cooperation slider in the working chamber, the cooperation slider with be connected with the fourth spring between the cooperation groove upside inner wall, cooperation slider lower extreme rotate be connected with downwardly extending and with fourth transmission shaft splined connection's fifth transmission shaft.

Wherein, the waste water entering assembly comprises a valve body fixedly arranged on the inner wall of the rear side of the working cavity, a valve cavity is arranged in the valve body, an input pipeline is connected between the valve cavity and an external polluted water source, an output pipeline is connected between the valve cavity and the reaction cavity, the inner wall of the upper side of the valve cavity is rotatably connected with a sixth transmission shaft which upwards extends into the working cavity, a valve ball is fixedly arranged on the sixth transmission shaft which is positioned in the valve cavity, a valve body through hole is arranged in the valve ball, a gear is fixedly arranged on the sixth transmission shaft which is positioned in the working cavity, an auxiliary coupler which is positioned on the upper side of the gear is fixedly arranged on the sixth transmission shaft, a sliding rack which can slide left and right is arranged on the inner wall of the rear side of the working cavity, a fifth spring is connected between the sliding rack and the left end of the reaction container, and the front end of, and a main coupler which can be matched and connected with the auxiliary coupler is fixedly arranged on the fifth transmission shaft positioned on the lower side of the rotating shaft support.

Wherein, the detection component comprises a spring support fixedly arranged on the inner wall of the left side of the reaction cavity, the inner wall of the reaction cavity is connected with a piston in a sliding manner, a sixth spring is connected between the piston and the spring support, a fixed rod is fixedly arranged at the upper end of the piston, a connecting rod extending rightwards is fixedly arranged at the upper end of the fixed rod, a scale extending downwards is fixedly arranged at the right end of the connecting rod, a chute which is run through from top to bottom is arranged on the piston, a connecting pipeline extending downwards into the reaction cavity through the chute is fixedly arranged on the inner wall of the upper side of the working cavity, the connecting pipeline extends upwards to the outside, a liquid discharge funnel is fixedly arranged at the upper end of the connecting pipeline positioned outside, a connecting cavity is arranged in the connecting pipeline, a baffle chute communicated with the working cavity is arranged on the inner wall of the left side of the connecting cavity, and, a fixed support is fixedly arranged at the lower end of the sliding baffle plate positioned in the working cavity, a seventh spring is connected between the fixed support and the connecting pipeline, a seventh transmission shaft positioned on the upper side of the sliding baffle plate is rotatably connected to the inner wall of the rear side of the working cavity, a matching friction wheel in friction connection with the upper end of the sliding baffle plate is fixedly arranged on the seventh transmission shaft, a third bevel gear positioned on the front side of the matching friction wheel is fixedly arranged on the seventh transmission shaft, a fourth bevel gear capable of being meshed and connected with the third bevel gear is fixedly arranged on the second transmission shaft, an eighth transmission shaft extending upwards into the reaction cavity is rotatably connected to the inner wall of the lower side of the working cavity, a stirring piece is fixedly arranged on the eighth transmission shaft positioned in the reaction cavity, a secondary belt wheel is fixedly arranged on the eighth transmission shaft positioned in the working cavity, and a main belt wheel is fixedly arranged on the first transmission shaft, a belt is connected between the main belt wheel and the auxiliary belt wheel.

The invention has the beneficial effects that: the invention can automatically control the amount of sewage entering the reaction cavity and the amount of saturated sodium carbonate solution entering the reaction cavity according to the liquid level in the reaction cavity, thereby ensuring the data precision in each detection treatment, automatically completing the whole detection process, reducing the possibility of direct contact of experimenters and reducing the potential safety hazard of acid sewage to experimenters.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic diagram of the overall structure of an acidity detection processing device for an acidic polluted water source according to the present invention;

FIG. 2 is a schematic enlarged view of the structure of "A" of FIG. 1;

FIG. 3 is a schematic enlarged view of the structure of "B" of FIG. 1;

fig. 4 is a schematic enlarged view of the structure of "C" of fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 4, an acidity detection processing apparatus for an acidic contaminated water source according to an embodiment of the present invention includes a detection processing housing 11, a working chamber 12 is disposed in the detection processing housing 11, a reaction container 34 is fixedly disposed on an inner wall of a rear side of the working chamber 12, a reaction chamber 33 is disposed in the reaction container 34, a liquid level control assembly 901 is disposed in the reaction chamber 33, the liquid level control assembly 901 includes a linkage through hole 25 disposed on an inner wall of a right side of the reaction chamber 33 and communicated with the working chamber 12, two linkage sliding grooves 27 disposed on the inner wall of the right side of the reaction chamber 33 and vertically symmetrical to the linkage through hole 25, a sliding plate 26 slidably connected to the linkage sliding grooves 27 and extending into the linkage through hole 25, a first spring 28 connected to ends of the sliding plate 26 and the linkage sliding grooves 27 far away from a symmetrical center, and a floating block 24 fixedly disposed on a lower end of the sliding plate 26 and fixedly connected to an upper end of the sliding plate 26, The resistance 23 that sets firmly in the rear side inner wall of working chamber 12, along with the change of the interior liquid level of reaction chamber 33, floating block 24 with the contact of the different height departments of resistance 23 left end still is equipped with in the working chamber 12 and is used for getting into with external water source control waste water in the reaction chamber 33 gets into subassembly 902, still be equipped with the detection subassembly 903 that is used for detecting acidity in the waste water in the working chamber 12.

Advantageously, a motor 36 is fixedly arranged on the inner wall of the lower side of the working chamber 12, a first transmission shaft 38 extending upwards to the inner wall of the upper side of the working chamber 12 is connected to the upper end of the motor 36 in a power connection mode, and the first transmission shaft 38 can transmit the power of the motor 36.

Advantageously, the inner wall of the lower side of the reaction chamber 33 is provided with a sealing plug 29 for releasing the liquid in the reaction chamber 33.

According to the embodiment, the liquid level control assembly 901 will be described in detail below, the liquid level control assembly 901 further includes a power supply 21 fixedly disposed at the right end of the reaction vessel 34, an electric wire is connected between a positive contact of the power supply 21 and the floating block 24, an auxiliary electromagnet 60 is fixedly disposed on the inner wall of the left side of the working chamber 12, an electric wire is connected between a positive contact of the auxiliary electromagnet 60 and a lower contact of the resistor 23, an electric wire is connected between a negative contact of the power supply 21 and a negative contact of the auxiliary electromagnet 60, a rotating shaft support 55 extending rightward is fixedly disposed on the inner wall of the left side of the working chamber 12, the rotating shaft support 55 is rotatably connected with the first transmission shaft 38, a horizontal sliding support 54 disposed at the upper side of the rotating shaft support 55 and capable of sliding up and down is disposed at the left end of the reaction vessel 34, a through hole 53 penetrating up and down is disposed in the horizontal sliding, working chamber 12 upside inner wall has set firmly main electromagnet 45, just main electromagnet 45 electric power is directly supplied by power 21, working chamber 12 rear side inner wall is equipped with gliding slip tape magnetism support 43 from top to bottom, slip tape magnetism support 43 with be connected with second spring 44 between the main electromagnet 45, rotate on the slip tape magnetism support 43 and be connected with the second transmission shaft 42 that extends about, be located it is left to slip tape magnetism support 43 first bevel gear 41 has set firmly on the second transmission shaft 42, working chamber 12 left side inner wall is equipped with and slides from top to bottom and is located the linkage tape magnetism support 58 of auxiliary electromagnet 60 downside, linkage tape magnetism support 58 with be connected with third spring 56 between the pivot support 55, linkage tape magnetism support 58 right-hand member have set firmly with horizontal sliding support 54 upper end fixed connection's connecting support 57, rotate on the connecting support 57 be connected with extend from top to bottom and with the third transmission shaft 38 splined connection's of first transmission shaft A shaft 40, a second bevel gear 59 capable of engaging with the first bevel gear 41 is fixedly arranged on the third transmission shaft 40 positioned on the upper side of the connecting bracket 57, a driving friction wheel 52 is fixedly arranged on the first transmission shaft 38 positioned between the horizontal sliding bracket 54 and the rotating shaft bracket 55, a fourth transmission shaft 49 which is positioned on the right side of the first transmission shaft 38 and extends from the top to the bottom is rotatably connected to the rotating shaft bracket 55, a driven friction wheel 51 which is positioned on the upper side of the rotating shaft bracket 55 and is in friction connection with the driving friction wheel 52 is fixedly arranged on the rotating shaft bracket 55, a matching groove 46 which is positioned on the right side of the through hole 53 and is communicated with the working chamber 12 is arranged in the horizontal sliding bracket 54, a matching slide block 48 which extends downwards into the working chamber 12 is slidably connected to the inner wall of the matching groove 46, and a fourth spring 47 is connected between the matching slide block 48 and the inner wall on the upper side of the, a fifth transmission shaft 50 extending downwards and connected with the fourth transmission shaft 49 in a spline manner is rotatably connected to the lower end of the matching slide block 48.

According to the embodiment, the wastewater inlet component 902 is described in detail below, the wastewater inlet component 902 includes a valve body 79 fixedly arranged on the inner wall of the rear side of the working chamber 12, a valve chamber 78 is arranged in the valve body 79, an input pipeline 80 is connected between the valve chamber 78 and an external polluted water source, an output pipeline 75 is connected between the valve chamber 78 and the reaction chamber 33, the inner wall of the upper side of the valve chamber 78 is rotatably connected with a sixth transmission shaft 70 extending upwards into the working chamber 12, a valve ball 77 is fixedly arranged on the sixth transmission shaft 70 positioned in the valve chamber 78, a valve body through hole 76 is arranged in the valve ball 77, a gear 73 is fixedly arranged on the sixth transmission shaft 70 positioned in the working chamber 12, an auxiliary coupler 71 positioned on the upper side of the gear 73 is fixedly arranged on the sixth transmission shaft 70, a sliding rack 81 capable of sliding left and right is arranged on the inner wall of the rear side of the working chamber 12, a fifth spring 74 is connected between the sliding rack 81 and the left end of the reaction vessel 34, a toothed part at the front end of the sliding rack 81 is engaged with the gear 73, and a main coupling 72 which can be matched and connected with the auxiliary coupling 71 is fixedly arranged on the fifth transmission shaft 50 which is positioned at the lower side of the rotating shaft bracket 55.

According to the embodiment, the detection assembly 903 is described in detail below, the detection assembly 903 includes a spring support 22 fixedly disposed on the inner wall of the left side of the reaction chamber 33, a piston 19 is slidably connected to the inner wall of the reaction chamber 33, a sixth spring 20 is connected between the piston 19 and the spring support 22, a fixing rod 17 is fixedly disposed at the upper end of the piston 19, a connecting rod 15 extending rightward is fixedly disposed at the upper end of the fixing rod 17, a scale 16 extending downward is fixedly disposed at the right end of the connecting rod 15, an experimenter can view acidity through the scale at the front end of the scale 16, a chute 18 penetrating up and down is disposed on the piston 19, a connecting pipe 13 extending downward into the reaction chamber 33 through the chute 18 is fixedly disposed on the inner wall of the upper side of the working chamber 12, the connecting pipe 13 extends upward to the outside, a tapping funnel 14 is fixedly disposed at the upper end of the connecting pipe 13, a connecting cavity 62 is arranged in the connecting pipeline 13, a baffle sliding chute 69 communicated with the working cavity 12 is arranged on the inner wall of the left side of the connecting cavity 62, a sliding baffle 61 extending into the working cavity 12 is connected on the baffle sliding chute 69 in a sliding manner, a fixed support 64 is fixedly arranged at the lower end of the sliding baffle 61 positioned in the working cavity 12, a seventh spring 63 is connected between the fixed support 64 and the connecting pipeline 13, a seventh transmission shaft 66 positioned on the upper side of the sliding baffle 61 is rotatably connected on the inner wall of the rear side of the working cavity 12, a matching friction wheel 67 in friction connection with the upper end of the sliding baffle 61 is fixedly arranged on the seventh transmission shaft 66, a third bevel gear 68 positioned on the front side of the matching friction wheel 67 is fixedly arranged on the seventh transmission shaft 66, and a fourth bevel gear 65 capable of being engaged and connected with the third bevel gear 68 is fixedly arranged on the second transmission shaft 42, working chamber 12 downside inner wall rotates to be connected with and upwards extends to eighth transmission shaft 31 in the reaction chamber 33 is located in the reaction chamber 33 stirring piece 30 has set firmly on the eighth transmission shaft 31, is located in working chamber 12 vice band pulley 32 has set firmly on the eighth transmission shaft 31, main band pulley 37 has set firmly on the first transmission shaft 38, main band pulley 37 with be connected with belt 35 between the vice band pulley 32.

In the initial state, the floating block 24 is at the lower limit position, the piston 19 is at the lower limit position, the sliding magnetic support 43 is at the upper limit position, the first bevel gear 41 is not meshed with the second bevel gear 59, the horizontal sliding support 54 is at the upper limit position, the fourth bevel gear 65 is not meshed with the third bevel gear 68, the sliding baffle 61 is at the right limit position, the valve body through hole 76 is arranged in the forward and backward direction and is not communicated with the input pipeline 80 and the output pipeline 75, and the sliding rack 81 is at the left limit position.

When the acidic polluted water source is detected, the motor 36 is started to rotate the first transmission shaft 38, the rotating first transmission shaft 38 sequentially passes through the primary belt wheel 37, the belt 35, the secondary belt wheel 32 and the eighth transmission shaft 31 to drive the stirring blade 30 to rotate slowly, at this time, the rotating first transmission shaft 38 drives the driving friction wheel 52 to rotate, the rotating driving friction wheel 52 drives the primary coupling 72 to rotate through the driven friction wheel 51, the fourth transmission shaft 49 and the fifth transmission shaft 50, the rotating first transmission shaft 38 drives the second bevel gear 59 to rotate through the third transmission shaft 40, the power supply 21 supplies power to the primary electromagnet 45 and the secondary electromagnet 60, at this time, the primary electromagnet 45 is electrified and has the same magnetism as the sliding magnetic support 43, the magnetic primary electromagnet 45 drives the sliding magnetic support 43 to move downwards, the second spring 44 accumulates elastic potential energy, and the downward moving sliding magnetic support 43 drives the first bevel gear 41, the second bevel gear 42, The fourth bevel gear 65 moves downwards, at this time, the fourth bevel gear 65 is meshed with the third bevel gear 68, at this time, because the resistance value of the resistor 23 entering the loop of the secondary electromagnet 60 is smaller, at this time, the secondary electromagnet 60 has larger magnetism and is the same as the linkage magnetic carrier 58, so that the linkage magnetic carrier 58 moves downwards, the third spring 56 accumulates elastic potential energy, the linkage magnetic carrier 58 moving downwards drives the connecting carrier 57 to move downwards, the connecting carrier 57 moving downwards drives the second bevel gear 59 to move downwards through the third transmission shaft 40, the connecting carrier 57 moving downwards abuts against the horizontal sliding carrier 54 and drives the horizontal sliding carrier 54 to move downwards, the horizontal sliding carrier 54 moving downwards drives the main coupler 72 and the secondary coupler 71 to be matched and connected through the fourth spring 47, the matching slide block 48 and the fifth transmission shaft 50, and at this time, because the secondary electromagnet 60 has larger magnetism, the horizontal sliding bracket 54 moves downwards for a large distance, so that under the action of the fourth spring 47, the auxiliary shaft coupling 71 and the main shaft coupling 72 are kept to be matched and connected all the time, the rotating main shaft coupling 72 drives the sixth transmission shaft 70 to rotate through the auxiliary shaft coupling 71, the rotating sixth transmission shaft 70 drives the sliding rack 81 to move rightwards through the gear 73, the fifth spring 74 accumulates elastic potential energy, the rotating sixth transmission shaft 70 drives the valve body through hole 76 to rotate through the valve ball 77, when the sliding rack 81 moves to the right limit position, the valve body through hole 76 rotates ninety degrees, so that the input pipeline 80 is communicated with the output pipeline 75 at the moment, an external water source enters the reaction cavity 33 through the input pipeline 80, the valve body through hole 76 and the output pipeline 75 in sequence, the liquid level in the reaction cavity 33 rises along with the increase of the waste water in the reaction cavity 33, so that the floating block 24 moves upwards, the first spring 28 on the upper side and the lower side accumulates elastic potential, the upward moving floating block 24 contacts with the higher left end of the resistor 23, so that the magnetism of the secondary electromagnet 60 is weakened, the third spring 56 releases elastic potential energy and drives the linkage magnetic support 58 to move upwards, so that the horizontal sliding support 54 gradually moves upwards, but at the moment, under the action of the fourth spring 47, the secondary coupling 71 still keeps matched connection with the primary coupling 72, when the liquid level in the reaction chamber 33 reaches a specified height, the upward moving horizontal sliding support 54 drives the primary coupling 72 to be no longer matched connection with the secondary coupling 71 through the fourth spring 47, the matching slide block 48 and the fifth transmission shaft 50, so that the fifth spring 74 releases elastic potential energy and drives the valve body through hole 76 to be no longer the same as the input pipeline 80 and the output pipeline 75 through the sliding rack 81, the gear 73, the sixth transmission shaft 70 and the valve ball 77, so that the external wastewater no longer enters the reaction chamber 33, and at the upward moving connecting support 57 drives the second bevel gear 59 to be meshed with the first bevel gear 41 through the third transmission shaft 40 And then the connection is combined, so that the rotating second bevel gear 59 drives the seventh transmission shaft 66 to rotate clockwise sequentially through the first bevel gear 41, the second transmission shaft 42, the fourth bevel gear 65 and the third bevel gear 68, the clockwise rotating seventh transmission shaft 66 drives the sliding baffle 61 to move leftwards through the matching friction wheel 67, the seventh spring 63 accumulates elastic potential energy, when the sliding baffle 61 moves to the left limit position, the saturated sodium carbonate solution in the liquid discharging funnel 14 enters the reaction chamber 33 through the connecting pipeline 13, so that the liquid level in the reaction chamber 33 continues to rise, when the floating block 24 moves upwards and is no longer in contact with the resistor 23, the auxiliary electromagnet 60 loses magnetism, the power supply 21 does not output electric power any more, so that the main electromagnet 45 loses magnetism at this time, the second spring 44 releases elastic potential energy and drives the sliding magnetic support 43 to reset upwards, and the fourth bevel gear 65 is no longer in meshed connection with the third bevel gear 68, so that the seventh spring 63 releases elastic potential energy and drives the sliding baffle 61 to reset rightwards through the fixing bracket 64, thereby the solution in the liquid discharging funnel 14 does not fall downwards any more, at this time, the rotating speed of the motor 36 is increased, the reaction of the mixed liquid in the reaction chamber 33 is accelerated, along with the progress of the reaction, the generated gas drives the piston 19 to move upwards, the sixth spring 20 accumulates the elastic potential energy, the piston 19 moving upwards drives the graduated scale 16 to move upwards through the fixing rod 17 and the connecting rod 15, an experimenter can read the acidity value through the upper end scale of the graduated scale 16, when the reaction is finished, the motor 36 is closed, the sealing plug 29 is unscrewed, the liquid in the reaction chamber 33 can be discharged, at this time, the floating block 24 recovers the initial height, the device recovers the initial state, when the reaction chamber 33 needs to be cleaned, the input pipeline 80 is connected to the cleaning liquid, and the cleaning liquid is, repeating the above steps.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (6)

1. The utility model provides an acidity detection processing apparatus at acid contaminated water source, handles the casing including examining, it is equipped with the working chamber in handling the casing to detect, working chamber rear side inner wall sets firmly has reaction vessel, be equipped with reaction chamber in the reaction vessel, its characterized in that:

the reaction chamber is internally provided with a liquid level control assembly, the liquid level control assembly comprises a linkage through hole which is arranged on the inner wall on the right side of the reaction chamber and communicated with the working chamber, and is opposite to the linkage through hole, two linkage sliding chutes which are arranged on the inner wall on the right side of the reaction chamber in an up-and-down symmetrical mode, a sliding plate which is connected with the linkage sliding chutes and extends into the linkage through hole, a first spring which is connected with the sliding plate and the linkage sliding chutes and is far away from one end of a symmetrical center, a floating block which is fixedly connected with the lower end of the sliding plate and the lower side of the sliding plate, and a resistor which is fixedly arranged on the inner wall on the rear side of the working chamber, wherein the.

2. The apparatus according to claim 1, wherein the apparatus comprises: the inner wall of the lower side of the working cavity is fixedly provided with a motor, and the upper end of the motor is in power connection with a first transmission shaft which extends upwards to the inner wall of the upper side of the working cavity.

3. The apparatus according to claim 1, wherein the apparatus comprises: and a sealing plug is arranged on the inner wall of the lower side of the reaction cavity.

4. The apparatus according to claim 1, wherein the apparatus comprises: the liquid level control assembly further comprises a power supply fixedly arranged at the right end of the reaction vessel, an electric wire is connected between the positive electrode contact of the power supply and the floating block, an auxiliary electromagnet is fixedly arranged on the inner wall of the left side of the working chamber, the electric wire is connected between the positive electrode contact of the auxiliary electromagnet and the lower end contact of the resistor, the electric wire is connected between the negative electrode contact of the power supply and the negative electrode contact of the auxiliary electromagnet, a rotating shaft support extending rightwards is fixedly arranged on the inner wall of the left side of the working chamber, the rotating shaft support is rotatably connected with the first transmission shaft, the left end of the reaction vessel is provided with a horizontal sliding support which is positioned on the upper side of the rotating shaft support and can slide up and down, a through hole which is vertically communicated is arranged in the horizontal sliding support, the first transmission shaft is positioned in the through hole, a main electromagnet is fixedly arranged, a second spring is connected between the sliding magnetic support and the main electromagnet, a second transmission shaft which extends leftwards and rightwards is rotatably connected to the sliding magnetic support, a first bevel gear is fixedly arranged on the second transmission shaft which is positioned on the left side of the sliding magnetic support, a linkage magnetic support which can slide upwards and downwards and is positioned on the lower side of the auxiliary electromagnet is arranged on the inner wall of the left side of the working cavity, a third spring is connected between the linkage magnetic support and the rotating shaft support, a connecting support which is fixedly connected with the upper end of the horizontal sliding support is fixedly arranged at the right end of the linkage magnetic support, a third transmission shaft which extends upwards and downwards and is connected with a spline of the first transmission shaft is rotatably connected to the connecting support, a second bevel gear which can be meshed with the first bevel gear is fixedly arranged on the third transmission shaft which is positioned on the upper side of the connecting support, and a driving friction wheel is fixedly arranged on the first transmission shaft which is positioned between the horizontal sliding, rotate on the pivot support to be connected with and be located the fourth transmission shaft that first transmission shaft right side and mountain extend is located pivot support upside the pivot support on set firmly with the driven friction pulley of initiative friction pulley friction connection, be equipped with in the horizontal slip support and be located the perforating hole right side and with the communicating cooperation groove of working chamber, cooperation inslot wall sliding connection has downwardly extending to the cooperation slider in the working chamber, the cooperation slider with be connected with the fourth spring between the cooperation groove upside inner wall, cooperation slider lower extreme rotate be connected with downwardly extending and with fourth transmission shaft splined connection's fifth transmission shaft.

5. The apparatus according to claim 1, wherein the apparatus comprises: the waste water inlet assembly comprises a valve body fixedly arranged on the inner wall of the rear side of the working cavity, a valve cavity is arranged in the valve body, an input pipeline is connected between the valve cavity and an external polluted water source, an output pipeline is connected between the valve cavity and the reaction cavity, a sixth transmission shaft extending upwards into the working cavity is rotatably connected on the inner wall of the upper side of the valve cavity, a valve ball is fixedly arranged on the sixth transmission shaft in the valve cavity, a valve body through hole is arranged in the valve ball, a gear is fixedly arranged on the sixth transmission shaft in the working cavity, an auxiliary coupler positioned on the upper side of the gear is fixedly arranged on the sixth transmission shaft, a sliding rack capable of sliding left and right is arranged on the inner wall of the rear side of the working cavity, a fifth spring is connected between the sliding rack and the left end of the reaction container, and the toothed part at the front end of the sliding rack is meshed, and a main coupler which can be matched and connected with the auxiliary coupler is fixedly arranged on the fifth transmission shaft positioned on the lower side of the rotating shaft support.

6. The apparatus according to claim 1, wherein the apparatus comprises: the detection assembly comprises a spring support fixedly arranged on the inner wall of the left side of the reaction cavity, a piston is connected to the inner wall of the reaction cavity in a sliding manner, a sixth spring is connected between the piston and the spring support, a fixed rod is fixedly arranged at the upper end of the piston, a connecting rod extending rightwards is fixedly arranged at the upper end of the fixed rod, a scale extending downwards is fixedly arranged at the right end of the connecting rod, a chute which is communicated up and down is arranged on the piston, a connecting pipeline extending downwards into the reaction cavity through the chute is fixedly arranged on the inner wall of the upper side of the working cavity and extends upwards to the outside, a liquid discharge funnel is fixedly arranged at the upper end of the connecting pipeline positioned outside, a connecting cavity is arranged in the connecting pipeline, a baffle chute communicated with the working cavity is arranged on the inner wall of the left side of the connecting cavity, and a sliding baffle extending into, a fixed support is fixedly arranged at the lower end of the sliding baffle plate positioned in the working cavity, a seventh spring is connected between the fixed support and the connecting pipeline, a seventh transmission shaft positioned on the upper side of the sliding baffle plate is rotatably connected to the inner wall of the rear side of the working cavity, a matching friction wheel in friction connection with the upper end of the sliding baffle plate is fixedly arranged on the seventh transmission shaft, a third bevel gear positioned on the front side of the matching friction wheel is fixedly arranged on the seventh transmission shaft, a fourth bevel gear capable of being meshed and connected with the third bevel gear is fixedly arranged on the second transmission shaft, an eighth transmission shaft extending upwards into the reaction cavity is rotatably connected to the inner wall of the lower side of the working cavity, a stirring piece is fixedly arranged on the eighth transmission shaft positioned in the reaction cavity, a secondary belt wheel is fixedly arranged on the eighth transmission shaft positioned in the working cavity, and a main belt wheel is fixedly arranged on the first transmission shaft, a belt is connected between the main belt wheel and the auxiliary belt wheel.

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