Wastewater treatment system

文档序号:2124 发布日期:2021-09-17 浏览:47次 中文

1. A wastewater treatment system comprising a denitrification device (200), characterized by further comprising:

the influent temporary storage device (100) is arranged before the wastewater enters the denitrification device (200) and is used for temporarily storing the wastewater;

temporary storage device (100) of intaking includes mainboard (110), still includes:

the box (130) is arranged at the top end of the main board (110) and used for storing wastewater:

and the lifting mechanism (140) is arranged on the main board (110) and is used for adjusting the horizontal height of the box body (130) to be higher than that of the denitrification device (200).

2. A wastewater treatment system according to claim 1, characterized in that said intake buffer (100) further comprises:

a partition (150) disposed on the tank (130) and dividing an inner space of the tank (130) into a first water storage tank and a second water storage tank;

and the driving mechanism (160) is arranged on the box body (130) and drives the partition plate (150) to slide in the box body (130) so as to adjust the horizontal height of the top end of the partition plate (150).

3. A wastewater treatment system according to claim 2, characterized in that: the driving mechanism (160) comprises a driving cylinder (161) arranged on the box body (130), a piston rod (162) arranged at the output end of the driving cylinder (161), and a connecting rod (163) arranged between the piston rod (162) and the partition plate (150).

4. A wastewater treatment system according to claim 3, characterized in that: elevating system (140) including setting up bottom plate (120) in mainboard (110) below, setting up bridging (141) between bottom plate (120) and mainboard (110) and be used for driving the flexible drive assembly (142) of bridging (141), drive assembly (142) is including setting up driving piece (1421) on bottom plate (120), setting up lead screw (1422) at driving piece (1421) output, run through by lead screw (1422) and with lead screw (1422) screw-thread fit's actuating lever (1423), actuating lever (1423) and bridging (141) bottom are connected the setting and are in order to drive the flexible of bridging (141).

5. The wastewater treatment system according to claim 4, wherein: a linkage mechanism (170) is arranged between the lifting mechanism (140) and the driving mechanism (160), the linkage mechanism (170) comprises a worm (1701) which is arranged on the screw rod (1422) and is coaxially arranged with the screw rod (1422), a worm wheel (1702) which is rotatably arranged on the bottom plate (120), a rotating shaft (1703) which is coaxially arranged with the worm wheel (1702), a screw rod (1704) which is arranged on the rotating shaft (1703), a sliding piece (1705) which is slidably arranged on the side wall of the box body (130) and a supporting platform (1706) which is rotatably arranged on the sliding piece (1705), the worm (1701) and the worm wheel (1702) are mutually meshed, the screw rod (1704) penetrates through the sliding piece (1705) and is in threaded fit with the sliding piece (1705), and the driving cylinder (161) is slidably arranged on the side wall of the box body (130).

6. A wastewater treatment system according to claim 3, characterized in that: be provided with additional case (180) on the lateral wall of box (130), be equipped with between additional case (180) and box (130) baffle (190) and separate through baffle (190), baffle (190) slide on box (130) and set up, baffle (190) with connect the setting between connecting rod (163).

7. A wastewater treatment system according to claim 3, characterized in that: when the partition plate (150) is adjusted to the lowest height under the action of the connecting rod (163), the horizontal position of the bottom wall of the additional tank (180) is higher than the horizontal position of the top end of the partition plate (150).

8. A wastewater treatment system according to claim 3, characterized in that: the top end of the box body (130) is arranged in an opening shape convenient for medicine adding, and a cover plate (1901) used for covering the opening is arranged on the connecting rod (163).

Background

At present, the wastewater in the power plant is mainly the backwashing regeneration wastewater of the yin-yang bed, and the daily water discharge is about 400 t. The salinity of the wastewater is about 7000mg/L, the wastewater is high-salinity wastewater, and the wastewater contains more nitrogen elements. Wherein, the nitrogen element mainly comprises nitrate nitrogen and ammonia nitrogen, the proportion of the nitrate nitrogen is about 97.6 percent, and the proportion of the ammonia nitrogen is about 2.4 percent.

In the related art, the treatment modes of the wastewater mainly comprise a physicochemical method and a biological method for denitrification. The physical and chemical methods include air stripping denitrification, ion exchange, chlorine treatment, etc. The biological denitrification method of nitrification-denitrification is mostly adopted to treat the wastewater. Various treatment procedures have been designed for anaerobic reaction and aerobic reaction in the treatment process of activated sludge method and biomembrane method through various forms of combination.

However, in the above related art, both the physicochemical method and the biological method for denitrification, the power consumption for transporting the wastewater is large during the flowing process of the wastewater, resulting in a large amount of energy waste.

Disclosure of Invention

In order to improve the treatment effect of nitrogenous waste water, reduce the power consumption in the waste water transportation, this application provides a waste water treatment system.

The application provides a wastewater treatment system, including denitrification facility, still include:

the influent temporary storage device is arranged before the wastewater enters the denitrification device and is used for temporarily storing the wastewater;

the temporary storage device of intaking includes the mainboard, still includes:

the box set up in the top of mainboard for the storage waste water:

and the lifting mechanism is arranged on the main board and is used for adjusting the horizontal height of the box body to be higher than that of the denitrification device.

Through adopting above-mentioned technical scheme, under the normality, denitrification facility and the temporary storage device of intaking are in same level, arrange waste water into in advance and keep in the box, then through the high position lifting of elevating system with the box, make box horizontal position be higher than denitrification facility's horizontal position, make the waste water of temporary storage in the box under the action of self gravity, the automatic flow is handled in denitrification facility, need not to establish in addition the water pump and carry out the transport of waste water, under the operating mode that produces a large amount of waste water, this kind of transport mode can play the effect of saving a large amount of kinetic energy consumptions.

Preferably, the temporary influent water storage device further comprises:

the partition plate is arranged on the box body and divides the inner space of the box body into a first water storage tank and a second water storage tank;

and the driving mechanism is arranged on the box body and drives the partition board to slide in the box body so as to adjust the horizontal height of the top end of the partition board.

By adopting the technical scheme, the partition plate is arranged, so that the wastewater can be pretreated in the first water storage tank and simultaneously flows into the second water storage tank in an overflow mode, a water pump is not required to be additionally arranged for conveying, the dosing in the first water storage tank and the second water storage tank is realized, the double pretreatment is carried out, and the subsequent denitrification effect is improved; and the adjustment of baffle height satisfies different waste water transport volume under the different waste water volume operating mode: when the amount of the waste water is less, the height of the partition plate is reduced so as to meet the requirement of faster overflow of the waste water; when the amount of the wastewater is large, the height of the partition plate is adjusted to be high, so that more amount of the wastewater is stored to meet the requirement of slow overflow of the wastewater, and the height of the partition plate can be adjusted in real time according to the amount of the wastewater and according to the amount of the wastewater.

Preferably, the driving mechanism comprises a driving cylinder arranged on the box body, a piston rod arranged at the output end of the driving cylinder and a connecting rod arranged between the piston rod and the partition plate.

Through adopting above-mentioned technical scheme, the piston rod drives baffle synchronous movement to realize the lift effect of baffle.

Preferably, elevating system is including setting up bottom plate, the bridging that sets up between bottom plate and mainboard in mainboard below and being used for driving the flexible drive assembly of bridging, drive assembly is including setting up driving piece on the bottom plate, setting at the lead screw of driving piece output, run through by the lead screw and with lead screw thread fit's actuating lever, the actuating lever is connected the setting with the bridging bottom and is used for driving the flexible of bridging.

Through adopting above-mentioned technical scheme, the driving piece drives the lead screw and rotates, and the lead screw drives the actuating lever and removes, and the actuating lever drives the bridging and stretches out and draws back to realize the elevating action of mainboard, and because of the screw-thread fit between lead screw and the actuating lever, there is self-locking function, so realize the real-time locking effect of mainboard at the lift in-process.

Preferably, a linkage mechanism is arranged between the lifting mechanism and the driving mechanism, the linkage mechanism comprises a worm which is arranged on the screw rod and is coaxial with the screw rod, a worm wheel which is rotatably arranged on the bottom plate, a rotating shaft which is coaxial with the worm wheel, a screw rod which is arranged on the rotating shaft, a sliding part which is arranged on the side wall of the box body in a sliding manner, and a supporting platform which is rotatably arranged on the sliding part, the worm and the worm wheel are mutually meshed, the screw rod penetrates through the sliding part and is in threaded fit with the sliding part, and the driving cylinder is arranged on the side wall of the box body in a sliding manner.

Through adopting above-mentioned technical scheme, rotate the bottom of driving cylinder with a supporting bench, the lead screw drives the worm and rotates, and the worm drives the slider and slides on the box, and the slider drives a supporting bench synchronous motion, so make the supporting bench carry out synchronous lifting to the driving cylinder, and the driving cylinder drives the baffle rebound in step, when making the great condition of waste water volume appear, need not the driving cylinder action, can realize the mainboard and drive the synchronous lifting of driving cylinder at the lift in-process.

Preferably, an additional box is arranged on the side wall of the box body, a baffle is arranged between the additional box and the box body and is separated by the baffle, the baffle is arranged on the box body in a sliding manner, and the baffle is connected with the connecting rod.

By adopting the technical scheme, the baffle plate is driven by the connecting rod to realize the sliding action; and when the connecting rod moved, when the waste water volume was great promptly, so the baffle slided and introduces waste water in the additional case, promoted the storage space of box, need not additionally to set up power supply drive baffle simultaneously and slides.

Preferably, when the partition plate is lowered to the lowest height by the connecting rod, the horizontal position of the bottom wall of the additional tank is higher than the horizontal position of the top end of the partition plate.

Through adopting above-mentioned technical scheme, the horizontal position of additional tank is higher than the top horizontal position of baffle when the least significant end, makes the waste water volume reduce the back, and the waste water in the additional tank can flow to the box again and carry out the preliminary treatment under the action of gravity, and need not additionally to set up drainage device and carry out the waste water discharge in the additional tank.

Preferably, the top end of the box body is arranged in an opening shape convenient for medicine adding, and the connecting rod is provided with a cover plate used for covering the opening.

Through adopting above-mentioned technical scheme, the apron is used for sealing the box when need not to add the medicine, reduces the influence of waste water to external environment, also avoids external environment to the influence of waste water preliminary treatment simultaneously.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the height position of the box body is lifted to be higher than the horizontal position of the denitrification device through the lifting mechanism, so that the wastewater temporarily stored in the box body automatically flows into the denitrification device for treatment under the action of the gravity of the wastewater, a water pump is not required to be additionally arranged for conveying the wastewater, and under the working condition of generating a large amount of wastewater, the conveying mode can play a role in saving a large amount of kinetic energy consumption;

2. the partition plate is arranged, so that wastewater can be pretreated in the first water storage tank and flows into the second water storage tank in an overflow mode, a water pump is not required to be additionally arranged for conveying, meanwhile, overflow wastewater with good water quality is collected firstly, and the energy consumption and difficulty of subsequent wastewater treatment can be reduced;

3. the height position of the partition plate is adjustable, and the position of the partition plate is adjusted to the lowest position, so that the wastewater in the first water storage tank flows into the second water storage tank to a greater extent, and the situation that the wastewater in the first water storage tank is excessive is reduced; the height position of the partition plate is adjusted to the highest position, the wastewater capacity of the first water storage tank can be improved, and the practicability is improved.

Drawings

FIG. 1 is a schematic flow diagram of an embodiment of the present application;

FIG. 2 is a schematic view of the overall structure of an embodiment of the present invention;

FIG. 3 is an enlarged partial schematic view of portion A of FIG. 2;

FIG. 4 is a schematic structural view of another perspective of the inlet buffer in the embodiment of the present application;

FIG. 5 is an enlarged partial view of portion B of FIG. 4;

fig. 6 is a top view angle structure diagram of the water inlet temporary storage device omitting the cover plate in the embodiment of the present application.

Description of reference numerals: 100. a temporary inlet water storage device; 110. a main board; 120. a base plate; 130. a box body; 140. a lifting mechanism; 141. a scissor support; 1411. a first leg; 1412. a second leg; 1413. a third leg; 1414. a fourth leg; 142. a drive assembly; 1421. a drive member; 1422. a screw rod; 1423. a drive rod; 150. a partition plate; 160. a drive mechanism; 161. a drive cylinder; 162. a piston rod; 163. a connecting rod; 1631. a cross bar; 1632. a vertical rod; 170. a linkage mechanism; 1701. a worm; 1702. a worm gear; 1703. a rotating shaft; 1704. a screw; 1705. a slider; 1706. a support table; 180. an additional tank; 190. a baffle plate; 1901. a cover plate; 200. a denitrification device; 300. a temporary effluent storage device; 400. a backwashing device; 500. a nutrient solution adding device; 600. a sludge treatment device.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses effluent disposal system, as shown in figure 1, including entering water temporary storage device 100, denitrification facility 200 and play water temporary storage device 300, waste water passes through in proper order behind entering water temporary storage device 100, denitrification facility 200 and play water temporary storage device 300, discharges the processing.

As shown in fig. 1 and 2, the influent water temporary storage device 100 includes a main board 110, a bottom board 120, a box body 130 and a lifting mechanism 140, wherein the box body 130 is disposed on the main board 110, the bottom board 120 is disposed below the main board 110, the lifting mechanism 140 is disposed between the bottom board 120 and the main board 110, and the lifting mechanism 140 is configured to adjust the horizontal height of the box body 130, so that the horizontal height of the box body 130 can be higher than the horizontal height of the denitrification device 200, so that the wastewater temporarily stored in the box body 130 automatically flows into the denitrification device 200 to be processed under the action of its own gravity, without an additional water pump for wastewater transportation, and under a condition of generating a large amount of wastewater, the transportation method can play a role in saving a large amount of kinetic energy consumption.

As shown in fig. 2 and 3, the lifting mechanism 140 includes a scissor support 141 and a drive assembly 142. In the present embodiment, four of the cross braces 141 are disposed at four corners of the main board 110, and each of the cross braces 141 has the same structure. The scissor support 141 includes a first leg 1411, a second leg 1412, a third leg 1413, and a fourth leg 1414. Wherein, one end of the first leg 1411 is rotatably connected to the bottom wall of the main plate 110, one end of the second leg 1412 rotates and slides on the bottom wall of the main plate 110, and the middle position of the first leg 1411 is hinged to the middle position of the second leg 1412; the other end of the first leg 1411 is hinged to one end of a third leg 1413, the other end of the third leg 1413 is hinged to the top wall of the base plate 120, the other end of the second leg 1412 is hinged to one end of a fourth leg 1414, and the other end of the fourth leg 1414 rotates and slides on the top wall of the base plate 120.

The driving assembly 142 includes a driving member 1421, a screw 1422, and a driving rod 1423. The driving member 1421 is fixed on the top wall of the bottom plate 120, and the driving member 1421 is a motor. The lead screw 1422 is fixed at the output end of the driving member 1421, and the driving member 1421 drives the lead screw 1422 to rotate around its own axis. The screw 1422 penetrates through the driving rod 1423, and the screw 1422 is in threaded fit with the driving rod 1423, so that the driving rod 1423 can be driven to move along the length direction of the screw 1422 when the screw 1422 rotates. The drive bar 1423 is fixedly attached to the fourth leg 1414.

In this embodiment, the screw 1422 is disposed as one and extends along the length direction of the bottom plate 120, the two driving rods 1423 are disposed in parallel, the length directions of the two driving rods 1423 are perpendicular to the length direction of the screw 1422, and the two ends of each driving rod 1423 are respectively welded to the screw 1422 on the fourth supporting leg 1414 of the two scissors 141 and simultaneously penetrate through the two driving rods 1423, so that when the screw 1422 rotates, the four scissors 141 can be driven to move up and down simultaneously.

As shown in fig. 3 and 4, the box 130 is provided with a partition 150 and a driving mechanism 160, and the driving mechanism 160 is used for driving the partition 150 to slide on the box 130, so as to adjust the height position of the partition 150.

The partition 150 partitions the inner space of the cabinet 130 into a first water storage and a second water storage, and the partition 150 is disposed through the bottom wall of the cabinet 130. In this embodiment, the partition board 150 is slidably disposed in the box 130 along a vertical direction, and two ends of the partition board 150 are tightly attached to the inner sidewall of the box 130 to achieve an isolation effect.

As shown in fig. 4 and 5, the driving mechanism 160 includes a driving cylinder 161, a piston rod 162 slidably disposed at an output end of the driving cylinder 161, and a connecting rod 163 disposed on the piston rod 162. The driving cylinder 161 drives the piston rod 162 to slide along the length direction of the driving cylinder 161, the piston rod 162 drives the connecting rod 163 to move synchronously, and the connecting rod 163 drives the partition board 150 to move, so as to realize the lifting action of the partition board 150.

In this embodiment, the driving cylinders 161 are air cylinders or electric cylinders, and two driving cylinders 161 are symmetrically disposed on the side walls of the two ends of the box 130, and the driving cylinders 161 are slidably connected to the side walls of the box 130 along the vertical direction and slidably limited on the side walls of the box 130 through dovetail grooves or T-shaped grooves.

As shown in fig. 4 and 6, the connecting rod 163 includes a cross rod 1631 and a vertical rod 1632, the cross rod 1631 is fixedly connected to the piston rod 162, the vertical rod 1632 is fixedly connected to the cross rod 1631, and the vertical rod 1632 is fixedly connected to the partition board 150.

In this embodiment, the horizontal rod 1631 is disposed along the horizontal direction, the vertical rod 1632 is disposed along the vertical direction, and the horizontal rod 1631 is fixed on the top end of the piston rod 162, one end of the vertical rod 1632 is fixedly connected to the middle position of the horizontal rod 1631, and the other end of the vertical rod 1632 is fixedly connected to the top wall of the partition board 150.

A linkage mechanism 170 is arranged between the lifting mechanism 140 and the driving mechanism 160, and the linkage mechanism 170 is used for realizing synchronous action of the lifting mechanism 140 and the driving mechanism 160.

As shown in fig. 2 and 3, the linkage 170 includes a transmission assembly and a support assembly, the transmission assembly includes a worm 1701, a worm wheel 1702, a rotation shaft 1703 and a screw 1704, the worm 1701 is disposed on the screw 1422 and coaxially disposed with the screw 1422, the worm wheel 1702 is rotatably disposed and intermeshed with the worm 1701, the rotation shaft 1703 is coaxially disposed with the worm wheel 1702, and the screw 1704 is disposed on the rotation shaft 1703. The screw 1422 drives the worm 1701 to rotate, the worm 1701 drives the worm wheel 1702 to rotate, the worm wheel 1702 drives the rotating shaft 1703 to rotate, and the rotating shaft 1703 drives the screw 1704 to rotate.

In this embodiment, the worm 1701 is fixed at the middle position of the screw 1422, the worm wheel 1702 is placed along the horizontal direction, the rotating shaft 1703 is arranged along the vertical direction, and one end of the rotating shaft 1703 is rotatably connected to the bottom plate 120, and the other end penetrates through the main plate 110 and is rotatably connected to the fixing block fixed on the side wall of the box 130. The screw 1704 is coaxially and fixedly connected to the top end of the rotating shaft 1703.

As shown in fig. 2 and 5, the support assembly includes a slide 1705 slidably disposed on a sidewall of the box 130 and a support 1706 rotatably disposed on the slide 1705. The screw 1704 penetrates through the sliding part and is in threaded fit with the sliding part, so that the sliding part is driven to slide on the side wall of the box 130. The support table 1706 is rotated to a position below the driving cylinder 161, so that the support table 1706 supports the driving cylinder 161, and the driving cylinder 161 is lifted synchronously in the lifting process of the main plate 110. The case that the amount of wastewater is large is applied, so that the partition boards 150 are lifted synchronously under the condition that the box body 130 is lifted, the internal space of the box body 130 is increased, and the overflow speed of the wastewater is reduced.

In this embodiment, the sliding member 1705 is a block-shaped platform, and the box 130 is provided with a dovetail groove or a T-shaped groove, so that the sliding member 1705 slides on the box 130 and does not fall off. The supporting table 1706 is rotatably connected to the bottom wall of the slider 1705, that is, the bottom wall of the slider 1705 is rotatably connected to a rotating shaft, the rotating shaft extends along the vertical direction, and the supporting table 1706 is fixedly connected to the peripheral wall of the rotating shaft, so that the supporting table 1706 rotates in the horizontal plane.

As shown in fig. 2 and 6, an additional tank 180 is disposed on a side wall of the tank body 130, a baffle 190 is disposed between the additional tank 180 and the tank body 130, and the baffle 190 separates the additional tank 180 from the tank body 130; baffle 190 slides on box 130 and sets up, and is connected between baffle 190 and the connecting rod 163 and set up, makes connecting rod 163 drive baffle 190 and remove, realizes the intercommunication in box 130 space and the additional box 180 body 130 space.

In this embodiment, two additional tanks 180 are provided and fixedly coupled to both ends of the tank body 130, respectively. The top wall of the apron 190 is fixedly connected with the cross rod 1631, so that the cross rod 1631 drives the apron 190 to move.

As shown in fig. 2 and 6, further, when the partition plate 150 is lowered to the lowest height by the connecting rod 163, the horizontal position of the bottom wall of the additional tank 180 is higher than the horizontal position of the top end of the partition plate 150, so that the amount of wastewater is reduced, and the wastewater in the additional tank 180 can flow to the tank 130 again for pretreatment by gravity without additionally providing a drain device for discharging the wastewater in the additional tank 180.

The top of box 130 and additional box 180 all is for being convenient for the opening form setting of medicine, and fixedly connected with is used for covering the apron 1901 on the opening of establishing box 130 and additional box 180 on the horizontal pole 1631 to seal box 130 and additional box 180, reduce the influence of waste water to external environment, also avoid external environment to the influence of waste water preliminary treatment simultaneously.

The denitrification apparatus 200 is an FT denitrification device for performing denitrification treatment on wastewater.

In the embodiment, the FT denitrification equipment is preferably a denitrification device of a novel high-efficiency HDN-FT denitrification reactor to realize the denitrification of the wastewater.

As shown in fig. 1, the effluent temporary storage device 300 includes an effluent temporary storage tank, which is used for collecting the wastewater after denitrification treatment, and is convenient for index detection of the wastewater in the effluent temporary storage tank to reach the standard index and then discharge.

The wastewater treatment system is also provided with a backwashing device 400, and the backwashing device 400 comprises a cleaning water tank, a backwashing pump and a backwashing pipeline. The cleaning water tank takes water from the water outlet temporary storage tank, and the denitrification device 200 is backwashed through the backwash pump, so that the cleaning effect on the denitrification device 200 is achieved.

As shown in fig. 1, the wastewater treatment system is further provided with a nutrient solution adding device 500, and the nutrient solution adding device 500 comprises a nutrient tank, a nutrient solution delivery pump and a delivery pipeline. The nutrient solution in the nutrient tank is conveyed into the denitrification device 200 by the nutrient solution conveying pump and is used for supplementing the nutrient solution for the microorganisms in the denitrification device 200.

As shown in fig. 1, the wastewater treatment system is further provided with a sludge treatment device 600, the sludge treatment device 600 comprises a sludge storage tank, a filter press and a plurality of sewage pipes, backwashed sludge enters the sludge storage tank through the sewage pipes, is discharged into the filter press from the sludge storage tank for dehydration treatment, and finally becomes solid for outward transportation treatment.

The implementation principle is as follows:

in a normal state, the wastewater is discharged into the tank body 130 in advance for temporary storage, then the height position of the tank body 130 is lifted by the lifting mechanism 140, so that the horizontal position of the tank body 130 is higher than that of the denitrification device 200, and under the working condition of generating a large amount of wastewater, the wastewater temporarily stored in the tank body 130 automatically flows into the denitrification device 200 under the action of the gravity thereof for treatment.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

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