DE202022102363U1 - Energy-saving device for treating carbonaceous waste water - Google Patents

Abstract

An energy-saving carbonaceous waste water treatment apparatus comprising a base, a pair of support columns and a reactor, characterized in that a pair of support columns and the reactor are mounted on top of the base. In addition, there is a loading structure on top of the base, and there is a cleaning structure inside the reactor;
The charging structure includes a material tank, the first delivery pipe, a filter head, a pump body, and the second delivery pipe;
The material tank is mounted on the top of the base, the first delivery pipe is connected to the pump body at one end through the top wall of the material tank, the connector is mounted at one end of the first delivery pipe, the pump body is mounted on the top of the material tank, the second delivery pipe is connected to the pump body at one end and to the reactor at the other end.

Description

technical field

This utility model relates to the technical field of treating carbonaceous waste water, particularly to an energy-saving device for treating carbonaceous waste water.

background technology

Coal effluents from power plants are mainly derived from coal transfer bridge wash water, coal field jetty wash water and boiler room wash water, which contain a large amount of suspended matter, a small amount of organic matter and bacteria, the main component of the suspended matter being coal dust.

With the existing technology, when treating the carbonaceous waste water, reaction residues are easy to remain in the reactor, which is easy to cause corrosion in the reactor, and at the same time, the existing facilities cannot collect and treat the carbon residues in the carbonaceous waste water, which is easy to waste coal resources and too economical can lead to losses. In view of the above, the present case arises from the in-depth study of the above issues.

Content of the utility model

In response to the shortcomings of the existing technology, the utility model provides an energy-saving carbonaceous waste water treatment apparatus, which solves the problem that the existing technology in the treatment of carbonaceous waste water easily leaves a waste residue after the reaction in the reactor, which is easy to corrode in the reactor, and at the same time, the existing facility is unable to capture and treat the carbon residue in the carbonaceous waste water, which can easily lead to wastage of carbon resources and economic losses.

In order to achieve the above purpose, the utility model is realized by the following technical solution. An energy-saving device for treating carbonaceous waste water, comprising a base, a pair of support columns and a reactor, with the support columns and reactor mounted on top of the base. In addition, there is a loading structure on top of the base and a cleaning structure inside the reactor.

The charging structure includes a material container, the first delivery pipe, a filter head, a pump body, and the second delivery pipe.

The material tank is mounted on the top of the base, the first delivery pipe is connected to the pump body at one end through the top wall of the material tank, the connector is mounted at one end of the first delivery pipe, the pump body is mounted on the top of the material tank, the second delivery pipe is connected to the pump body at one end and to the reactor at the other end.

Preferably, the cleaning structure includes a cover, two rinsing components, a motor, a rotary shaft, a pair of impellers, a drain opening, and a filter device, the cleaning structure.

The cover is mounted on the top of the reactor, the two flushing components as well as the motor are mounted on the top of the cover, and the motor drive end passes through the cover, the top of the rotary shaft is connected to the motor drive end, the agitator blades are mounted on the rotary shaft, the drain port is mounted on the bottom of the reactor and the filter device is mounted on the bottom of the drain port.

Preferably, one of the two flushing devices includes two electric actuators, a water jet, an inlet tube, a moving block and a plug.

The two electric actuators are installed on the top of the cover, and the telescopic ends of the two electric actuators pass through the cover, the inlet pipe is installed on the cover and is connected to the top of the water jet, the top of the moving block is connected to the telescopic Ends of the two electric actuators are connected and the plug is attached to the top of the moving block.

The filter assembly preferably includes a filter canister, a plurality of screens and a drain pipe.

The filter canister is mounted at the bottom of the drain hole, the screens are mounted inside the filter canister, and the drain pipe is mounted on one side of the filter canister.

The front end of the reactor is preferably provided with a manhole opening.

The settling agent delivery tube is preferably attached to the top of the cover.

The utility model represents an energy-saving carbonaceous waste water treatment device. It has the following advantageous effects: This kind of energy-saving carbonaceous waste water treatment device uses the charging structure to feed the carbonaceous waste water into the inside of the reactor, and uses the cleaning structure to discharge the carbonaceous waste water Waste water to fully react with the settling agent, and after the reaction is completed, uses the filter device to filter out the settling agent in the waste water, and after the operation of the apparatus is finished, the two flushing components run to flush the residue in the reactor, and uses the filter device to to filter again, thereby solving the problem that in the prior art in the treatment of carbonaceous waste water, the post-reaction waste residue is easy to remain in the reactor, which is easy to cause corrosion in the reactor, and at the same time, the existing Equipment is unable to collect and treat the coal residue in the carbonaceous waste water, which can easily lead to wasting of coal resources and cause economic losses, etc.

character list

• 1 Fig. 12 is a schematic representation of the main view of an energy-saving carbonaceous waste water treatment apparatus described in this utility model.
• 2 Fig. 12 is a schematic representation of the main view of an energy-saving carbonaceous waste water treatment apparatus described in the utility model.
• 3 Fig. 12 is a schematic view showing the partially enlarged structure of an energy-saving carbonaceous waste water treatment apparatus described in this utility model.

The numbers in the figures: 1 - the base, 2 - support column, 3 - the reactor, 4 - material container, 5 - the first conveying pipe, 6 - the filter head; 7 - the pump body, 8 - the second delivery pipe; 9 - the cover, 10 - the motor, 11 - the rotating shaft, 12 - agitator blades, 13 - the drain hole, 14 - electric actuators, 15 - the water jet, 16 - the inlet pipe, 17 - moving block, 18 - the plug, 19 - the filter tank, 20 - strainer, 21 - the drain pipe, 22 - the manhole opening, 23 - the settling agent supply pipe.

Specific Embodiments

In the following, the technical solutions in the utility model embodiments are described clearly and completely in conjunction with the accompanying drawings in the utility model embodiments. Of course, the described embodiments are only part of the utility model embodiments, not all embodiments. Starting from the embodiments of the utility model, all other embodiments achieved by ordinary technicians in the field without any creative work belong to the scope of protection of the utility model.

All electrical parts in this case will be connected to their corresponding power supply through wires, and should be selected based on the actual situation, the appropriate controller and encoder must be selected to meet the control needs, the specific connection and control. Specific connection and control sequence, should refer to the following working principle of electrical parts between the work sequence to complete the electrical connection. The detailed means of connection are well known in the field. The following description mainly describes the working principle and process, and does not explain the electrical control. (People in practice will see the parts in order in this case. The detailed means of connection are well known in the field. The following description mainly describes the working principle and process, and does not explain the electrical control).

As in the 1 until 3 1 shows an energy-saving device for treating carbonaceous waste water, comprising a base 1, a pair of supporting columns 2 and a reactor 3. The supporting columns 2 and the reactor 3 are mounted on top of the base 1. FIG. In addition, on top of the base 1 there is a charging structure and inside the reactor 3 there is a cleaning structure.

The charging structure includes a material tank 4, the first delivery pipe 5, a filter head 6, a pump body 7 and the second delivery pipe 8.

The material tank 4 is mounted on the top of the base 1, the first delivery pipe 5 is connected to the pump body 7 at one end through the top wall of the material tank 4, the connector is mounted at one end of the first delivery pipe 5, the pump body 7 is on mounted on the top of the material container 4, the second conveyor tube 8 is connected to the pump body 7 at one end and to the reactor 3 at the other end.

As seen above, the operator controls the operation of the pump body 7, so that the carbonaceous waste water inside the material tank 4 is sucked out through the first conveying pipe 5, and the filter head 6 can effectively prevent the larger particle impurities in the carbonaceous waste water from entering enter the inside of the pump body 7 and damage the pump body 7, and the carbonaceous sewage enters the inside of the second conveying pipe 8 through the first conveying pipe 5 and the pump body 7, and finally enters the inside of the reactor 3 under the drive of the pump body 7 reaction reached.

In a preferred solution, the cleaning structure also includes: a cover 9, two flushing components, a motor 10, a rotating shaft 11, a pair of stirring blades 12, a drain opening 13 and a filter device.

The cover 9 is mounted on the top of the reactor 3, the two flushing components as well as the motor 10 are mounted on the top of the cover, and the motor drive end passes through the cover 9, the top of the rotary shaft 11 is connected to the motor drive end, the impeller 12 are mounted on the rotary shaft 11, the drain port 13 is mounted on the bottom of the reactor 3, and the filter device is mounted on the bottom of the drain port 13.

As can be seen from the above, after the material tank discharges the carbonaceous waste water into the reactor 3, the operator controls the motor 10 to rotate the rotary shaft 11, which in turn rotates a series of agitator blades 12. At this time, the operator feeds the settling agent into the reactor 3 through the settling agent supply pipe 23, and the rotation of impellers 12 causes the carbonaceous waste water to be fully mixed with the settling agent and the reaction proceeds. After the reaction is completed, the mixture enters the filter device through the drain port 13, and the drain port 13 is equipped with an opening and closing device, the filter device separates the sediment and the remaining water, and after the separation is completed, the operator can take out the sediment from the filter device for reuse, and after the cleaning is finished, the operator controls the operation of two rinsing components to clean the inside of the reactor 3, the rinsing preventing the remaining waste residues from causing corrosion inside the reactor 3 .

A preferred solution is that the two flushing components, one of which includes two electric actuators 14, a water jet 15, an inlet tube 16, a moving block 17 and a plug 18.

The two electric actuators 144 are mounted on the top of the cover 9 and the telescopic ends of the two electric actuators 14 pass through the cover 9, the inlet pipe 15 is mounted on the cover 9, the inlet pipe 16 is connected to the top of the water jet 15, the top of the moving block 17 is connected to the telescopic ends of the two electric actuators 14, and the plug 18 is mounted on top of the moving block 17.

As can be seen from the above, residues remain inside the reactor 3 before the operation of the cleaning system and after the end of the operation, and these residues can easily lead to corrosion inside the reactor 3 . When flushing is not required the telescopic end of the electric actuators 14 is retracted so that the plug 18 is inserted into the water jet 15 and the bottom of the water jet 15 is blocked and when cleaning is required the operator controls the electric actuators 14, to run and move the moving block 17 down. At the same time, the operator directs the high-pressure cleaning water through the inlet pipe 16 into the water jet 15, and the high-pressure water hits the top of the plug 18, and the top of the plug 18 and the moving block 17 are trapezoidal, and the high-pressure water becomes fan-shaped by the impact distributed, which can flush the inner wall of the reactor 3 and the surface of the stirring blades 12. After rinsing, the waste water can enter the filter device through the drain opening 13 and be filtered. After flushing, the operator can remove the filter assembly and treat the sediment therein.

In a preferred solution, the filter device also contains a filter container 19, several sieves 20 and a drain pipe 21.

The filter case 19 is attached to the bottom of the drain port 13 , the screens 20 are attached inside the filter case 19 , and the drain pipe 21 is attached to a side of the filter case 19 .

As seen above, the screens 20 are detachable structure, after the end of the filtration, the water is discharged through the drain pipe 21, the sediment is inside the filter tank 19. The operator can detach the screens 20 and that Remove sediment for central processing and recycling.

In a preferred embodiment, the front end of the reactor 3 is also provided with a manhole opening 22 .

In a preferred embodiment, the cover 9 is also provided with a settling agent feed pipe 23 .

It is noted that in this document relational terms such as "first" and "second" are only used to distinguish one entity or process from another and do not necessarily imply any such actual relationship or sequence between such entities or processes require or imply. In addition, the terms "comprises," "includes," or any other variation thereof are intended to cover non-exclusive inclusion such that a process, method, item, or device that includes a number of elements, not just those elements, but also includes other elements not expressly listed, or which also includes a process, method, object or device to be used for the purpose of the process, method, object or device, or elements, inherent in such process, method, article or device. In the absence of other restrictions. The statement 'contains a ......' does not preclude the existence of other identical elements in the process, method, article or device incorporating those elements'.

Although embodiments of the utility model have been shown and described, those skilled in the art will understand that numerous variations, modifications, substitutions and variations of these embodiments can be made without departing from the principles and spirit of the utility model, the scope of which is limited by the appended claims and their equivalents is.

Claims (6)

An energy-saving carbonaceous waste water treatment apparatus comprising a base, a pair of support columns and a reactor, characterized in that a pair of support columns and the reactor are mounted on top of the base. In addition, there is a loading structure on top of the base, and there is a cleaning structure inside the reactor; The charging structure includes a material tank, the first delivery pipe, a filter head, a pump body, and the second delivery pipe; The material tank is mounted on the top of the base, the first delivery pipe is connected to the pump body at one end through the top wall of the material tank, the connector is mounted at one end of the first delivery pipe, the pump body is mounted on the top of the material tank, the second delivery pipe is connected to the pump body at one end and to the reactor at the other end. An energy-saving device for the treatment of carbonaceous waste water claim 1 is characterized in that the cleaning structure includes a cover, two rinsing components, a motor, a rotary shaft, a pair of stirring blades, a drain hole and a filter device; The cover is mounted on the top of the reactor, the two flushing components as well as the motor are mounted on the top of the cover, and the motor drive end passes through the cover, the top of the rotary shaft is connected to the motor drive end, the agitator blades are mounted on the rotary shaft, the drain port is mounted on the bottom of the reactor and the filter device is mounted on the bottom of the drain port. An energy-saving device for the treatment of carbonaceous waste water claim 2 is characterized in that there are two flushing components, one of which includes two electric actuators, a water jet, an inlet tube, a moving block and a plug; The two electric actuators are installed on the top of the cover, and the telescopic ends of the two electric actuators pass through the cover, the inlet pipe is installed on the cover and is connected to the top of the water jet, the top of the moving block is connected to the telescopic Ends of the two electric actuators are connected and the plug is attached to the top of the moving block. An energy-saving device for the treatment of carbonaceous waste water claim 2 is characterized in that the filter device includes a filter container, several screens and a drain pipe; The filter canister is mounted at the bottom of the drain hole, the screens are mounted inside the filter canister, and the drain pipe is mounted on one side of the filter canister. An energy-saving device for the treatment of carbonaceous waste water claim 1 is characterized in that the front end of the reactor is provided with a manhole opening. An energy-saving device for the treatment of carbonaceous waste water claim 2 is characterized in that a settling agent feed tube is attached to the top of the cover.

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