DE202023103852U1 - A device for reusing wastewater from a thermal power plant - Google Patents

Abstract

A device for reusing wastewater from a thermal power plant, characterized in that it comprises:
a wastewater processing mechanism (100) comprising a storage element (101), a support element (104) and a feed magazine (102), and a drain fitting (105) attached to the storage element (101); and
a shaking and processing mechanism (200) comprising an entry assembly (201), a shaking and connection assembly (202) attached to the entry assembly (201), and a rotary drive assembly (203);
a rotation and cleaning mechanism (300), which has a connection cleaning assembly (301) running under the storage element (101), a movable adsorption assembly (302) provided in the connection cleaning assembly (301), and a piston control assembly (303) arranged in the storage element (101), and comprises a carrier ring (304).

Description

Technical area

The utility model relates to the technical field of coal mills, in particular to a device for reusing wastewater from a thermal power plant.

Background technology

The wastewater from thermal power plants includes production and household wastewater. After a long period of operation, the wastewater from the boilers and production pipes of thermal power plants contains rust or other iron-containing impurities, and the household wastewater contains odors caused by obvious bacterial growth. Existing wastewater treatment methods mostly consist of filtering and then using certain chemicals to remove the impurities in the wastewater. The filtration and chemical methods are not effective in treating iron impurities and bacteria in the wastewater, and some of the wastewater is discharged at a certain temperature, causing scale in the water to easily attach to the wastewater treatment tank. For this purpose, a device for reusing wastewater from a thermal power plant is proposed.

Content of the utility model

The purpose of this part is to outline some aspects of the embodiments of the utility model and to briefly describe some preferred embodiments. In this part and in the summary of the description and designation of the utility model of this application, some simplifications or omissions may be made so as not to obscure the purpose of this part, the summary of the description and designation of the utility model; such simplifications or omissions should not be construed as limiting the scope of application of the utility model.

In view of the above and/or the problems existing in the prior art, this utility model is proposed.

The technical problems that the present utility model aims to solve are therefore the poor treatment of iron-containing deposits in wastewater and the fact that wastewater at a certain temperature can lead to scale adhesion to the inside of the container, as well as the poor treatment of the Bacterial growth using chemicals in wastewater and the possible contamination of chemicals.

In order to achieve the above-mentioned purpose, the present utility model provides the following technical solution: an apparatus for reusing the wastewater of a thermal power plant, comprising a wastewater processing mechanism including a storage element, a support element and a feed magazine, as well as a drain fitting attached to the storage element; and
a shaking and processing mechanism including an entry assembly, a shaking and connection assembly attached to the entry assembly, and a rotary drive assembly;
a rotation and cleaning mechanism including a connection cleaning assembly extending under the storage element, a movable adsorption assembly provided in the connection cleaning assembly, and a piston control assembly arranged in the storage element and a support ring.

A further solution of the present utility model is that a cooling chamber is provided in the storage element, with the support element being connected under the storage element, with the feed magazine element and the drain fitting being connected to the storage element, with the storage element being provided with an overflow fitting on one side.

A further solution of the present utility model is that the inlet assembly comprises an inlet pipe, the inlet pipe being connected to an overflow pipe, the inlet pipe being provided in a first support sleeve, the first support sleeve being connected under a storage element, the shaking and Connection assembly has a connection tube at the rear, the connection tube being connected to the cooling chamber, the shaking and connection assembly comprising a support connection and a support ventilation element, the support connection comprising two connection hoods and an intermediate tube, the connection hood having an elastic connection tube at each end is connected, the intermediate tube being connected to both elastic connecting tubes, the elastic connecting tube being connected to the inlet tube, the intermediate tube being provided on the outside with two second support sleeves which are attached under the storage element.

A further solution of the present utility model is that the support ventilation element comprises an ozone ventilation tube which is snapped under the connection hood, wherein the ozone ventilation pipe is externally connected to two mounting frames, the mounting frame is connected to the intermediate pipe, the mounting frame is provided with an air outlet pipe which is continuously connected to the ozone ventilation pipe, the mounting frame has a vertical rod.

Another solution of the present utility model is that the rotary drive assembly comprises two connection blocks connected outside the connection hood, the two connection blocks being connected by an intermediate rod, one side of the connection block being connected to the movable frame by a sliding rod, the Sliding rod is provided with a sliding sleeve connected under the bearing member, the movable frame being provided internally with a connecting column, the connecting column being connected to the first gear, the drive motor being connected under the first gear.

Another solution of the present utility model is that the connection cleaning assembly comprises a second gear, the second gear meshing with a first gear, the second gear having a rotating shaft clamped therethrough, the rotating shaft having a first bearing, which is clamped through it under a storage element, the rotary shaft having two cleaning rods connected thereto by an extension rod, the rotary shaft having two guide holes outside it, the rotary shaft having a swivel joint at its tip.

Another solution of the present utility model is that the movable adsorption assembly comprises a reciprocating screw, the reciprocating screw being provided with a connecting shaft at both ends, the connecting shaft being provided with a second bearing which is in a rotating shaft, wherein the connecting shaft is connected to the connecting frame at the bottom at the lower end, the drive motor being arranged on the connecting frame, the connecting frame being arranged under the storage element, the reciprocating screw being provided with a threaded cap on the outside, wherein the threaded cap is connected to a telescopic air cylinder at the corresponding position of the guide hole, the telescopic air cylinder being slidably provided in the guide hole, the telescopic air cylinder being provided with an electromagnetic adsorption block on the outside.

Another solution of the present utility model is that the telescopic air cylinder is connected to a support ring and the electromagnetic adsorption block is arranged on the top of the support ring.

Another solution of the present utility model is that the piston control assembly comprises a piston frame connected to the interior of a storage element, the piston frame being connected to a hose to the outside, the hose being connected to a swivel joint and to a telescopic air cylinder, wherein the piston frame has a sliding piston plate inside, the piston plate having two piston rods at the bottom, the piston rods running through the piston frame and sliding under it.

Another solution of the present utility model is that the piston rod is provided in an elastic assembly, the two ends of the elastic assembly being respectively connected to the piston plate and the piston frame, the lower end of the piston rod being connected to a movable contact plate, which is coupled to the support ring, the piston frame being connected to a pressure switch, the pressure switch being in contact with the movable contact plate, and the pressure switch being electrically connected to the electromagnetic adsorption block.

Compared with the prior art, the advantageous effects of the utility model are as follows: The device for reusing the wastewater of a thermal power plant is equipped with the storage element, the ozone ventilation pipe, the rotating shaft, the driving motor, the reciprocating screw, the cleaning rod, the piston frame, the piston plate, the movable contact plate, the telescopic air cylinder, the electromagnetic adsorption block, the support ring, the fixing frame, the connection hood and the air outlet pipe; the driving motor drives the first gear to rotate, the second gear drives the rotating shaft and the cleaning rod to rotate, the cleaning rod cleans the inner wall of the storage element, and the rotating shaft rotates while driving the threaded cap and the telescopic air cylinder to rotate. At this time, the connecting shaft and the reciprocating screw remain stationary, and the thread cap realizes the up and down movement process on the surface of the reciprocating screw. When the electromagnetic adsorption block moves downward, the support ring is separated from the movable contact plate. At this point shrinks the telescopic air cylinder and the electromagnetic adsorption block are located in a relatively middle position in the storage element to realize the adsorption of iron-containing dirt in the wastewater in the storage element. When the electromagnetic adsorption block moves up, the support ring pushes the movable contact plate to move; At this time, the air in the piston frame is transferred to the telescopic air cylinder through the connecting pipe and the swivel joint, and the telescopic air cylinder is stretched to the support ring, with the electrical connection of the electromagnetic adsorption block being interrupted by the pressure switch at the same time, with the adsorbed on the electromagnetic adsorption block ferrous deposits fall on the support ring and the first gear rotates while controlling the movable frame and terminal hood through the connecting column to perform rapid back and forth shaking in the horizontal direction. The ozone aeration pipe is fed with ozone, and the connection hood moves back and forth to shake the wastewater inside the connection hood, which breaks up the ozone and at the same time has a certain knocking effect on the water flow. The mixing effect of ozone and wastewater is better, and the odor and iron-containing residues in the wastewater can be treated smoothly and efficiently. At the same time, the accumulation of more deposits on the side walls of the storage element can be avoided.

Illustration of the accompanying drawings

• 1 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist.
• 2 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks im Querschnitt, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist.
• 3 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus vom Schüttel- und Verarbeitungsmechanismus einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist; und
• 4 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus der Schüttel- und Anschlussbaugruppe einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist;
• 5 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus der Schüttel- und Anschlussbaugruppe einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist;
• 6 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus einer Drehantriebsbaugruppe einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist; und
• 7 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus des Stützbelüftungselements einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist;
• 8 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus der Kolbensteuerungsbaugruppe einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist;
• 9 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus der Verbindungsreinigungsbaugruppe einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist;
• 10 zeigt eine schematische Darstellung des dreidimensionalen Aufbaus der beweglichen Adsorptionsbaugruppe einer Vorrichtung zur Wiederverwendung des Abwassers eines Wärmekraftwerks, wie es in einer Ausführungsform der vorliegenden Erfindung beschrieben ist;

In order to illustrate the technical solution of the exemplary embodiments of the utility model more clearly, the attached drawings which are to be used in the exemplary embodiments are briefly presented below, it being easy to see that the following attached drawings only represent certain exemplary embodiments of the utility model, whereby the General professional in the industry without creative work can also get further relevant accompanying drawings based on these attached drawings. Included:

• 1 shows a schematic representation of the three-dimensional structure of a device for reusing the wastewater of a thermal power plant, as described in an embodiment of the present invention.
• 2 shows a schematic representation of the three-dimensional structure of a device for reusing the wastewater of a thermal power plant in cross section, as described in an embodiment of the present invention.
• 3 1 shows a schematic representation of the three-dimensional structure of the shaking and processing mechanism of an apparatus for reusing the wastewater of a thermal power plant as described in an embodiment of the present invention; and
• 4 shows a schematic representation of the three-dimensional structure of the shaking and connection assembly of a device for reusing the wastewater of a thermal power plant as described in an embodiment of the present invention;
• 5 shows a schematic representation of the three-dimensional structure of the shaking and connection assembly of a device for reusing the wastewater of a thermal power plant as described in an embodiment of the present invention;
• 6 1 shows a schematic representation of the three-dimensional structure of a rotary drive assembly of a thermal power plant wastewater reuse device as described in an embodiment of the present invention; and
• 7 shows a schematic representation of the three-dimensional structure of the support aeration element of a device for reusing the wastewater of a thermal power plant as described in an embodiment of the present invention;
• 8th shows a schematic representation of the three-dimensional structure of the piston control assembly of a device for reusing the wastewater of a thermal power plant as described in an embodiment of the present invention;
• 9 Fig. 12 shows a schematic representation of the three-dimensional structure of the connection cleaning assembly of a thermal power plant wastewater reuse apparatus as described in an embodiment of the present invention;
• 10 shows a schematic representation of the three-dimensional structure of the movable adsorption assembly of a device for reusing the wastewater of a thermal power plant as described in an embodiment of the present invention;

Specific Embodiments

In order to make the aforementioned objects, features and advantages of the utility model clearer and more understandable, the utility model is attached below in connection with the following th drawings and specific embodiments described in more detail

Many specific details are set forth in the following description to provide a complete understanding of the utility model, but the utility model may be implemented in ways other than those described herein, and one skilled in the art may make similar extensions without violating the connotations of the utility model, so that the utility model is not limited by the specific embodiments disclosed below.

Secondly, the utility model is described in detail in connection with the schematic representation. In the detailed description of the utility model embodiment, the sectional view showing the structure of the device is not locally enlarged according to the general scale for the purpose of illustration, and the schematic diagram is only an example, which is not intended to limit the scope of the utility model here. In addition, the actual production should include the length, width and depth of three-dimensional space dimensions.

Third, the term “an embodiment” or “embodiments” is used herein to refer to a particular feature, structure or characteristic that may be included in at least one embodiment of the utility model. The words “in one embodiment” appearing in various places throughout this specification do not all refer to the same embodiment, nor are they separate or selective embodiments that are mutually exclusive.

Example 1

As in 1-7 The present utility model discloses an apparatus for reusing the wastewater of a thermal power plant, comprising a wastewater processing mechanism 100 including a storage element 101, a support element 104 and a feed magazine 102, and a drain fitting 105 attached to the storage element 101; and
a shaking and processing mechanism 200 including an entry assembly 201, a shaking and connection assembly 202 attached to the entry assembly 201, and a rotary drive assembly 203;
a rotation and cleaning mechanism 300, which includes a connection cleaning assembly 301 extending under the storage element 101, a movable adsorption assembly 302 provided in the connection cleaning assembly 301, and a piston control assembly 303 arranged in the storage element 101 and a carrier ring 304.

A cooling chamber 106 is further provided in the storage element 101, the support element 104 being connected under the storage element 101, the feed magazine element 102 and the drain fitting 105 being connected to the storage element 101, the storage element 101 being provided with an overflow fitting 103 on one side.

The inlet assembly 201 comprises an inlet pipe 201a, the inlet pipe 201a being connected to an overflow pipe 103, the inlet pipe 201a being provided in a first support sleeve 201b, the first support sleeve 201b being connected under a storage element 101, the shaking and connection assembly 202 has a connecting tube 204 on the back, the connecting tube 204 being connected to the cooling chamber 106, the shaking and connection assembly 202 comprising a support connection 202a and a support ventilation element 202b, the support connection 202a having two connection hoods 202a-1 and an intermediate tube 202a-3 comprises, wherein the connection hood 202a-1 is connected at each end to an elastic connecting tube 202a-2, the intermediate tube 202a-3 is connected to both elastic connecting tubes 202a-2, the elastic connecting tube 202a-2 is connected to the inlet tube 201a, wherein the intermediate tube 202a-3 is provided on the outside with two second support sleeves 202a-4, which are attached under the storage element 101.

The support ventilation element 202b includes an ozone ventilation tube 202b-1 which is snapped under the connection hood 202a-1, the ozone ventilation tube 202b-1 being externally connected to two fastening frames 202b-2, the fastening frame 202b-2 being connected to the intermediate tube 202a-3 , wherein the mounting frame 202b-2 is provided with an air outlet pipe 202b-3 continuously connected to the ozone ventilation pipe 202b-1, the mounting frame 202b-2 having a vertical rod 202b-4.

Compared with the prior art, the advantageous effects of the utility model are as follows: The apparatus for reusing the wastewater of a thermal power plant is equipped with the storage element 101, the ozone aeration pipe 202b-1, the rotating shaft 301b, the driving motor 203h, the reciprocating screw 302a , the cleaning rod 301e, the piston frame 303a, the piston plate 303c, the movable contact plate 303e, the telescopic air cylinder 302f, the electromagnetic adsorption block 302g, the support ring 304, the mounting frame 202b-2, the movable frame 203e, the connection hood 202a-1 and the air outlet pipe 202a-3; the drive motor 203h drives the first gear 203g to rotate, the second gear 301a drives the rotating shaft 301b and the cleaning rod 301e to rotate, the cleaning rod 301e cleans the inner wall of the storage element 101, and the rotating shaft 301b rotates while the threaded cap 302h and the telescopic air cylinders 302f are driven to rotate. At this time, the connecting shaft 302c and the reciprocating screw 302a remain stationary, and the thread cap 302h realizes the up-and-down movement process on the surface of the reciprocating screw 302a. When the electromagnetic adsorption block 302g moves downward, the support ring 302e is separated from the movable contact plate 303e. At this time, the telescopic air cylinder 302f shrinks and the electromagnetic adsorption block 302g is in a relatively middle position in the storage element 101 to realize the adsorption of iron-containing dirt in the wastewater in the storage element 101. When the electromagnetic adsorption block 302g moves up, the support ring 302e pushes the movable contact plate 303e to move; At this time, the air in the piston frame 303a is transferred to the telescopic air cylinder 302f through the connecting pipe 204 and the swivel joint 301g, and the telescopic air cylinder 302f is stretched to the support ring 304, with the electrical connection of the electromagnetic adsorption block 302g being interrupted at the same time by the pressure switch 303h , wherein the ferrous deposits adsorbed on the electromagnetic adsorption block 302g fall onto the support ring 304, and the first gear 203g rotates while controlling the movable frame 203e and the terminal hood 202a-1 through the connecting column 203f to enable rapid back and forth shaking horizontal direction. The ozone aeration pipe 202b-1 is fed with ozone, and the port hood 202a-1 moves back and forth to shake the wastewater within the port hood 202a-1, which breaks up the ozone and at the same time has a certain knocking effect on the water flow. The mixing effect of ozone and wastewater is better, and the odor and iron-containing residues in the wastewater can be treated smoothly and efficiently. At the same time, the accumulation of more deposits on the side walls of the storage element 101 can be avoided.

Example 2

Combined with 6 and 9-10 As can be seen, the rotary drive assembly 203 includes two connection blocks 203a connected outside the connection hood 202a-1, the two connection blocks 203a being connected by an intermediate rod 203b, one side of the connection block 203a being connected to the movable frame 203e by a slide rod 203c , wherein the slide rod 203c is provided with a slide sleeve 203d connected under the bearing member 101, the movable frame 203e is provided inside with a connecting column 203f, the connecting column 203f is connected to the first gear 203g, the drive motor 203h underneath the first gear 203g is connected.

The connection cleaning assembly 301 includes a second gear 301a, the second gear 301a meshing with a first gear 203g, the second gear 301a having a rotating shaft 301b clamped therethrough, the rotating shaft 301b having a first bearing 301c passing through it is clamped under a storage element 101, the rotating shaft 301b having two cleaning rods 301e connected to it by an extension rod 301d, the rotating shaft 301b having two guide holes 301f outside it, the rotating shaft 301b having a swivel joint 301g at its tip having.

In this embodiment: By providing a connection hood 202a-1, a drive motor 203h, a movable frame 203e, a connection column 203f, a slide rod 203c and a slide sleeve 203d, the drive motor 203h controls the rotation of the first gear 203g and the connection column 203f while driving controls horizontal reciprocation of the movable frame 203e to realize the rapid reciprocation of the slide rod 203c and the connection hood 202a-1 and the rapid shaking of the wastewater within the connection hood 202a-1, respectively. At the same time, the cooled water stream in the connection hood 202a-1 flows through the connecting pipe 204 into the cooling chamber 106 to achieve cooling of the wastewater at a certain temperature in the storage element 101 and to ensure sufficient mixing and treatment effect between the wastewater and the ozone.

Example 3

Combined with 3 , 8th and 10 can be seen: The movable adsorption assembly 302 includes a reciprocating screw 302a, the reciprocating screw 302a being provided with a connecting shaft 302c at both ends, the connecting shaft 302c being provided with a second bearing 302d which is in a Rotary shaft 301b is attached, the ver binding shaft 302c is connected to the connecting frame 302b at the bottom at the lower end, the drive motor 203h being arranged on the connecting frame 302b, the connecting frame 302b being arranged under the storage element 101, the reciprocating screw 302a being provided with a threaded cap 302h on the outside, wherein the threaded cap 302h is connected to a telescopic air cylinder 302f at the corresponding position of the guide hole 301f, the telescopic air cylinder 302f is slidably provided in the guide hole 301f, the telescopic air cylinder 302f is externally provided with an electromagnetic adsorption block 302g.

The telescopic air cylinder 302f is connected to a support ring 302e, and the electromagnetic adsorption block 302g is arranged on the top of the support ring 304.

The piston control assembly 303 includes a piston frame 303a connected to the interior of a storage element 101, the piston frame 303a connected to a hose 303b to the outside, the hose 303b connected to a swivel joint 301g and to a telescopic air cylinder 302f, the Piston frame 303a has a sliding piston plate 303c inside, the piston plate 303c having two piston rods 303d at the bottom, the piston rods 303d running through the piston frame 303a and sliding under it.

The piston rod 303d is provided in an elastic assembly 303g, the two ends of the elastic assembly 303g are connected to the piston plate 303c and the piston frame 303a, respectively, the lower end of the piston rod 303d is connected to a movable contact plate 303e connected to the support ring 302e is coupled, wherein the piston frame 303a is connected to a pressure switch 303h, the pressure switch 303h is in contact with the movable contact plate 303e, and the pressure switch 303h is electrically connected to the electromagnetic adsorption block 302g.

In this embodiment: While the rotating shaft 301b is driven to rotate by the second gear 301a, the guide hole 301f can be used to rotate the telescopic air cylinder 302f by providing a reciprocating screw 302a, a threaded cap 302h and a connecting frame 302b to drive; the threaded cap 302h rotates relative to the connecting shaft 302c and the reciprocating screw 302a while rotating with the rotating shaft 301b; the reciprocating screw 302a drives the height adjustment thread cap 302h in the vertical direction to control the up and down movement and simultaneous rotation of the electromagnetic adsorption block 302g and to fully adsorb iron-containing impurities in the wastewater in the storage element 101. By providing the electromagnetic adsorption block 302g, the telescopic air cylinder 302f, the swivel joint 301g, the piston frame 303a, the 303C contact plate and the pressure switch 302e presses the movable contact plate 303e to move, during the telescopic air -cylinder 302f emotional; At this time, the air in the piston frame 303a is transferred to the telescopic air cylinder 302f, and the telescopic air cylinder 302f is stretched to the support ring 304 together with the electromagnetic adsorption block 302g, with the electrical connection of the electromagnetic adsorption block 302g being simultaneously interrupted by the pressure switch 303h; the ferrous material absorbed by the electromagnetic adsorption block 302g falls onto the bearing ring 304, and the air in the telescopic air cylinder 302f is pumped into the piston frame 303a when the telescopic air cylinder 302f moves downward, and the telescopic air cylinder 302f becomes the inside of the support ring 304 shortened and can move smoothly in vertical direction.

The utility model works as follows: the wastewater to be treated is injected directly into the storage element 101 through the feed magazine 102, and the drive motor 203h is controlled to drive the first gear 203g to rotate so that the first gear 203g drives the second gear 301a to rotate Rotating drives that the second gear 301a controls the rotating shaft 301b and the cleaning rod 301e to rotate so that the cleaning rod 301e cleans the inner wall of the storage element 101. The rotating shaft 301b rotates while the threaded cap 302h and the telescopic air cylinder 302f are driven to rotate by the limitation of the guide hole 301f. At this time, the connecting shaft 302c and the reciprocating screw 302a remain stationary, and the thread cap 302h realizes the up-and-down movement process on the surface of the reciprocating screw 302a. When the electromagnetic adsorption block 302g and the telescopic air cylinder 302f move downward, the support ring 302e is separated from the movable contact plate 303e. At this time, the movable contact plate 303e is disconnected with the pressure switch 303h, the electromagnetic adsorption block 302g is turned on, and the elastic assembly 303g drives the piston plate 303c to move downward, so that the air in the telescopic air cylinder 302f in the piston frame 303a is absorbed. At this time, the telescopic air cylinder 302f shrinks and the electromagnetic adsorption block 302g is in a relatively middle position in the storage element 101 to realize the adsorption of iron-containing dirt in the wastewater in the storage element 101. When the threaded cap 302h controls the telescopic air cylinder 302f and the electromagnetic adsorption block 302g to move upward, the support ring 302e pushes the movable contact plate 303e to move; At this time, the movable contact plate 303e controls the piston plate 303c upward through the piston rod 303d, and the piston plate 303c transfers the air in the piston frame 303a to the telescopic air cylinder 302f through the connecting pipe 204 and the swivel joint 301g, and the telescopic air cylinder 302f becomes together with the electromagnetic adsorption block 302g to the support ring 304, the electrical connection of the electromagnetic adsorption block 302g being simultaneously interrupted by the pressure switch 303h, the ferrous deposits adsorbed on the electromagnetic adsorption block 302g falling onto the support ring 304 and the first gear 203g rotating while it is movable frame 203e and the connection hood 202a-1 are controlled by the connecting column 203f to perform rapid back and forth shaking in the horizontal direction. The mounting frame 202b-2 is connected in the intermediate tube 202a-3 and remains stationary; Then the ozone aeration pipe 202b-1 is fed with ozone, and the connection hood 202a-1 moves back and forth to shake the wastewater inside the connection hood 202a-1, with the vertical rod 202b-4 breaking the ozone in the wastewater and at the same time producing a certain knocking effect on the water flow. The mixing effect of ozone and wastewater is relatively better. The ozone-treated and cooled water stream enters the cooling chamber 106, which exerts a certain cooling effect on the wastewater entering the storage element 101 at a certain temperature and reduces the degree of scale precipitation in the wastewater due to the temperature.

What is important to note is that the structure and arrangement of the present application, presented in a number of different exemplary embodiments, are exemplary only. Although only a few embodiments are described in detail in this disclosure, it should be readily apparent to those who refer to this disclosure that many adaptations are possible without materially departing from the novel teachings and advantages of the subject matter described in this application (e.g. changes in size, scale, construction, shape and proportions of various elements as well as parameter values (e.g. temperature, pressure, etc.), installation assemblies, use of materials, color, orientation, etc.). For example, the positions of the elements shown as being made up of multiple parts or elements may be reversed or otherwise changed, and the type or number or position of individual elements may be changed or changed. Therefore, all such adjustments should be included within the scope of coverage of the utility model. The order or sequence of the process or method steps can be changed or rearranged according to alternative embodiments. In the claims, any "device plus function" clause is intended to cover the structures described herein for performing those functions, whether merely structurally equivalent or representing equivalent structures. Without departing from the scope of the utility model, other substitutions, adjustments, changes and omissions may be made in the construction, operating conditions and arrangement of the exemplary embodiments. The utility model is therefore not limited to a specific embodiment, but extends to a wide range of adaptations that still fall within the scope of the appended claims.

Additionally, in order to provide a concise description of the exemplary embodiments, not all features of the actual embodiment may be described (i.e., those features that are not relevant to the best way of carrying out the utility model currently being contemplated, or those features that are essential to realizing the utility model are not relevant).

It can be understood that during the development of a practical implementation, such as: For example, in any engineering or design project, a large number of specific implementation decisions can be made. Such a development effort can be complex and time consuming, but will become routine in design, manufacturing and production without too much experimentation for the skilled person who will benefit from this disclosure.

It should be noted that the above embodiments serve only to illustrate the technical solutions of the utility model and are not intended to limit them. Despite the detailed description of the utility model with reference to the preferred embodiment, one skilled in the art should understand that it is still possible to make modifications or the like to make any necessary substitutions to the technical solution of the utility model, and that these changes or equivalent substitutions do not cause the modified technical solution to depart from the spirit and scope of the technical solution of the utility model, so that they are all covered by the scope of the claims of the utility model .

Claims (10)

A device for reusing the wastewater of a thermal power plant, characterized in that it comprises: a wastewater processing mechanism (100) comprising a storage element (101), a support element (104) and a feed magazine (102), and a drain fitting attached to the storage element (101). (105) includes; and a shaking and processing mechanism (200) comprising an entry assembly (201), a shaking and connection assembly (202) attached to the entry assembly (201), and a rotary drive assembly (203); a rotation and cleaning mechanism (300), which has a connection cleaning assembly (301) running under the storage element (101), a movable adsorption assembly (302) provided in the connection cleaning assembly (301), and a piston control assembly (303) arranged in the storage element (101), and comprises a carrier ring (304). A device for reusing wastewater from a thermal power plant Claim 1 , characterized in that a cooling chamber (106) is provided in the storage element (101), the support element (104) being connected under the storage element (101), the feed magazine element (102) and the drain fitting (105) being connected to the storage element (101 ) are connected, the storage element (101) being provided on one side with an overflow fitting (103). A device for reusing wastewater from a thermal power plant Claim 1 or 2 , characterized in that the inlet assembly (201) comprises an inlet pipe (201a), the inlet pipe (201a) being connected to an overflow pipe (103), the inlet pipe (201a) being provided in a first support sleeve (201b), the first support sleeve (201b) is connected under a storage element (101), the shaking and connection assembly (202) having a connecting tube (204) on the back, the connecting tube (204) being connected to the cooling chamber (106), the Shaking and connection assembly (202) comprises a support connection (202a) and a support ventilation element (202b), the support connection (202a) comprising two connection hoods (202a-1) and an intermediate tube (202a-3), the connection hood (202a-1 ) is connected at each end to an elastic connecting tube (202a-2), the intermediate tube (202a-3) being connected to both elastic connecting tubes (202a-2), the elastic connecting tube (202a-2) to the inlet tube (201a) is connected, the intermediate tube (202a-3) being provided on the outside with two second support sleeves (202a-4) which are attached under the storage element (101). A device for reusing wastewater from a thermal power plant Claim 3 , characterized in that the support ventilation element (202b) comprises an ozone ventilation tube (202b-1) which is snapped under the connection hood (202a-1), the ozone ventilation tube (202b-1) being connected on the outside to two fastening frames (202b-2). , wherein the mounting frame (202b-2) is connected to the intermediate pipe (202a-3), wherein the mounting frame (202b-2) is provided with an air outlet pipe (202b-3) which is continuously connected to the ozone ventilation pipe (202b-1). is, wherein the fastening frame (202b-2) has a vertical rod (202b-4). A device for reusing wastewater from a thermal power plant Claim 1 , characterized in that the rotary drive assembly (203) comprises two connection blocks (203a) connected outside the connection hood (202a-1), the two connection blocks (203a) being connected by an intermediate rod (203b), one side of the connection block (203a) is connected to the movable frame (203e) by a sliding rod (203c), the sliding rod (203c) being provided with a sliding sleeve (203d) connected under the bearing member (101), the movable frame (203e ) is provided inside with a connecting column (203f), the connecting column (203f) being connected to the first gear (203g), the drive motor (203h) being connected under the first gear (203g). A device for reusing wastewater from a thermal power plant Claim 1 , characterized in that the connection cleaning assembly (301) comprises a second gear (301a), the second gear (301a) meshing with a first gear (203g), the second gear (301a) having a rotating shaft (301b) which passes through it is clamped through it, the rotary shaft (301b) having a first bearing (301c) clamped therethrough under a storage element (101), the rotary shaft (301b) having two cleaning rods (301e) connected thereto by a Extension rod (301d), the rotary shaft (301b) having two guide holes (301f) outside it, the rotary shaft (301b) having a swivel joint (301g) at its tip. A device for reusing wastewater from a thermal power plant Claim 1 , characterized in that the movable adsorption assembly (302) comprises a reciprocating screw (302a), the reciprocating screw (302a) being provided with a connecting shaft (302c) at both ends, the connecting shaft (302c ) is provided with a second bearing (302d) which is fixed in a rotating shaft (301b), the connecting shaft (302c) being connected to the connecting frame (302b) at the lower end, the drive motor (203h) being connected to the connecting frame (302b ) is arranged, wherein the connecting frame (302b) is arranged under the storage element (101), the reciprocating screw (302a) being provided on the outside with a threaded cap (302h), the threaded cap (302h) being at the corresponding position of the Guide hole (301f) is connected to a telescopic air cylinder (302f), the telescopic air cylinder (302f) being slidably provided in the guide hole (301f), the telescopic air cylinder (302f) being provided on the outside with an electromagnetic adsorption block (302g). A device for reusing wastewater from a thermal power plant Claim 7 , characterized in that the telescopic air cylinder (302f) is connected to a support ring (302e) and the electromagnetic adsorption block (302g) is arranged on the top of the support ring (304). A device for reusing wastewater from a thermal power plant Claim 1 , 6 or 7 , characterized in that the piston control assembly (303) comprises a piston frame (303a) connected to the interior of a storage element (101), the piston frame (303a) being connected to the outside with a hose (303b), the hose ( 303b) is connected to a swivel joint (301g) and to a telescopic air cylinder (302f), the piston frame (303a) having a sliding piston plate (303c) inside, the piston plate (303c) having two piston rods (303d) at the bottom, whereby the piston rods (303d) run through the piston frame (303a) and slide under it. A device for reusing wastewater from a thermal power plant Claim 9 , characterized in that the piston rod (303d) is provided in an elastic assembly (303g), the two ends of the elastic assembly (303g) being respectively connected to the piston plate (303c) and the piston frame (303a), the lower end the piston rod (303d) is connected to a movable contact plate (303e) which is coupled to the support ring (302e), the piston frame (303a) being connected to a pressure switch (303h), the pressure switch (303h) being connected to the movable contact plate (303e) is in contact and the pressure switch (303h) is electrically connected to the electromagnetic adsorption block (302g).

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