CN112709315B - Toilet sewage treatment and reuse device - Google Patents

Abstract

The invention relates to the technical field of sewage treatment, in particular to a toilet sewage treatment and recycling device, which comprises a power mechanism, an impurity filtering mechanism, a sliding frame mechanism, a mixing and stirring mechanism, a mixing reaction box and a heat exchange box, wherein the power mechanism is in transmission connection with the impurity filtering mechanism and the sliding frame mechanism; the impurity filtering mechanism is connected to the sliding frame mechanism in a matching manner and is positioned right above the mixing reaction box with the open top; the sliding frame mechanism is in sliding fit with the mixing reaction box, the upper end of the mixing and stirring mechanism is connected with the sliding frame mechanism in a matched mode, and the lower end of the mixing and stirring mechanism is connected with the inner side of the mixing reaction box in a matched mode. When the cylindrical filtering basket in the invention filters impurities, the impurities can be led out through the matching of the first helical impeller and the second helical impeller with the cylindrical filtering basket, the conical impurity discharging hopper and the impurity output pipe, so that the blockage caused by excessive impurities in the cylindrical filtering basket in the filtering process can be prevented.

Description

Toilet sewage treatment and reuse device

Technical Field

The invention relates to the technical field of sewage treatment, in particular to a toilet sewage treatment and recycling device.

Background

The household toilet is an important place causing water resource pollution and waste, water after people have a bath and wash hands is usually directly discharged through a drainage pipeline, so that not only is the environment polluted, but also a large amount of renewable water resources are wasted; therefore, it is very important to filter and recycle the sewage in the toilet, but the sewage filtering apparatus in the prior art is easy to be blocked when filtering the sewage, thereby affecting the sewage treatment effect.

Disclosure of Invention

The invention aims to provide a toilet sewage treatment and recycling device which can effectively solve the problems in the prior art.

In order to achieve the purpose, the application provides a toilet sewage treatment and recycling device which comprises a power mechanism, an impurity filtering mechanism, a sliding frame mechanism, a mixing and stirring mechanism, a mixing reaction box and a heat exchange box, wherein the power mechanism is in transmission connection with the impurity filtering mechanism and the sliding frame mechanism; the impurity filtering mechanism is connected to the sliding frame mechanism in a matching manner and is positioned right above the mixing reaction box with the top opened; the sliding frame mechanism is in sliding fit with the mixing reaction box, the upper end of the mixing and stirring mechanism is connected to the sliding frame mechanism in a matching manner, and the lower end of the mixing and stirring mechanism is connected to the inner side of the mixing reaction box in a matching manner; the lower end of the mixing reaction box is hermetically connected and communicated with the heat exchange box.

Optionally, the impurity filtering mechanism comprises a sewage inlet pipe, a front end cover, a cylindrical filtering basket, a rear end cover, a conical impurity discharging hopper, an impurity output pipe, a rotating shaft, a first helical impeller and a second helical impeller; the sewage inlet pipe is connected in a water inlet of the front end cover in a matching way; a plurality of primary filtering holes are uniformly arranged on the cylindrical filtering basket in a surrounding manner; two ends of the cylindrical filtering basket are arranged in an open mode and are respectively and rotatably matched in the front end cover and the rear end cover; the front end cover and the rear end cover are respectively fixed at the front end and the rear end of the sliding frame mechanism; the rear end cover, the conical impurity discharging hopper and the impurity output pipe are fixedly connected in sequence, and the axis of the rear end cover, the axis of the conical impurity discharging hopper and the axis of the impurity output pipe are collinear; the rotating shaft is in running fit in the central through hole of the front end cover; the rotating shaft is fixedly connected with a first spiral impeller and a second spiral impeller, the first spiral impeller is rotatably matched on the inner side of the cylindrical filtering basket, and the second spiral impeller is rotatably matched on the inner sides of the conical impurity discharging hopper and the impurity output pipe.

Optionally, the carriage mechanism includes a socket ring and a sliding cross-frame; the two sleeving rings are fixedly connected with two ends of the two sliding cross frames which are oppositely arranged; the two sliding cross frames are in sliding fit with the mixing reaction box; the inner side of one of the sleeving connection rings is fixedly connected with the front end cover, and the inner side of the other sleeving connection ring is fixedly connected with the rear end cover; the upper end of the mixing and stirring mechanism is connected to the sliding cross frame in a matching manner.

Optionally, the power mechanism comprises a servo motor, a driving worm gear, a wheel shaft, a rotating disc, an eccentric shaft and a push-pull connecting rod; the servo motor is fixedly connected to the mixing reaction box through a motor bracket; an output shaft of the servo motor is in transmission connection with the driving worm through a coupler; the driving worm is in meshed transmission connection with the driving worm wheel; the driving worm wheel is fixed in the middle of the wheel shaft; the wheel shaft is rotationally matched on the motor bracket through a bearing bracket; the outer end of the wheel shaft is fixed with a rotary disc; an eccentric shaft is fixed at the eccentric position of the outer side face of the rotating disc; one end of the push-pull connecting rod is in rotating fit with the eccentric shaft, and the other end of the push-pull connecting rod is in rotating fit with the sliding cross frame so as to drive the sliding cross frame to perform reciprocating sliding in the horizontal direction on the mixing reaction box; the center of the driving worm is provided with a sliding shaft hole, and the rotating shaft is in sliding fit in the sliding shaft hole; and the inner wall of the sliding shaft hole is fixedly connected with a limiting convex edge which is in sliding fit with a limiting groove on the rotating shaft.

Optionally, a plurality of secondary filtering holes are uniformly formed in the bottom surface of the mixing reaction box, the mixing reaction box is communicated with the inside of the heat exchange box through the secondary filtering holes, and the aperture of each secondary filtering hole is smaller than that of each primary filtering hole; the heat exchange box is internally provided with a heat exchange mechanism, and the heat exchange box is provided with a water outlet pipe with a control valve.

Optionally, the heat exchange mechanism comprises a water inlet pipe with a control valve, a heat exchange box and a water drain pipe with a control valve; the water inlet pipe and the water outlet pipe are respectively fixedly connected and communicated with two ends of the heat exchange box; the water inlet pipe and the water outlet pipe are respectively fixed in a sealing mode and penetrate out of two ends of the heat exchange box.

Optionally, the toilet sewage treatment and recycling device further comprises a filter basket cleaning brush; the sleeving ring is fixedly connected with a filter basket cleaning brush; the brush hair of the filter basket cleaning brush is attached to the cylindrical filter basket.

Optionally, the toilet sewage treatment and recycling device further comprises a cleaning linkage mechanism; the cleaning linkage mechanism comprises a first linkage rack, a first gear, a first linkage shaft, a driving bevel gear, a driven bevel gear, a linkage worm gear and a bearing rod seat; the front end and the rear end of the first linkage rack are fixed at the front end and the rear end of the mixing reaction box; the teeth on the outer side surface of the first linkage rack are in meshed transmission connection with the first gear; the first gear and the driving bevel gear are respectively fixed at two ends of the first linkage shaft; the first linkage shaft is rotationally matched on the sliding cross frame; the driving bevel gear is in meshed transmission connection with the driven bevel gear; the driven bevel gear is fixed on the linkage worm; the linkage worm is rotationally matched on the bearing rod seat, and the bearing rod seat is fixed on the sliding cross frame; the linkage worm is in meshed transmission connection with the linkage worm wheel; the center of linkage worm wheel is equipped with circular mounting hole, and cylindrical filter basket fixed connection is in the inboard of circular mounting hole.

Optionally, the mixing and stirring mechanism comprises a hanger, a stirring shaft, a stirring impeller, a driven belt wheel and a horizontal sliding seat; the upper ends of the two hanging frames are relatively fixed at the front end and the rear end of the bottom surface of the sliding cross frame; the lower ends of the two hanging brackets are respectively and rotatably connected with one end of a stirring shaft, the middle parts of the two stirring shafts are respectively and fixedly connected with a stirring impeller, and the two stirring impellers are rotatably matched on the inner side of the mixing reaction box; the other ends of the two stirring shafts are rotationally matched on a horizontal sliding seat, and the horizontal sliding seat is in sliding fit in a transverse sliding groove on the inner side surface of the mixing reaction box; two stirring shafts are respectively fixedly connected with a driven belt wheel.

Optionally, the toilet sewage treatment recycling device further comprises a stirring linkage mechanism; the stirring linkage mechanism comprises a second linkage rack, a second gear, a second linkage shaft, a bearing seat and a driving belt wheel; two ends of the second linkage rack are respectively fixed at the front end and the rear end of the mixing reaction box; the second linkage rack and the first linkage rack are respectively positioned on two sides of the mixing reaction box; the second gear is in meshed transmission connection with the second linkage rack; the second gear and the driving belt wheel are respectively fixed at two ends of the second linkage shaft; the second coupling shaft is rotationally matched on the sliding cross frame through a bearing seat; the driving belt wheel is connected with the two driven belt wheels through a synchronous belt in a transmission mode so as to drive the two stirring shafts to rotate.

The invention has the beneficial effects that:

1. when the cylindrical filtering basket in the invention filters impurities, the impurities can be led out through the matching of the first helical impeller and the second helical impeller with the cylindrical filtering basket, the conical impurity discharging hopper and the impurity output pipe, so that the phenomenon that the cylindrical filtering basket is blocked due to excessive impurities in the filtering process is prevented;

2. the cleaning linkage mechanism is arranged in the filter basket cleaning device, and when the power mechanism drives the sliding frame mechanism to slide on the mixing reaction box in a reciprocating manner, the power mechanism can drive the cylindrical filter basket to rotate around the axis of the cylindrical filter basket through the matching with the cleaning linkage mechanism, so that different positions of the cylindrical filter basket are scrubbed and cleaned through the filter basket cleaning brush, and the filter effect is prevented from being influenced by the blockage of a primary filter hole on the filter basket cleaning brush;

3. when the power mechanism drives the sliding frame mechanism to slide on the mixing reaction box in a reciprocating manner, the stirring impeller in the mixing mechanism can be driven by matching with the stirring linkage mechanism to carry out rotational flow stirring work, so that the effect of mixing preliminarily filtered sewage and a sewage treatment agent is improved, and the treatment effect of the sewage is improved;

4. the invention only adopts one motor to control the inside, has good equipment continuity, saves energy and reduces consumption.

In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the embodiments of the present invention or technical solutions in related arts, the drawings used in the description of the embodiments or related arts will be briefly described below, and it is obvious that the drawings in the description below are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a first general schematic diagram provided in accordance with an embodiment of the present invention;

FIG. 2 is a second overall view provided in accordance with an embodiment of the present invention;

FIG. 3 is a third overall schematic diagram provided in accordance with an embodiment of the present invention;

fig. 4 is a schematic view of a power mechanism according to an embodiment of the invention;

FIG. 5 is a schematic view of a contaminant filter mechanism provided in accordance with an embodiment of the present invention;

FIG. 6 is a cross-sectional view of a contaminant filter mechanism provided in accordance with an embodiment of the present invention;

FIG. 7 is a schematic view of a carriage mechanism provided by an embodiment of the present invention;

FIG. 8 is a schematic view of a mixing and agitating mechanism provided in accordance with an embodiment of the present invention;

FIG. 9 is a schematic view of a mixing chamber provided in accordance with an embodiment of the present invention;

FIG. 10 is a schematic view of a cleaning linkage provided in accordance with an embodiment of the present invention;

fig. 11 is a schematic view of a stirring linkage mechanism according to an embodiment of the present invention.

An icon: a power mechanism 1; a servo motor 101; a drive worm 102; a drive worm gear 103; an axle 104; a rotating disk 105; an eccentric shaft 106; a push-pull connecting rod 107; an impurity filtering mechanism 2; a sewage inlet pipe 201; a front end cap 202; a cylindrical filter basket 203; a rear end cap 204; a tapered trash-discharge hopper 205; an impurity output pipe 206; a rotating shaft 207; a first helical impeller 208; a second helical impeller 209; a carriage mechanism 3; a ferrule ring 301; a sliding cross-frame 302; a mixing and stirring mechanism 4; a hanger 401; an agitating shaft 402; a stirring impeller 403; a driven pulley 404; a horizontal slide 405; a mixing reaction box 5; a heat exchange tank 6; a filter basket cleaning brush 7; a cleaning linkage 8; a first linked rack 801; a first gear 802; a first linkage shaft 803; a drive bevel gear 804; driven bevel gears 805; a linkage worm 806; a linked worm gear 807; a stem bearing seat 808; a stirring link mechanism 9; a second linkage rack 901; a second gear 902; a second coupling shaft 903; bearing seat 904; a driving pulley 905.

Detailed Description

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

It will be understood that when an element is referred to as being "fixed" or "disposed" to another element, it can be directly on the other element or be indirectly disposed on the other element; when an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings to facilitate the description of the application and to simplify the description, and are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed in a particular orientation, and be constructed in operation as a limitation of the application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, the meaning of a plurality or a plurality is two or more unless explicitly defined otherwise.

It should be understood that the structures, ratios, sizes, and the like shown in the drawings and described in the specification are only used for matching the disclosure and are not used for limiting the practical limitations of the present application, so that the modifications, the changes of the ratio relationships, and the adjustments of the sizes of the structures and the structures are not essential to the technology, and the functions and the purposes of the present application can be achieved without affecting the technical scope of the present application. In addition, the terms such as "upper", "lower", "left", "right", "middle" and "one" used in the present specification are used for clarity of description only, and are not used to limit the scope of the present application, and the relative relationship between the terms may be changed or adjusted without substantial technical change.

The present invention is described in further detail below with reference to FIGS. 1-11.

The first embodiment is as follows:

as shown in fig. 1-11, the device for treating and recycling sewage in a toilet comprises a power mechanism 1, an impurity filtering mechanism 2, a sliding frame mechanism 3, a mixing and stirring mechanism 4, a mixing reaction box 5 and a heat exchange box 6, wherein the power mechanism 1 is in transmission connection with the impurity filtering mechanism 2 and the sliding frame mechanism 3; the impurity filtering mechanism 2 is connected to the sliding frame mechanism 3 in a matching manner and is positioned right above the mixing reaction box 5 with an open top; the sliding frame mechanism 3 is in sliding fit with the mixing reaction box 5, the upper end of the mixing mechanism 4 is in fit connection with the sliding frame mechanism 3, and the lower end of the mixing mechanism 4 is in fit connection with the inner side of the mixing reaction box 5; the lower end of the mixing reaction box 5 is hermetically connected and communicated with the heat exchange box 6. The toilet sewage treatment and recycling device is used for filtering and recycling the sewage in the toilet; when the device is used, a sewage drainage pipe is communicated with the impurity filtering mechanism 2, the power mechanism 1 can be driven to drive the impurity filtering mechanism 2 to operate after being started, impurities filtered out from the inside of the impurity filtering mechanism 2 are led out to the outside, sewage filtered by the impurity filtering mechanism 2 falls into the mixing reaction box 5, a sewage treatment agent is put into the mixing reaction box 5, the power mechanism 1 can drive the carriage mechanism 3 to slide on the mixing reaction box 5 while driving the impurity filtering mechanism 2 to discharge the impurities, so that the carriage mechanism 3 drives the mixing mechanism 4 arranged at the lower end of the carriage mechanism to efficiently mix the sewage treatment agent in the mixing reaction box 5 with the sewage primarily filtered, the mixing reaction effect is improved, the treated water source falls into the heat exchange box 6 to be collected and reused, when the toilet sewage is hot water, the water source or gas arranged in the heat exchange mechanism in the heat exchange box 6 can be subjected to heat exchange, effectively utilizes the waste heat in the sewage of the toilet, and achieves the effects of energy conservation and environmental protection.

Example two:

as shown in fig. 1 to 11, the impurity filtering mechanism 2 includes a sewage inlet pipe 201, a front end cap 202, a cylindrical filtering basket 203, a rear end cap 204, a tapered impurity discharging hopper 205, an impurity outlet pipe 206, a rotating shaft 207, a first helical impeller 208 and a second helical impeller 209; the sewage inlet pipe 201 is connected in a matching way in the water inlet of the front end cover 202; a plurality of primary filtering holes are uniformly arranged on the cylindrical filtering basket 203 in a surrounding manner; two ends of the cylindrical filter basket 203 are arranged in an open manner and are respectively and rotatably matched in the front end cover 202 and the rear end cover 204; the front end cover 202 and the rear end cover 204 are respectively fixed at the front end and the rear end of the carriage mechanism 3; the rear end cover 204, the conical impurity discharging hopper 205 and the impurity output pipe 206 are sequentially and fixedly connected, and the axis of the rear end cover 204, the axis of the conical impurity discharging hopper 205 and the axis of the impurity output pipe 206 are collinear; the rotating shaft 207 is rotatably fitted in a central through hole of the front end cover 202; the rotating shaft 207 is fixedly connected with a first helical impeller 208 and a second helical impeller 209, the first helical impeller 208 is rotationally matched on the inner side of the cylindrical filter basket 203, and the second helical impeller 209 is rotationally matched on the inner sides of the conical impurity discharging hopper 205 and the impurity outlet pipe 206. The impurity filtering mechanism 2 is used for primarily filtering sewage and controlling the discharge work of filtered impurities by matching with the power mechanism 1, so that the impurities are prevented from being accumulated in the cylindrical filtering basket 203 to cause blockage, the cylindrical filtering basket 203 is not required to be cleaned frequently by manpower, and the filtering effect and the filtering efficiency are improved; sewage inlet tube 201 be used for with the water piping connection of bathroom sewage, sewage enters into through sewage inlet tube 201 and filters in cylindrical filtration basket 203, and rotation axis 207 can power unit 1's drive rotates down, can drive first helical impeller 208 and second helical impeller 209 during rotation of rotation axis 207 and rotate around self axis, and impurity discharge that will filter out through the cooperation with cylindrical filtration basket 203, toper trash removal fill 205 and impurity output tube 206 when first helical impeller 208 and second helical impeller 209 rotate need not the manual work and dismantles the clearance, and cleaning efficiency is higher.

Example three:

as shown in fig. 1 to 11, the carriage mechanism 3 includes a collar 301 and a slide cross-bar 302; two sleeving rings 301 are arranged, and two ends of the two sleeving rings 301 are fixedly connected with two ends of two opposite sliding transverse frames 302; the two sliding cross frames 302 are in sliding fit on the mixing reaction box 5; the inner side of one of the splicing rings 301 is fixedly connected with the front end cover 202, and the inner side of the other splicing ring 301 is fixedly connected with the rear end cover 204; the upper end of the mixing and stirring mechanism 4 is connected to the sliding cross frame 302 in a matching manner. The sliding cross frame 302 in the carriage mechanism 3 can slide on the mixing reaction box 5 in a reciprocating manner in the horizontal direction under the driving of the power mechanism 1, so as to drive the mixing mechanism 4 to mix and stir the filtered sewage and the sewage treatment agent in the mixing reaction box 5, thereby improving the reaction treatment effect; and the socket ring 301 and the sliding cross frame 302 drive the cylindrical filtering basket 203 to perform reciprocating sliding motion above the mixing reaction box 5, so that the sewage filtered by the cylindrical filtering basket 203 can be uniformly scattered at different positions in the mixing reaction box 5, and the mixing effect of the sewage and a sewage treatment agent can be improved.

Example four:

as shown in fig. 1 to 11, the power mechanism 1 comprises a servo motor 101, a driving worm 102, a driving worm gear 103, a wheel shaft 104, a rotating disc 105, an eccentric shaft 106 and a push-pull connecting rod 107; the servo motor 101 is fixedly connected to the mixing reaction box 5 through a motor bracket; an output shaft of the servo motor 101 is in transmission connection with the driving worm 102 through a coupler; the driving worm 102 is in meshing transmission connection with the driving worm wheel 103; the driving worm gear 103 is fixed in the middle of the wheel shaft 104; the wheel shaft 104 is rotationally matched on the motor bracket through a bearing bracket; a rotary disc 105 is fixed at the outer end of the wheel shaft 104; an eccentric shaft 106 is fixed at an eccentric position on the outer side surface of the rotating disc 105; one end of the push-pull connecting rod 107 is rotationally matched on the eccentric shaft 106, and the other end of the push-pull connecting rod 107 is rotationally matched on the sliding cross frame 302 so as to drive the sliding cross frame 302 to perform reciprocating sliding in the horizontal direction on the mixing reaction box 5; a sliding shaft hole is formed in the center of the driving worm 102, and the rotating shaft 207 is in sliding fit in the sliding shaft hole; and the inner wall of the sliding shaft hole is fixedly connected with a limiting convex edge which is in sliding fit with a limiting groove on the rotating shaft 207. The servo motor 101 in the power mechanism 1 is started to drive the driving worm 102 to rotate, and the driving worm 102 can drive the rotating shaft 207 to rotate when rotating, so that the impurity filtering mechanism 2 is controlled to discharge filtered impurities; the driving worm 102 can also drive the driving worm wheel 103 to rotate when rotating, the driving worm wheel 103 can drive the rotating disc 105 to rotate through the transmission of the wheel shaft 104 when rotating, the rotating disc 105 can drive one end of the push-pull connecting rod 107 to rotate and move around through the eccentric shaft 106 when rotating, and the other end of the push-pull connecting rod 107 drives the sliding cross frame 302 to perform reciprocating sliding movement in the horizontal direction on the mixing reaction box 5.

Example five:

as shown in fig. 1-11, a plurality of secondary filtering holes are uniformly formed on the bottom surface of the mixing reaction box 5, the mixing reaction box 5 is communicated with the inside of the heat exchange box 6 through the secondary filtering holes, the aperture of the secondary filtering holes is smaller than that of the primary filtering holes, and the multi-stage filtering improves the filtering treatment effect on sewage and facilitates the recycling of the sewage; a heat exchange mechanism is arranged in the heat exchange box 6, and a water outlet pipe with a control valve is arranged on the heat exchange box 6.

The heat exchange mechanism comprises a water inlet pipe with a control valve, a heat exchange box and a drain pipe with a control valve; the water inlet pipe and the water outlet pipe are respectively fixedly connected and communicated with two ends of the heat exchange box; the water inlet pipe and the water outlet pipe are respectively fixed in a sealing way and penetrate out of two ends of the heat exchange box 6. When bathroom sewage has the waste heat, be connected the inlet tube with the water source that needs the heating to use, cold water enters into to the heat transfer box through the inlet tube in, and cold water in the heat transfer box carries out the heat transfer under the heat energy that contains waste heat sewage in heat transfer box 6, then discharges to subsequent firing equipment through the drain pipe, required energy consumption when can reducing follow-up heating, and improves heating efficiency.

Example six:

as shown in fig. 1-11, the toilet sewage treatment and recycling device further comprises a filter basket cleaning brush 7; the sleeving ring 301 is fixedly connected with a filter basket cleaning brush 7; the bristles of the filter basket cleaning brush 7 engage the cylindrical filter basket 203. The cylindrical filter basket 203 is rotated to enable different positions of the cylindrical filter basket 203 to be in contact with the filter basket cleaning brush 7, so that the cleaning and brushing work of the filter basket cleaning brush 7 on the cylindrical filter basket 203 is achieved, and impurities are prevented from being blocked in one-level filter holes of the cylindrical filter basket 203 when the cylindrical filter basket 203 is filtered.

Example seven:

as shown in fig. 1-11, the toilet sewage treatment and recycling device further comprises a cleaning linkage mechanism 8; the cleaning linkage mechanism 8 comprises a first linkage rack 801, a first gear 802, a first linkage shaft 803, a driving bevel gear 804, a driven bevel gear 805, a linkage worm 806, a linkage worm wheel 807 and a bearing rod seat 808; the front end and the rear end of the first linkage rack 801 are fixed at the front end and the rear end of the mixing reaction box 5; the teeth on the outer side surface of the first linkage rack 801 are in meshing transmission connection with the first gear 802; the first gear 802 and the drive bevel gear 804 are respectively fixed at two ends of the first linkage shaft 803; the first linkage shaft 803 is rotationally matched with the sliding cross frame 302; the driving bevel gear 804 is in meshed transmission connection with the driven bevel gear 805; the driven bevel gear 805 is fixed on the linkage worm 806; the linkage worm 806 is in running fit with a bearing rod seat 808, and the bearing rod seat 808 is fixed on the sliding cross frame 302; the linkage worm 806 is in meshed transmission connection with the linkage worm wheel 807; a circular mounting hole is formed in the center of the linkage worm wheel 807, and the cylindrical filter basket 203 is fixedly connected to the inner side of the circular mounting hole. The first linkage rack 801 inside the cleaning linkage mechanism 8 is fixed on the mixing reaction box 5, when the first linkage shaft 803 is driven by the sliding cross frame 302 to reciprocate horizontally, the first gear 802 can be driven to roll on the first linkage rack 801, thereby drive first gear 802 and rotate around self axis, can drive the rotation of drive bevel gear 804 through first universal driving shaft 803 when first gear 802 rotates, can mesh the transmission when drive bevel gear 804 rotates and drive driven bevel gear 805 and rotate, can drive linkage worm 806 when driven bevel gear 805 rotates and rotate, can drive when linkage worm 806 rotates and drive linkage worm wheel 807 and rotate, can drive when linkage worm wheel 807 rotates and drive cylindrical filter basket 203 and rotate, make different positions of cylindrical filter basket 203 and strain basket cleaning brush 7 contact, thereby realize straining basket cleaning brush 7 and filter the cleaning of basket 203 to cylindrical filter basket 203.

Example eight:

as shown in fig. 1 to 11, the mixing and stirring mechanism 4 includes a hanger 401, a stirring shaft 402, a stirring impeller 403, a driven pulley 404 and a horizontal slide 405; the number of the hanging brackets 401 is two, and the upper ends of the two hanging brackets 401 are relatively fixed at the front end and the rear end of the bottom surface of the sliding cross frame 302; the lower ends of the two hanging brackets 401 are respectively and rotatably connected with one end of a stirring shaft 402, the middle parts of the two stirring shafts 402 are respectively and fixedly connected with a stirring impeller 403, and the two stirring impellers 403 are rotatably matched on the inner side of the mixing reaction box 5; the other ends of the two stirring shafts 402 are rotatably matched on a horizontal sliding seat 405, and the horizontal sliding seat 405 is in sliding fit in a transverse sliding groove on the inner side surface of the mixing reaction box 5; two stirring shafts 402 are respectively fixedly connected with a driven pulley 404.

The toilet sewage treatment and recycling device also comprises a stirring linkage mechanism 9; the stirring linkage mechanism 9 comprises a second linkage rack 901, a second gear 902, a second linkage shaft 903, a bearing seat 904 and a driving pulley 905; two ends of the second linkage rack 901 are respectively fixed at the front end and the rear end of the mixing reaction box 5; the second linkage rack 901 and the first linkage rack 801 are respectively positioned at two sides of the mixing reaction box 5; the second gear 902 is in meshed transmission connection with the second linkage rack 901; the second gear 902 and the driving pulley 905 are fixed at two ends of the second coupling shaft 903 respectively; the second coupling shaft 903 is rotatably fitted on the sliding cross frame 302 through a bearing seat 904; the driving pulley 905 is connected with the two driven pulleys 404 through synchronous belt transmission so as to drive the two stirring shafts 402 to rotate.

A second linkage rack 901 inside the stirring linkage mechanism 9 is fixed on the mixing reaction box 5, a bearing pedestal 904 can drive a second linkage shaft 903 to move when driven by the sliding cross frame 302 to reciprocate in the horizontal direction, the second linkage shaft 903 can drive a second gear 902 to roll on the second linkage rack 901, so as to drive the second gear 902 to rotate around the axis of the second gear 902, the second gear 902 can rotate and drive a driving pulley 905 to rotate through the second linkage shaft 903, the driving pulley 905 can drive two driven pulleys 404 to rotate through synchronous belt transmission when rotating, the driven pulleys 404 can drive the second linkage shaft 903 to rotate, the second linkage shaft 903 can drive a stirring impeller 403 to carry out rotational flow mixing stirring when rotating, and the stirring linkage mechanism 9 can carry out reciprocating displacement motion in the horizontal direction under the drive of the sliding cross frame 302, the stirring impeller 403 can contact with sewage treatment agents and sewage at different positions, so that the mixing uniformity of the sewage treatment agents and the sewage is improved, and the sewage reaction treatment effect is improved.

The principle is as follows: the toilet sewage treatment and recycling device is used for filtering and recycling the sewage in the toilet; when the device is used, a sewage drainage pipe is communicated with the impurity filtering mechanism 2, the power mechanism 1 can be driven to drive the impurity filtering mechanism 2 to operate after being started, impurities filtered out from the inside of the impurity filtering mechanism 2 are led out to the outside, sewage filtered by the impurity filtering mechanism 2 falls into the mixing reaction box 5, a sewage treatment agent is put into the mixing reaction box 5, the power mechanism 1 can drive the carriage mechanism 3 to slide on the mixing reaction box 5 while driving the impurity filtering mechanism 2 to discharge the impurities, so that the carriage mechanism 3 drives the mixing mechanism 4 arranged at the lower end of the carriage mechanism to efficiently mix the sewage treatment agent in the mixing reaction box 5 with the sewage primarily filtered, the mixing reaction effect is improved, the treated water source falls into the heat exchange box 6 to be collected and reused, when the toilet sewage is hot water, the water source or gas arranged in the heat exchange mechanism in the heat exchange box 6 can be subjected to heat exchange, effectively utilizes the waste heat in the sewage of the toilet, and achieves the effects of energy conservation and environmental protection.

The embodiments are described in a progressive mode in the specification, the emphasis of each embodiment is on the difference from the other embodiments, and the same and similar parts among the embodiments can be referred to each other. It should be noted that, for those skilled in the art, it is possible to make several improvements and modifications to the present application without departing from the principle of the present application, and such improvements and modifications also fall within the scope of the claims of the present application.

It is further noted that, in the present specification, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in the process, method, article, or apparatus that comprises the element.

Claims (4)

1. Bathroom sewage treatment recycles device includes power unit (1), impurity filtering mechanism (2), balladeur train mechanism (3), mixes and stirs mechanism (4), mixing reaction case (5) and heat transfer case (6), its characterized in that: the power mechanism (1) is in transmission connection with the impurity filtering mechanism (2) and the sliding frame mechanism (3); the impurity filtering mechanism (2) is connected to the sliding frame mechanism (3) in a matching manner and is positioned right above the mixing reaction box (5) with the top opened; the sliding frame mechanism (3) is in sliding fit with the mixing reaction box (5), the upper end of the mixing mechanism (4) is connected to the sliding frame mechanism (3) in a matching manner, and the lower end of the mixing mechanism (4) is connected to the inner side of the mixing reaction box (5) in a matching manner; the lower end of the mixing reaction box (5) is hermetically connected and communicated with the heat exchange box (6);

the impurity filtering mechanism (2) comprises a sewage inlet pipe (201), a front end cover (202), a cylindrical filtering basket (203), a rear end cover (204), a conical impurity discharging hopper (205), an impurity outlet pipe (206), a rotating shaft (207), a first spiral impeller (208) and a second spiral impeller (209); the sewage inlet pipe (201) is connected in a water inlet of the front end cover (202) in a matching manner; a plurality of first-stage filtering holes are uniformly arranged on the cylindrical filtering basket (203) in a surrounding manner; the two ends of the cylindrical filtering basket (203) are arranged in an open mode and are respectively and rotatably matched in the front end cover (202) and the rear end cover (204); the front end cover (202) and the rear end cover (204) are respectively fixed at the front end and the rear end of the sliding frame mechanism (3); the rear end cover (204), the conical impurity discharging hopper (205) and the impurity output pipe (206) are fixedly connected in sequence, and the axis of the rear end cover (204), the axis of the conical impurity discharging hopper (205) and the axis of the impurity output pipe (206) are collinear; the rotating shaft (207) is rotatably matched in a central through hole of the front end cover (202); the rotating shaft (207) is fixedly connected with a first spiral impeller (208) and a second spiral impeller (209), the first spiral impeller (208) is rotationally matched on the inner side of the cylindrical filtering basket (203), and the second spiral impeller (209) is rotationally matched on the inner sides of the conical impurity discharging hopper (205) and the impurity discharging pipe (206);

the sliding frame mechanism (3) comprises a socket ring (301) and a sliding cross frame (302); two sleeving rings (301) are arranged, and two ends of the two sleeving rings (301) are fixedly connected with two ends of two opposite sliding transverse frames (302); the two sliding cross frames (302) are in sliding fit on the mixing reaction box (5); the inner side of one of the socket rings (301) is fixedly connected with the front end cover (202), and the inner side of the other socket ring (301) is fixedly connected with the rear end cover (204); the upper end of the mixing and stirring mechanism (4) is connected to the sliding transverse frame (302) in a matching manner;

the power mechanism (1) comprises a servo motor (101), a driving worm (102), a driving worm wheel (103), a wheel shaft (104), a rotating disc (105), an eccentric shaft (106) and a push-pull connecting rod (107); the servo motor (101) is fixedly connected to the mixed reaction box (5) through a motor support; an output shaft of the servo motor (101) is in transmission connection with the driving worm (102) through a coupler; the driving worm (102) is in meshed transmission connection with the driving worm wheel (103); the driving worm wheel (103) is fixed in the middle of the wheel shaft (104); the wheel shaft (104) is rotationally matched on the motor bracket through a bearing bracket; a rotary disc (105) is fixed at the outer end of the wheel shaft (104); an eccentric shaft (106) is fixed at the eccentric position of the outer side surface of the rotating disc (105); one end of the push-pull connecting rod (107) is in rotating fit with the eccentric shaft (106), and the other end of the push-pull connecting rod (107) is in rotating fit with the sliding cross frame (302) so as to drive the sliding cross frame (302) to perform reciprocating sliding in the horizontal direction on the mixing reaction box (5); the center of the driving worm (102) is provided with a sliding shaft hole, and a rotating shaft (207) is in sliding fit in the sliding shaft hole; the inner wall of the sliding shaft hole is fixedly connected with a limiting convex edge which is in sliding fit with a limiting groove on the rotating shaft (207);

the toilet sewage treatment and recycling device also comprises a cleaning linkage mechanism (8); the cleaning linkage mechanism (8) comprises a first linkage rack (801), a first gear (802), a first linkage shaft (803), a driving bevel gear (804), a driven bevel gear (805), a linkage worm (806), a linkage worm wheel (807) and a bearing rod seat (808); the front end and the rear end of the first linkage rack (801) are fixed at the front end and the rear end of the mixing reaction box (5); the teeth on the outer side surface of the first linkage rack (801) are in meshed transmission connection with the first gear (802); the first gear (802) and the driving bevel gear (804) are respectively fixed at two ends of the first linkage shaft (803); the first linkage shaft (803) is rotationally matched on the sliding cross frame (302); the driving bevel gear (804) is in meshed transmission connection with the driven bevel gear (805); the driven bevel gear (805) is fixed on the linkage worm (806); the linkage worm (806) is in running fit with a bearing rod seat (808), and the bearing rod seat (808) is fixed on the sliding cross frame (302); the linkage worm (806) is in meshed transmission connection with the linkage worm wheel (807); a circular mounting hole is formed in the center of the linkage worm wheel (807), and the cylindrical filter basket (203) is fixedly connected to the inner side of the circular mounting hole;

the mixing and stirring mechanism (4) comprises a hanger (401), a stirring shaft (402), a stirring impeller (403), a driven pulley (404) and a horizontal sliding seat (405); the number of the hanging frames (401) is two, and the upper ends of the two hanging frames (401) are relatively fixed at the front end and the rear end of the bottom surface of the sliding cross frame (302); the lower ends of the two hanging brackets (401) are respectively and rotatably connected with one end of a stirring shaft (402), the middle parts of the two stirring shafts (402) are respectively and fixedly connected with a stirring impeller (403), and the two stirring impellers (403) are rotatably matched on the inner side of the mixing reaction box (5); the other ends of the two stirring shafts (402) are in running fit with a horizontal sliding seat (405), and the horizontal sliding seat (405) is in sliding fit with a transverse sliding groove on the inner side surface of the mixing reaction box (5); two stirring shafts (402) are respectively and fixedly connected with a driven belt wheel (404);

the toilet sewage treatment and recycling device also comprises a stirring linkage mechanism (9); the stirring linkage mechanism (9) comprises a second linkage rack (901), a second gear (902), a second linkage shaft (903), a bearing seat (904) and a driving belt wheel (905); two ends of the second linkage rack (901) are respectively fixed at the front end and the rear end of the mixing reaction box (5); the second linkage rack (901) and the first linkage rack (801) are respectively positioned at two sides of the mixing reaction box (5); the second gear (902) is in meshed transmission connection with the second linkage rack (901); the second gear (902) and the driving pulley (905) are respectively fixed at two ends of the second linkage shaft (903); the second coupling shaft (903) is rotatably matched on the sliding cross frame (302) through a shaft bearing seat (904); the driving belt wheel (905) is connected with the two driven belt wheels (404) through synchronous belt transmission so as to drive the two stirring shafts (402) to rotate.

2. The toilet sewage treatment and reuse apparatus according to claim 1, wherein: a plurality of secondary filtering holes are uniformly formed in the bottom surface of the mixing reaction box (5), the mixing reaction box (5) is communicated with the interior of the heat exchange box (6) through the secondary filtering holes, and the aperture of each secondary filtering hole is smaller than that of each primary filtering hole; a heat exchange mechanism is arranged in the heat exchange box (6), and a water outlet pipe with a control valve is arranged on the heat exchange box (6).

3. The toilet sewage treatment and reuse apparatus according to claim 2, wherein: the heat exchange mechanism comprises a water inlet pipe with a control valve, a heat exchange box and a drain pipe with a control valve; the water inlet pipe and the water outlet pipe are respectively fixedly connected and communicated with two ends of the heat exchange box; the water inlet pipe and the water outlet pipe are respectively fixed in a sealing way and penetrate out of two ends of the heat exchange box (6).

4. The toilet sewage treatment and reuse apparatus according to claim 3, wherein: also comprises a filter basket cleaning brush (7); a filter basket cleaning brush (7) is fixedly connected to the sleeving ring (301); the brush hair of the filter basket cleaning brush (7) is attached to the cylindrical filter basket (203).

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