CN115077269A

CN115077269A - Bathing wastewater waste heat utilization equipment based on dynamic characteristics

Info

Publication number: CN115077269A
Application number: CN202210855650.9A
Authority: CN
Inventors: 高亚民; 程世哲; 闫首弟
Original assignee: Shenyang Hong Cheng Shiji Refrigeration Equipment Co ltd
Current assignee: Shenyang Hong Cheng Shiji Refrigeration Equipment Co ltd
Priority date: 2022-07-21
Filing date: 2022-07-21
Publication date: 2022-09-20
Anticipated expiration: 2042-07-21
Also published as: CN115077269B

Abstract

The invention belongs to the technical field of waste heat utilization of bath waste water, and particularly relates to a waste heat utilization device of bath waste water based on dynamic characteristics, which comprises a waste heat recovery main body, a wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism, a treading feedback type temperature difference deformation rolling type hair collection mechanism and a cuttage type multi-dimensional heat preservation mechanism, wherein the wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism is arranged in the waste heat recovery main body, the treading feedback type temperature difference deformation rolling type hair collection mechanism is arranged in the wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism, and the cuttage type multi-dimensional heat preservation mechanism is arranged in the wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism; the invention provides a wrapping opposite-flushing type fluid inward-turning efficient heat exchange mechanism, which can efficiently recycle the waste heat of bath wastewater through the mutual cooperation of an efficient heat energy recovery assembly, a coiled permeable nested waste heat recovery mechanism and an internal turning type unpowered accelerating heat conduction mechanism.

Description

Bathing wastewater waste heat utilization equipment based on dynamic characteristics

Technical Field

The invention belongs to the technical field of waste heat utilization of bath wastewater, and particularly relates to a waste heat utilization device of bath wastewater based on dynamic characteristics.

Background

At present, most of domestic waste water after bathing is directly discharged into a sewer, according to actual measurement results, the temperature of the waste water after bathing still ranges from 35 ℃ to 40 ℃, the waste water still has high heat, if the waste water is directly discharged, a large amount of energy is wasted, at present, partial devices for recovering waste heat of the bathing waste water exist in the market, but the general power of the devices is high, the heat recovery efficiency is not high, the devices are not suitable for families, and the hair after bathing is easy to stack a sewer pipe, so that the waste heat of the waste water cannot be effectively utilized.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides a bath wastewater waste heat utilization device based on dynamic characteristics, aiming at solving the problems that partial bath wastewater waste heat recovery devices exist in the market, but the general power of the devices is higher, the heat recovery efficiency is not high, and the devices are not suitable for household use.

The technical scheme adopted by the invention is as follows: the invention provides a bath wastewater waste heat utilization device based on dynamic characteristics, which comprises a waste heat recovery main body, a wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism, a treading feedback type temperature difference deformation rolling type hair collection mechanism and a cuttage type multi-dimensional heat preservation mechanism, wherein the wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism is arranged in the waste heat recovery main body, the treading feedback type temperature difference deformation rolling type hair collection mechanism is arranged in the wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism, and the cuttage type multi-dimensional heat preservation mechanism is arranged in the wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism.

Further, the waste heat recovery main part includes water heater, water inlet one, delivery port one, gondola water faucet, heat transfer platform and water service pipe, the heat transfer platform is located in the waste heat recovery main part, the one end of water service pipe can be dismantled and locate heat transfer bench side one end, the other end of water service pipe is located to the water heater, lower extreme one side of water heater is located to water inlet one, the other end of water service pipe can be dismantled and locate water inlet one, the lower extreme opposite side of water heater is located to delivery port one, the one end of gondola water faucet can be dismantled and locate delivery port one.

Further, parcel formula offset type fluid enstrophe high-efficient heat transfer mechanism includes that high-efficient heat recovery subassembly, coiled type infiltration nested formula waste heat recovery mechanism and inside tumble unpowered heat conduction mechanism with higher speed, the heat transfer bench is located to the high-efficient heat recovery subassembly, coiled type infiltration nested formula waste heat recovery mechanism locates in the heat transfer bench, the unpowered heat conduction mechanism that accelerates of inside tumble type locates in the nested formula waste heat recovery mechanism of coiled type infiltration.

Further, the efficient heat energy recovery assembly comprises a second water inlet, a second water outlet, a floor drain and an enclosing block, the second water inlet is arranged on one side of the upper end of the heat exchange table, the second water outlet is arranged on the other side of the upper end of the heat exchange table, one end of the water through pipe is detachably arranged on the second water outlet, the enclosing block is arranged on the heat exchange table, and the floor drain is detachably arranged on the heat exchange table.

Further, nested formula waste heat recovery mechanism of coil type infiltration includes coil type heat exchange inlet tube, coil type heat exchange waste water discharge pipe, waste water inlet and waste water discharge port, waste water inlet locates the lower extreme of floor drain, waste water discharge port locates on the lateral wall of heat transfer platform, the one end of coil type heat exchange inlet tube link up and locates on water inlet two, the other end of coil type heat exchange inlet tube link up and locates on delivery port two, coil type heat exchange waste water discharge pipe cup joints and locates on the coil type heat exchange inlet tube, the one end of coil type heat exchange waste water discharge pipe link up and locates on the waste water discharge port, the other end of coil type heat exchange waste water discharge pipe is located and is trampled on the mechanism is collected to reaction type temperature difference deformation rolling type hair.

Further, inside formula of tumbling unpowered heat conduction mechanism with higher speed includes spout, pulley, screw and puddler, the spout is located in the pipe wall of coiling type heat exchange inlet tube, the pulley slides and locates in the spout, the other end of pulley is located to the one end of screw, the puddler is located on the lateral wall of screw.

Further, the treading feedback type temperature difference deformation rolling type hair collecting mechanism comprises a pressure feedback type driving transmission mechanism, a pulling type reciprocating rolling mechanism and a temperature triggering rolling piece deformation type contraction mechanism, the pressure feedback type driving transmission mechanism is arranged on the heat exchange table, the pulling type reciprocating rolling mechanism is arranged in the heat exchange table, and the temperature triggering rolling piece deformation type contraction mechanism is arranged at the lower end of the floor drain.

Further, pressure feedback formula drive transmission mechanism includes the silica gel head, steps on a pipe one, tramples a pipe two, piston one, spring one, communicating pipe and water tray, the inside upper end of heat transfer platform is located to the water tray, the one end of trampling a pipe two link up and locate on the water tray, piston one slides and locates in trampling a pipe two, the lower extreme of piston one is located to the one end of spring one, the inner wall lower extreme of trampling a pipe two is located to the other end of spring one, trample a pipe one and locate on the piston one, the silica gel head is located and is trampled on a pipe one, the one end of communicating pipe link up and locates on the water tray.

Furthermore, the pull-type reciprocating winding mechanism comprises a first push-pull pipe, a second piston and flowing liquid, one end of the first push-pull pipe is communicated with one end of the communicating pipe, the second piston is slidably arranged in the first push-pull pipe, one end of the second push-pull pipe is arranged on the second piston, and the flowing liquid flows in the first push-pull pipe, the communicating pipe, the water tray and the trampling pipe.

Furthermore, the temperature-triggered rolling sheet deformation type contraction mechanism comprises a porous filter screen, a rolling rod, a two-way shape memory rolling sheet, an elastic memory alloy barb, a bearing I, a bearing II, a tooth block I, a tooth block II and a connecting pipe, the bearing II is arranged at the lower end of the wastewater discharge port, the bearing I is arranged at the water inlet end of the coiled heat exchange wastewater discharge pipe, one end of the connecting pipe is arranged at the lower end of the bearing II in a penetrating way, the other end of the connecting pipe is arranged on the bearing I in a penetrating way, the porous filter screen is arranged in the connecting pipe, the rolling rod is arranged at the lower end of the floor drain, the two-way shape memory rolling sheet is arranged on the side wall of the rolling rod, the elastic memory alloy barb is arranged on the two-way shape memory rolling piece, the first tooth block is arranged on the side wall of the second push-pull pipe, the tooth blocks are arranged on the side wall of the connecting pipe in an annular array mode, and the first tooth block and the second tooth block are connected in a meshing rotation mode; the cuttage formula multidimension heat preservation mechanism includes heat preservation one, heat preservation two and insulating block three, the inside bottom of heat exchange platform is located to heat preservation one, the upper end of coil type infiltration nested formula waste heat recovery mechanism is located to heat preservation two, insulating block three is located between heat preservation one and the heat preservation two.

The invention adopting the structure has the following beneficial effects: the invention provides a bath wastewater waste heat utilization device based on dynamic characteristics, which realizes the following beneficial effects:

(1) in order to improve the utilization efficiency of the waste heat of the bath wastewater, the invention provides a wrapping type hedging fluid inversion efficient heat exchange mechanism, and the waste heat of the bath wastewater can be efficiently recycled through the mutual cooperation of an efficient heat energy recovery assembly, a coiled type infiltration nested waste heat recovery mechanism and an internal connected tumbling type unpowered accelerating heat conduction mechanism.

(2) In order to further improve the practicability and the popularization, the invention provides a treading feedback type temperature difference deformation rolling type hair collecting mechanism, and the hair is prevented from influencing the recovery efficiency when the waste heat of the bathing wastewater is utilized through the mutual matching of a pressure feedback type driving transmission mechanism, a pulling type reciprocating rolling mechanism and a temperature triggering rolling piece deformation type contraction mechanism.

(3) The temperature-triggered winding-piece-shaped variable shrinkage mechanism can roll hair irregularly, so that a sewer is prevented from being blocked.

(4) The setting of cuttage formula multidimension heat preservation mechanism reduces the energy loss of waste water in the flow process.

(5) The arrangement of the elastic memory alloy barb facilitates the hair winding.

Drawings

FIG. 1 is a front view of a bath wastewater waste heat utilization device based on dynamic characteristics, which is provided by the invention;

FIG. 2 is a front sectional view of a bath wastewater waste heat utilization device based on dynamic characteristics, which is provided by the invention;

FIG. 3 is a left side sectional view of a bath wastewater waste heat utilization device based on dynamic characteristics according to the present invention;

FIG. 4 is a top view of a bathing wastewater waste heat utilization device based on dynamic characteristics, which is provided by the invention;

FIG. 5 is a top sectional view of a bath wastewater waste heat utilization device based on dynamic characteristics according to the present invention;

FIG. 6 is a rear view of the internal tumbling unpowered accelerating heat transfer mechanism;

FIG. 7 is a right side view of the internal tumbling unpowered accelerating heat transfer mechanism;

FIG. 8 is a schematic view of an initial state of the temperature triggered take-up sheet form shrink mechanism;

FIG. 9 is a schematic view of the temperature triggered winding deformation type contraction mechanism in an expanded state;

FIG. 10 is an enlarged view of a portion A of FIG. 2;

FIG. 11 is a partial enlarged view of portion B of FIG. 3;

fig. 12 is a partial enlarged view of a portion C in fig. 5.

Wherein, 1, a waste heat recovery main body, 2, a wrapping hedging type fluid internal turning high-efficiency heat exchange mechanism, 3, a treading feedback type temperature difference deformation rolling hair collection mechanism, 4, a cutting type multidimensional heat preservation mechanism, 5, a water heater, 6, a water inlet I, 7, a water outlet I, 8, a shower head, 9, a heat exchange table, 10, a water pipe, 11, a high-efficiency heat energy recovery component, 12, a coiled penetration nested type waste heat recovery mechanism, 13, an internal rolling type unpowered accelerating heat conduction mechanism, 14, a water inlet II, 15, a water outlet II, 16, a floor drain, 17, a surrounding block, 18, a coiled heat exchange water inlet pipe, 19, a coiled heat exchange waste water discharge pipe, 20, a waste water discharge inlet, 21, a waste water discharge port, 22, a sliding chute, 23, a pulley, 24, a propeller, 25, a stirring rod, 26, a pressure feedback type driving transmission mechanism, 27, a pulling type reciprocating rolling mechanism, 28. the temperature-triggered winding sheet type variable contraction mechanism comprises a temperature-triggered winding sheet type variable contraction mechanism body 29, a silica gel head 30, a first stepping pipe 31, a second stepping pipe 32, a first piston 33, a first spring 34, a communication pipe 35, a water tray 36, a first push-pull pipe 37, a second push-pull pipe 38, a second piston 39, flowing liquid 40, a porous filter screen 41, a winding rod 42, a two-way shape memory winding sheet 43, an elastic memory alloy barb 44, a first bearing 45, a second bearing 46, a first tooth block 47, a second tooth block 48, a first heat-preservation layer 49, a second heat-preservation layer 50, a third heat-preservation block 51 and a connecting pipe.

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the 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 invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present invention.

As shown in figure 2, the invention provides a bath wastewater waste heat utilization device based on dynamic characteristics, which comprises a waste heat recovery main body 1, a wrapped opposite-flushing type fluid inward turning efficient heat exchange mechanism 2, a treading feedback type temperature difference deformation rolling type hair collection mechanism 3 and a cutting type multi-dimensional heat preservation mechanism 4, wherein the wrapped opposite-flushing type fluid inward turning efficient heat exchange mechanism 2 is arranged in the waste heat recovery main body 1, the treading feedback type temperature difference deformation rolling type hair collection mechanism 3 is arranged in the wrapped opposite-flushing type fluid inward turning efficient heat exchange mechanism 2, and the cutting type multi-dimensional heat preservation mechanism 4 is arranged in the wrapped opposite-flushing type fluid inward turning efficient heat exchange mechanism 2.

As shown in fig. 2, the waste heat recovery main body 1 includes a water heater 5, a water inlet 6, a water outlet 7, a shower head 8, a heat exchange table 9 and a water service pipe 10, the heat exchange table 9 is arranged on the waste heat recovery main body 1, one end of the water service pipe 10 can be detachably arranged at one end of the upper side of the heat exchange table 9, the water heater 5 is arranged at the other end of the water service pipe 10, the water inlet 6 is arranged at one side of the lower end of the water heater 5, the other end of the water service pipe 10 can be detachably arranged on the water inlet 6, the water outlet 7 is arranged at the other side of the lower end of the water heater 5, and one end of the shower head 8 can be detachably arranged on the water outlet 7.

As shown in fig. 2 and 5, the wrapped opposite-flushing fluid inward-turning efficient heat exchange mechanism 2 comprises an efficient heat recovery assembly 11, a coiled permeable nested waste heat recovery mechanism 12 and an internal tumbling unpowered accelerating heat conduction mechanism 13, the efficient heat recovery assembly 11 is arranged on the heat exchange table 9, the coiled permeable nested waste heat recovery mechanism 12 is arranged in the heat exchange table 9, and the internal tumbling unpowered accelerating heat conduction mechanism 13 is arranged in the coiled permeable nested waste heat recovery mechanism 12.

As shown in fig. 4 and 5, the high-efficiency heat energy recovery assembly 11 includes a second water inlet 14, a second water outlet 15, a floor drain 16 and an enclosing block 17, the second water inlet 14 is disposed on one side of the upper end of the heat exchange platform 9, the second water outlet 15 is disposed on the other side of the upper end of the heat exchange platform 9, one end of the water pipe 10 is detachably disposed on the second water outlet 15, the enclosing block 17 is disposed on the heat exchange platform 9, and the floor drain 16 is detachably disposed on the heat exchange platform 9.

As shown in fig. 2, fig. 4, fig. 5, and fig. 12, the coil-type infiltration nested waste heat recovery mechanism 12 includes a coil-type heat exchange water inlet pipe 18, a coil-type heat exchange wastewater discharge pipe 19, a wastewater discharge port 20, and a wastewater discharge port 21, the wastewater discharge port 20 is disposed at the lower end of the floor drain 16, the wastewater discharge port 21 is disposed on the sidewall of the heat exchange table 9, one end of the coil-type heat exchange water inlet pipe 18 is disposed at the water inlet port two 14, the other end of the coil-type heat exchange water inlet pipe 18 is disposed at the water outlet port two 15, the coil-type heat exchange wastewater discharge pipe 19 is sleeved on the coil-type heat exchange water inlet pipe 18, one end of the coil-type heat exchange wastewater discharge pipe 19 is disposed at the wastewater discharge port 21, and the other end of the coil-type heat exchange wastewater discharge pipe 19 is disposed at the winding position of the treading feedback type temperature difference deformation hair collection mechanism 3.

As shown in fig. 5, 6 and 7, the internal rolling unpowered accelerating heat conducting mechanism 13 includes a sliding chute 22, a pulley 23, a propeller 24 and a stirring rod 25, the sliding chute 22 is disposed in the pipe wall of the coiled heat exchange water inlet pipe 18, the pulley 23 is slidably disposed in the sliding chute 22, one end of the propeller 24 is disposed at the other end of the pulley 23, and the stirring rod 25 is disposed on the side wall of the propeller 24.

As shown in fig. 2, 3, 4 and 5, the treading feedback type temperature difference deformation rolling type hair collecting mechanism 3 comprises a pressure feedback type driving transmission mechanism 26, a pulling type reciprocating rolling mechanism 27 and a temperature triggering rolling piece deformation type contraction mechanism 28, wherein the pressure feedback type driving transmission mechanism 26 is arranged on the heat exchange platform 9, the pulling type reciprocating rolling mechanism 27 is arranged in the heat exchange platform 9, and the temperature triggering rolling piece deformation type contraction mechanism 28 is arranged at the lower end of the floor drain 16.

As shown in fig. 2 and 10, the pressure feedback type driving transmission mechanism 26 includes a silica gel head 29, a first stepping tube 30, a second stepping tube 31, a first piston 32, a first spring 33, a communication pipe 34 and a water tray 35, the water tray 35 is disposed at the upper end inside the heat exchange platform 9, one end of the second stepping tube 31 penetrates the water tray 35, the first piston 32 is slidably disposed in the second stepping tube 31, one end of the first spring 33 is disposed at the lower end of the first piston 32, the other end of the first spring 33 is disposed at the lower end of the inner wall of the second stepping tube 31, the first stepping tube 30 is disposed on the first piston 32, the silica gel head 29 is disposed on the first stepping tube 30, and one end of the communication pipe 34 penetrates the water tray 35.

As shown in fig. 2, 5, 10 and 12, the pull-type reciprocating winding mechanism 27 includes a first push-pull pipe 36, a second push-pull pipe 37, a second piston 38 and a flowing liquid 39, wherein one end of the first push-pull pipe 36 is disposed through one end of the communicating pipe 34, the second piston 38 is slidably disposed in the first push-pull pipe 36, one end of the second push-pull pipe 37 is disposed on the second piston 38, and the flowing liquid 39 is movably disposed in the first push-pull pipe 36, the communicating pipe 34, the water tray 35 and the second stepping pipe 31.

As shown in fig. 2, 3, 4, 5, 8, 9, 11, 12, the temperature-triggered winding sheet type variable contraction mechanism 28 includes a porous filter screen 40, a winding rod 41, a two-way shape memory winding sheet 42, an elastic memory alloy barb 43, a first bearing 44, a second bearing 45, a first tooth block 46, a second tooth block 47, and a connecting pipe 51, the second bearing 45 is disposed at the lower end of the waste water discharge port 20, the first bearing 44 is disposed at the water inlet end of the coiled heat exchange waste water discharge pipe 19, one end of the connecting pipe 51 is disposed at the lower end of the second bearing 45, the other end of the connecting pipe 51 is disposed on the first bearing 44, the porous filter screen 40 is disposed in the connecting pipe 51, the winding rod 41 is disposed at the lower end of the floor drain 16, the two-way shape memory winding sheet 42 is disposed on the side wall of the winding rod 41, the elastic memory alloy barb 43 is disposed on the two-way shape memory winding sheet 42, the first tooth block 46 is disposed on the side wall of the push-pull pipe 37, the second gear block 47 is annularly arranged on the side wall of the connecting pipe 51 in an array, and the first gear block 46 and the second gear block 47 are in meshed rotary connection; inserting type multidimension heat preservation mechanism 4 includes heat preservation 48, two 49 heat preservation and insulating block three 50, and the inside bottom of heat transfer platform 9 is located to heat preservation 48, and the upper end of coiled infiltration nested formula waste heat recovery mechanism 12 is located to two 49 heat preservation, and insulating block three 50 is located between heat preservation 48 and the two 49 heat preservation.

When the water heater is used specifically, the water heater 5 is started, tap water is introduced into the water inlet II 14, the tap water is heated by the water heater 5 and then sprayed out through the shower head 8, waste heat and waste water after washing the body enters the coiled heat exchange waste water discharge pipe 19 through the floor drain 16, the tap water entering later is heated, in order to improve the efficiency of heat energy conversion, the later tap water drives the propeller 24 to rotate when passing through the coiled heat exchange water inlet pipe 18, the propeller 24 rotates to drive the stirring rod 25 to rotate, the stirring rod 25 rotates to stir the tap water in the coiled heat exchange water inlet pipe 18, the situation that the water close to the inner wall of the coiled heat exchange water inlet pipe 18 is heated quickly and the middle is heated slowly is avoided, when hot water flows into the porous filter screen 40, the two-way shape memory coiling sheet 42 is changed into a straight shape from a bent shape, and when a user steps on the silica gel head 29, the stepping pipe I30 is driven to move downwards, the first trampling pipe 30 moves to drive the first piston 32 to move, the first piston 32 moves to extrude water in the second trampling pipe 31 into the first push-pull pipe 36, the second piston 38 is pushed to drive the second push-pull pipe 37 to move, the second push-pull pipe 37 moves to drive the first tooth block 46 to move, the first tooth block 46 moves to drive the second tooth block 47 to rotate, the second tooth block 47 rotates to drive the connecting pipe 51 to rotate, the connecting pipe 51 rotates to drive the porous filter screen 40 to rotate, so that hair in the porous filter screen 40 is collected on the elastic memory alloy barb 43, after bathing is finished, the two-way shape memory winding sheet 42 is restored to a winding state to prevent the hair from blocking the porous filter screen 40, so that the whole working process is completed, and the step is repeated when the device is used next time.

It is noted that, herein, relational terms such as first and second, and the like may be 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.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. A bathing waste water waste heat utilization equipment based on dynamic characteristics is characterized in that: the device comprises a waste heat recovery main body (1), a wrapped hedging type fluid inversion high-efficiency heat exchange mechanism (2), a treading feedback type temperature difference deformation winding type hair collection mechanism (3) and a cutting type multi-dimensional heat preservation mechanism (4), wherein the wrapped hedging type fluid inversion high-efficiency heat exchange mechanism (2) is arranged in the waste heat recovery main body (1), the treading feedback type temperature difference deformation winding type hair collection mechanism (3) is arranged in the wrapped hedging type fluid inversion high-efficiency heat exchange mechanism (2), and the cutting type multi-dimensional heat preservation mechanism (4) is arranged in the wrapped hedging type fluid inversion high-efficiency heat exchange mechanism (2); the waste heat recovery main body (1) comprises a water heater (5), a first water inlet (6), a first water outlet (7), a shower head (8), a heat exchange table (9) and a water through pipe (10), the heat exchange table (9) is arranged on the waste heat recovery main body (1), one end of the water through pipe (10) is detachably arranged at one end of the upper side of the heat exchange table (9), the water heater (5) is arranged at the other end of the water through pipe (10), the first water inlet (6) is arranged on one side of the lower end of the water heater (5), the other end of the water through pipe (10) is detachably arranged on the first water inlet (6), the first water outlet (7) is arranged on the other side of the lower end of the water heater (5), and one end of the shower head (8) is detachably arranged on the first water outlet (7); the wrapped opposite-flushing type fluid inward-turning efficient heat exchange mechanism (2) comprises an efficient heat energy recovery assembly (11), a coiled infiltration nested type waste heat recovery mechanism (12) and an internal tumbling type unpowered accelerating heat conduction mechanism (13), wherein the efficient heat energy recovery assembly (11) is arranged on a heat exchange table (9), the coiled infiltration nested type waste heat recovery mechanism (12) is arranged in the heat exchange table (9), and the internal tumbling type unpowered accelerating heat conduction mechanism (13) is arranged in the coiled infiltration nested type waste heat recovery mechanism (12); the efficient heat energy recovery assembly (11) comprises a water inlet II (14), a water outlet II (15), a floor drain (16) and an enclosing block (17), the water inlet II (14) is arranged on one side of the upper end of the heat exchange platform (9), the water outlet II (15) is arranged on the other side of the upper end of the heat exchange platform (9), one end of the water through pipe (10) is detachably arranged on the water outlet II (15), the enclosing block (17) is arranged on the heat exchange platform (9), and the floor drain (16) is detachably arranged on the heat exchange platform (9); coil type infiltration nested formula waste heat recovery mechanism (12) is including coil type heat exchange inlet tube (18), coil type heat exchange waste water discharge pipe (19), waste water inlet (20) and waste water discharge port (21), the lower extreme of floor drain (16) is located in waste water inlet (20), waste water discharge port (21) are located on the lateral wall of heat transfer platform (9), the one end of coil type heat exchange inlet tube (18) link up and is located on two (14) of water inlet, the other end of coil type heat exchange inlet tube (18) link up and is located on two (15) of delivery port, coil type heat exchange waste water discharge pipe (19) are cup jointed and are located on coil type heat exchange inlet tube (18), the one end of coil type heat exchange waste water discharge pipe (19) link up and is located on waste water discharge port (21), the other end of coil type heat exchange waste water discharge pipe (19) is located and is trampled feedback formula difference in temperature and is deformed and is received roll type hair collection mechanism (3) ) The above step (1); inside formula of tumbling unpowered heat conduction mechanism (13) with higher speed includes spout (22), pulley (23), screw (24) and puddler (25), in the pipe wall of coiling type heat exchange inlet tube (18) was located in spout (22), pulley (23) slide and locate in spout (22), the other end of pulley (23) is located to the one end of screw (24), puddler (25) are located on the lateral wall of screw (24).

2. The bathing wastewater waste heat utilization equipment based on the dynamic characteristic as claimed in claim 1, is characterized in that: the trample feedback type temperature difference deformation winding type hair collecting mechanism (3) comprises a pressure feedback type driving transmission mechanism (26), a pull type reciprocating winding mechanism (27) and a temperature trigger winding shape deformation type shrinkage mechanism (28), wherein the pressure feedback type driving transmission mechanism (26) is arranged on the heat exchange table (9), the pull type reciprocating winding mechanism (27) is arranged in the heat exchange table (9), and the temperature trigger winding shape deformation type shrinkage mechanism (28) is arranged at the lower end of the floor drain (16).

3. The bathing wastewater waste heat utilization equipment based on the dynamic characteristic as claimed in claim 2, is characterized in that: the pressure feedback type driving transmission mechanism (26) comprises a silica gel head (29), a first treading pipe (30), a second treading pipe (31), a first piston (32), a first spring (33), a communication pipe (34) and a water tray (35), wherein the water tray (35) is arranged at the upper end of the interior of the heat exchange platform (9), one end of the second treading pipe (31) is arranged on the water tray (35) in a penetrating mode, the first piston (32) is arranged in the second treading pipe (31) in a sliding mode, one end of the first spring (33) is arranged at the lower end of the first piston (32), the other end of the first spring (33) is arranged at the lower end of the inner wall of the second treading pipe (31), the first treading pipe (30) is arranged on the first piston (32), the silica gel head (29) is arranged on the first treading pipe (30), and one end of the communication pipe (34) is arranged on the water tray (35) in a penetrating mode.

4. The dynamic characteristic-based bathing wastewater waste heat utilization equipment is characterized in that: the pulling type reciprocating winding mechanism (27) comprises a first pushing and pulling pipe (36), a second pushing and pulling pipe (37), a second piston (38) and flowing liquid (39), one end of the first pushing and pulling pipe (36) is arranged at one end of the communicating pipe (34) in a penetrating mode, the second piston (38) is arranged in the first pushing and pulling pipe (36) in a sliding mode, one end of the second pushing and pulling pipe (37) is arranged on the second piston (38), and the flowing liquid (39) is arranged in the first pushing and pulling pipe (36), the communicating pipe (34), the water disc (35) and the stepping pipe (31) in a flowing mode.

5. The dynamic characteristic-based bathing wastewater waste heat utilization equipment is characterized in that: the temperature-triggered winding sheet-shaped variable-type contraction mechanism (28) comprises a porous filter screen (40), a winding rod (41), a two-way shape memory winding sheet (42), an elastic memory alloy barb (43), a first bearing (44), a second bearing (45), a first tooth block (46), a second tooth block (47) and a connecting pipe (51), wherein the second bearing (45) is arranged at the lower end of a wastewater discharge port (20), the first bearing (44) is arranged at the water inlet end of a coiled heat exchange wastewater discharge pipe (19), one end of the connecting pipe (51) is arranged at the lower end of the second bearing (45) in a penetrating manner, the other end of the connecting pipe (51) is arranged on the first bearing (44) in a penetrating manner, the porous filter screen (40) is arranged in the connecting pipe (51), the winding rod (41) is arranged at the lower end of a floor drain (16), and the two-way shape memory winding sheet (42) is arranged on the side wall of the winding rod (41), the elastic memory alloy barb (43) is arranged on the two-way shape memory coiling sheet (42), the first tooth block (46) is arranged on the side wall of the second push-pull pipe (37), the second tooth block (47) is annularly arranged on the side wall of the connecting pipe (51), and the first tooth block (46) and the second tooth block (47) are connected in a meshing and rotating mode; cuttage formula multidimension heat preservation mechanism (4) are including heat preservation (48), two (49) in heat preservation and insulating block three (50), the inside bottom of heat transfer platform (9) is located in heat preservation (48), the upper end of coil type infiltration nested formula waste heat recovery mechanism (12) is located in heat preservation two (49), insulating block three (50) are located between heat preservation (48) and heat preservation two (49).