CN109506294B - Green intelligent temperature regulation system - Google Patents

Abstract

The invention discloses a green intelligent temperature adjusting system, which is arranged between an indoor bottom layer of a building and an indoor surface pavement layer of the building, and comprises a temperature conversion piece and a temperature transmission assembly; the temperature conversion piece comprises an indoor unit arranged in the building and an outdoor unit arranged outside the building; the temperature transmission assembly comprises an energy storage body and a transportation mechanism for realizing the movement of the energy storage body between the temperature conversion part and the temperature regulation demand area. The invention can intensively and effectively regulate the temperature of a designated area, including indoor air and earth surface, is accurate, quick and effective, has skillful and concealed layout, small occupied space, low energy consumption, low use cost and convenient installation and maintenance, and can comprehensively replace the traditional indoor temperature regulating equipment such as a floor heating system, a ceiling radiation air conditioning system and the like.

Description

Green intelligent temperature regulation system

Technical Field

The invention relates to the field of intelligent home furnishing, in particular to a green intelligent temperature adjusting system.

Background

The real estate industry is an important component of national economic construction, wherein the market of commercial houses is the central importance of the real estate industry. At present, the domestic room price is in a high position and still shows a rising trend, people spend the whole life to accumulate and buy the square cun residence, and the residence is naturally hoped to be comfortable. However, in severe weather such as haze and sand storm, hot and humid summer, severe cold and difficult-to-endure external large environment in winter, the indoor environment is kept healthy, comfortable and pleasant, people are not afraid of spending heavy money to be equipped with floor heating indoors, a ceiling radiation air-conditioning system, a fresh air system, an air purifier and the like are multiple devices which are helpful for improving and keeping indoor good residential air and environment. Therefore, the decoration cost is high, the occupied space of equipment is large, the energy consumption is large, the use cost is high, the facilities are basically carried out along with the decoration, the facilities are embedded in the indoor wall body and need to be maintained and maintained regularly, and in case of failure, the facilities need to be processed by professional personnel, so that the decoration is very inconvenient.

Disclosure of Invention

The invention aims to provide a green intelligent temperature adjusting system which can overcome the defects of the prior art, intensively and effectively adjust the temperature of a designated area, is accurate and quick, has ingenious and concealed layout, small occupied space, low energy consumption, low use cost and convenient installation and maintenance, and can comprehensively replace traditional indoor temperature adjusting equipment such as a floor heating system, a ceiling radiation air conditioning system and the like.

The technical purpose of the invention is realized by the following technical scheme: a green intelligent temperature adjusting system is arranged between an indoor bottom layer of a building and an indoor surface pavement layer of the building, and comprises a temperature conversion piece and a temperature transmission assembly; the temperature conversion piece comprises an indoor unit arranged in the building and an outdoor unit arranged outside the building; the temperature transmission assembly comprises an energy storage body and a transportation mechanism for realizing the movement of the energy storage body between the temperature conversion part and the temperature regulation demand area.

The indoor surface pavement layer can be a floor, floor tiles and other common pavement layers, the number of the indoor units can be one or more, the indoor units are generally arranged at the end part of the transportation direction of the transportation mechanism, and each indoor unit can share the outdoor unit, so that the outdoor unit is economical and energy-saving, and different indoor areas can be heated or cooled simultaneously; each indoor unit can also be provided with a separate outdoor unit, so that each indoor unit can independently operate, the temperature of different indoor areas can be regulated as required, and various requirements of heating one area, cooling the other area and the like are met. The energy storage body transmits high and low temperature energy provided by the indoor unit to an indoor required space under the control of the movement speed and the movement circuit of the transportation mechanism, so that the temperature regulation of the indoor space is quick and effective, and the concealment is convenient.

Preferably, the indoor unit comprises an air return opening formed in the upper portion of the indoor unit, at least one first air outlet opening formed in the indoor unit and having a horizontal air outlet direction, and a condensed water outlet.

The indoor unit sucks indoor air into the indoor unit through the air return opening, cools hot air or heats cold air through the work of the compressor, blows the hot air out of the first air outlet, transfers the heat to the energy storage body, and transfers the heat to a required area through the energy storage body.

Preferably, the indoor unit has at least one second outlet port with an upward outlet air direction.

The second air outlet is connected with the indoor unit pipeline, so that the temperature adjusting system has a humidity adjusting function: when the indoor humidity is high, the air is humid, the indoor moisture is sent into the indoor unit through the air return opening to be processed into clean dry air, the dry air is sent back to the indoor unit through the second air outlet, and the moisture in the moisture is discharged through the condensed water outlet in the form of condensed water, so that the indoor moisture is removed, and the air is kept dry and fresh. And when temperature regulation is carried out, if no specific area exists, the temperature regulation is only carried out in the whole indoor space, the air after temperature conversion can directly return to the indoor space through the second air outlet, the large-range temperature regulation is directly carried out, the loss of heat transfer and conversion is reduced, and the temperature regulation effect is maximized.

Preferably, the condensed water outlet is communicated with a floor drain in the building.

Thereby replenishing the water for the floor drain and solving the problem of water seal failure of the floor drain.

Preferably, the air outlet area of the first air outlet is larger than the area of the portion, which receives the air outlet, of the energy storage body.

Therefore, the wind area of the energy storage body is ensured, the heat blown out of the indoor unit is fully received, the heat transfer efficiency and effect are improved, and the energy loss is reduced.

Preferably, the indoor unit further includes a waste heat recovery pipe provided at an end portion of the indoor unit in a longitudinal direction.

When too much heat is emitted through the first air outlet, the energy storage body cannot absorb the heat in time, or the heat gradually emitted from the energy storage body is remained between the indoor bottom layer of the building and the indoor surface pavement layer of the building, the heat is recovered by the waste heat recovery pipe, and the heat is repeatedly utilized after being accumulated to a certain amount and then treated by the indoor unit, so that the surrounding space of the adjusting system is ensured to be comfortable, and the heat is fully utilized.

Preferably, the energy storage body comprises a shell and an energy storage material packaged in the shell, the energy storage material is a solid-liquid phase change energy storage material, and the phase change temperature of the solid-liquid phase change energy storage material is 18-24 ℃.

The heat is transferred to the energy storage material through the shell, the energy storage material generates phase change to store the heat, and the phase change occurs again to transfer the heat when the heat reaches a required area.

Preferably, the housing comprises an outer housing, an inner housing, and an encapsulating space formed between the outer housing and the inner housing for encapsulating the energy storage material; the outer shell comprises a first shell wall close to the indoor unit, a first top wall positioned at the top of the outer shell, and other shell walls which form the outer shell together with the first shell wall and the first top wall; the first vehicle wall and the first roof wall have a thermal conductivity greater than that of the other vehicle walls and the wall forming the inner vehicle body.

The first shell wall and the first top wall can be made of materials with higher heat conductivity coefficient such as copper and aluminum, so that the first shell wall can effectively absorb heat sent by the indoor unit and transmit the heat to the energy storage material, the first top wall can effectively release the heat stored in the energy storage material, and other shell walls and the shell walls forming the inner shell can be made of heat insulation materials such as asbestos plates with lower heat conductivity coefficient; preventing unnecessary heat transfer and loss.

Preferably, an air bag is fixedly arranged on the inner walls of the first shell wall and the first top wall, and an air pump arranged at the bottom of the energy storage body and used for driving the air bag to expand and contract is arranged on the inner walls of the first shell wall and the first top wall.

The air bag is provided with an intubation tube which is communicated with an air pump at the bottom of the energy storage body and can be inflated and deflated. When heat is required to be transferred to a designated area, the energy storage bodies in the area are sequentially conveyed to a first air outlet, the air bag at the first shell wall is in a dry-shriveled state, the air bag at the first top wall is in a full state, the heat is transferred into the packaging space and stored in the energy storage material, and after the energy is completely charged, the air bag at the first shell wall is inflated, so that the stored heat is not leaked; when the energy storage body reaches the area needing heat transfer, the air bag at the first top wall is deflated, and the heat is diffused outwards from the first top wall.

Preferably, the energy storage body comprises a heat conduction rib plate arranged at the top of the energy storage body; the heat conducting rib plates are made of metal ceramics.

Cermet's coefficient of heat conductivity is big, can effectively help the heat to transmit to the indoor surface layer of mating formation of building from first roof to hardness is high, and the support effect on layer of mating formation is good.

Preferably, the transportation mechanism is a route net arranged on the indoor bottom surface of the building; the route network comprises vertical route groups and transverse route groups which are mutually staggered, the intersection points of the vertical route groups and the transverse route groups form stop points of the energy storage body, and the vertical route groups comprise first vertical routes which are closest to and parallel to the length direction of the indoor unit; the stopping points comprise heat exchange points formed by the first vertical lines and the transverse lines in a staggered mode and used for storing heat of the energy storage volume; the vertical lines and the transverse lines passing through the stopping points form a cross-shaped crossed line.

Therefore, the movement of the energy storage body on the route network is effectively normalized; the distances between every two adjacent stop points are the same, the transportation mechanism is a criss-cross square matrix route network with the stop points as the centers, and the distance between every two adjacent stop points is matched with the appearance of the energy storage body, so that the energy storage bodies are close to each other and stop side by side, and the whole structure is compact and concentrated.

Preferably, the energy storage body comprises a sensor group and a wheel set which are arranged at the bottom of the energy storage body.

The sensor group is responsible for carrying out signal communication with the transport mechanism to control the motion trail of the energy storage body, and the wheel group is directly in physical contact with the transport mechanism and executes and realizes walking or stopping of the energy storage body.

Preferably, the sensor group includes four grayscale sensors, and when the bottom center of the energy storage body overlaps with the stop point, each grayscale sensor on the energy storage body overlaps with each line of the cross-shaped cross line of the stop point one by one.

The running route of the energy storage body on the route network is standardized through the interaction of the gray sensor and the route network, the gray sensors are arranged in the advancing directions of stop points through which the energy storage body passes, so that the energy storage body is clearly guided by the routes before and after the advancing route, when any gray sensor is triggered, the energy storage body moves towards the direction of the gray sensor, and when the opposite gray sensor of the gray sensor is triggered, the energy storage body decelerates to stop and then reverses.

Preferably, the sensor group further comprises a displacement sensor arranged on the wheel group.

Therefore, the travel distance of the energy storage body can be grasped according to the distance between the adjacent stop points, and the movement of the energy storage body can be controlled more accurately.

Preferably, the first air outlet of the indoor unit is provided with a plurality of openable baffles which have the same area with the air outlet bearing part of the energy storage body.

The baffle is used for adjusting the size of first air outlet to the quantity of the energy storage body that needs carry out heat transfer is carried out in accurate control, is used for the accurate temperature regulation in specific minimum region.

Preferably, the wheel set is a plurality of moving bodies arranged in a central array of the energy storage bodies, each moving body comprises a hollow shell connected with the bottom of the energy storage body, a driving wheel arranged at the upper part of the hollow shell, and a rolling ball arranged below the driving wheel and having a certain rolling gap with the hollow shell; the moving body further comprises a bearing which is connected with the driving wheel and erects the driving wheel on a central rod on the hollow shell, the upper parts of the two ends of the central rod and the upper part of the hollow shell are fixedly connected with springs, the lower parts of the two ends of the central rod are magnetic, and electromagnetic sheets are arranged on the hollow shell below the two ends of the central rod.

Under the condition that the electromagnetic sheet is not electrified, the driving wheel is separated from the rolling ball under the action of the spring force of the spring, and the moving body is driven at the moment; the electromagnetic sheet is magnetic after being electrified, the electromagnetic sheet is attracted with the central rod, the driving wheel is downwards pressed with the rolling ball, the driving wheel is driven by the power supply and drives the rolling ball to rotate, at the moment, the moving body is driven, the rolling ball is a ball body, so that the energy storage body can move without obstacles in a quarter turn or even any driving route, the driving moving body drives the energy storage body to move, the driven moving body can contact with the rolling ball downwards under the action of the electromagnetic sheet, only the contact or the reverse rotation is realized, and the speed regulation and control can be realized.

Preferably, both ends of the center rod extend out of the hollow shell, and the rolling ball is partially exposed out of the bottom end of the hollow shell.

Therefore, the rotation direction of the driving wheel is convenient to confirm, the installation and the control are convenient, the physical contact between the transportation mechanism and the energy storage body is always completed through the rolling ball, and the transportation mechanism is flexible to move, stable and free of direction dead angles.

Preferably, the axial direction of the drive wheels of at least two of the moving bodies is parallel to the vertical line group, and the axial direction of the drive wheels of at least two of the moving bodies is parallel to the lateral line group.

Thereby ensuring that the energy storage body can obtain good power and power balance when moving longitudinally or transversely.

Preferably, a magnetic paste is arranged on the stopping point, and a central magnetic paste which interacts with the magnetic paste is arranged in the center of the bottom of the energy storage body; the magnetic paste and the central magnetic paste are both in a cross shape; the acting force of the magnetic patches and the central magnetic patch is smaller than the driving force of the wheel set.

The stop position of the energy storage body is more accurate due to the cross-shaped magnetic paste and the central magnetic paste, and the position error of the energy storage body in movement can be corrected once when the energy storage body passes through a stop point, so that the gap between adjacent energy storage bodies can be set to be shorter, the structure is more compact, and the number of the energy storage bodies which can be set is more. The relatively small force does not affect the movement of the energy storing body.

In conclusion, the invention has the following beneficial effects: the utility model provides a green intelligent temperature regulation system, locates between the indoor bottom of building and the indoor surface layer of mating formation of building, uses and conceals quietly, can adjust indoor air temperature, can adjust the temperature on indoor ground again, replaces traditional ground heating and ceiling radiation air conditioning system, and occupation space is little, and the energy consumption is little, has increased indoor usable area, and use cost is low.

The energy storage body and the transportation mechanism ensure that heat provided by the indoor unit is fully absorbed and transferred, and accurate temperature regulation of a designated area is performed according to needs. Specifically, the color of a route network of the transportation mechanism is uniform, the route network is obviously different from the color of the indoor bottom surface of the building, the route guiding effect of a gray level sensor on an energy storage body is fully exerted, when in a preparation state, no energy storage body is retained at a heat exchange point, the first vertical line is in an empty state, when a certain area needs temperature adjustment, the energy storage body in the area is driven by a wheel set and controlled by a route of a sensor group, travels to the first vertical line along a transverse line where the energy storage body is located, stops at the heat exchange point, and returns to the original position in sequence after heat is stored successively, so that the heat is transferred to the area; the energy storage bodies on the plurality of transverse lines need to be sequentially carried out according to the lines when heat transfer is needed, so that accurate temperature adjustment of specific areas is completed, and the device is efficient, energy-saving, quick and effective.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present invention; FIG. 2 is a top view of the embodiment of FIG. 1 under an indoor surface mat; FIG. 3 is a schematic structural diagram of an energy storage body; FIG. 4 is a schematic structural view of an energy storage body in another state; FIG. 5 is a schematic structural view of the bottom of the energy storage body; FIG. 6 is a schematic view of the transport mechanism; fig. 7 is a schematic structural view of the moving body.

Detailed Description

The invention is described in further detail below with reference to the drawings and preferred embodiments.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

Example (b): as shown in fig. 1-7, a green intelligent temperature adjusting system is arranged between an indoor bottom layer 1 of a building and an indoor surface pavement layer 2 of the building, and comprises a temperature conversion part 10 and a temperature transmission component 20; the temperature conversion member 10 includes an indoor unit 11 provided inside the building and an outdoor unit 12 provided outside the building; the temperature transfer assembly 20 comprises an energy storage body 40, a transport mechanism 50 enabling movement of the energy storage body 40 between the temperature conversion element 10 and the area of need for temperature regulation.

The indoor unit 11 comprises an air return opening 111 arranged at the upper part of the indoor unit 11, at least one first air outlet 112 arranged on the indoor unit 11 and having a horizontal air outlet direction, and a condensed water outlet 113, wherein the indoor unit 11 is provided with at least one second air outlet 114 with an upward air outlet direction; the air outlet area of the first air outlet 112 is larger than the area of the air outlet bearing part of the energy storage body 40; a plurality of openable baffles with the same area as the air outlet part of the energy storage body 40 can be arranged on the first air outlet 112 of the indoor unit 11; the indoor unit 11 further includes a waste heat recovery pipe 13 provided at an end portion of the indoor unit 11 in a longitudinal direction.

The energy storage body 40 comprises a shell 41 and an energy storage material 42 packaged in the shell 41, wherein the energy storage material 42 is a solid-liquid phase change energy storage material, and the phase change temperature of the solid-liquid phase change energy storage material is 18-24 ℃.

The housing 41 includes an outer housing 411, an inner housing 412, an enclosing space 413 formed between the outer housing 411 and the inner housing 412 for enclosing the energy storage material 42; the outer casing 411 includes a first wall 4111 close to the indoor unit 11, a first top wall 4112 at the top of the outer casing 411, and other walls 4113 forming the outer casing 411 together with the first wall 4111 and the first top wall 4112. The thermal conductivity of the first housing wall 4111 and the first top wall 4112 is larger than that of the other housing wall 4113 and the housing wall forming the inner housing 412.

An air bag 4114 and an air pump 415 arranged at the bottom of the energy storage body 40 to drive the air bag 4114 to expand and contract are fixedly arranged on the inner walls of the first shell wall 4111 and the first top wall 4112; the energy storage body 40 comprises a heat conduction rib plate 414 arranged at the top of the energy storage body 40; the material of the heat conductive ribs 414 is cermet.

The transportation mechanism 50 is a route net arranged on the indoor bottom surface of the building; the route network comprises vertical route groups 51 and transverse route groups 52 which are mutually staggered, the intersection points of the vertical route groups 51 and the transverse route groups 52 form stop points 53 of the energy storage body 40, and the vertical route groups 51 comprise first vertical routes 511 which are closest to and parallel to the length direction of the indoor unit 11; the stopping point 53 comprises a heat exchange point 531 for accumulating heat in the energy accumulation body 40, formed by the interleaving of the first vertical line 511 and the transverse lines; the vertical and horizontal lines passing by the stop points 53 form a crisscross line.

The energy storage body 40 comprises a sensor group 43 and a wheel group 44 which are arranged at the bottom of the energy storage body 40; the sensor group 43 comprises four gray sensors 431, when the bottom center of the energy storage body 40 is overlapped with the position of the stop point 53, the gray sensors 431 on the energy storage body are overlapped with the positions of the sections of the cross-shaped cross line of the stop point one by one; the sensor group 43 further comprises displacement sensors provided on the wheel group 44.

The wheel set 44 is a plurality of moving bodies 440 arranged in a central array of the energy storage bodies, the moving bodies 440 include hollow shells 441 connected with the bottoms of the energy storage bodies 40, driving wheels 442 arranged on the upper portions of the hollow parts of the hollow shells, and rolling balls 443 arranged below the driving wheels 442 and having a certain rolling gap with the hollow shells 441; the moving body 440 further comprises a center rod 444 which is connected with the driving wheel 442 through a bearing and enables the driving wheel 442 to be erected on the hollow shell 441, the upper parts of the two ends of the center rod 444 are fixedly connected with a spring 445 with the upper part of the hollow shell 441, the lower parts of the two ends of the center rod 444 are magnetic, and electromagnetic sheets 446 are arranged on the hollow shell below the two ends of the center rod 444; both ends of the center rod 444 extend out of the hollow shell 441; the roller ball 443 is partially exposed at the bottom end of the hollow housing 441.

The axial direction of the driving wheels of the at least two moving bodies 440 is parallel to the vertical line group 51, and the axial direction of the driving wheels of the at least two moving bodies 440 is parallel to the lateral line group 52.

A magnetic paste 54 is arranged on the stopping point 53, and a central magnetic paste 45 which interacts with the magnetic paste 54 is arranged in the center of the bottom of the energy storage body 40; the magnetic paste 54 and the central magnetic paste 45 are both in a cross shape; the force of the magnet 54 against the central magnet 45 is less than the driving force of the wheel set 44.

Claims (1)

1. The utility model provides a green intelligent temperature regulation system which characterized in that: the temperature adjusting system is arranged between the indoor bottom layer (1) of the building and the indoor surface pavement layer (2) of the building, and comprises a temperature conversion piece (10) and a temperature transmission component (20); the temperature conversion piece (10) comprises an indoor unit (11) arranged in the building and an outdoor unit (12) arranged outside the building; the temperature transmission assembly (20) comprises an energy storage body (40), a transportation mechanism (50) for realizing the movement of the energy storage body (40) between the temperature conversion piece (10) and a temperature regulation demand area;

the transportation mechanism (50) is a route net arranged on the indoor bottom surface of the building; the route network comprises vertical route groups (51) and transverse route groups (52) which are mutually staggered, the intersection points of the vertical route groups (51) and the transverse route groups (52) form stop points (53) of the energy storage body (40), and the vertical route groups (51) comprise first vertical routes (511) which are closest to and parallel to the length direction of the indoor unit (11); the stopping point (53) comprises a heat exchange point (531) formed by the first vertical line (511) and each transverse line in a staggered manner, and used for accumulating heat in the energy accumulator (40); the vertical lines and the transverse lines passing through the stopping points (53) form a cross-shaped crossed line;

the energy storage body (40) comprises a sensor group (43) and a wheel group (44) which are arranged at the bottom of the energy storage body (40); the sensor group (43) comprises four grayscale sensors (431), when the bottom center of the energy storage body (40) is overlapped with the position of the stop point (53), the grayscale sensors (431) on the energy storage body are overlapped with the positions of the sections of the crossed lines of the stop point one by one; the sensor group (43) further comprises a displacement sensor arranged on the wheel group (44);

the wheel set (44) is a plurality of moving bodies (440) which are arranged in a central array of the energy storage bodies, each moving body (440) comprises a hollow shell (441) connected with the bottom of each energy storage body (40), a driving wheel (442) arranged at the upper part of the hollow shell, and a rolling ball (443) which is arranged below the driving wheel (442) and has a certain rolling clearance with the hollow shell (441); the moving body (440) further comprises a center rod (444) which is connected with the driving wheel (442) through a bearing and is used for erecting the driving wheel (442) on the hollow shell (441), the upper parts of two ends of the center rod (444) are fixedly connected with a spring (445) with the upper part of the hollow shell (441), the lower parts of two ends of the center rod (444) are magnetic, and electromagnetic sheets (446) are arranged on the hollow shell below two ends of the center rod (444); two ends of the central rod (444) extend out of the hollow shell (441); the rolling ball (443) is partially exposed out of the bottom end of the hollow shell (441);

the indoor unit (11) comprises an air return opening (111) arranged at the upper part of the indoor unit (11), at least one first air outlet (112) arranged on the indoor unit (11) and having a horizontal air outlet direction, and a condensed water outlet (113), wherein the indoor unit (11) is provided with at least one second air outlet (114) having an upward air outlet direction; the air outlet area of the first air outlet (112) is larger than the area of the air outlet bearing part of the energy storage body (40); a plurality of openable baffles with the same area as the air outlet part of the energy storage body (40) can be arranged on the first air outlet (112) of the indoor unit (11); the indoor unit (11) also comprises a waste heat recovery pipe (13) arranged at the end part of the indoor unit (11) in the length direction;

the energy storage body (40) comprises a shell (41) and an energy storage material (42) packaged in the shell (41), wherein the energy storage material (42) is a solid-liquid phase change energy storage material, and the phase change temperature of the solid-liquid phase change energy storage material is 18-24 ℃;

the shell (41) comprises an outer shell (411), an inner shell (412), and an encapsulating space (413) formed between the outer shell (411) and the inner shell (412) and used for encapsulating the energy storage material (42); -the outer casing (411) comprises a first casing wall (4111) close to the indoor unit (11), -a first ceiling wall (4112) at the top of the outer casing (411), -a further casing wall (4113) forming the outer casing (411) together with the first casing wall (4111) and the first ceiling wall (4112), -the thermal conductivity of the first casing wall (4111) and the first ceiling wall (4112) is greater than the thermal conductivity of the further casing wall (4113) and the casing wall forming the inner casing (412);

an air bag (4114) is fixedly arranged on the inner walls of the first shell wall (4111) and the first top wall (4112), and an air pump (415) which is arranged at the bottom of the energy storage body (40) and drives the air bag (4114) to expand and contract is arranged; the energy storage body (40) comprises a heat conduction rib plate (414) arranged at the top of the energy storage body (40); the material of the heat conduction rib plate (414) is metal ceramic;

the axial direction of the driving wheels in at least two of the moving bodies (440) is parallel to the vertical line group (51), and the axial direction of the driving wheels in at least two of the moving bodies (440) is parallel to the lateral line group (52);

a magnetic paste (54) is arranged on the stopping point (53), and a central magnetic paste (45) which interacts with the magnetic paste (54) is arranged in the center of the bottom of the energy storage body (40); the magnetic paste (54) and the central magnetic paste (45) are both in a cross shape; the acting force of the magnetic patch (54) and the central magnetic patch (45) is smaller than the driving force of the wheel set (44).

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