CN116131397A - Rechargeable modeler and modeler system - Google Patents

Abstract

The invention discloses a rechargeable molding machine and a molding machine system, which comprise an upper shell component, a lower shell component and a rotating shaft component for hinging the upper shell component and the lower shell component; the lower shell component is provided with a first cavity, the upper shell component is provided with a second cavity, a rechargeable battery pack is detachably connected in the first cavity, and a control component is arranged in the second cavity; at least one side part of the first cavity extends to the rotating shaft assembly to be provided with a wire passing channel, an electric wire is buried in the wire passing channel, and two ends of the electric wire are respectively connected with the rechargeable battery pack and the control assembly. This chargeable formula modeler is through the optimal design to circuit part space arrangement, makes rechargeable battery group and control assembly be located respectively in last casing subassembly and lower casing subassembly, evenly arranges the installation space of two casings, reduces the overall dimension of casing, the user of being convenient for is handheld. And the rechargeable battery pack is standardized and designed, so that the rechargeable battery pack is suitable for various electrical products and has higher general performance.

Description

Rechargeable modeler and modeler system

Technical Field

The invention relates to the technical field of molders, in particular to a rechargeable molder and a molder system.

Background

The hair straightener is a heating element MCH or PTC or heating wire which is heated by current and is conducted to an aluminum plate or a ceramic plate to heat and straighten hair, and is a relatively common hairstyling tool.

In the prior art, a hollow accommodating cavity is formed in the middle part and the rear part of the main shell, and the detachable rechargeable battery pack is fixedly arranged in the hollow accommodating cavity in a pluggable manner, so that a power supply connecting wire is omitted, the occupied space is small, the portable type rechargeable battery pack is convenient to carry, and the rechargeable battery pack can be used without an external power supply; however, this molding apparatus has a structural disadvantage in that the rechargeable battery pack and the control main board are installed in the main housing side by side, resulting in a long size of the main housing, which is inconvenient for a user to hold the apparatus in his/her hand.

In view of this, there is a need for an improvement in the molding apparatus of the prior art to solve the technical problem of longer housing size caused by the installation of the rechargeable battery pack and the control main board.

Disclosure of Invention

The invention aims to provide a rechargeable molding machine and a molding machine system, which solve the technical problems.

To achieve the purpose, the invention adopts the following technical scheme:

a rechargeable molding machine comprising an upper housing assembly, a lower housing assembly, and a spindle assembly for hinging the upper housing assembly and the lower housing assembly;

the lower shell assembly is provided with a first cavity, the upper shell assembly is provided with a second cavity, a rechargeable battery pack is detachably connected in the first cavity, and a control assembly is arranged in the second cavity;

at least one side of the first cavity is provided with a wire passing channel, the wire passing channel extends towards the rotating shaft assembly and penetrates through the rotating shaft assembly, and two ends of the wire are respectively connected with the rechargeable battery pack and the control assembly.

Optionally, the length of the wire is greater than the length of the wire passing channel, and an anti-stretching section of the wire is reserved in the wire passing channel.

Optionally, an electrical slip ring is sleeved on the rotating shaft;

the electric wire comprises a first electric wire connected with the rechargeable battery pack and a second electric wire connected with the control assembly, and the first electric wire and the second electric wire are respectively connected with the electric slip ring.

Optionally, the control assembly includes a control mainboard and locates a plurality of control button on the control mainboard, the one end of control button expose in upper housing assembly.

Optionally, a mounting opening communicated with the first cavity is formed in a side wall of the lower housing component, and the rechargeable battery pack is detachably mounted in the first cavity through the mounting opening.

Optionally, the mounting opening is hinged with a protective cover, the protective cover is rotated, and the protective cover is covered on the mounting opening.

Optionally, an opening is formed at one end of the lower housing component, and the rechargeable battery pack is detachably inserted into the first cavity through the opening.

Optionally, the rechargeable battery group includes the battery body, a tip of battery body is equipped with spacing knot subassembly, spacing knot subassembly buckle connect in on the inferior valve subassembly.

Optionally, the rechargeable battery pack is a universal rechargeable battery pack with replaceability;

wherein the number of the rechargeable battery packs is a plurality of, and any one of the rechargeable battery packs is arranged in the first cavity;

the plurality of rechargeable batteries are respectively used for supplying power to any one of the styling device, the hair curler or the hair curler.

Optionally, the rechargeable battery pack further includes a battery rear cover, the battery rear cover is disposed at one end of the battery body, and the battery rear cover is exposed out of the opening;

wherein, the battery back cover with battery body integral type sets up.

Optionally, the opening part is provided with a notch groove matched with the limit buckle assembly, and the inner side wall of the first cavity close to one end of the opening part is provided with a rotary groove;

during installation, the rechargeable battery pack is inserted into the first cavity, the limiting buckle assembly is inserted into the rotary groove along the notch groove, and the limiting buckle assembly is rotated, so that the limiting buckle assembly is clamped in the rotary groove.

Optionally, the insertion end of the rechargeable battery pack is provided with a first conductive part;

the first cavity is internally provided with a second conductive part, and when the rechargeable battery pack is inserted into the first cavity, the first conductive part is electrically connected with the second conductive part.

Optionally, the first conductive part is a plurality of electric connection pieces arranged on one end face of the rechargeable battery pack;

optionally, the second conductive part includes conductive base, and locates a plurality of conductive thimble on the conductive base, conductive thimble with the electric connection piece one-to-one sets up, conductive thimble with the electric connection piece electricity is connected.

Optionally, the first conductive part is a plurality of electric connection pieces arranged on a side wall at one end of the rechargeable battery pack.

Optionally, the second conductive part includes a conductive base and a plurality of conductive elastic pieces arranged on the conductive base;

an elastic clamping space is formed between the plurality of conductive elastic sheets, the insertion end of the rechargeable battery pack is clamped in the elastic clamping space, and the conductive elastic sheets are elastically abutted to the electric connecting sheets.

Optionally, the second conductive part further includes a limiting plate, where the limiting plate is disposed on the outer side of the conductive elastic sheet, and the limiting plate is used to limit the position of the conductive elastic sheet.

Optionally, a first accommodating groove is formed in one end face of the lower shell assembly, and a first heating plate is arranged in the first accommodating groove;

the first heating plate comprises a first half section and a second half section, and the first half section is provided with a first sensing element.

Optionally, a second accommodating groove is formed in the end face, close to the lower shell component, of the upper shell component, and a second heating plate is arranged in the second accommodating groove;

the second heating plate comprises a third half section aligned with the first half section and a fourth half section aligned with the second half section, and the fourth half section is provided with a second sensing element.

Optionally, the first sensing element and the second sensing element are NTC temperature sensing elements, respectively.

Optionally, the first heating plate and the second heating plate are respectively and electrically connected with the control assembly through connecting lines;

the connecting line of the first heating plate and the control assembly is connected with a temperature fusing switch in series, and the temperature fusing switch is attached to the first heating plate.

The invention also provides a modeler system comprising a rechargeable modeler as described above.

Optionally, the molding machine system further comprises a charging mechanism, the charging mechanism comprises a charging base, a plurality of charging holes are formed in the upper end face of the charging base, and the charging holes are used for respectively supplying power to the rechargeable battery pack.

Optionally, a charging clamping assembly is arranged in the charging hole, and the insertion end of the rechargeable battery pack is clamped on the charging clamping assembly.

Optionally, a charging method is characterized by being applied to the molding machine system, wherein the molding machine system comprises a charging mechanism, the charging mechanism comprises a charging base, and a plurality of charging holes are formed in the upper end face of the charging base; the method specifically comprises the following steps:

detecting the assembled state of the rechargeable battery of the plurality of charging holes respectively;

the switches of the charging holes are sequentially opened, and electric quantity detection is carried out on the charging holes in a charging state; if the electric quantity of the rechargeable battery pack is detected to be full, the switch corresponding to the charging hole is closed, and if the electric quantity of the rechargeable battery pack is detected to be not full, the operation corresponding to the charging hole is continued.

Compared with the prior art, the invention has the following beneficial effects: when the rechargeable molding machine works, the rechargeable battery pack is arranged in the first cavity, the rechargeable battery pack is electrically connected with the control assembly through an electric wire, the rechargeable battery pack supplies power to the control assembly, and the control assembly controls the operation of each part of the rechargeable molding machine, so that the molding function is realized; the circuit is connected with the rechargeable battery pack and the control assembly through the rotating shaft, so that the condition that wires are wound when the rotating shaft rotates is avoided, and the rationality of circuit arrangement is improved; this chargeable formula modeler is through the optimal design to circuit part space arrangement, makes rechargeable battery group and control assembly be located respectively in last casing subassembly and lower casing subassembly, evenly arranges the installation space of two casings, reduces the overall dimension of casing, the user of being convenient for is handheld.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained from these drawings without inventive faculty for a person skilled in the art.

The structures, proportions, sizes, etc. shown in the drawings are shown only in connection with the present disclosure, and are not intended to limit the scope of the invention, since any modification, variation in proportions, or adjustment of the size, etc. of the structures, proportions, etc. should be considered as falling within the spirit and scope of the invention, without affecting the effect or achievement of the objective.

Fig. 1 is a schematic diagram of the whole structure of the rechargeable molding machine.

Fig. 2 is a schematic cross-sectional view of the rechargeable molding machine at the spindle assembly.

Fig. 3 is a schematic rear view of the housing of the rechargeable molding machine.

Fig. 4 is a schematic structural view of a rechargeable battery pack of the rechargeable molding machine.

Fig. 5 is a schematic front view of the rechargeable battery pack of the rechargeable molding machine.

Fig. 6 is a schematic diagram of a rechargeable battery pack and a second conductive portion of the rechargeable molding machine.

FIG. 7 is a second schematic diagram of the rechargeable battery pack and the second conductive portion of the rechargeable molding machine.

Fig. 8 is a schematic structural view of one of the second conductive parts of the rechargeable molding machine.

Fig. 9 is a schematic diagram of a main board structure of the rechargeable molding machine.

Fig. 10 is a schematic longitudinal sectional view of the present rechargeable molding machine.

Fig. 11 is a schematic structural view showing versatility of the rechargeable battery pack of the rechargeable molding machine.

Fig. 12 is a schematic diagram of the charging structure of the present molding machine system.

Fig. 13 is a logic diagram of a heating method of the heating plate of the present rechargeable molder.

Illustration of: the lower shell assembly 1, the first cavity 11, the rotating shaft assembly 12, the opening part 13, the notch groove 14, the second conductive part 15, the conductive base 151, the conductive thimble 152, the conductive spring 153 and the limiting plate 154;

an upper housing assembly 2, a second cavity 21;

the control assembly 3, the control main board 31 and the control keys 32;

a wire passing channel 4;

the rechargeable battery pack 5, the battery body 51, the limit button assembly 52, the battery rear cover 53, the first conductive part 54 and the electric connection sheet 541;

a first heating plate 6, a first sensing element 61, and a thermal fuse switch 62;

a second heating plate 7, a second sensing element 71;

a charging mechanism 8, a charging base 81 and a charging hole 82;

a styler 100, a curler 200, and a curling comb 300.

Detailed Description

In order to make the objects, features and advantages of the present invention more comprehensible, the technical solutions in the embodiments of the present invention are described in detail below with reference to the accompanying drawings, and it is apparent that the embodiments described below are only some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "top", "bottom", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention. It is noted that when one component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present.

The technical scheme of the invention is further described below by the specific embodiments with reference to the accompanying drawings.

Embodiment one:

the invention provides a rechargeable molding machine, which comprises a lower shell assembly 1, an upper shell assembly 2 and a rotating shaft assembly 12 for hinging the upper shell assembly 2 and the lower shell assembly 1;

the lower shell component 1 is provided with a first cavity 11, the upper shell component 2 is provided with a second cavity 21, the first cavity 11 is detachably connected with the rechargeable battery pack 5, and the second cavity 21 is internally provided with the control component 3;

at least one side of the first cavity 11 is provided with a wire passing channel 4, the wire passing channel 4 extends towards the rotating shaft assembly 12 and penetrates through the rotating shaft assembly 12, an electric wire is embedded in the wire passing channel 4, and two ends of the electric wire are respectively connected with the rechargeable battery pack 5 and the control assembly 3.

It should be noted that one of the hinging manners of the upper housing component 2 and the lower housing component 1 is that the rotating shaft component 12 is fixedly connected to the lower housing component 1, the upper housing component 2 is rotatably connected to the rotating shaft component 12, that is, when the upper housing component 2 is rotated, the rotating shaft component 12 does not rotate along with the rotating, and at this time, the wire passing channel 4 is arranged in the rotating shaft component 12 to achieve the effect of protecting the wire.

It is easy to understand that the lower housing component 1 and the upper housing component 2 are hinged through the rotating shaft component 12, and the conventional circuit is arranged in a way of directly bypassing the rotating shaft component 12, unlike the conventional circuit, the wire passing channel 4 in the scheme is penetrated through the rotating shaft component 12, so that the length stroke of the wire is kept unchanged in the process of rotating the upper housing and the lower housing of the molding machine, and the wire cannot be stretched and wound, thereby improving the rationality of the circuit.

The working principle of the invention is as follows: during operation, the rechargeable battery pack 5 is arranged in the first cavity 11, the rechargeable battery pack 5 is electrically connected with the control assembly 3 through wires, the rechargeable battery pack 5 supplies power to the control assembly 3, and the control assembly 3 controls the operation of each part of the rechargeable molding machine, so that the molding function is realized; the circuit passes through the rotating shaft assembly 12 to connect the rechargeable battery pack 5 and the control assembly 3, so that the condition of winding wires when the rotating shaft rotates is avoided, and the rationality of circuit arrangement is improved; compared with modeling equipment in the prior art, the rechargeable modeling device has the advantages that through the optimal design of spatial arrangement of circuit components, the rechargeable battery pack 5 and the control assembly 3 are respectively located in the upper shell assembly 2 and the lower shell assembly 1, the installation spaces of the two shells are uniformly arranged, the overall size of the shells is reduced, and the rechargeable modeling device is convenient for users to hold.

As an alternative of this embodiment, the length of the wire is longer than the length of the wire passing channel 4, and the wire passing channel 4 is reserved with a stretch-proof section of the wire.

The stretch-proof section of the electric wire is the length of the electric wire of the folded part. For the hinge manner that the rotating shaft assembly 12 is rotatably connected to the lower housing assembly 1, that is, the rotating shaft assembly 12 will rotate along with the upper housing assembly, the wire passing channel 4 is reserved in the rotating shaft assembly 12, but in order to avoid the rotating shaft assembly 12 from rotating, the wire is broken, wherein one manner is to set the length of the wire to be longer than that of the wire passing channel 4, that is, fold part of the length of the wire in the wire passing channel 4 so as to protect the wire from being broken.

As an alternative of this embodiment, an electrical slip ring is sleeved on the rotating shaft; the electric wires include a first electric wire connected with the rechargeable battery pack 5, and a second electric wire connected with the control assembly 3, the first electric wire and the second electric wire being connected with the electrical slip ring, respectively.

It should be noted that, realize the electricity connection of first electric wire and second electric wire through electric slip ring, wherein, electric slip ring includes stator and rotor, rotor and pivot subassembly 12 fixed connection, thereby follow pivot subassembly 12 rotation, the stator can be connected with last casing subassembly 2, when pivot subassembly 12 drove the rotor rotation, the stator is motionless, simultaneously rotor and stator keep the state of electric conduction, thereby under the circumstances of guaranteeing that first electric wire and second electric wire do not follow the rotation, realize the circuit connection of both, play the effect of protection circuit.

In this embodiment, the control assembly 3 includes a control main board 31 and a plurality of control keys 32 disposed on the control main board 31, wherein one ends of the control keys 32 are exposed out of the upper housing assembly 2.

As shown in fig. 3 and 9, the control main board 31 in this embodiment is disposed in the upper housing assembly 2, and a control command is input to the control main board 31 through the control key 32, so that the control main board 31 can control the operation states of each component, such as the on and off of the heating assembly, and the control of the heating temperature of the heating assembly.

As an alternative of this embodiment, a mounting opening communicating with the first cavity 11 is formed in a side wall of the lower housing assembly 1, and the rechargeable battery pack 5 is detachably mounted in the first cavity 11 through the mounting opening.

Further stated, the mounting opening is hinged with a protective cover, the protective cover is rotated, and the protective cover is covered on the mounting opening.

It should be noted that, there are various detachable connection manners between the rechargeable battery pack 5 and the lower housing assembly 1, one of which is to place the rechargeable battery pack 5 through the mounting opening on the side wall, and to protect the rechargeable battery pack 5 by covering the protective cover.

The connection mode of the protective cover and the lower housing component 1 is not limited to the hinging mode, and can be a buckling connection mode.

In this embodiment, an opening 13 is formed at one end of the lower housing component 1, and the rechargeable battery pack 5 is detachably inserted into the first cavity 11 through the opening 13.

As shown in fig. 1, the rechargeable battery pack 5 in the present embodiment is plug-connected through the opening 13 of the lower case assembly 1; the preferred setting position of the opening 13 is to locate the rear end of the lower housing assembly 1, and the user inserts the rechargeable battery pack 5 into the first cavity 11 from the direction of the rear end of the lower housing assembly 1, so that the installation of the rechargeable battery pack 5 can be completed, thereby simplifying the installation operation of the rechargeable battery pack 5 and facilitating the taking and placing of the rechargeable battery pack 5.

As a preferred scheme of the present embodiment, the rechargeable battery pack 5 includes a battery body 51, a limiting buckle assembly 52 is disposed at one end of the battery body 51, and the limiting buckle assembly 52 is connected to the lower housing assembly 1 in a snap-fit manner. Wherein, battery body 51 realizes the detachable connection with lower casing subassembly 1 through spacing knot subassembly 52, and spacing knot subassembly 52 plays spacing rechargeable battery group 5's effect for rechargeable battery group 5 can be fixed a position the installation fast when pegging graft in first cavity 11.

As a preferable aspect of the present embodiment, the rechargeable battery pack 5 is a universal rechargeable battery pack 5 having a replaceable property. Wherein the number of the rechargeable battery packs 5 is a plurality of, any one of the rechargeable battery packs 5 is arranged in the first cavity; a plurality of rechargeable batteries are respectively used to power any one of the styler 100, the hair curler 200, or the hair curler comb 300.

Referring to fig. 11, the universal rechargeable battery pack 5 of the present embodiment may be adapted to a styler 100, a hair curler 200, and a hair curler comb 300; the tail end of the styling device 100, the hair curler 200 or the hair curler comb 300 is respectively provided with an opening 13 for inserting the rechargeable battery packs 5, the rechargeable battery packs 5 in the scheme have universality, and different rechargeable battery packs 5 also have interchangeability, so that one rechargeable battery pack 5 can quickly replace other rechargeable battery packs 5 when the electric quantity is low, and the use convenience is improved;

it should be noted that, the general rechargeable battery pack 5 in the present embodiment refers to a standardized design of the rechargeable battery pack 5, so that the rechargeable battery pack 5 is not only suitable for the modeler in the present embodiment, but also applicable to a battery product with higher versatility, such as a shaver, a flashlight or other medium-and small-sized electrical products; the standardized design refers to standardized design of the external design, the size and the interface of the rechargeable battery pack 5, for example, the peripheral design part may be a cylindrical design.

Specifically, the rechargeable battery pack 5 further includes a battery rear cover 53, the battery rear cover 53 is disposed at one end of the battery body 51, and the battery rear cover 53 is exposed at the opening 13; wherein, the battery rear cover 53 is integrally provided with the battery body 51.

It should be noted that, the conventional battery structure needs to be matched with a rear cover so as to protect the battery structure, in this scheme, through setting the battery rear cover 53 and the battery body 51 as a whole, when the battery body 51 is clamped in the first cavity 11, one end of the rear cover is exposed out of the first cavity 11, thereby playing the role of protecting the battery body 51, and on the other hand, the battery rear cover 53 is provided with a pattern part, so as to facilitate taking the rechargeable battery pack 5 through the pattern part.

Further, the opening 13 is provided with a notch groove 14 matched with the limit buckle assembly 52, and the inner side wall of the first cavity 11 near one end of the opening 13 is provided with a rotary groove;

during installation, the rechargeable battery pack 5 is inserted into the first cavity 11, the limiting buckle assembly 52 is inserted into the rotary groove along the notch groove 14, and the limiting buckle assembly 52 is rotated, so that the limiting buckle assembly 52 is clamped in the rotary groove.

Referring to fig. 3 to 6, the limiting buckle assembly 52 in the present embodiment adopts a rotary clamping structure, that is, the limiting buckle assembly 52 is aligned with the notch groove 14 and inserted into the rotary groove, and then the limiting buckle assembly 52 is rotated to a preset angle, so that the limiting buckle assembly 52 is staggered with the notch groove, thereby achieving the effect of clamping the limiting buckle assembly 52, and being convenient and fast to use; and has certain operation threshold, avoids children's maloperation to pull out the condition of battery, improves holistic safety in utilization.

In the present embodiment, the insertion end of the rechargeable battery pack 5 is provided with a first conductive portion 54; the first cavity 11 is provided with a second conductive portion 15, and when the rechargeable battery pack 5 is plugged into the first cavity 11, the first conductive portion 54 is electrically connected with the second conductive portion 15.

It should be noted that, when the rechargeable battery pack 5 is installed, the rechargeable battery pack 5 is inserted into the first cavity 11, and therefore, a corresponding conductive structure needs to be disposed on the inner sidewall of the first cavity 11 to conduct the electrical connection between the rechargeable battery pack 5, i.e. the first conductive portion 54 and the second conductive portion 15.

As an alternative of the present embodiment, the first conductive portion 54 is a plurality of electrical connection pads 541 provided on one end surface of the rechargeable battery pack 5.

Specifically, the second conductive portion 15 includes a conductive base 151 and a plurality of conductive pins 152 disposed on the conductive base 151, where the conductive pins 152 are disposed in one-to-one correspondence with the electrical connection pads 541, and the conductive pins 152 are electrically connected with the electrical connection pads 541.

Referring to fig. 7, one of the first conductive portion 54 and the second conductive portion 15 is that the first conductive portion 54 includes a plurality of electrical connection pads 541 disposed on the same end surface, and a conductive pin 152 is used to cooperate with the electrical connection pads to achieve the electrical conduction function of the first conductive portion and the second conductive portion.

As shown in connection with fig. 4 to 6, the following is another embodiment of the first conductive portion 54 and the second conductive portion 15:

as a preferred aspect of the present embodiment, the first conductive portion 54 is a plurality of electrical connection pads 541 disposed on a sidewall at one end of the rechargeable battery pack 5.

To be further described, the second conductive portion 15 includes a conductive base 151 and a plurality of conductive elastic pieces 153 disposed on the conductive base 151; an elastic clamping space is formed between the plurality of conductive elastic sheets 153, the insertion end of the rechargeable battery pack 5 is clamped in the elastic clamping space, and the conductive elastic sheets 153 are elastically abutted with the electric connection sheet 541.

It should be noted that, in the structural design of the other conductive portion of the present embodiment, the first conductive portion 54 is a plurality of electrical connection pads 541 disposed on a sidewall of one end of the rechargeable battery pack 5; correspondingly, a plurality of conductive elastic pieces 153 on the conductive base 151, elastic clamping spaces are formed among the plurality of conductive elastic pieces 153, the insertion end of the rechargeable battery pack 5 is clamped through the elastic clamping spaces, and the conductive elastic pieces 153 are electrically connected with the electric connection sheet 541; the design has the advantages that on one hand, the stability of the connection of the rechargeable battery pack can be improved, and the deviation condition in the use process is avoided; on the other hand, through the optimal design of the first conductive portion 54, the plurality of electric connection pieces 541 are respectively arranged in different directions on the side wall of the rechargeable battery pack 5, so that the situation that short circuits are easy to occur when the rechargeable battery pack 5 is put out is avoided, and the safety performance of the rechargeable battery pack 5 is improved.

Further, the second conductive portion 15 further includes a limiting plate 154, the limiting plate 154 is disposed on the outer side of the conductive spring 153, and the limiting plate 154 is used for limiting the position of the conductive spring 153.

In this embodiment, a first accommodating groove is formed in one end face of the lower housing component 1, and a first heating plate 6 is arranged in the first accommodating groove;

the first heating plate 6 comprises a first half-section provided with a first sensor element 61 and a second half-section.

Further stated, a second accommodating groove is formed in one end face, close to the lower shell assembly 1, of the upper shell assembly 2, and a second heating plate 7 is arranged in the second accommodating groove; the second heating plate 7 comprises a third half-section arranged in alignment with the first half-section and a fourth half-section arranged in alignment with the second half-section, the fourth half-section being provided with a second sensing element 71.

It should be noted that, referring to fig. 6, the first heating plate 6 in this embodiment is divided into a first half section and a second half section that are disposed left and right, the second heating plate 7 is divided into a third half section and a fourth half section that are disposed left and right, the first half section and the third half section are aligned, and the first half section and the third half section are aligned;

the first sensor element 61 and the second sensor element 71 are arranged in a staggered manner, i.e. on different sides, respectively, which has the advantage that the design of the temperature detection part of the styling apparatus is optimized, i.e. when the hair is located between the first heating plate 6 and the second heating plate 7, the two temperature-sensing elements are arranged in a staggered manner; and plays a role in preventing over-temperature protection during load deflection.

In the present embodiment, the first sensing element 61 and the second sensing element 71 are NTC temperature sensing elements, respectively.

In this embodiment, the first heating plate 6 and the second heating plate 7 are electrically connected to the control assembly 3 through connection lines, respectively; wherein, connect in series on the connecting wire of first hot plate 6 and control assembly 3 has temperature fuse switch 62, and temperature fuse switch 62 laminating sets up in first hot plate 6.

It should be noted that, another thermal fuse switch 62 is disposed between the second heating plate 7 and the control component 3, and the two thermal fuse switches 62 have the same function, that is, are attached to the first sensing element 61, when the temperature of the first sensing element 61 is too high, the thermal fuse switch 62 will automatically fuse to disconnect the circuit, thereby playing a role in protecting the personal safety of the user and improving the safety performance.

It should be noted that the present solution also provides a heating method of the heating plate, which specifically includes:

turning on a power supply, and scanning and setting a target temperature through an operation key; (wherein, the temperature shift is displayed by LCD/LED)

The Hall switch detects whether the first heating plate 6 and the second heating plate 7 are clamped or not;

if yes, the first sensing element 61 and the second sensing element 71 are respectively subjected to temperature detection, and the higher temperature of the two heating plates is compared with the target temperature; judging whether the temperature is higher than the target temperature, if so, stopping heating the two heating plates simultaneously, and if not, stopping heating the two heating plates simultaneously;

if not, it is determined whether the temperatures of the first heating plate 6 and the second heating plate 7 are higher than the target temperatures, respectively, if so, heating is stopped, and if not, heating is continued.

Embodiment two:

the invention also provides a modeler system comprising a rechargeable modeler as in embodiment one.

In this embodiment, the molding machine system further includes a charging mechanism 8, the charging mechanism 8 includes a charging base 81, a plurality of charging holes 82 are formed in an upper end surface of the charging base 81, and the charging holes 82 are used for respectively supplying power to the rechargeable battery pack 5.

Referring to fig. 11, the charging structure 8 in this embodiment is provided with a plurality of charging holes 82, so that a plurality of rechargeable battery packs 5 can be charged simultaneously during use, which is beneficial to providing working efficiency; and because the rechargeable battery group 5 in this scheme is standardized design, consequently, charging structure 8 in this scheme not only can regard as the electric pile that fills of molding ware, can also act on a generalized electric pile that fills, provide the service that charges for multiple electrical apparatus, reduce the use to all kinds of charging connector, convenience of customers uses.

In this embodiment, a charging clamping assembly is disposed in the charging hole 82, and the insertion end of the rechargeable battery pack 5 is clamped on the charging clamping assembly.

It is easy to understand that the charging clamping assembly in the scheme can be designed into a clamping structure with the rechargeable battery pack 5 on the molding machine; in the first embodiment, elastic clamping spaces are formed between the conductive elastic pieces 153, so that the design of the plugging mode is optimized, and no additional structural design is required for the rechargeable battery pack.

Embodiment III:

the invention also provides a charging method which is applied to the molding machine system as in the second embodiment, wherein the molding machine system comprises a charging mechanism, the charging mechanism comprises a charging base, and a plurality of charging holes are formed in the upper end face of the charging base; the method specifically comprises the following steps:

detecting the assembled state of the rechargeable battery of the plurality of charging holes respectively;

the switches of the charging holes are sequentially opened, and electric quantity detection is carried out on the charging holes in a charging state; if the electric quantity of the rechargeable battery pack is detected to be full, the switch corresponding to the charging hole is closed, and if the electric quantity of the rechargeable battery pack is detected to be not full, the operation corresponding to the charging hole is continued. The sequence of opening the switches of the plurality of charging holes can be used for charging the battery pack firstly according to the time sequence of inserting the battery pack.

It should be noted that two charging holes of the charging base are provided, one charging hole is a single charging hole, and the charging logic under the charging hole specification is that the single charging hole works and detects the electric quantity until the electric quantity of the charging battery pack is full, and the charging is stopped;

another is two or more charging holes (two charging holes are taken as examples in the following), and the charging logic at this time is various:

the first one is that the switches of the charging holes are sequentially opened, namely, the charging battery packs in the two charging holes are sequentially charged with electricity;

secondly, half power is adopted to charge the two charging holes at the same time, and the charging holes corresponding to the charged battery pack stop working;

thirdly, firstly detecting electric quantity of the rechargeable battery packs with two charging holes, then supplying power to the rechargeable battery pack with higher electric quantity preferentially, and charging the next battery after the battery is full; the advantage of setting up like this is that can be preferentially full of the rechargeable battery group of high electric quantity to in order to take fast the of user, improve user's use swiftly, another rechargeable battery group of lower electric quantity can follow-up re-use.

The above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (26)

1. A rechargeable molding machine, comprising an upper housing assembly, a lower housing assembly, and a spindle assembly for hinging the upper housing assembly and the lower housing assembly;

the lower shell assembly is provided with a first cavity, the upper shell assembly is provided with a second cavity, a rechargeable battery pack is detachably connected in the first cavity, and a control assembly is arranged in the second cavity;

the wire passing channel extends towards the rotating shaft assembly and penetrates through the rotating shaft assembly, wires are buried in the wire passing channel, and two ends of each wire are connected with the rechargeable battery pack and the control assembly respectively.

2. The rechargeable molding machine of claim 1, wherein said wire has a length greater than a length of said wire passage, said wire passage having a stretch resistant segment of said wire reserved therein.

3. The rechargeable molding machine of claim 1, wherein the rotating shaft is sleeved with an electrical slip ring;

the electric wire comprises a first electric wire connected with the rechargeable battery pack and a second electric wire connected with the control assembly, and the first electric wire and the second electric wire are respectively connected with the electric slip ring.

4. The rechargeable molding machine of claim 1, wherein said control assembly comprises a control main board and a plurality of control keys disposed on said control main board, one end of said control keys being exposed to said upper housing assembly.

5. The rechargeable molding machine of claim 1, wherein a sidewall of said lower housing assembly defines a mounting opening in communication with said first cavity, said rechargeable battery pack being removably mounted in said first cavity through said mounting opening.

6. The mold of claim 5, wherein the mounting port is hinged with a protective cap, and the protective cap is rotated to cover the mounting port.

7. The rechargeable molding machine of claim 1, wherein an opening is formed at one end of the lower housing assembly, and the rechargeable battery pack is detachably inserted into the first cavity through the opening.

8. The rechargeable molding machine of claim 7, wherein said rechargeable battery pack comprises a battery body, a retaining button assembly is provided at an end of said battery body, and said retaining button assembly is snap-coupled to said lower housing assembly.

9. The rechargeable molding machine of claim 7, wherein said rechargeable battery pack is a universal rechargeable battery pack having a replaceable nature;

wherein the number of the rechargeable battery packs is a plurality of, and any one of the rechargeable battery packs is arranged in the first cavity;

the plurality of rechargeable batteries are respectively used for supplying power to any one of the styling device, the hair curler or the hair curler.

10. The rechargeable molding machine of claim 8, wherein said rechargeable battery pack further comprises a battery back cover, said battery back cover being disposed at one end of said battery body, and said battery back cover being exposed at said opening;

wherein, the battery back cover with battery body integral type sets up.

11. The rechargeable molding machine of claim 10, wherein the opening is provided with a notch groove matched with the limit buckle assembly, and the inner side wall of the first cavity close to one end of the opening is provided with a rotary groove;

during installation, the rechargeable battery pack is inserted into the first cavity, the limiting buckle assembly is inserted into the rotary groove along the notch groove, and the limiting buckle assembly is rotated, so that the limiting buckle assembly is clamped in the rotary groove.

12. The rechargeable molding machine of claim 1, wherein said insertion end of said rechargeable battery pack is provided with a first conductive portion;

the first cavity is internally provided with a second conductive part, and when the rechargeable battery pack is inserted into the first cavity, the first conductive part is electrically connected with the second conductive part.

13. The rechargeable molding machine of claim 12, wherein said first conductive portion is a plurality of electrical connection pads disposed on an end surface of said rechargeable battery pack.

14. The chargeable molding machine of claim 13, wherein the second conductive portion comprises a conductive base, and a plurality of conductive pins disposed on the conductive base, the conductive pins being disposed in one-to-one correspondence with the electrical connection pads, the conductive pins being electrically connected with the electrical connection pads.

15. The rechargeable molding machine of claim 12, wherein said first conductive portion is a plurality of electrical connection pads disposed on a sidewall of one end of said rechargeable battery pack.

16. The rechargeable molding machine of claim 15, wherein said second conductive portion comprises a conductive base and a plurality of conductive clips disposed on said conductive base;

an elastic clamping space is formed between the plurality of conductive elastic sheets, the insertion end of the rechargeable battery pack is clamped in the elastic clamping space, and the conductive elastic sheets are elastically abutted to the electric connecting sheets.

17. The mold of claim 16, wherein the second conductive portion further comprises a limiting plate, the limiting plate being disposed outside the conductive spring, the limiting plate being configured to limit a position of the conductive spring.

18. The rechargeable molding machine of claim 1, wherein a first receiving groove is formed in an end surface of said lower housing assembly, and a first heating plate is disposed in said first receiving groove;

the first heating plate comprises a first half section and a second half section, and the first half section is provided with a first sensing element.

19. The rechargeable molding machine of claim 18, wherein a second receiving groove is formed in an end surface of said upper housing assembly adjacent to said lower housing assembly, and a second heating plate is disposed in said second receiving groove;

the second heating plate comprises a third half section aligned with the first half section and a fourth half section aligned with the second half section, and the fourth half section is provided with a second sensing element.

20. The rechargeable molding machine of claim 19, wherein said first and second sensing elements are NTC temperature sensing elements, respectively.

21. The rechargeable molding machine of claim 19, wherein said first heating plate and said second heating plate are electrically connected to said control assembly via connecting lines, respectively;

the connecting line of the first heating plate and the control assembly is connected with a temperature fusing switch in series, and the temperature fusing switch is attached to the first heating plate.

22. A molding machine system comprising a rechargeable molding machine according to any one of claims 1 to 21.

23. The molding machine system of claim 22, further comprising a charging mechanism, said charging mechanism comprising a charging base, an upper end surface of said charging base being provided with a plurality of charging holes, said charging holes being configured to respectively power said rechargeable battery packs.

24. The molding machine system of claim 23, wherein a charging clip assembly is disposed within said charging aperture, and wherein an insertion end of said rechargeable battery pack is clipped onto said charging clip assembly.

25. The molding machine system of claim 22, further comprising a charging mechanism, an end face of the charging mechanism being provided with a charging aperture.

26. A charging method, characterized in that the method is applied to the molding machine system of any one of claims 22 to 25, the molding machine system comprises a charging mechanism, the charging mechanism comprises a charging base, and the upper end surface of the charging base is provided with a plurality of charging holes; the method specifically comprises the following steps:

detecting the assembled state of the rechargeable battery of the plurality of charging holes respectively;

the switches of the charging holes are sequentially opened, and electric quantity detection is carried out on the charging holes in a charging state; if the electric quantity of the rechargeable battery pack is detected to be full, the switch corresponding to the charging hole is closed, and if the electric quantity of the rechargeable battery pack is detected to be not full, the operation corresponding to the charging hole is continued.

Images