TYPE OF ELECTRIC SPLINT STRUCTURE

Abstract

Disclosed is a new type of electric splint structure, which includes two hinged splint parts and a tail end part; the splint part includes a housing and a heating-plate component mounted on the inner side of the housing, an air duct is arranged inside the housing, opposite air outlet holes and bristle-planting comb-teeth are respectively provided on one side edge of the two opposite housings, and the air outlet holes communicate with the air duct and are inclined toward the outside; the tail end part includes a fan component. The air outlet holes inclined toward the outside are provided on the side of the heating-plate component.

Description

TECHNICAL FIELD

The present disclosure relates to the technical field of hairdressing equipment, and more particularly, to a new type of electric splint structure.

BACKGROUND

The electric splint is a hairdressing tool. The hair is heated and softened by the electric splint, and the hair is shaped after cooling. The traditional electric splint has the following problems during use: as the hair heated by the electric splint cools slowly, the hair straightening operation takes a longer time, and the hair is prone to be deformed during the cooling process; in addition, when straightening hair, the hair clamped by the electric splint not only needs to be held by hand, but the hair will be overlapped instead of uniformly distributed, which affects the clamping operation and the straightening effect.

Chinese utility model patent with publication number CN213757030U discloses an air duct structure and a hairdressing device with the air duct structure. Air outlet holes are arranged on both sides of the electric splint to realize the rapid cooling and shaping of the hair. However, the air outlet holes are arranged perpendicular to the upper and lower splints, so that the cold air blown from the air outlet holes is very close to the splints. On the one hand, the surface temperature of the heated hair is relatively high, and the cooling effect is not ideal when the temperature is temporarily cooled by the cold air from the air outlet holes, on the other hand, part of the cold air is directly blown to the splint, thereby affecting the heating effect of the splint.

SUMMARY

The purpose of the present disclosure is to provide an electric splint structure that can quickly shape hair and is convenient to operate.

In order to achieve the above purpose, the technical solutions adopted by the present disclosure are:

A new type of electric splint structure, which includes two splint parts that correspond up and down and are hinged at the rear end, and a tail end part; the splint part includes a housing, and a heating-plate component mounted on an inner side of the housing, an inside of the housing has an air duct along an axial direction, and positions corresponding to one side edge of the heating-plate component on two opposite housings are respectively provided with one or more opposite air outlet holes and bristle-planting comb-teeth, the air outlet hole is in communication with the air duct and is inclined toward the outside; the tail end part includes an outer casing, an air inlet provided on the outer casing, and a fan component for providing cold air to two opposite air ducts.

The beneficial effects of the above solution are: air outlet holes inclined toward the outside are provided on the side of the heating-plate component, and the heated hair is cooled by the air blown from the air outlet holes after a natural cooling within a certain distance. In addition, the area covered by the obliquely blown air is larger, thereby achieving a better cooling effect. At the same time, the cold air from the air outlet hole will not be blown to the heating-plate component; the planted bristles of the bristle-planting comb-teeth can hold and fix the hair without manual assistance, and can evenly arrange the hair passing through the electric splint, thereby being easy to operate and having a good hair-straightening effect, at the same time, the planted bristles have a hair care effect for the friction of the hair, and can improve the problem of hair frizz after heating.

According to a preferred solution, the bristle-planting comb-tooth comprises a bristle-planting bundle and a bristle-planting strip that fixes the bristle-planting bundle, and the bristle-planting strip is penetratingly embedded in the housing and communicated with the air duct.

In the above solution, part of the cold air in the air duct can cool down the bristle-planting strip, avoiding rapid aging of the bristle-planting strip due to heat, and thereby prolonging the service life of the bristle-planting strip.

According to a preferred solution, positions corresponding to the other side edge of the heating-plate component on the two opposite housings are also respectively provided with one or more opposite air outlet holes and bristle-planting comb-teeth, and one side edge of the same heating-plate component is provided with the air outlet, and the other side edge is provided with the bristle-planting comb-teeth.

In the above solution, both sides of the electric splint are provided with air outlet holes and bristle-planting comb-teeth, and the two sides of the same clamping part are provided with air outlet holes and bristle-planting comb-teeth, thus, regardless of the left and right hand operation or the forward and reverse grasping, the hair can be easily fixed and cooled, thereby making the operation easier.

According to a preferred solution, the housing includes a front section for installing the heating-plate component and a rear section for grasping, and the air duct is configured to axially penetrate entire inside of the housing.

In the above solution, the housing is provided with a front section and a rear section, thereby being convenient for holding the rear section for opening and closing operations of the electric splint and avoiding burning the hand.

According to a preferred solution, the front section of the housing is provided with an air deflector that separates the areas on both sides, whereby the air duct being divided into a left part and a right part in the front section.

In the above solution, an air deflector is provided to avoid excessive dispersion of the air blown to the air outlet holes.

According to a preferred solution, one of the housings is further provided with a control circuit board in the rear section, and control buttons provided on a side.

In the above solution, the control circuit board and the control buttons are arranged in the rear section, so that the layout of the electric splint structure is reasonable, avoiding the excessive diameter of the splint part, and at the same time, being convenient for one-handed operation and control.

According to a preferred solution, a spring is pressed against the two splint parts between the inner sides of the tail end of the rear section, whereby the two splint parts being in a normally open state.

In the above solution, the normally open state of the two splints is more convenient for operation.

According to a preferred solution, a lower half part of the outer casing and a tail end of the housing are an integral structure, a front end of an upper half part of the outer casing is provided with a rotatable locking key, and a tail end of the other movable housing has an axial locking groove corresponding to the locking key, when the locking key is rotated to deviate from the locking groove, the two splint parts cannot be opened.

In the above solution, the two splints can be locked by rotating the locking key, thereby being convenient for storage, packaging and transportation.

According to a preferred solution, the fan component comprises a motor and air blades arranged in the outer casing along the axial direction, and the air inlet includes circumferentially distributed air inlet holes provided on the outer casing and an air inlet grid provided on a tail end surface of the outer casing.

According to a preferred solution, the heating-plate component comprises a heat-conducting plate fixed on an inner side surface of the housing, the heat-conducting plate has a mounting cavity inside, and the mounting cavity is equipped with a PTC heat generating element and an NTC temperature control element.

In the above solution, the heating-plate component has uniform temperature, small volume, and stable and controllable temperature.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure will be further described in detail below with reference to the drawings and specific embodiments.

FIG. 1 is a schematic diagram of an overall structure of an electric splint according to an embodiment;

FIG. 2 is a schematic diagram of an axial cross-sectional structure of an electric splint according to an embodiment;

FIG. 3 is a schematic diagram of a radial cross-sectional structure of a front section of an electric splint according to an embodiment;

FIG. 4 is a schematic diagram of an exploded structure of the parts of an electric splint according to an embodiment.

DETAILED DESCRIPTION OF THE DRAWINGS

The present disclosure will be further described below in conjunction with the accompanying drawings:

Referring to FIG. 1 to FIG. 4, a new type of electric splint structure includes two splint parts 1 which are corresponding up and down and hinged at the rear end, and a tail end part 2; the splint part 1 includes a housing 11 and a heating-plate component 12 mounted on the inner side of the housing 11; the heating-plate component 12 includes a heat-conducting plate fixed on the inner surface of the housing 11, the heat-conducting plate has a mounting cavity inside, and the mounting cavity is equipped with a PTC heat generating element and an NTC temperature control element; the housing 11 has an air duct 13 along an axial direction inside, opposing air outlet hole 14 and bristle-planting comb-teeth 15 are respectively provided at positions corresponding to one side edge of the heating-plate component 12 on the two opposite housings 11, the air outlet hole 14 communicates with the air duct 13 and is inclined toward the outside; the tail end part 2 includes an outer casing 21, an air inlet 22 provided on the outer casing 21, and a fan component 23 for providing cold air to the two opposite air ducts 13; the fan component 23 includes a motor and air blades arranged in the outer casing 21 along the axial direction, the air inlet 22 includes air inlet holes arranged on the outer casing 21 and distributed around the circumference and an air inlet grid arranged on the tail end surface of the outer casing 21.

The air outlet holes 14 inclined toward the outside are provided on the side of the heating-plate component 12, and the heated hair is cooled by the air blown from the air outlet holes 14, after a natural cooling within a certain distance. In addition, the area covered by the obliquely blown air is larger, thereby achieving a better cooling effect and reducing the styling time. At the same time, the cold air from the air outlet hole 14 will not be blown to the heating-plate component 12; the planted bristles of the bristle-planting comb-teeth 15 can hold and fix the hair without manual assistance, and can evenly arrange the hair passing through the electric splint, thereby being easy to operate and having a good hair-straightening effect, at the same time, the planted bristles have a hair care effect for the friction of the hair, and can improve the problem of hair frizz after heating. The heating-plate component 12 adopts a PTC heat generating element to make the temperature uniform and small in size, and adopts an NTC temperature control element to make the temperature stable and controllable.

In a preferred implementation structure, the bristle-planting comb-tooth 15 includes a bristle-planting bundle 151 and a bristle-planting strip 152 for fixing the bristle-planting bundle 151, the bristle-planting strip 152 is embedded in the housing 11 and communicates with the air duct 13. The positions corresponding to the other side edge of the heating-plate component 12 on the two opposite housings 11 are further provided with an opposite air outlet hole 14 and bristle-planting comb-teeth 15 respectively. Moreover, one side edge of the same heating-plate component 12 is the provided with the air outlet hole 14, while the other side edge is provided with the bristle-planting comb-tooth 15. Both sides of the electric splint are provided with air outlet holes 14 and bristle-planting comb-teeth 15, and the two sides of the same clamping part are provided with both the air outlet holes 14 and the bristle-planting comb-teeth 15, thus, regardless of the left and right hand operation or the forward and reverse grasping, the hair can be easily fixed and cooled, thereby making the operation easier. Part of the cold air in the air duct 13 is blown out from the air outlet hole 14 and part of it can cool the bristle-planting strip 152 to avoid rapid aging of the bristle-planting strip 152 due to heat, thereby prolonging the service life of the bristle-planting strip 152.

According to a preferred implementation structure, the housing 11 includes a front section 111 for installing the heating-plate component 12 and a rear section 112 for grasping. The air duct 13 is configured to axially penetrate the entire inside of the housing 11. In this structure, the housing 11 is divided into the front section 111 and the rear section 112, thereby being convenient for holding the rear section 112 to open and close the electric splint and avoiding burning the hand. The electric splint of this structure is relatively slender, thereby being convenient for grasping operation, and safer at the same time. But if the housing 11 is not divided into the front section 111 and the rear section 112, it can also be realized. When each structure such as the circuit board is arranged in a position inside the housing 11 corresponding to the position of the heating-plate component 12, the overall diameter of the electric splint is larger, and the opening of the two splint parts 1 is realized by the pressing handle at the tail end.

According to a preferred implementation structure, the front section 111 of the housing 11 has an air deflector 131 that separates the areas on both sides, thereby the air duct 13 being divided into a left part and a right part in the front section 111. In this structure, the air deflector 131 is provided to prevent the air blowing to the air outlet hole 14 from being excessively dispersed.

According to a preferred implementation structure, a control circuit board 16 is further provided in the rear section 112 of the housing 11, and control buttons 161 are provided on the side. In this structure, the control circuit board 16 and the control buttons 161 are arranged in the rear section 112, thereby the electric splint structure being reasonably arranged, avoiding the splint part 1 from being too large in diameter, and at the same time, being convenient for one-handed operation and control.

According to a preferred implementation structure, a spring is pressed against the two splint parts 1 between the inner sides of the tail end of the rear section 112, whereby the two splint parts 1 being in a normally open state. A lower half part of the outer casing 21 and a tail end of the housing 11 are an integral structure, a front end of an upper half part of the outer casing 21 is provided with a rotatable locking key 24, and a tail end of the other movable housing 11 is provided with an axial locking groove 17 corresponding to the locking key 24, when the locking key 24 is rotated to deviate from the locking groove 17, the two splint parts 1 cannot be opened. In this structure, the normally open state of the two splint parts 1 is more convenient for operation. By rotating the locking key 24, the two splint parts 1 can be locked, thereby being convenient for storage, packaging and transportation.

The above description does not limit the technical scope of the present disclosure in any way, any amendment, equivalent change and modification made to the above embodiments based on the technical essence of the present disclosure still fall within the scope of the technical solution of the present disclosure.

Claims

1. A new type of electric splint structure, comprising two splint parts corresponding up and down and hinged at a rear end, and a tail end part; wherein the splint part comprises a housing, and a heating-plate component mounted on an inner side of the housing, an inside of the housing has an air duct along an axial direction, and positions corresponding to one side edge of the heating-plate component on two opposite housings are respectively provided with one or more opposite air outlet holes and bristle-planting comb-teeth, the air outlet hole is in communication with the air duct and is inclined toward the outside; wherein the tail end part comprises an outer casing, an air inlet provided on the outer casing, and a fan component for providing cold air to two opposite air ducts.

2. The new type of electric splint structure of claim 1, wherein the bristle-planting comb-tooth comprises a bristle-planting bundle and a bristle-planting strip that fixes the bristle-planting bundle, and the bristle-planting strip is penetratingly embedded in the housing and in communication with the air duct.

3. The new type of electric splint structure of claim 2, wherein positions corresponding to the other side edge of the heating-plate component on the two opposite housings are also respectively provided with one or more opposite air outlet holes and bristle-planting comb-teeth, and one side edge of the same heating-plate component is provided with the air outlet, and the other side edge is provided with the bristle-planting comb-teeth.

4. The new type of electric splint structure of claim 3, wherein the housing includes a front section for installing the heating-plate component and a rear section for grasping, and the air duct is configured to axially penetrate entire inside of the housing.

5. The new type of electric splint structure of claim 4, wherein the front section of the housing is provided with an air deflector that separates the areas on both sides, whereby the air duct being divided into a left part and a right part in the front section.

6. The new type of electric splint structure of claim 4, wherein one of the housings is further provided with a control circuit board in the rear section, and control buttons provided on a side of the control circuit board.

7. The new type of electric splint structure of claim 6, wherein a spring is pressed against the two splint parts between the inner sides of the tail end of the rear section, whereby the two splint parts being in a normally open state.

8. The new type of electric splint structure of claim 7, wherein a lower half part of the outer casing and a tail end of one of the housings are an integral structure, a front end of an upper half part of the outer casing is provided with a rotatable locking key, and a tail end of the other movable housing has an axial locking groove corresponding to the locking key, when the locking key is rotated to deviate from the locking groove, the two splint parts cannot be opened.

9. The new type of electric splint structure of claim 1, wherein the fan component comprises a motor and air blades arranged in the outer casing along the axial direction, and the air inlet includes circumferentially distributed air inlet holes provided on the outer casing and an air inlet grid provided on a tail end surface of the outer casing.

10. The new type of electric splint structure of claim 1, wherein the heating-plate component comprises a heat-conducting plate fixed on an inner side surface of the housing, the heat-conducting plate has a mounting cavity inside, and the mounting cavity is equipped with a PTC heat generating element and an NTC temperature control element.