WARM-AIR COMB

Abstract

A brush includes a housing, an air inlet formed in an end of the housing, an air discharge portion formed in the housing, the air discharge portion having a plurality of air outlets, and an air combing head disposed at the air discharge portion, the air combing head having a plurality of brush teeth. A thermal insulation cylinder is arranged inside the housing, where the thermal insulation cylinder has a cylinder opening facing toward the air inlet, an outlet formed a distance away from the cylinder opening, and an inner diameter gradually decreasing from the cylinder opening to the outlet. A heating element is arranged inside the thermal insulation cylinder. An air guiding mechanism is also positioned within the housing to direct air from the air inlet to the air discharge portion of the housing.

Description

BACKGROUND

A warm-air comb is a comb with an air blowing function, which can dry and set hair when combing the same. The existing combs generally comprise a housing, a heating element, comb teeth, a vane and a motor, wherein a plurality of air outlets are formed in the circumference of the housing; the comb teeth are uniformly distributed on the circumference of the housing; the heating element, the vane and the motor are installed inside the housing; the motor is used for driving the vane to rotate and bring external air into the housing; and the air is discharged via the air outlets after being heated by the heating element.

In the case of the existing warm-air combs, the outgoing air is not concentrated, the air volume is relatively small and the air speed is relatively low. Moreover, the heating effect is poor and the outgoing air is not uniform in temperature.

SUMMARY

In view of the shortcomings in the prior art, the object of the present invention is to provide a warm-air comb, which may provide concentrated outgoing air, large air volume, high air speed, good heating effect and relatively uniform outgoing air temperature.

To achieve the above object, the following technical solution may be adopted:

A warm-air comb may include a housing and an air guiding mechanism, wherein an air inlet is formed in one end of the housing; the air guiding mechanism is arranged inside the housing and is used for bringing external air into the housing via the air inlet. The warm-air comb may also include a thermal insulation cylinder, a heating element and an air combing head, where the thermal insulation cylinder is arranged inside the housing, a cylinder opening of the thermal insulation cylinder faces toward the air inlet, and the outer edge of the cylinder opening is attached to the inner wall of the housing. An opening may be formed in the lower portion of one end of the thermal insulation cylinder away from the cylinder opening, and an inner diameter of the thermal insulation cylinder may gradually decrease from the cylinder opening to the opening. The heating element may be arranged inside the thermal insulation cylinder. An air discharge position may be provided on the housing below the opening, and a plurality of air outlets may be formed in the air discharge position. The air combing head may include a base installed on the housing and comb teeth fixedly arranged on the base, where a plurality of air holes communicated with the air outlets one by one are formed in the base.

The air guiding mechanism may be located between the air inlet and the cylinder opening, and the air guiding mechanism may include a motor and a vane driven by the motor.

A clamping hole may be formed in the base. The warm-air comb may further include a sliding element and an elastic resetting element. A clamping tongue may be arranged at one end of the sliding element close to the base; a shifting part may be arranged at the lower end of the sliding element; the sliding element may be slidably installed on the housing, and the shifting part may be exposed outside the housing. The shifting part may be used for being shifted to drive the sliding element to move between a position where the clamping tongue is clamped in the clamping hole and a position where the clamping tongue is located outside the clamping hole; and the elastic resetting element may be used for providing an elastic resetting force for the sliding element to approach the air combing head.

The heating element may be a quartz tube.

Embodiments according to the present disclosure may have the following beneficial effects:

When a warm-air comb according to embodiments of the present disclosure is at work, the air guiding mechanism may bring external air into the housing via the air inlet. The external air may then enter the thermal insulation cylinder via the cylinder opening to be heated by the heating element. Meanwhile the air may be gradually compressed with the gradual decrease of the inner diameter of the thermal insulation cylinder and is passed to the air discharge position via the opening at a relatively high air speed. Then, a portion of the air may be discharged via the air outlets and the air holes. In this way, the outgoing air may be relatively concentrated, and the air speed may be relatively high and the air volume may be relatively large. Moreover, since the air holes are small, a portion of the air incapable of passing through the air holes may be blocked by the inner wall of the housing, return into the thermal insulation cylinder, and mixed with new air, which may be heated together with the same. In this way, the heating effect is better, and the mixed air is more uniform in temperature when compared with previous combs.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a structural schematic diagram of the present invention.

FIG. 2 is an exploded assembly view of FIG. 1.

FIG. 3 is a structural schematic diagram of a lower housing of the present invention.

FIG. 4 is a structural schematic diagram of an air combing head of the present invention.

FIG. 5 is a structural schematic diagram of a lower housing, an air combing head, a sliding element and an elastic resetting element of the present invention.

FIG. 6 is a partial enlarged view of a site A in FIG. 5.

FIG. 7 is a structural schematic diagram of the present invention from another perspective.

Reference numerals: 10—housing, 101—upper housing, 102—lower housing, 103—reticular sleeving element, 104—back housing, 11—air inlet, 12—air discharge position, 121—air outlet, 20—air guiding mechanism, 21—motor, 22—vane, 30—thermal insulation cylinder, 31—cylinder opening, 32—opening, 40—air combing head, 41—base, 411—air hole, 412—inserting part, 413—clamping hole, 42—combing tooth, 50—sliding element, 51—clamping tongue, 52—shifting part, 60—elastic resetting element.

DETAILED DESCRIPTION

A further description of the present invention will be given below in combination with the accompanying drawings and specific embodiments.

As shown in FIGS. 1-7, a warm-air comb provided by the present invention comprises a housing 10, an air guiding mechanism 20, a thermal insulation cylinder 30, a heating element (not shown in the figures) and an air combing head 40. An air inlet 11 is formed in one end of the housing 10; the air guiding mechanism 20 is arranged inside the housing 10 and is used for bringing external air into the housing 10 via the air inlet 11; the thermal insulation cylinder 30 is arranged inside the housing 10; a cylinder opening 31 of the thermal insulation cylinder 30 faces toward the air inlet 11, and the outer edge of the cylinder opening 31 is attached to an inner wall of the housing 10; an opening 32 is formed in a lower portion of one end of the thermal insulation cylinder 30 away from the cylinder opening 31; an inner diameter of the thermal insulation cylinder 30 gradually decreases from the cylinder opening 31 to the opening 32; the heating element is arranged inside the thermal insulation cylinder 30; an air discharge position 12 is provided on the housing 10 below the opening 32; a plurality of air outlets 121 are formed in the air discharge position 12; the air combing head 40 comprises a base 41 installed on the housing 10 and comb teeth 42 fixedly arranged on the base 41; and a plurality of air holes 411 communicated with the air outlets 121 one by one are formed in the base 41.

When the warm-air comb is at work, the air guiding mechanism 20 brings external air into the housing 10 via the air inlet 11, the external air enters the thermal insulation cylinder 30 via the cylinder opening 31 to be heated by the heating element, meanwhile the air is gradually compressed with the gradual decrease of the inner diameter of the thermal insulation cylinder 30 and is passed to the air discharge position 12 via the opening 32 at a relatively high air speed, a portion of the air is discharged via the air outlets 121 and the air holes 411, in this way, the outgoing air is relatively concentrated, and the air speed is relatively high and the air volume is relatively large; moreover, since the air holes 411 are small, a portion of the air incapable of passing through the air holes 411 is blocked by the inner wall of the housing 10, returns into the thermal insulation cylinder 30, and is mixed with new air and is heated together with the same, in this way, the heating effect is better, and the mixed air is more uniform in temperature.

Further, the air guiding mechanism 20 is located between the air inlet 11 and the cylinder opening 31, and the air guiding mechanism 20 comprises a motor 21 and a vane 22 driven by the motor 21. The air guiding mechanism 20 can also be other mechanisms, as long as the external air can be introduced into the housing 10 at a certain speed.

Further, a clamping hole 413 is formed in the base 41; the warm-air comb further comprises a sliding element 50 and an elastic resetting element 60; a clamping tongue 51 is arranged at one end of the sliding element 50 close to the base 41; a shifting part 52 is arranged at the lower end of the sliding element 50; the sliding element 50 is slidably installed on the housing 10, and the shifting part 52 is exposed outside the housing 10; the shifting part 52 is used for being shifted to drive the sliding element 50 to move between a position where the clamping tongue 51 is clamped in the clamping hole 413 and a position where the clamping tongue 51 is located outside the clamping hole 413; and the elastic resetting element 60 is used for providing an elastic resetting force for the sliding element 50 to approach the air combing head 40, so that when the shifting part 52 is not shifted, the clamping tongue 51 can be clamped in the clamping hole 413. In this way, after the air comb is installed, the clamping tongue 51 can be clamped in the clamping hole 413 to fix the air combing head 40, and for disassembly, it only needs to shift the shifting part 52 so that the clamping tongue 51 is removed from the clamping hole 413, so as to detach the air combing head 40 for cleaning (as shown in FIGS. 6 and 7).

Further, an inserting part 412 is arranged on the base 41; the inserting part 412 can be inserted on the housing 10; and a portion of the inserting part 412 located inside the housing 10 is provided with the clamping hole 413.

Further, the elastic resetting element 60 is a spring; one end of the spring abuts against the sliding element 50, and the other end thereof abuts against the inner wall of the housing 10 or abuts against a component which is fixedly connected with the housing 10. Alternatively, the elastic resetting element 60 can also be other components, such as an elastic plastic element or the like, as long as an elastic resetting force can be provided for the sliding element 50 to approach the air combing head 40.

Further, the housing 10 comprises an upper housing 101 and a lower housing 102; the upper housing 101 and the lower housing 102 are combined to form the housing 10; and the air discharge position 12 is provided on the lower housing 102.

Further, reticular structures are arranged at the ends of both the upper housing 101 and the lower housing 102; the housing 10 further comprises a reticular sleeving element 103 and a back housing 104; the reticular sleeving element 103 is sleeved on the ends of the upper housing 101 and the lower housing 102 with the reticular structures; the back housing 104 is sleeved on the outer side of the reticular sleeving element 103; and the air inlet 11 is formed in the back housing 104. In this way, air enters via the air inlet 11 and enters the housing 10 after passing through the through hole of the reticular sleeving element 103 and the through holes of the reticular structures of the upper housing 101 and the lower housing 102 in sequence, and thus ensuring that the air can be uniformly blown into the housing 10.

Further, the heating element is a quartz tube, so that the heating effect is better, and the quartz tube can be changed into different colors, light emitted by the quartz tube can transmit to the outside through the air outlets 121 and the air holes 411 and irradiated on the comb teeth 42, thereby being beautiful. It should be noted that the heating element can be also an electric heating wire.

Those skilled in the art can make a variety of other corresponding modifications and variations according to the technical solutions and concepts described above, and all these modifications and variations should fall into the protection scope of the claims of the present invention.

Claims

1. A brush, comprising: a housing;an air inlet formed in an end of the housinga thermal insulation cylinder arranged inside the housing, the thermal insulation cylinder comprising: a cylinder opening facing toward the air inlet;an outlet formed a distance away from the cylinder opening; andan inner diameter gradually decreasing from the cylinder opening to the outlet;a heating element arranged inside the thermal insulation cylinder;an air discharge portion formed in the housing, the air discharge portion comprising a plurality of air outlets;an air guiding mechanism positioned within the housing to direct air from the air inlet to the air discharge portion; andan air combing head disposed at the air discharge portion, the air combing head comprising a plurality of brush teeth.

2. The brush of claim 1, wherein the air guiding mechanism is located between the air inlet and the cylinder opening.

3. The brush of claim 1, further comprising: a clamping hole formed in a base of the air combing head;a release mechanism configured to releasably engage the clamping hole, the release mechanism comprising: a sliding element slidably installed in the housing, the sliding element comprising: a shifting part exposed outside the housing; anda clamping tongue formed at one end of the sliding element and configured to insert into the clamping hole; andan elastic resetting element positioned at an opposite end of the sliding element from the clamping tongue.

4. The brush of claim 1, wherein the heating element is a quartz tube.

5. The brush of claim 1, wherein the heating element is an electric heating wire.

6. The brush of claim 1, wherein the air guiding mechanism comprises a motor and a vane driven by the motor.

7. The brush of claim 1, wherein the air combing head is removably installed on the air discharge portion, the air combing head comprising: a base disposed on the air discharge portion of the housing; anda plurality of air holes formed through the base, where each air hole is arranged on the base to correspond with each of the air outlets formed in the air discharge portion;wherein the plurality of brush teeth are fixedly disposed on the base.

8. The brush of claim 1, wherein an outer edge of the cylinder opening is attached to an inner wall of the housing.

9. The brush of claim 1, wherein the housing comprises a lower housing and an upper housing assembled together around the thermal insulation cylinder and a back housing forming the end of the housing, wherein the air inlet is foamed in the back housing.

10. The brush of claim 9, further comprising a reticular sleeve element disposed between the back housing and the thermal insulation cylinder.

11. A method of making a brush, comprising: providing housing comprising: a lower housing having an air discharge portion formed therein; andan upper housing; andassembling a thermal insulation cylinder between the lower housing and the upper housing, the thermal insulation cylinder having an inner diameter gradually decreasing from a cylinder opening to an outlet; wherein the outlet is aligned with the air discharge portion; andwherein the cylinder opening faces an air inlet formed at an end of the housing;assembling and an air guiding mechanism between the lower housing and the upper housing; andproviding a power source to the air guiding mechanism.

12. The method of claim 11, further comprising arranging a heating element inside the thermal insulation cylinder.

13. The method of claim 12, wherein the heating element is a quartz tube and is arranged inside the thermal insulation cylinder such that light emitted from the quartz tube transmits through the air discharge portion.

14. The method of claim 11, further comprising: providing an air combing head comprising: a base;a plurality of air holes formed through the base; anda plurality of brush teeth fixedly disposed on the base;removably attaching the base to the lower housing at the air discharge portion, wherein each air hole is arranged on the base to correspond with each of the air outlets formed in the air discharge portion.

15. The method of claim 11, further comprising attaching a release mechanism to the lower housing, the release mechanism comprising: a sliding element slidably installed to the lower housing, the sliding element comprising: a shifting part exposed outside the lower housing; anda clamping tongue formed at an end of the sliding element; andan elastic resetting element positioned at an opposite end of the sliding element from the clamping tongue.

16. The method of claim 11, wherein the housing further comprises a back housing having the air inlet formed therein, and wherein the back housing forms the end of the housing.

17. The method of claim 16, further comprising assembling a reticular element between the back housing and the lower and upper housings.

18. A method of directing air through a brush, comprising: providing a brush housing having an inlet, an air discharge portion formed a distance away from the inlet, and a thermal insulation cylinder disposed within the brush housing; andchanneling air through a decreasing inner diameter of the thermal insulation cylinder, from the inlet to the air discharge portion.

19. The method of claim 18, further comprising heating the air during channeling.

20. The method of claim 18, wherein an air guiding mechanism channels the air, the air guiding mechanism disposed between the inlet and the thermal insulation cylinder.