Patent Description:
The present disclosure relates to the field of hair clipper technologies, and more particularly, to a moving blade adjusting structure for a hair clipper.

At present, an adjustment stroke of a moving blade of the hair clippers on the market is small, and it is difficult to control a force. Thus, it is difficult for consumers to adjust to a desired scale. In addition, there is a problem of retreat when the moving blade of the hair clippers is adjusted to the topmost position, and a position of the moving blade is unstable, thus, affecting a length of haircut.

<CIT> discloses a Hair clipper which includes stationary blade, movable blade, main body, and dial. Guide groove is formed in dial. Movable blade slides relative to stationary blade in a longer direction of main body by moving boss inserted into guide groove. A slide mechanism includes first spring that pushes movable blade against stationary blade, and second spring that applies force to boss in a direction opposite to first spring. Characteristics of first and second springs are set such that a magnitude relation of the forces to boss applied by first spring and second spring switches with a change in relative positions of guide groove and boss. Accordingly, the hair clippers with pleasant operability can be offered.

<CIT> discloses a hair clipper with a light supplementing function. Blade assembly comprising a housing, wherein a power supply assembly and a motor are arranged in the shell, the blade assembly comprises a fixed knife rest, a fixed blade and a movable knife rest, the movable knife rest is provided with a movable blade, the fixed knife rest is installed on the shell through a knife head seat, a switch circuit board electrically connected with the power supply assembly is arranged in the shell, the switch circuit board is provided with a lamp bead, the shell is provided with a through hole, and the knife head seat is provided with irradiation holes; a mounting hole is formed in the shell, a switch button is arranged in the mounting hole, and a button spring is further arranged in the mounting hole. The utility model has the following advantages and effects: the lamp beads are adopted for supplementing light, so that geographical hair can be easily and conveniently made in dark, the hairdressing effect is better, and the safety is higher; the light guide surface and the light guide block are adopted to converge light to the tool bit of the blade assembly; a blade adjusting mechanism is adopted to conveniently adjust the tooth pitch; and a multi-gear speed regulation function is achieved.

The present disclosure provides a moving blade adjusting structure for a hair clipper, and solves the technical problems of an inconvenient adjustment of a position of the moving blade of the hair clipper and an unstable position of the moving blade.

In order to achieve the above objective, the present invention provides the following technical solutions.

A moving blade adjusting structure for a hair clipper, including a blade assembly, a blade adjusting push rod <NUM>, an inner container assembly <NUM>, a knob assembly, a blade cover <NUM> and a body housing <NUM>. The blade adjusting push rod <NUM> is slidably coupled to the inner container assembly <NUM>, the inner container assembly <NUM> is fitted in the body housing <NUM>, the knob assembly is arranged on a stud of the inner container assembly <NUM>, and the blade adjusting push rod <NUM> is movably coupled to the knob assembly. The blade assembly is arranged in the blade cover <NUM>, the blade assembly is movably coupled to the blade adjusting push rod <NUM>, and the blade cover <NUM> is fixedly coupled to the body housing <NUM>.

The knob assembly includes a knob pressing block <NUM>, a knob <NUM>, a metal elastic sheet <NUM> and a cam <NUM>. The cam <NUM> is arranged on the inner container assembly <NUM> through the stud on the inner container assembly <NUM>, and an end face of the cam <NUM> is engaged with the blade adjusting push rod <NUM> in a movement direction of the blade adjusting push rod <NUM>. The metal elastic sheet <NUM> is coupled to the knob <NUM> in a snapped manner, the knob <NUM> is concentrically assembled with the cam <NUM> through the stud on the inner container assembly <NUM>, and the knob pressing block <NUM> is concentrically assembled with the knob <NUM> through the stud of the inner container assembly <NUM>.

In some embodiments, the knob assembly also includes a scale trim <NUM> arranged on the knob <NUM>.

In some embodiments, the cam <NUM> is a structure of an eccentric wheel, and the knob <NUM> rotates, to drive the cam <NUM> to rotate synchronously.

In some embodiments, the blade assembly includes a stationary blade <NUM>, a moving blade <NUM>, a stationary blade holder <NUM>, a moving blade holder <NUM>, a moving blade compression spring <NUM> and a compression spring holder <NUM>. The moving blade compression spring <NUM> is arranged on the compression spring holder <NUM>, the stationary blade <NUM> is fixedly arranged on the stationary blade holder <NUM>, and the moving blade <NUM> is fixedly arranged on the moving blade holder <NUM>. The stationary blade holder <NUM> is movably coupled to the moving blade holder <NUM> through the moving blade compression spring <NUM>, and the compression spring holder <NUM> is movably coupled to the blade adjusting push rod <NUM>.

In some embodiments, the blade assembly further includes a coupling elastic sheet configured to couple the blade assembly to the inner container assembly <NUM>.

By implementing the above technical solutions, the following technical effects are realized: in the moving blade adjustment structure for the hair clipper according to the disclosure, a structure of a force-saving knob is employed, and a self-locking function is realized, thus achieving easy adjustment of a position of the blade and solving the problem of the retreat of the blade at the same time. Through the rotation of the cam, the blade adjusting push rod is driven to move horizontally, so that a rotary motion is converted into a horizontal motion. Moreover, a self-locking function is realized, and the overall structure is stable and reliable.

In order to better understand the technical solution of the present disclosure, embodiments of the present disclosure are described in detail below with reference to the accompanying drawings.

A moving blade adjusting structure for a hair clipper according to the claimed invention includes: a blade assembly, a blade adjusting push rod <NUM>, an inner container assembly <NUM>, a knob assembly, a blade cover <NUM> and a body housing <NUM>. The blade adjusting push rod <NUM> is slidably coupled to the inner container assembly <NUM>, the inner container assembly <NUM> is fitted in the body housing <NUM>, the knob assembly is arranged on a stud of the inner container assembly <NUM>, and the blade adjusting push rod <NUM> is movably coupled to the knob assembly. The blade assembly is arranged in the blade cover <NUM>, the blade assembly is movably coupled to the blade adjusting push rod <NUM>, and the blade cover <NUM> is fixedly coupled to the body housing <NUM>. The knob assembly rotates to drive the blade adjusting push rod <NUM> to slide up and down, and the blade adjusting push rod <NUM> pushes the blade assembly. The knob assembly and the blade adjusting push rod <NUM> constitute a force-saving structure, so that the knob assembly converts a rotary motion into a horizontal motion, thus achieving a purpose of adjusting the moving blade. A structure of a force-saving knob is employed, and a self-locking function is realized, thus achieving easy adjustment of a position of the blade.

The claimed knob assembly further includes a knob pressing block <NUM>, a knob <NUM>, a metal elastic sheet <NUM> and a cam <NUM>. The cam <NUM> is arranged on the inner container assembly <NUM> through the stud on the inner container assembly <NUM>, and an end face of the cam <NUM> is engaged with the blade adjusting push rod <NUM> in a movement direction of the blade adjusting push rod <NUM>. The metal elastic sheet <NUM> is coupled to the knob <NUM> in a snapped manner, the knob <NUM> is concentrically assembled with the cam <NUM> through the stud on the inner container assembly <NUM>, and the knob pressing block <NUM> is concentrically assembled with the knob <NUM> through the stud of the inner container assembly <NUM>. As illustrated in <FIG>, the blade adjusting push rod <NUM> is assembled with the inner container assembly <NUM> in the snapped manner, a movable gap is provided between a snap position on the inner container assembly <NUM> and a sliding groove of the blade adjusting push rod <NUM>, to slide up and down. The cam <NUM> is assembled concentrically with the stud of the inner container assembly <NUM>, and the inner container assembly <NUM> is fixed to the body housing <NUM> by a screw. The metal elastic sheet <NUM> is assembled with the knob <NUM> in the snapped manner, the knob <NUM> is assembled concentrically through the stud of the inner container assembly <NUM>, and the knob pressing block <NUM> is assembled concentrically with the knob <NUM> through the stud of the inner container assembly <NUM>. In this embodiment, the knob assembly further includes a scale trim <NUM>, and the scale trim <NUM> is arranged on the knob <NUM>. In this embodiment, the scale trim <NUM> is bonded with the knob <NUM> through an adhesive backing, and the knob <NUM> rotates to drive the cam <NUM> to rotate synchronously. As illustrated in <FIG>, the cam <NUM> has a structure of an eccentric wheel. The knob <NUM> rotates to drive the cam <NUM> to rotate synchronously. The blade adjusting push rod <NUM> is engaged with the end face of the cam <NUM> in the horizontal direction. A radius of the cam <NUM> changes during the rotation, to drive the blade adjusting push rod <NUM> to slide forward. The blade adjusting push rod <NUM> slides forward to drive a compression spring holder to move, achieving the purpose of adjusting the moving blade. The knob <NUM> drives the cam <NUM> to rotate, and the blade adjusting push rod <NUM> slides up and down through the eccentric wheel. A torque of the knob <NUM> is big, and converts the rotary motion into the horizontal motion, thus constituting the force-saving structure. The metal elastic sheet <NUM> is fixedly coupled to the knob <NUM>. The metal elastic sheet <NUM> is provided with a protruding rib snapped with a groove in the body housing <NUM>, to achieve the self-locking function of the knob. Each groove corresponds to a stop position. Moreover, due to impact sound of metal and plastic, a feedback function of the stop position through the sound can be provided when the metal elastic sheet slides on the body housing and suddenly falls into the groove from a high position.

On the basis of the various embodiments described above, in other embodiments, the blade assembly further includes a stationary blade <NUM>, a moving blade <NUM>, a stationary blade holder <NUM>, a moving blade holder <NUM>, a moving blade compression spring <NUM> and a compression spring holder <NUM>. The moving blade compression spring <NUM> is arranged on the compression spring holder <NUM>. The stationary blade <NUM> is fixedly arranged on the stationary blade holder <NUM>, and the moving blade <NUM> is fixedly arranged on the moving blade holder <NUM>. The stationary blade holder <NUM> is movably coupled to the moving blade holder <NUM> through the moving blade compression spring <NUM>, and the compression spring holder <NUM> is movably coupled to the blade adjusting push rod <NUM>. In this embodiment, the compression spring holder <NUM> includes a cylindrical shaft and a support rod with the cylindrical shaft as an axis. The blade adjusting push rod <NUM> slides up and down to drive the support rod to rotate, and the support rod drives the compression spring holder <NUM>, to drive the stationary blade and the moving blade to move, thus realizing the technical effect of adjusting the blade. In this embodiment, the blade assembly further includes a coupling elastic sheet configured to couple the blade assembly to the inner container assembly <NUM>. The coupling elastic sheet can be a metal elastic sheet, a first end of the coupling elastic sheet is coupled to a stationary blade fixing seat, and a second end of the coupling elastic sheet is coupled to the inner container assembly, so that a coupling between the blade assembly and the inner container assembly is more stable and not easy to separate.

Claim 1:
A moving blade adjusting structure for a hair clipper, comprising a blade assembly, a blade adjusting push rod (<NUM>), an inner container assembly (<NUM>), a knob assembly, a blade cover (<NUM>) and a body housing (<NUM>);
the blade adjusting push rod (<NUM>) being slidably coupled to the inner container assembly (<NUM>), the inner container assembly (<NUM>) being fitted in the body housing (<NUM>), the knob assembly being arranged on a stud of the inner container assembly (<NUM>), and the blade adjusting push rod (<NUM>) being movably coupled to the knob assembly; and
the blade assembly being arranged in the blade cover (<NUM>), the blade assembly being movably coupled to the blade adjusting push rod (<NUM>), and the blade cover (<NUM>) being fixedly coupled to the body housing (<NUM>),
characterized in that the knob assembly comprises a knob pressing block (<NUM>), a knob (<NUM>), a metal elastic sheet (<NUM>) and a cam (<NUM>), the cam (<NUM>) is arranged on the inner container assembly (<NUM>) through the stud on the inner container assembly (<NUM>), and an end face of the cam (<NUM>) is engaged with the blade adjusting push rod (<NUM>) in a movement direction of the blade adjusting push rod (<NUM>); and
wherein the metal elastic sheet (<NUM>) is coupled to the knob (<NUM>) in a snapped manner, the knob (<NUM>) is concentrically assembled with the cam (<NUM>) through the stud on the inner container assembly (<NUM>), and the knob pressing block (<NUM>) is concentrically assembled with the knob (<NUM>) through the stud of the inner container assembly (<NUM>).