CN214959224U - Driving motor - Google Patents

Abstract

The utility model provides a driving motor, it includes elastic support, linear drive assembly, axle subassembly, vibrator subassembly and spring leaf. Wherein the elastic support comprises a fixing plate, a first cavity, a second cavity, a first deformation part and a second deformation part. The fixing plate is used for being connected and fixed with the product shell; the first cavity and the second cavity are oppositely arranged at two ends of the fixing plate; the linear driving assembly is used for driving the first cavity and the second cavity to move oppositely; the shaft assembly is arranged at one end of the elastic support and is connected with the first cavity; the vibrator assembly is arranged at the other end of the elastic support and connected with the second cavity, the vibrator assembly and the shaft assembly move oppositely, and the vibrator assembly is used for keeping the driving motor balanced integrally. The utility model discloses a driving motor has realized vibration and two kinds of functions of drive through setting up the integrated equipment of elastic support with linear drive assembly and vibrator subassembly, has promoted driving motor's functionality and practicality.

Description

Driving motor

Technical Field

The utility model relates to a motor field, in particular to driving motor.

Background

With the rise of the revolution in the oral health care field at home and abroad, the electric toothbrush becomes a necessary daily necessity for many families. Compared with the common toothbrush, the electric toothbrush is more scientific and effective, can more thoroughly remove dental plaque, and reduce gingivitis and gingival bleeding. One method recommended by the american dental association for more effective removal of plaque near the gingival margin and in the gingival sulcus: the Papanicolaou brushing method is also called gingival sulcus cleaning method or horizontal vibration method. The specific tooth brushing method comprises the following steps: according to the gum junction area, one part of the bristles enters the gingival sulcus, one part of the bristles is paved on the gingival margin and extends into the adjacent gap as far as possible, the bristles horizontally vibrate for 10 times in the front-back direction short distance in the original position by using soft pressure, the toothbrush moves for only about 1mm during vibration, and 2-3 teeth are brushed each time.

The electric toothbrush can make the brush head generate high-frequency vibration and reciprocating motion through rapid rotation or high-speed linear reciprocating motion, and the toothpaste is instantly decomposed into fine foam. However, the existing electric toothbrush uses a rotary motor, a swing motor and a pure vibration motor, which cannot meet the requirements of generating vibration and reciprocating linear motion, and is difficult to realize the intellectualization of the pasteurization tooth brushing method.

Therefore, it is desirable to provide a driving motor to solve the above-mentioned technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a driving motor, it is through setting up the elastic support with the integrated equipment of linear drive assembly and vibrator subassembly to solve the problem of the motor single structure among the prior art, not intelligent enough.

In order to solve the technical problem, the utility model adopts the technical scheme that: a drive motor; it includes:

the elastic support comprises a fixing plate, a first cavity, a second cavity, a first deformation part and a second deformation part, wherein the first cavity and the second cavity are oppositely arranged at two ends of the fixing plate, the two sides of the fixing plate are oppositely provided with the first deformation part and the second deformation part, the first deformation part is connected with one end of the first cavity and one end of the second cavity, and the second deformation part connects the other end of the first cavity with the other end of the second cavity;

the linear driving assembly is arranged between the first cavity and the second cavity and used for driving the first cavity and the second cavity to move oppositely;

the shaft assembly is arranged at one end of the elastic support and is connected with the first cavity; and

the vibrator assembly is arranged at the other end of the elastic support and is connected with the second cavity, and the vibrator assembly and the shaft assembly move oppositely to keep the whole balance of the driving motor;

the elastic support is an integrally formed elongated frame structure.

In the utility model, a coil assembly cavity is arranged at the center of the fixing plate and is arranged between the first cavity and the second cavity; the linear drive assembly includes:

the coil assemblies are arranged in the coil assembly cavities, n coil assemblies are arranged along the axial direction of the elastic support, and n is a positive integer;

the first permanent magnet is arranged in the first cavity and is a multi-pole magnet with alternately different polarities; and

the second permanent magnet is arranged in the second cavity, the second permanent magnet is a multi-pole magnet with alternately different polarities, and the magnetic poles of the corresponding side surfaces between the second permanent magnet and the first permanent magnet are like magnetic poles;

the first permanent magnet and the second permanent magnet are respectively oppositely arranged at two ends of the coil assembly, a gap is reserved between the coil assembly and the two groups of permanent magnets, and the number of poles of the permanent magnets in the first permanent magnet and the second permanent magnet is n + 1;

the projection of the single coil assembly on the first cavity is positioned between two adjacent pole numbers in the first permanent magnet;

the projection of the single coil assembly on the second cavity is positioned between two adjacent pole numbers in the second permanent magnet.

The utility model discloses still include the spring leaf, the spring leaf sets up in the elastic support, the spring leaf will first cavity and second cavity connection, the spring leaf be used for with the vibration transmission that the vibrator subassembly produced gives the axle subassembly.

The utility model discloses in, the spring leaf includes:

the first fixing part is arranged at one end of the spring piece and is fixedly connected with the first cavity;

the second fixing part is arranged at the other end of the spring piece relative to the first fixing part and is fixedly connected with the second cavity; and

and the elastic part is arranged in the middle of the spring piece and connects the first fixing part with the second fixing part, and the elastic part is arranged at one end of the linear driving assembly arranged along the axial direction.

The utility model discloses in, the elasticity position includes at least one elastic connection section, the elastic connection section is "U" style of calligraphy structure.

In the utility model, the first permanent magnet comprises a first magnetic pole and a second magnetic pole which are adjacent and opposite, the first cavity comprises a first driving position and a second driving position along the motion track of the long edge of the elastic bracket,

when the first cavity is positioned at a first driving position, the distance between a single coil assembly and the first magnetic pole is smaller than the distance between a single coil assembly and the second magnetic pole,

when the first cavity is located at a second driving position, the distance between a single coil assembly and the second magnetic pole is smaller than the distance between a single coil assembly and the first magnetic pole;

the second permanent magnet comprises a third magnetic pole and a fourth magnetic pole which are adjacent and opposite, the third magnetic pole is opposite to the first magnetic pole and has the same magnetic pole, the fourth magnetic pole is opposite to the second magnetic pole and has the same magnetic pole, the second cavity comprises a third driving position and a fourth driving position along the motion track of the long edge of the elastic bracket,

when the second cavity is positioned at the third driving position, the distance between a single coil assembly and the fourth magnetic pole is smaller than the distance between a single coil assembly and the third magnetic pole,

when the second cavity is located at a fourth driving position, the distance between a single coil assembly and the third magnetic pole is smaller than the distance between a single coil assembly and the fourth magnetic pole;

when the first cavity is located at the first driving position, the second cavity is located at the third driving position; when the first cavity is in the second driving position, the second cavity is in the fourth driving position.

The utility model discloses in, when n is greater than 1, adjacent coil pack's coiling opposite direction.

In the utility model, when n is larger than 1, the winding directions of the adjacent coil assemblies are the same;

the first permanent magnets and the second permanent magnets are respectively provided with n, and the arrangement directions of the n first permanent magnets and the n second permanent magnets are parallel to the arrangement direction of the n adjacent coil assemblies; wherein the single coil assembly corresponds to the single first permanent magnet and the single second permanent magnet one to one;

the first permanent magnet comprises two permanent magnet poles with alternately different polarities, and the magnetic poles at two adjacent ends of the adjacent first permanent magnets are different;

the second permanent magnet also comprises two permanent magnet poles with alternately different polarities, the magnetic poles at two adjacent ends of the adjacent second permanent magnets are different, and the permanent magnet magnetic poles at the corresponding side between the second permanent magnet and the first permanent magnet are same-polarity magnetic poles;

the projection of the single coil assembly on the first cavity is positioned between the adjacent two permanent magnet poles in the first permanent magnet;

the projection of the single coil assembly on the first cavity is positioned between the adjacent two permanent magnet poles in the second permanent magnet.

The utility model discloses in, first deformation portion includes:

the first connecting block is arranged at one end of the first cavity, and one end of the fixing plate is connected with the first cavity through the first connecting block;

the second connecting block is arranged at one end of the second cavity, and the fixing plate is connected with the second cavity through the second connecting block; wherein a gap is formed between the first connecting block and the second connecting block.

The utility model discloses in, the vibrator subassembly includes:

the vibrator is arranged at one end of the elastic bracket and is used for generating vibration;

the oscillator support is connected with the second cavity, and the oscillator is connected with the second cavity through the oscillator support;

the oscillator support includes:

the first connecting part is fixedly connected with the second cavity, extends along one end of the axis of the elastic support and is connected with the second cavity; and

the first bending part is arranged at one end of the elastic support and formed by bending the first connecting part, and the vibrator is fixedly connected with the first bending part.

The utility model discloses compare in prior art, its beneficial effect is: the utility model discloses a driving motor has realized vibration and two kinds of functions of drive through setting up the integrated equipment of elastic support with linear drive assembly and vibrator subassembly, has promoted driving motor's functionality and practicality.

The utility model provides an elastic support both plays spring drive's effect and plays supporting role, and driving motor installs on electrical products through elastic support's fixed plate, and axle subassembly and vibrator subassembly are connected through two cavitys of elastic support with electrical apparatus shell, and axle subassembly and vibrator subassembly are arranged separately, and axle subassembly and vibrator subassembly do reciprocating motion in opposite directions, have further optimized driving motor's performance, have reduced electrical apparatus shell's vibration and have felt, have promoted the use the utility model discloses driving motor product's comfort level.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments are briefly introduced below, and the drawings in the following description are only corresponding drawings of some embodiments of the present invention.

Fig. 1 is a perspective view of a preferred embodiment of a driving motor of the present invention.

Fig. 2 is a schematic side cross-sectional view of a preferred embodiment of the drive motor of the present invention.

Fig. 3 is a top view of the internal structure of the preferred embodiment of the driving motor of the present invention.

Fig. 4 is a schematic diagram of the internal structure of the elastic support of the preferred embodiment of the driving motor of the present invention.

Fig. 5 is a perspective view of a coil block according to a preferred embodiment of the driving motor of the present invention.

Fig. 6 is a perspective view of the elastic support of the preferred embodiment of the driving motor of the present invention.

Fig. 7 is a side view of the elastic support of the preferred embodiment of the driving motor of the present invention.

Fig. 8 is a top view of the elastic support of the preferred embodiment of the driving motor of the present invention.

Fig. 9 is a perspective view of a spring plate according to a preferred embodiment of the driving motor of the present invention.

Fig. 10 is a schematic view of the shaft assembly structure of the preferred embodiment of the driving motor of the present invention.

Fig. 11 is a schematic structural diagram of a vibrator assembly according to a preferred embodiment of the driving motor of the present invention.

Fig. 12 is a top view of a linear drive assembly of a preferred embodiment of the drive motor of the present invention.

Fig. 13 is a schematic view of a partial structure of the elastic support when a positive pulse voltage is input to the coil assembly of the preferred embodiment of the driving motor of the present invention.

Fig. 14 is a partial structural view of the elastic support when negative pulse voltage is input to the coil assembly of the preferred embodiment of the driving motor of the present invention.

Fig. 15 is a schematic structural diagram of a linear driving assembly according to a second embodiment of the driving motor of the present invention.

Fig. 16 is a schematic structural diagram of an operating principle of a linear driving assembly according to a second embodiment of the driving motor of the present invention.

Fig. 17 is a schematic view of a partial structure of an elastic support when a positive pulse voltage is input to a coil assembly according to a second embodiment of the driving motor of the present invention.

Fig. 18 is a schematic view of a partial structure of an elastic support when a negative pulse voltage is input to a coil assembly according to a second embodiment of the driving motor of the present invention.

Reference numbers for the first embodiment: the coil assembly comprises an elastic support 1, a fixing plate 11, a first limiting protrusion 111, a second limiting protrusion 112, a first cavity 12, a second cavity 13, a first deformation part 14, a first connecting block 141, a second connecting block 142, a first limiting groove 143, a second deformation part 15, a third connecting block 151, a fourth connecting block 152, a second limiting groove 153, a coil assembly cavity 16, a linear driving assembly 2, a coil assembly 21, a coil 211, an iron core 212, a framework 213, a first coil assembly 21a, a first coil 211a, a first iron core 212a, a first framework 213a, a second coil assembly 21b, a second coil 211b, a second iron core 212b, a second framework 213b, a first permanent magnet 22, a second permanent magnet 23, a shaft assembly 3, a shaft body 31, a frame 32, a second connecting part 321, a third shaft mounting plate 3211, a fourth mounting plate 2, a second bending part 322, a vibrator assembly 4, a vibrator 41, a 3211, a fourth mounting plate 2, a vibrator assembly, The vibrator support 42, the first connection portion 421, the first mounting plate 4211, the second mounting plate 4212, the first bending portion 422, the spring piece 5, the first fixing portion 51, the second fixing portion 52, and the elastic portion 53.

Reference numerals of the second embodiment: the coil assembly comprises an elastic support 6, a first cavity 62, a second cavity 63, a coil assembly cavity 66, a linear driving assembly 7, a coil assembly 71, a coil 711, an iron core 712, a first coil assembly 71a, a first iron core 712a, a second coil assembly 71b, a second iron core 712b, a first permanent magnet 72 and a second permanent magnet 73.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by the skilled in the art without creative work belong to the protection scope of the present invention.

In the drawings, elements having similar structures are denoted by the same reference numerals.

The terms "first," "second," and the like in the terms of the present invention are used for descriptive purposes only and are not to be construed as indicating or implying relative importance, nor should they be construed as limiting in any way.

Referring to fig. 1, fig. 2 and fig. 3, wherein fig. 1 is a perspective view of a preferred embodiment of the driving motor of the present invention, fig. 2 is a schematic side cross-sectional view of the preferred embodiment of the driving motor of the present invention, and fig. 3 is a top view of an internal structure of the preferred embodiment of the driving motor of the present invention.

The present invention provides a preferred embodiment of a driving motor capable of solving the above technical problems.

The utility model provides a driving motor's preferred embodiment does: a drive motor; it comprises an elastic support 1, a linear driving assembly 2, a shaft assembly 3, a vibrator assembly 4 and a spring plate 5. The elastic support 1 is an integrally formed elongated frame structure, and includes a fixing plate 11, a first cavity 12, a second cavity 13, a first deformation portion 14, and a second deformation portion 15. The fixing plate 11 is used for being connected and fixed with a product shell; the first cavity 12 and the second cavity 13 are oppositely arranged at two ends of the fixing plate 11, the first deformation part 14 and the second deformation part 15 are oppositely arranged at two sides of the fixing plate 11, the first deformation part 14 is connected with one end of the first cavity 12 and one end of the second cavity 13, and the second deformation part 15 connects the other end of the first cavity 12 with the other end of the second cavity 13.

The linear driving assembly 2 is arranged between the first cavity 12 and the second cavity 13, and the linear driving assembly 2 is used for driving the first cavity 12 and the second cavity 13 to move oppositely; the shaft assembly 3 is arranged at one end of the elastic bracket 1 and is connected with the first cavity 12; the vibrator assembly 4 is arranged at the other end of the elastic bracket 1, the vibrator assembly 4 is connected with the second cavity 13, the vibrator assembly 4 and the shaft assembly 3 move towards each other, and the vibrator assembly 4 is used for keeping the whole balance of the driving motor.

In this embodiment, a spring plate 5 is further disposed in the elastic support 1, the spring plate 5 connects the first cavity 12 and the second cavity 13, and the spring plate 5 is used for transmitting the vibration generated by the vibrator component 4 to the shaft component 3. Preferably, the spring pieces 5 in this embodiment are provided in two sets, and the two sets of spring pieces 5 are oppositely arranged at two ends of the coil assembly 2 in the arrangement direction.

The utility model provides a driving motor realizes vibration and two kinds of functions of drive through setting up linear drive assembly 2 and oscillator subassembly 4, and carries out the transmission through elastic support 1, has promoted driving motor's functionality and practicality. The elastic support 1 serves both for spring drive and for support. The driving motor is installed on electrical product through the fixed plate 11 of elastic support 1, and axle subassembly 3 and vibrator subassembly 4 are connected through two cavitys of elastic support 1 with the electrical apparatus shell, and axle subassembly 3 and vibrator subassembly 4 separately arrange, and axle subassembly 3 and vibrator subassembly 4 do reciprocating motion in opposite directions, have further optimized driving motor's performance, have reduced electrical apparatus shell's vibration and have felt, have promoted the use the utility model discloses the comfort level of driving motor product.

Referring to fig. 4, fig. 4 is a schematic diagram of an internal structure of an elastic bracket according to a preferred embodiment of the driving motor of the present invention. The structure of the linear drive assembly 2 in this embodiment will be explained in detail:

the fixing plate 11 in this embodiment is provided with a coil mounting cavity 16 at the center, and the coil mounting cavity 16 is located between the first cavity 12 and the second cavity 13. The linear drive assembly 2 in the present embodiment includes a coil assembly 21, a first permanent magnet 22, a second permanent magnet 23; the coil assemblies 21 are arranged in the coil assembling cavity 16, n coil assemblies 21 are arranged along the axial direction of the elastic support 1, and n is a positive integer; the first permanent magnet 22 is arranged in the first cavity 12, and the first permanent magnet 22 is a multi-pole magnet with alternately different polarities; the second permanent magnet 23 is disposed in the second cavity 13, the second permanent magnet 23 is a multi-pole magnet with alternately different polarities, and the permanent magnet poles on the corresponding sides between the second permanent magnet 23 and the first permanent magnet 22 are like poles.

In this embodiment, the first permanent magnet 22 and the second permanent magnet 23 are respectively disposed at two ends of the coil assembly 21, a gap is formed between the coil assembly 21 and the first permanent magnet 22 and the second permanent magnet 23, and the number of poles of the permanent magnets in the first permanent magnet 22 and the second permanent magnet 23 is n + 1; the projection of the single coil assembly 21 on the first cavity 12 is positioned between two adjacent pole numbers in the first permanent magnet 22; the projection of the single coil assembly 21 onto the second cavity 13 is located between two adjacent opposite permanent magnets in the second permanent magnet 23.

When n is greater than 1, the winding directions of the adjacent coil assemblies 21 are opposite. Preferably, the distance between the centers of the adjacent coil assemblies 21 in this embodiment is equal to the distance between the centers of the adjacent magnetic poles in the first permanent magnet 22 and the distance between the centers of the adjacent magnetic poles in the second permanent magnet 23. The structural design and arrangement of the components in the linear driving assembly 2 are orderly, and the stability of the linear driving assembly 2 in the operation process of driving the first cavity 12 and the second cavity 13 is improved.

Referring to fig. 5, fig. 5 is a perspective view of a coil assembly according to a preferred embodiment of the driving motor of the present invention. The coil assembly 21 in the present embodiment includes a coil 211, a core 212, and a bobbin 213. Wherein the coil 211 is wound on the bobbin 213; the iron core 212 is disposed inside the bobbin 213, and the iron core 212 serves to increase the magnetic field strength.

Referring to fig. 6, 7 and 8, fig. 6 is a perspective view of an elastic bracket according to a preferred embodiment of the driving motor of the present invention. Fig. 7 is a side view of the elastic support of the preferred embodiment of the driving motor of the present invention. Fig. 8 is a top view of the elastic support of the preferred embodiment of the driving motor of the present invention. The structure of the elastic support 1 in the present embodiment is explained:

the utility model provides an elastic support 1 is the integration part with engineering plastics injection moulding of high elasticity, high tenacity, has avoided the equipment error that many parts combination brought to promote the precision among the driving motor transmission process, made the driving motor performance have the uniformity.

The first permanent magnet 22 of the present invention includes a first magnetic pole and a second magnetic pole, which are adjacent and opposite, and the first cavity 12 includes a first driving position and a second driving position along the long-side movement track of the elastic support 1. When the first cavity 12 is located at the first driving position, the distance between the single coil assembly 21 and the first magnetic pole is smaller than the distance between the single coil assembly 21 and the second magnetic pole; when the first cavity 12 is located at the second driving position, the distance between the single coil assembly 2 and the second magnetic pole is smaller than the distance between the single coil assembly 2 and the first magnetic pole.

The second permanent magnet 23 includes a third magnetic pole and a fourth magnetic pole which are adjacent and opposite, the third magnetic pole is opposite to the first magnetic pole and has the same magnetic pole, the fourth magnetic pole is opposite to the second magnetic pole and has the same magnetic pole, and the second cavity 13 includes a third driving position and a fourth driving position along the movement track of the long edge of the elastic bracket 1.

When the second cavity 13 is located at the third driving position, the distance between the single coil assembly 21 and the fourth magnetic pole is smaller than the distance between the single coil assembly 21 and the third magnetic pole. When the second cavity 13 is located at the fourth driving position, the distance between the single coil assembly 21 and the third magnetic pole is smaller than the distance between the single coil assembly 21 and the fourth magnetic pole.

When the first cavity 12 is located at the first driving position, the second cavity 13 is located at the third driving position; when the first chamber 12 is in the second drive position, the second chamber 13 is in the fourth drive position. The elastic support 1 in this embodiment moves in opposite directions under the action of the linear driving assembly 2 through the first cavity 12 and the second cavity 13, so that the stability of the overall structure of the linear driving assembly is improved.

Preferably, when the elastic support 1 in this embodiment is in the initial state, the projection of the single coil assembly 21 on the first cavity 12 is located at the center of two adjacent poles in the first permanent magnet 22; the projection of the single coil assembly 21 onto the second chamber 13 is located at the center of two adjacent poles in the second permanent magnet 23.

Referring to fig. 7, the second deformation part 15 of the present embodiment is provided with a second limiting groove 153 near the fixing plate 11, a second limiting protrusion 112 is provided at a position corresponding to the second limiting groove 153 on the fixing plate 11, the second limiting protrusion 112 is provided in the second limiting groove 153, and the second limiting protrusion 112 is used for limiting the position of the second deformation part 15. The structural stability of the elastic support 1 in the use process is improved.

The structure of the first deformation portion 14 in the present embodiment will be explained with reference to fig. 8: the first deformation part 14 in this embodiment includes a first connection block 141 and a second connection block 142; the first connecting block 141 is disposed at one end of the first cavity 12, and one end of the fixing plate 11 is connected to the first cavity 12 through the first connecting block 141; the second connecting block 142 is disposed at one end of the second chamber 13, and the fixing plate 11 is connected to the second chamber 13 through the second connecting block 142, preferably, there is a gap between the first connecting block 141 and the second connecting block 142 in this embodiment. The connecting block of the first deformation part 14 of the elastic support 1 has an elastic supporting function and a vibration damping function, and ensures that the vibration of the motor is not transmitted to the shell of the electric appliance.

Further, in this embodiment, a first limiting groove 143 is disposed on a side of the first deformation portion 14 close to the fixing plate 11, a first limiting protrusion 111 is disposed on a side of the fixing plate 11 corresponding to the first limiting groove 143, the first limiting protrusion 111 is disposed in the first limiting groove 143, and the first limiting protrusion 111 is used for limiting a position of the first deformation portion 14. The stability of the structure of the elastic support 1 in the using process is improved.

The structure of the second deforming part 15 in the present embodiment will be explained: the second deformation part 15 in this embodiment includes a third connecting block 151 and a fourth connecting block 152; the third connecting block 151 is arranged at the other end of the first cavity 12, and one end of the fixing plate 11 is connected with the other end of the first cavity 12 through the third connecting block 151; the fourth connecting block 152 is disposed at the other end of the second cavity 13, and the fixing plate 11 is connected to the second cavity 13 through the fourth connecting block, preferably, a gap is formed between the third connecting block 151 and the fourth connecting block 152 in this embodiment. The two connecting blocks of the second deformation part 15 of the elastic bracket 1 have elastic supporting function and also have damping function, so that the vibration of the motor is not transmitted to the shell of the electric appliance.

Referring to fig. 6 and 9, fig. 6 is a perspective view of an elastic bracket according to a preferred embodiment of the driving motor of the present invention, and fig. 9 is a perspective view of a spring plate according to a preferred embodiment of the driving motor of the present invention. The structure of the spring plate 5 in this embodiment will be explained in detail:

the spring plate 5 in this embodiment includes a first fixing portion 51, a second fixing portion 52, and an elastic portion 53; wherein the first fixing part 51 is arranged at one end of the spring piece 5, and the first fixing part 51 is fixedly connected with the first cavity 12; the second fixing part 52 is arranged at the other end of the spring piece 5 opposite to the first fixing part 51, and the second fixing part 52 is fixedly connected with the second cavity 13; the elastic portion 53 is disposed in the middle of the spring plate 5, the elastic portion 53 connects the first fixing portion 51 and the second fixing portion 52, and the elastic portion 53 is disposed at one end of the linear driving unit 2 arranged in the axial direction.

Preferably, the elastic portion 53 in this embodiment includes at least one elastic connecting section, and the elastic connecting section is in a "U" shape.

The utility model provides a spring leaf 5 adopts many U style of calligraphy structure, has ensured that driving motor's air gap is unanimous, and the first permanent magnet 22 and the second permanent magnet 23 of driving motor both sides and the distance between coil pack 21 all equal promptly to it is even to have guaranteed that motor both sides magnetic field force, has promoted axle subassembly 2 and vibrator subassembly 3 and has made the equilibrium of reciprocating motion in opposite directions.

Referring to fig. 10, fig. 10 is a schematic view of a shaft assembly structure of a driving motor according to a preferred embodiment of the present invention. The structure of the shaft assembly 3 in this embodiment will be explained in detail:

the shaft assembly 3 in the present embodiment includes a shaft body 31 and a shaft support 32, the shaft body 31 being used for transmission; the shaft body 31 is arranged at one end of the elastic support 1, the straight line of the shaft body 31 is positioned in parallel with the central axis of the elastic support 1, and the shaft body 31 is connected with the first cavity 12 through the shaft support 32. The shaft support 32 not only plays a role of a fixing shaft, but also has the function of a magnetic conduction block, and the practicability is strong.

The shaft support 32 includes a second connecting portion 321 and a second bent portion 322; the second connecting portion 321 is fixedly connected to the first cavity 12, the second connecting portion 321 extends along the other end of the axis of the elastic support 1, and the second connecting portion 321 is connected to the first cavity 12; the second bending portion 322 is disposed at the other end of the elastic bracket 1, the second bending portion 322 is formed by bending the second connecting portion 321, and the shaft body 31 is fixedly connected to the second bending portion 322.

Preferably, the second connecting portion 321 in this embodiment includes a third mounting plate 3211 and a fourth mounting plate 3212; the third mounting plate 3211 is connected to the first cavity 12 at a side away from the fixing plate, and the second mounting plate 4212 is used for sealing the coil assembly 21 assembly cavity; the fourth mounting plate 3212 is connected to the side of the first cavity 12 away from the second cavity 13, and the fourth mounting plate 3212 is sequentially fastened to the first cavity 12 and the first fixing portion 51 of the spring piece 5 by a second connecting member.

Referring to fig. 11, fig. 11 is a schematic structural diagram of a vibrator assembly according to a preferred embodiment of the driving motor of the present invention. The structure of the vibrator assembly 4 in the present embodiment will be explained in detail:

the vibrator assembly 4 in the present embodiment includes a vibrator 41 and a vibrator holder 42; wherein, the vibrator 41 is arranged at one end of the elastic bracket 1, and the vibrator 41 is used for generating vibration; the oscillator bracket 42 is fixed on one side of the elastic bracket 1, and the oscillator 41 is connected with the second cavity 13 of the elastic bracket 1 through the oscillator bracket 42.

Further, the vibrator support 42 includes a first connecting portion 421 and a first bending portion 422; the first connecting portion 421 is fixedly connected to the second cavity 13, and the first connecting portion 421 extends along one end of the axis of the elastic bracket 1, and the first connecting portion 421 is connected to the second cavity 13; the first bending portion 422 is disposed at one end of the elastic support 1, the first bending portion 422 is formed by bending the first connecting portion 421, and the vibrator 41 is fixedly connected to the first bending portion 422. The oscillator bracket 42 is simple in structure and ingenious in design, the oscillator bracket 42 not only plays a role in fixing the oscillator 41, but also has the function of a magnetic conduction block, and the practicability is high.

Further, the structure of the first connection portion 421 matches with the outer wall structure of the second cavity 13, so that the structural connection between the vibrator support 42 and the elastic support 1 is more stable. Preferably, the first connection portion 421 in the present embodiment includes a first mounting plate 4211 and a second mounting plate 4212; the first mounting plate 4211 is connected with one side, away from the fixing plate, of the second cavity 13, and the first mounting plate 4211 is used for sealing the coil assembly 21 assembling cavity; the second mounting plate 4212 is connected with one side of the second cavity 13, which is far away from the first cavity 12, the second mounting plate 4212 is sequentially fastened and connected with the second cavity 13 and the second fixing portion 52 of the spring piece 5 through a first connecting piece, and the second cavity 13 is sealed by the second mounting plate 4212. The first mounting plate 4211 can define the position of the coil assembly 21, and the second mounting plate 4212 closes the first cavity, so that the position of the second permanent magnet 23 is defined, and the compactness of the whole structure of the driving motor and the stability of the driving motor in use are improved.

The first embodiment is the preferred embodiment of the driving motor of the present invention, and the working principle of the driving motor of the present invention is elaborated as follows:

the number of coil units 21 in this embodiment is n, n is a positive integer, and may be 1, 2, 3, or …, and the number of poles of the first permanent magnet 22 and the second permanent magnet 23 corresponding to the coil unit 21 is n +1, and is 2, 3, 4, or …, respectively. In this embodiment, the operation process of the motor is described by taking 2 coil assemblies 21 as an example. The 2 coil components 21 in the present embodiment are a first coil component 21a disposed on the left side, and a second coil component 21b disposed on the right side, respectively, as shown in fig. 12. The first coil 21a of the first coil assembly 21a is wound in the opposite direction to the second coil 21b of the second coil assembly 2 b.

Taking the first coil 21a of the first coil assembly 21a wound clockwise as an example, the second coil 21b of the second coil 2b is wound counterclockwise, and the magnetic poles of the two permanent magnets inside the motor are N, S, N poles from left to right.

First, when the coil assembly starts to input a pulse with a positive pulse voltage, as shown in fig. 13, the magnetic field generated at the upper end of the first iron core 212a is an N pole, and the magnetic field generated at the lower end is an S pole; the magnetic field generated at the upper end of the second core 212b is an S-pole, and the magnetic field generated at the lower end is an N-pole.

Since the opposite magnetic poles attract each other and the same magnetic poles repel each other, a repulsive force is generated between the upper ends of the first coil element 21a and the second coil element 21b and the left magnetic pole of the corresponding first permanent magnet 22, and an attractive force is generated between the right magnetic pole of the corresponding first permanent magnet 22.

Attraction force is generated between the lower ends of the first coil element 21a and the second coil element 21b and the left magnetic pole of the second permanent magnet 23, and repulsion force is generated between the right magnetic pole of the second permanent magnet 23. The elastic support 1 has elastic deformation capability, and the first cavity 12 and the second cavity 13 for fixing the two groups of permanent magnets move relatively at the moment.

The shaft assembly 3 and the first permanent magnet 22 are fixed by the first cavity 12 of the elastic bracket, so that the shaft assembly 3 moves to the left under the action of the magnetic field force.

Meanwhile, since the vibrator assembly 4 and the second permanent magnet 23 are coupled and fixed by the second cavity 13 in the elastic bracket 1, the vibrator assembly 4 moves rightward by the magnetic field force. The vibrator assembly 4 moves towards the shaft assembly 3, thereby ensuring that the motor is balanced as a whole.

Second, when the coil assembly inputs the positive pulse voltage, the negative pulse voltage is input, as shown in fig. 14. The magnetic field generated at the upper end of the first iron core 212a is an S pole, and the magnetic field generated at the lower end is an N pole; the magnetic field generated at the upper end of the second core 212b is an N-pole, and the magnetic field generated at the lower end is an S-pole.

Since the opposite magnetic poles attract each other and the same magnetic poles repel each other, an attractive force is generated between the upper ends of the first coil element 21a and the second coil element 21b and the left magnetic pole of the corresponding first permanent magnet 22, and a repulsive force is generated between the right magnetic pole of the corresponding first permanent magnet 22.

The lower ends of the first coil element 21a and the second coil element 21b generate repulsive force with respect to the left magnetic pole of the corresponding second permanent magnet 23, and attractive force with respect to the right magnetic pole of the corresponding second permanent magnet 23. Since the shaft assembly 3 and the first permanent magnet 22 are fixed by the first cavity 12 of the elastic bracket 1, the shaft assembly 3 moves rightward by these forces.

Meanwhile, since the vibrator assembly 4 and the second permanent magnet 23 are coupled and fixed by the second cavity 13 in the elastic bracket 1, the vibrator assembly 4 moves leftward by these forces. The vibrator assembly 4 moves towards the shaft assembly 3, so that the overall balance of the linear vibrator assembly 4 is ensured.

The linear oscillator module 4 of the present invention inputs alternating pulse voltage, and the coil 211 in the coil module 21 is connected with electricity, so that the iron core 212 generates an alternating magnetic field, and the alternation between the upper end of the iron core 212 and the first permanent magnet 22 generates attraction/repulsion force, and the alternation between the second permanent magnets 23 at the lower end of the iron core 212 generates repulsion/attraction force; so that the shaft assembly 3 and the vibrator assembly 4 reciprocate left and right by these forces.

The vibrator assembly 4 is continuously accelerated and decelerated during the reciprocating motion to generate vibration, and the vibration generated by the vibrator assembly 4 is transmitted to the shaft assembly 3 through the spring plate 5, so that the shaft body 31 is driven to generate vibration and reciprocating motion, and thus the shaft body 31 can drive the electrical function part to perform the vibrating reciprocating motion.

This completes the operation of the motor of the preferred embodiment in which the linear vibrator assembly 4 is used.

The second embodiment of the driving motor of the present invention is as follows:

as shown in fig. 15, the elastic holder 6 in this embodiment has the same structure as the elastic holder 6 in the first embodiment, and the linear driving unit 7 is accommodated in the coil assembling chamber 66 of the elastic holder 6 when n is greater than 1 and the winding directions of the adjacent coil units 71 are the same. N groups of corresponding first permanent magnets 72 and second permanent magnets 73 are also provided, and a plurality of groups of coil assemblies 71 are arranged along the long side direction of the elastic support; and the arrangement direction of the n groups of first permanent magnets 72 is parallel to the arrangement direction of the plurality of groups of coil assemblies 71, and the arrangement direction of the n groups of second permanent magnets 73 is parallel to the arrangement direction of the plurality of groups of coil assemblies 71.

The first permanent magnets 72 are disposed in the first cavity 62 of the elastic support 6, and each first permanent magnet 72 includes two permanent magnets with alternately different polarities, and the magnetic poles of two adjacent ends of adjacent first permanent magnets are different.

A plurality of second permanent magnets 73 are arranged in the second cavity 63, each second permanent magnet 73 comprises two permanent magnets with alternately different polarities, and the magnetic poles of two adjacent ends of the adjacent second permanent magnets 73 are different; and the magnetic poles of the corresponding sides between the second permanent magnet 73 and the first permanent magnet 72 are like poles. The first permanent magnet 72 and the second permanent magnet 73 are respectively disposed at two sides of the coil assembly 71, and the number of poles of the permanent magnets in the first permanent magnet 72 and the second permanent magnet 73 is 2.

In the present invention, the projection of the single coil assembly 71 on the first cavity 62 is located between the two adjacent permanent magnet poles in the first permanent magnet 72; the projection of the single coil assembly 71 onto the first chamber 62 is located between two adjacent permanent magnet poles in the second permanent magnet 73.

In the driving motor of this embodiment, the coil assembly 71 with a plurality of same magnetic poles is arranged to cooperate with the first permanent magnet 72 and the second permanent magnet 73, so as to drive the relative movement of the first cavity 62 and the second cavity 63 of the elastic support 6, thereby ensuring uniform magnetic field force on both sides of the motor and making the balance of the movement of the driving motor better.

The operating principle of the vibration coil assembly of the second embodiment is explained in detail as follows:

as shown in fig. 15 and 16, in the present embodiment, the number of coil units 71 is n, n is a positive integer, and may be 1, 2, 3, or …, and the number of poles of the first permanent magnet 72 and the second permanent magnet 73 corresponding to the coil unit 71 is n +1, and is 2, 3, 4, or …, respectively. In this embodiment, the operation process of the motor is described by taking 2 coils as an example. The 2 coil components in the present embodiment are a first coil component 71a disposed on the left side, and a second coil component 71b disposed on the right side, respectively, as shown in fig. 12. The first coil 711a of the first coil block 71a is wound in the same direction as the second coil 711b of the second coil block 2 b.

Taking the first coil 711a of the first coil assembly 71a as an example, the second coil 711b of the second coil 2b is wound clockwise, and the magnetic poles of the two groups of first permanent magnets 72 and the two groups of second permanent magnets 73 in the inner permanent magnet of the motor are N, S, N, S poles from left to right.

First, when the input pulse of the coil assembly starts to be a positive pulse voltage, as shown in fig. 17, the magnetic field generated at the upper end of the first iron core 712a is an N pole, and the magnetic field generated at the lower end is an S pole; the magnetic field generated at the upper end of the second core 712b is an N-pole, and the magnetic field generated at the lower end is an S-pole.

Due to the attraction of the opposite magnetic poles and the repulsion of the same magnetic poles, the repulsion is generated between the upper ends of the first coil assembly 71a and the second coil assembly 71b and the left magnetic poles of the two corresponding groups of first permanent magnets 72, and the attraction is generated between the right magnetic poles of the two corresponding groups of first permanent magnets 72.

Attraction force is generated between the lower ends of the first coil element 71a and the second coil element 71b and the left magnetic poles of the two groups of second permanent magnets 73, and repulsion force is generated between the right magnetic poles of the two groups of second permanent magnets 73. The elastic support 1 has elastic deformation capacity, and the first cavity 62 and the second cavity 63 which fix the two groups of two permanent magnets move relatively at the moment, namely the first cavity 62 moves leftwards under the action of the magnetic field force, and the second cavity 63 moves rightwards under the action of the magnetic field force.

Second, when the coil assembly inputs the positive pulse voltage, the negative pulse voltage is input, as shown in fig. 18. The magnetic field generated at the upper end of the first iron core 712a is an S pole, and the magnetic field generated at the lower end is an N pole; the magnetic field generated at the upper end of the second core 712b is an S-pole, and the magnetic field generated at the lower end is an N-pole.

Because the opposite magnetic poles attract and the same magnetic poles repel, an attraction force is generated between the upper ends of the first coil assembly 71a and the second coil assembly 71b and the left magnetic poles of the two corresponding groups of first permanent magnets 72, and a repulsion force is generated between the right magnetic poles of the two corresponding groups of first permanent magnets 72.

Attraction force is generated between the lower ends of the first coil unit 71a and the second coil unit 71b and the right magnetic poles of the two corresponding sets of second permanent magnets 73, and repulsion force is generated between the left magnetic poles of the two corresponding sets of second permanent magnets 73. The first chamber 62 is moved rightward by the magnetic field force and the second chamber 63 is moved leftward.

The linear driving assembly in the utility model inputs alternating pulse voltage, and the coil in the coil assembly is electrified to enable the iron core to generate an alternating magnetic field, the alternating between the upper end of the iron core and the first permanent magnet generates attraction/repulsion force, and the alternating between the lower end of the iron core and the second permanent magnet generates repulsion/attraction force; so that the first cavity 62 and the second cavity 63 reciprocate leftwards and rightwards under the action of the forces, and the linear driving component can drive the electrical functional component to reciprocate in a vibration mode.

This completes the operation of the linear drive assembly in the present embodiment.

In summary, although the present invention has been described with reference to the preferred embodiments, the above-described preferred embodiments are not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, so that the scope of the present invention shall be determined by the scope of the appended claims.

Claims (10)

1. A drive motor; it is characterized by comprising:

the elastic support comprises a fixing plate, a first cavity, a second cavity, a first deformation part and a second deformation part, wherein the first cavity and the second cavity are oppositely arranged at two ends of the fixing plate, the two sides of the fixing plate are oppositely provided with the first deformation part and the second deformation part, the first deformation part is connected with one end of the first cavity and one end of the second cavity, and the second deformation part connects the other end of the first cavity with the other end of the second cavity;

the linear driving assembly is arranged between the first cavity and the second cavity and used for driving the first cavity and the second cavity to move oppositely;

the shaft assembly is arranged at one end of the elastic support and is connected with the first cavity; and

the vibrator assembly is arranged at the other end of the elastic support and is connected with the second cavity, and the vibrator assembly and the shaft assembly move oppositely to keep the whole balance of the driving motor;

the elastic support is an integrally formed elongated frame structure.

2. The driving motor as claimed in claim 1, wherein a coil assembly chamber is provided at a center of the fixing plate, the coil assembly chamber being provided between the first and second cavities; the linear drive assembly includes:

the coil assemblies are arranged in the coil assembly cavities, n coil assemblies are arranged along the axial direction of the elastic support, and n is a positive integer;

the first permanent magnet is arranged in the first cavity and is a multi-pole magnet with alternately different polarities; and

the second permanent magnet is arranged in the second cavity, the second permanent magnet is a multi-pole magnet with alternately different polarities, and the magnetic poles of the corresponding side surfaces between the second permanent magnet and the first permanent magnet are like magnetic poles;

the first permanent magnet and the second permanent magnet are respectively oppositely arranged at two ends of the coil assembly, and the number of poles of the permanent magnets in the first permanent magnet and the second permanent magnet is n + 1;

the projection of the single coil assembly on the first cavity is positioned between two adjacent pole numbers in the first permanent magnet;

the projection of the single coil assembly on the second cavity is positioned between two adjacent poles in the second permanent magnet.

3. The drive motor of claim 1, further comprising a spring plate disposed within the resilient mount, the spring plate connecting the first cavity and the second cavity, the spring plate configured to transmit vibrations generated by the vibrator assembly to the shaft assembly.

4. The drive motor of claim 3, wherein the spring plate comprises:

the first fixing part is arranged at one end of the spring piece and is fixedly connected with the first cavity;

the second fixing part is arranged at the other end of the spring piece relative to the first fixing part and is fixedly connected with the second cavity; and

and the elastic part is arranged in the middle of the spring piece and connects the first fixing part with the second fixing part, and the elastic part is arranged at one end of the linear driving assembly arranged along the axial direction.

5. The drive motor as claimed in claim 4, wherein the elastic portion comprises at least one elastic connection section, and the elastic connection section has a "U" -shaped structure.

6. The driving motor as claimed in claim 2, wherein the first permanent magnet includes a first magnetic pole and a second magnetic pole which are adjacent and opposite, the first cavity includes a first driving position and a second driving position along the motion path of the long side of the elastic support,

when the first cavity is positioned at a first driving position, the distance between a single coil assembly and the first magnetic pole is smaller than the distance between a single coil assembly and the second magnetic pole,

when the first cavity is located at a second driving position, the distance between a single coil assembly and the second magnetic pole is smaller than the distance between a single coil assembly and the first magnetic pole;

the second permanent magnet comprises a third magnetic pole and a fourth magnetic pole which are adjacent and opposite, the third magnetic pole is opposite to the first magnetic pole and has the same magnetic pole, the fourth magnetic pole is opposite to the second magnetic pole and has the same magnetic pole, the second cavity comprises a third driving position and a fourth driving position along the motion track of the long edge of the elastic bracket,

when the second cavity is positioned at the third driving position, the distance between a single coil assembly and the fourth magnetic pole is smaller than the distance between a single coil assembly and the third magnetic pole,

when the second cavity is located at a fourth driving position, the distance between a single coil assembly and the third magnetic pole is smaller than the distance between a single coil assembly and the fourth magnetic pole;

when the first cavity is located at the first driving position, the second cavity is located at the third driving position; when the first cavity is in the second driving position, the second cavity is in the fourth driving position.

7. The driving motor of claim 2, wherein when n is greater than 1, the winding directions of adjacent coil assemblies are opposite.

8. The driving motor of claim 2, wherein when n is greater than 1, the winding directions of adjacent coil assemblies are the same;

the first permanent magnets and the second permanent magnets are respectively provided with n, and the arrangement directions of the n first permanent magnets and the n second permanent magnets are parallel to the arrangement direction of the n adjacent coil assemblies; wherein the single coil assembly corresponds to the single first permanent magnet and the single second permanent magnet one to one;

the first permanent magnet comprises two permanent magnet poles with alternately different polarities, and the magnetic poles at two adjacent ends of the adjacent first permanent magnets are different;

the second permanent magnet also comprises two permanent magnet poles with alternately different polarities, the magnetic poles at two adjacent ends of the adjacent second permanent magnets are different, and the permanent magnet magnetic poles at the corresponding side between the second permanent magnet and the first permanent magnet are same-polarity magnetic poles;

the projection of the single coil assembly on the first cavity is positioned between the adjacent two permanent magnet poles in the first permanent magnet;

the projection of the single coil assembly on the first cavity is positioned between the adjacent two permanent magnet poles in the second permanent magnet.

9. The drive motor of claim 2, wherein the first deformation portion comprises:

the first connecting block is arranged at one end of the first cavity, and one end of the fixing plate is connected with the first cavity through the first connecting block;

the second connecting block is arranged at one end of the second cavity, and the fixing plate is connected with the second cavity through the second connecting block; wherein a gap is formed between the first connecting block and the second connecting block.

10. The drive motor of claim 1, wherein the vibrator assembly comprises:

the vibrator is arranged at one end of the elastic bracket and is used for generating vibration;

the oscillator support is connected with the second cavity, and the oscillator is connected with the second cavity through the oscillator support;

the oscillator support includes:

the first connecting part is fixedly connected with the second cavity, extends along one end of the axis of the elastic support and is connected with the second cavity; and

the first bending part is arranged at one end of the elastic support and formed by bending the first connecting part, and the vibrator is fixedly connected with the first bending part.

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