CN109966748B - Gyro toy - Google Patents

Abstract

The invention discloses a gyroscopic toy, which comprises a transmitter and a gyroscopic body, wherein the transmitter comprises a pulling driving unit and a transmitting head, the pulling driving unit drives the transmitting head to rotate, the emitter head is used for connecting the gyro body and can drive the gyro body to rotate, and the emitter also comprises an accelerator and an acceleration signal detection unit; the gyro body comprises an acceleration signal receiving unit, a processor and a motor; the driving unit is pulled to drive the accelerator to accelerate, the acceleration signal detection unit is used for detecting the accelerator and sending the acquired speed signal to the acceleration signal receiving unit, the acceleration signal receiving unit receives the speed signal and then transmits the speed signal to the processor, and the processor controls the rotating speed of the motor according to the speed signal, so that the faster the accelerator rotates, the faster the motor rotates. The invention has the advantages of convenient and safe operation, and the advantage of the secondary acceleration can be realized without recovering the gyro.

Description

Gyro toy

Technical Field

The invention relates to the technical field of toys, in particular to a gyroscopic toy.

Background

The existing mainstream gyro toy launcher accelerates and launches the gyro toy mainly through manually pulling gears or pulling ropes, and the launcher can not accelerate the gyro for many times when the gyro fights.

Part of battle top products on the market can accelerate secondarily, but the top in the battle needs to be recovered to the transmitting head of the transmitter by the transmitter for secondary acceleration and then is transmitted.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide the gyro toy which is convenient and safe to operate and can realize secondary acceleration without recovering the gyro.

The technical proposal of the invention provides a gyroscopic toy, which comprises a transmitter and a gyroscopic body, wherein the transmitter comprises a pulling driving unit and a transmitting head, the pulling driving unit drives the transmitting head to rotate, the transmitting head is used for connecting with the gyroscopic body and can drive the gyroscopic body to rotate,

the transmitter further comprises an accelerator and an acceleration signal detection unit;

the gyro body comprises an acceleration signal receiving unit, a processor and a motor;

the pulling driving unit drives the accelerator to accelerate, the accelerating signal detecting unit is used for detecting the accelerator and sending the acquired speed signal to the accelerating signal receiving unit, the accelerating signal receiving unit receives the speed signal and then transmits the speed signal to the processor, the processor controls the rotating speed of the motor according to the speed signal, and the faster the accelerator rotates, the faster the motor rotates.

Further, the acceleration signal detection unit comprises a signal transmitting module, a signal receiving module and a calculating module, wherein the signal transmitting module is used for transmitting signals towards the accelerator, the signal receiving module is used for receiving signals, and the calculating module is used for calculating the received signals to obtain the speed signals.

Further, the pulling driving unit comprises a pull rope, a recoverer and driving teeth, wherein the pull rope is connected with the driving teeth through the recoverer, the driving teeth are connected with an accelerator, and the accelerator is connected with the emission head.

Further, the gyroscopic toy includes a launch mode and an acceleration mode;

in the launching mode, the top body is connected to the launching head, the pull rope is pulled, the pull rope drives the driving teeth to rotate, the driving teeth drive the accelerator to rotate, the accelerator drives the launching head to rotate, and the launching head drives the top body to rotate and launches the top body;

during acceleration mode, the emitter is located near the top body, pulls the stay cord, the stay cord drives the driving tooth rotates, the driving tooth drives the accelerator rotates, after the acceleration signal detecting element detects the speed signal of accelerator and with the speed signal is given the acceleration signal receiving element, the acceleration signal receiving element receives the speed signal after the transmission gives the treater, the treater is according to the speed signal control motor pivoted speed, the top body is rotated under the motor is accelerated.

Further, the accelerator comprises a swing tooth and a transmission gear, and the driving tooth is meshed with the swing tooth;

when the pull rope is pulled out to drive the driving teeth to rotate positively, the driving teeth drive the swinging teeth to swing to a position meshed with the transmission gear, the transmission gear drives the transmitting head to rotate, and the recoverer rotates positively and stores energy;

when the pull rope is loosened after a certain distance is pulled out, the recoverer can reversely rotate and drive the pull rope to retract, and the driving teeth drive the swing teeth to swing to a position separated from the transmission gear.

Further, the rotating shaft of the swing tooth is arranged in a chute, and the chute comprises a first end point and a second end point;

when the recoverer rotates forwards, the driving gear drives the swing tooth to swing the first end point;

when the recoverer reversely rotates, the driving gear drives the swing tooth to swing the second end point.

Further, the accelerator further comprises a speed measuring gear, the speed measuring gear is meshed with the transmission gear, and the acceleration signal detection unit is used for detecting and acquiring the speed signal of the speed measuring gear.

Further, the signal transmitting module is an infrared transmitting tube, the signal receiving module is an infrared receiver, the infrared transmitting tube and the infrared receiver are respectively positioned on two sides of a speed measuring surface of the speed measuring gear, a light hole is formed in the speed measuring surface, the central axis of the light hole is positioned on the same straight line as the infrared transmitting tube and the infrared receiver, and the speed measuring gear rotates once every time the infrared receiver receives a signal.

Further, the signal transmitting module is an infrared transmitting tube, the signal receiving module is an infrared receiver, the infrared transmitting tube and the infrared receiver are both positioned on the same side of the speed measuring surface of the speed measuring gear, a reflecting plate is arranged on the speed measuring surface, when the reflecting plate rotates above the infrared transmitting tube along with the test gear, the reflecting plate reflects an infrared signal to the infrared receiver, and the infrared receiver receives a signal every time the speed measuring gear rotates.

Further, the top body further comprises a top cover and a top base which can rotate up and down relatively, the motor is located in the inner cavity of the top base, and a rotating shaft of the motor is connected with the top cover and drives the top cover to rotate.

Further, a circle of ratchets is arranged in the top cover of the top, and a plurality of pawls are arranged on the top base;

when the top cover is driven to rotate forward by the transmitting head in the transmitting mode, the ratchet teeth of the top cover are meshed with the pawl, and the top cover drives the top base to rotate together;

when in an acceleration mode, the motor rotates, the motor drives the top cover to reversely rotate, and the top cover drives the ratchet to be separated from the pawl and drives the top base to accelerate.

Further, the gyro body and the emitter are both provided with a power switch, and the gyro body or the emitter is also provided with a code matching switch;

when the code is matched, the power switches of the gyro body and the transmitter are turned on, and then the transmitting head of the transmitter faces the receiving head of the gyro body and presses the code matching switch.

After the technical scheme is adopted, the method has the following beneficial effects:

according to the invention, the gyro body is driven to rotate and emit by the pulling driving unit, when the rotating speed of the gyro body is reduced, the emitter faces the gyro body, the pulling driving unit is operated again, the motor is controlled to rotate by the accelerator, the accelerating signal receiving unit and the processor, and the faster the pulling driving unit pulls, the faster the accelerator rotates, and the faster the motor rotates. The invention has the advantages of convenient and safe operation and can realize secondary acceleration without recovering the gyro.

Drawings

The present disclosure will become more readily understood with reference to the accompanying drawings. It should be understood that: the drawings are for illustrative purposes only and are not intended to limit the scope of the present invention. In the figure:

FIG. 1 is a perspective view of a gyroscopic toy in accordance with one embodiment of the present invention;

FIG. 2 is a cross-sectional view of a top body according to one embodiment of the present invention;

FIG. 3 is a schematic view of the structure of the recycler and accelerator in one embodiment of the invention;

FIG. 4 is a schematic diagram of the structure of an infrared transmitting tube and a gyro body according to an embodiment of the present invention;

FIG. 5 is a schematic view of the structure of a top body and a transmitter part in an embodiment of the invention;

FIG. 6 is a schematic view showing an internal structure of a gyro body according to an embodiment of the present invention;

FIG. 7 is a partially exploded view of a top body in accordance with one embodiment of the present invention;

FIG. 8 is a partial exploded view of a transmitter in an embodiment of the invention;

FIG. 9 is a burst view of the trigger and firing head in one embodiment of the present invention;

fig. 10 is a schematic view of a part of the structure of a transmitting head in an embodiment of the present invention.

Reference numeral control table:

transmitter 1 gyro body 2

Tab 11 handle 12 emitter 13

Accelerator 14 recuperator 15 emitter housing 16

Infrared transmitting tube 17 pull rope 18 trigger 19

Top base 22 top base 23 of motor 21 top

Cell box 121 of top 24 pawl 25

Oblique block 131 connecting pin 132 transmission shaft 133

End cap 134 first platen 135 second platen 136

Jaw 137 emitter head housing 138 drive gear 142

Rotating shaft 143 oscillating tooth 141a oscillating tooth 141b

The tachometer gear 144 drives the teeth 151 and the ratchet 221

Shaft 1311 defines a bore 1351 through bore 1361

Wedge 1371 hook 1372 return spring 1373

Detailed Description

Specific embodiments of the present invention will be further described below with reference to the accompanying drawings.

It is to be readily understood that, according to the technical solutions of the present invention, those skilled in the art may replace various structural modes and implementation modes with each other without changing the true spirit of the present invention. Accordingly, the following detailed description and drawings are merely illustrative of the invention and are not intended to be exhaustive or to limit the invention to the precise form disclosed.

Terms of orientation such as up, down, left, right, front, rear, front, back, top, bottom, etc. mentioned or possible to be mentioned in the present specification are defined with respect to the configurations shown in the drawings, which are relative concepts, and thus may be changed according to different positions and different use states thereof. These and other directional terms should not be construed as limiting terms.

As shown in fig. 1-2 and 8, the gyro toy comprises a launcher 1 and a gyro body 2, wherein the launcher 1 comprises a pulling driving unit and a launching head 13, the pulling driving unit drives the launching head 13 to rotate, the launching head 13 is used for connecting the gyro body 2 and can drive the gyro body 2 to rotate,

the transmitter 1 further includes an accelerator 14 (see fig. 3) and an acceleration signal detection unit;

the gyro body 2 includes an acceleration signal receiving unit, a processor, and a motor 21;

the driving unit is pulled to drive the accelerator 14 to accelerate, the acceleration signal detecting unit is used for detecting the accelerator 14 and sending the acquired speed signal to the acceleration signal receiving unit, the acceleration signal receiving unit receives the speed signal and then sends the speed signal to the processor, and the processor controls the rotating speed of the motor 21 according to the speed signal, so that the faster the accelerator rotates, the faster the motor 21 rotates.

Specifically, as shown in fig. 1, the transmitter 1 further includes a transmitter housing 16, a handle 12, a pull ring 11, an accelerator 14, and an acceleration signal detection unit, and the pulling driving unit includes a pulling rope 18.

The pull ring 11 is located outside the transmitter housing 16, the pull ring 11 is connected to one end of the pull cord 18, the remainder of the pull cord 18 is housed in the transmitter housing 16, and the pull ring 11 is capable of pulling the pull cord 18 from the transmitter housing 16.

The handle 12 extends from the emitter housing 16 to facilitate one hand of a user holding the handle 12 and the other hand pulling on the tab 11.

The emitter head 13 is located below the emitter housing 16, the emitter head 13 being adapted to interface or align with the gyro body 2.

The accelerator 14 and the acceleration signal detection unit are mounted inside the emitter housing 16.

As shown in fig. 2, the gyro body 2 includes a gyro upper cover 22, a gyro base 23, a motor 21, and a gyro tip 24.

The motor 21 is installed in the inside cavity of top base 23, and motor 21 can drive top upper cover 22 rotation, and top 24 installs in top base 23's center bottom, and top 24 is used for with fight against the dish or ground contact.

When launching the top, launching head 13 and top body 2 butt joint, pulling pull ring 11, stay cord 18 drive accelerator 14 rotation, and accelerator 14 drives top body 2 through launching head 13 and launches out top body 2, and top body 2 can be at the battle plate or ground rotation.

When the gyro body 2 gradually slows down, the emitter head 13 of the emitter 1 is aligned with the gyro body 2, and at this time, the emitter head 13 is not in contact with the gyro body 2, but is just located above or near the gyro body 2. Pulling the pull ring 11, the pull rope 18 drives the accelerator 14 to rotate, the acceleration signal detection unit is used for detecting the accelerator 14 and sending the acquired speed signal to the acceleration signal receiving unit, the acceleration signal receiving unit receives the speed signal and then sends the speed signal to the processor, and the processor controls the rotating speed of the motor 21 according to the speed signal. The faster the pull ring 11 and pull cord 18 are pulled, the faster the accelerator rotates and the faster the motor 21 rotates.

In this embodiment, the gyro body 2 is convenient and safe to operate, and the second acceleration in combat can be achieved without recovering the gyro body 2.

Further, as shown in fig. 4, the acceleration signal detecting unit includes a signal transmitting module, a signal receiving module and a calculating module, in this embodiment, the signal transmitting module is an infrared transmitting tube 17, the signal receiving module is an infrared receiver, the infrared transmitting tube 17 is used for transmitting infrared rays towards the accelerator 14, the infrared receiver is used for receiving reflected signals after reflection, and the calculating module calculates the reflected signals to obtain a speed signal.

Alternatively, the signal transmitting module and the signal receiving module may also be other signal transmitting and receiving modes.

Further, as shown in fig. 4-5 and 8, the accelerator 14 further includes a tachometer gear 144, the tachometer gear 144 is meshed with the transmission gear 142, and the acceleration signal detecting unit is configured to detect and acquire a speed signal of the tachometer gear 144.

In this embodiment, the infrared transmitting tube 17 is located near the speed measuring gear 144, the infrared transmitting tube 17 and the infrared receiver are both located on the same side of the speed measuring surface of the speed measuring gear 144, and the speed measuring surface is provided with a reflecting plate.

Optionally, the infrared transmitting tube 17 and the infrared receiver may also be located at two sides of the speed measuring surface of the speed measuring gear 144, where the speed measuring surface is provided with a light hole, the central axis of the light hole and the infrared transmitting tube 17 and the infrared receiver are located in the same line, and the speed measuring gear 144 receives a signal once when rotating for each circle of the infrared receiver.

Further, as shown in fig. 3, the pulling driving unit further includes a recoverer 15 and a driving tooth 151, the pulling rope 18 is used for driving the driving tooth 151 to rotate, the driving tooth 151 is connected with an accelerator 14, and the accelerator is connected with the emitter head 13.

When the pull rope 18 is pulled out, the recoverer 15 is driven to rotate positively for energy storage, meanwhile, the driving teeth 151 are driven to rotate, the driving teeth 151 drive the accelerator 14 to rotate, and the accelerator 14 is used for driving the emitter head 13 to rotate;

when the pull rope 18 is pulled out by a certain length or is pulled to a limit length and then the pull rope 18 is loosened, the recoverer 15 releases energy to rotate reversely and drives the pull rope 18 to retract into the emitter shell 16, and the recoverer 15 does not accelerate the emitter head 13.

The automatic recovery of the pull rope 18 can be realized through the recoverer 15, the pull rope 18 can drive the accelerator 14 to rotate through the driving teeth 151, the accelerator 14 drives the transmitting head 13 to rotate, and the transmitting head 13 finally drives the gyro body 2 to rotate and transmits the gyro body 2 out.

As shown in fig. 5, the recoverer 15 is fixedly connected with the driving teeth 151, and when the pull rope 18 drives the driving teeth 151 to rotate forward, the driving teeth 151 drive the recoverer 15 to rotate forward for energy storage; when the pull rope 18 is loosened, the recoverer 15 releases energy to rotate reversely, and the recoverer 15 drives the driving teeth 151 to rotate reversely.

Further, the gyroscopic toy includes a launch mode and an acceleration mode;

in the launching mode, the top body 2 is connected to the launching head 13, the pull rope 18 is pulled, the pull rope 18 drives the driving teeth 151 to rotate, the driving teeth 151 drive the accelerator 14 to rotate, the accelerator 14 drives the launching head 13 to rotate, and the launching head 13 drives the top body 2 to rotate and launches the top body 2;

in the acceleration mode, the emitter 1 is located near the gyro body 2, the pull rope 18 is pulled, the pull rope 18 drives the driving teeth 151 to rotate, the driving teeth 151 drive the accelerator 14 to rotate, the acceleration signal detection unit detects a speed signal of the accelerator 14 and sends the speed signal to the acceleration signal receiving unit, the acceleration signal receiving unit receives the speed signal and then sends the speed signal to the processor, the processor controls the rotating speed of the motor 21 according to the speed signal, and the gyro body 2 accelerates and rotates under the rotation of the motor 21.

Further, as shown in fig. 3-5, the accelerator 14 includes a wobble tooth and a transfer gear 142;

in fig. 3, the teeth 141a and 141b represent two different states of the same tooth, the tooth 141a represents a tooth in a state of being disengaged from the transmission gear 142, and the tooth 141b represents a tooth in a state of being engaged with the transmission gear 142.

The driving teeth 151 are meshed with the swinging teeth, when the driving teeth 151 are driven to rotate forward when the pull rope 18 is pulled out, as shown in fig. 3, the driving teeth 151 drive the swinging teeth 141b to swing to a position meshed with the transmission gear 142, the transmission gear 142 drives the transmitting head 13 to rotate, and the recoverer 15 rotates forward and stores energy.

When the pull rope 18 is pulled out for a certain distance and then the pull rope 18 is loosened, the driving teeth 151 drive the swinging teeth 141a to swing to a position separated from the transmission gear 142, and the recoverer 15 releases energy to reversely rotate so as to drive the pull rope 18 to retract.

The swing teeth are switched between two positions, so that the swing teeth can be meshed with or separated from the transmission gear 142, and the accelerator 14 can accelerate the gyro body 2 during meshing; the accelerator 14 cannot accelerate the gyro body 2 at the time of detachment.

Further, the rotating shaft 143 of the swing tooth is installed in a sliding groove (not shown), the sliding groove comprises a first end point and a second end point, and the sliding groove is formed inside the emitter housing 16;

when the recoverer 15 rotates in the forward direction (anticlockwise direction in fig. 3 in this embodiment), the driving gear 151 drives the oscillating tooth 141b to oscillate to a first end point, and the first end point is located at the lower side in fig. 3, and at this time, the oscillating tooth 141b is meshed with the transmission gear 142;

when the recoverer 15 rotates reversely (clockwise in fig. 3 in this embodiment), the driving gear 151 drives the oscillating tooth 141a to oscillate at the second end point, the second end point is located at the upper side in fig. 3, and at this time, the oscillating tooth 141a is separated from the driving gear 142, and the power is not transmitted to the driving gear 142, so that the emitter head 13 is not driven to rotate.

The first end point and the second end point of the sliding groove can limit two positions of the swing tooth, and the precise connection relation of disengagement or engagement between the swing tooth and the transmission gear is ensured.

Further, as shown in fig. 6 to 7, a circle of ratchet 221 is provided in the top cover 22, and a plurality of pawls 25 are mounted on the top base 23.

When the launching head 13 drives the top cover 22 to rotate forward in the launching mode, the ratchet 221 of the top cover 22 is meshed with the pawl 25, and the top cover 22 can drive the top base 23 to rotate together after the ratchet 25 is arranged on the top base 23.

When in acceleration mode, the motor 21 rotates, the motor 21 drives the top cover 22 to rotate reversely, and the top cover 22 drives the ratchet 221 to separate from the pawl 25, so as to drive the top base 23 to accelerate.

By the engagement of the ratchet 221 and the pawl 25, the gyro upper cover 22 and the gyro base 23 are rotated together in the emission mode, and only the gyro base 23 is accelerated in the acceleration mode.

Further, as shown in fig. 1 and 8, the emitter 1 is gun-shaped, a battery box 121 is arranged at the handle 12, and a battery is installed in the battery box 121 to provide power for the emitter 1. The front end of the muzzle can be provided with an LED lamp.

Further, as shown in fig. 9 to 10, the transmitter 1 further includes a trigger 19, and the transmitter head 13 includes a sloping block 131, a connecting pin 132, a transmission shaft 133, an end cover 134, a first pressure plate 135, a second pressure plate 136, a claw 137, and a transmitter head housing 138;

wherein the shaft 1311 of the swash block 131 is connected with the transmitter housing 16 of the transmitter 1, and when the trigger 19 is pressed, the trigger 19 pushes the swash block 131 upward, and the swash block 131 rotates upward around the shaft 1311;

the connecting pin 132 passes through the inclined block 131 from top to bottom, the upper end of the connecting pin 132 is lapped on the inclined block 131, and when the inclined block 131 rotates upwards, the connecting pin 132 is driven to move upwards together;

the upper end of the transmission shaft 133 is connected with the connecting pin 132, and the lower end passes through the end cover 134 and the first pressure plate 135 and is fixedly connected with the second pressure plate 136. The transmission gear 142 is fixed on the transmission shaft 133, and the transmission gear 142 can move up and down along with the transmission shaft 133, and when the transmission gear 142 moves up and down, no influence is exerted on the speed measuring gear 144.

The first platen 135 is located between the end cap 134 and the second platen 136;

the wedge-shaped blocks 1371 of the two pawls 137 are inserted into the defining holes 1351 of the first platen 135 after passing through the through holes 1361 of the second platen 136, and when the connecting pin 132 moves upward, the driving shaft 133 also moves upward, and the driving shaft 133 drives the pawls 137 to move upward, and the wedge-shaped blocks 1371 of the pawls 137 relatively move radially outward under the action of the defining holes 1351, so that the distance between the two pawls 137 increases. The hook 1372 of the claw 137 is separated from the gyro body 2 for releasing the gyro body 2.

Wherein, as shown in fig. 10, a return spring 1373 is connected between the two pawls 137, and when the two pawls 137 move radially outward, the return spring 1373 is stretched.

When the trigger 19 is released, the swash block 131, the connecting pin 132, the transmission shaft 133, the second pressure plate 136 and the pawl 137 fall back, the wedge 1371 is no longer acted upon by the limiting hole 1351, and the pawl 137 moves radially inward by the return spring 1373 to return to the original position.

The gyro body 2 can be manually clamped into the two clamping hooks 1372, the two clamping hooks 1372 are extruded outwards by the gyro body 2, and after the gyro body 2 is completely clamped into the gyro body, the two clamping hooks 1372 move inwards along the radial direction under the action of the reset spring 1373 and are used for clamping the gyro body 2.

The playing method of the gyroscopic toy in the embodiment is as follows:

firstly, pulling a power switch of the gyro body 2 to an ON position, and flashing an indicator lamp of the gyro body 2; then the power switch of the transmitter 1 is pulled to the ON position, the transmitting head 13 of the transmitter 1 is opposite to the receiving head of the gyro body 2, the code matching switch is pressed, the indicator lamp of the transmitter 1 is changed into a long-lighting state from flashing, and meanwhile, the indicator lamp of the gyro body 2 is changed into a breathing lamp state from flashing, and the code matching is successful. The transmitter 1 can be matched with different gyro bodies 2 through code matching, and one transmitter 1 can transmit or accelerate a plurality of gyro bodies 2.

Then the gyro body 2 is arranged on the emitter 13, the pull rope 18 is driven by the pull ring 11, the pull rope 18 drives the driving teeth 151 to rotate, the recoverer 15 stores force, the driving teeth 151 drive the accelerator 14, and finally the accelerator 14 drives the emitter 13 to rotate; when the pull rope 18 is pulled to a certain distance or is loosened after the pull rope 18 is at the end, the recoverer 15 is released to rotate reversely, the pull rope 18 is recovered by the storage force of the recoverer 15, the pull ring 11 is pulled again by a user, the pull ring 11 drives the pull rope 18, the pull rope 18 drives the accelerator 14, finally the accelerator 14 drives the emitter 13 to rotate at a high speed, the emitter 13 is rotated at a high speed by pulling the pull ring 11 back and forth, and finally the gyro body 2 is emitted.

When the speed of the gyro body 2 is slow, the emitter 1 is used for facing the upper part of the gyro body 2, the gyro body 2 is not required to be sucked or clamped, the pull rope 18 is pulled back and forth by hand after facing the upper part of the gyro body 2, and when the pull rope 18 is pulled, the pull rope drives the accelerator 14 to rotate, wherein an infrared transmitting tube 17 is arranged beside the speed measuring gear 144 to measure the rotating speed of the speed measuring gear 144; when the pull rope 18 is pulled faster, the speed measuring gear 144 rotates faster, then the speed signal detected by the infrared transmitting tube 17 is transmitted to the gyro body 2, and after the gyro body 2 receives the signal and processes the signal by the processor, the motor 21 on the gyro body 2 rotates at a high speed, so as to realize the principle that the faster the pull rope 18 is, the faster the gyro is.

What has been described above is merely illustrative of the principles and preferred embodiments of the present invention. It should be noted that several other variants are possible to those skilled in the art on the basis of the principle of the invention and should also be considered as the scope of protection of the present invention.

Claims (10)

1. A top toy, which comprises a launcher and a top body, wherein the launcher comprises a pulling driving unit and a launching head, the pulling driving unit drives the launching head to rotate, the launching head is used for connecting the top body and can drive the top body to rotate, the top toy is characterized in that,

the transmitter further comprises an accelerator and an acceleration signal detection unit;

the gyro body comprises an acceleration signal receiving unit, a processor and a motor;

the pulling driving unit drives the accelerator to accelerate, the accelerating signal detecting unit is used for detecting the accelerator and sending the acquired speed signal to the accelerating signal receiving unit, the accelerating signal receiving unit receives the speed signal and then sends the speed signal to the processor, the processor controls the rotating speed of the motor according to the speed signal, and the faster the accelerator rotates, the faster the motor rotates;

the pulling driving unit comprises a pull rope and driving teeth, the pull rope is connected with the driving teeth, the driving teeth are connected with the accelerator, and the accelerator is connected with the emission head;

the accelerator comprises a swing tooth and a transmission gear, and the driving tooth is meshed with the swing tooth;

when the pull rope is pulled out to drive the driving teeth to rotate in the forward direction, the driving teeth drive the swinging teeth to swing to a position meshed with the transmission gear, and the transmission gear drives the transmitting head to rotate;

when the pull rope is loosened after being pulled out by a certain distance, the pull rope is retracted, and the driving teeth drive the swing teeth to swing to a position separated from the transmission gear.

2. The gyroscopic toy of claim 1, wherein the acceleration signal detection unit comprises a signal emitting module, a signal receiving module, and a computing module, the signal emitting module configured to emit a signal toward the accelerator, the signal receiving module configured to receive a signal, and the computing module configured to compute the speed signal from the signal.

3. The gyroscopic toy of claim 1, wherein said gyroscopic toy comprises a launch mode and an acceleration mode;

in the launching mode, the top body is connected to the launching head, the pull rope is pulled, the pull rope drives the driving teeth to rotate, the driving teeth drive the accelerator to rotate, the accelerator drives the launching head to rotate, and the launching head drives the top body to rotate and launches the top body;

during acceleration mode, the emitter is located near the top body, pulling the stay cord, the stay cord drives the driving tooth rotates, the driving tooth drives the accelerator rotates, after the acceleration signal detecting element detects the speed signal of accelerator and with the speed signal send the acceleration signal receiving element, the acceleration signal receiving element receives the speed signal after the transmission gives the processor, the processor is according to the speed signal control motor pivoted speed, the top body is rotated under the motor is accelerated.

4. The gyroscopic toy of claim 1, wherein said pull drive unit further comprises a retriever, said pull cord being coupled to said drive teeth through said retriever;

the rotating shaft of the swing tooth is arranged in a chute, and the chute comprises a first end point and a second end point;

when the recoverer rotates forwards, the driving gear drives the swing tooth to swing the first end point;

when the recoverer reversely rotates, the driving gear drives the swing tooth to swing the second end point.

5. The gyroscopic toy of claim 2, wherein said accelerator further comprises a tachometer gear, said tachometer gear being in mesh with said drive gear, said acceleration signal detection unit being configured to detect and acquire said speed signal of said tachometer gear.

6. The spinning top toy of claim 5, wherein the signal transmitting module is an infrared transmitting tube, the signal receiving module is an infrared receiver, the infrared transmitting tube and the infrared receiver are respectively positioned at two sides of a speed measuring surface of the speed measuring gear, a light transmitting hole is formed in the speed measuring surface, a central axis of the light transmitting hole is positioned in the same straight line with the infrared transmitting tube and the infrared receiver, and the speed measuring gear receives a signal once when rotating for one circle of the infrared receiver.

7. The spinning top toy of claim 5, wherein the signal transmitting module is an infrared transmitting tube, the signal receiving module is an infrared receiver, the infrared transmitting tube and the infrared receiver are both positioned on the same side of the speed measuring surface of the speed measuring gear, a reflecting plate is arranged on the speed measuring surface, when the reflecting plate rotates above the infrared transmitting tube along with the speed measuring gear, the reflecting plate reflects an infrared signal to the infrared receiver, and the speed measuring gear receives a signal once every time the speed measuring gear rotates.

8. The spinning top toy of claim 1, wherein the spinning top body further comprises a spinning top cover and a spinning top base which can rotate up and down relatively, the motor is located in the inner cavity of the spinning top base, and a rotating shaft of the motor is connected with the spinning top cover and drives the spinning top cover to rotate.

9. The spinning top toy of claim 8, wherein a circle of ratchet teeth is arranged in the spinning top upper cover, and a plurality of pawls are arranged on the spinning top base;

when the top cover is driven to rotate forward by the transmitting head in the transmitting mode, the ratchet teeth of the top cover are meshed with the pawl, and the top cover drives the top base to rotate together;

when in an acceleration mode, the motor rotates, the motor drives the top cover to reversely rotate, and the top cover drives the ratchet to be separated from the pawl and drives the top base to accelerate.

10. The gyroscopic toy of claim 1, wherein the gyroscopic body and the launcher are provided with a power switch, and the gyroscopic body or the launcher is further provided with a code matching switch;

when the code is matched, the power switches of the gyro body and the transmitter are turned on, and then the transmitting head of the transmitter faces the receiving head of the gyro body and presses the code matching switch.