阅读说明：本技术 一种弹链式发射器玩具 (Elastic chain type launcher toy ) 是由 梁文建 李德铭 于 2021-06-30 设计创作，主要内容包括：本发明公开了一种弹链式发射器玩具,包括发射器和弹链；弹链由多个弹装部连接成链状,每个弹装部可连接一个被驱动玩具；发射器包括发射壳体、步进控制件、驱动件和解锁件；发射壳体上设置有连接口,步进控制件、驱动件和解锁件设置在发射壳体上；弹链插入到连接口后,可通过步进控制件对弹链进行步进操作,每步进一次切换一个弹装部进入到连接口；驱动件可对位于连接口中的弹装部上的被驱动玩具进行动力驱动；解锁件可解锁位于连接口中的弹装部上的被驱动玩具,以使被驱动玩具脱离弹装部。弹链式发射器玩具的发射器可以连续释放被驱动玩具,提高了玩耍的连贯性和乐趣。驱动件为被驱动玩具提供动力,使被驱动玩具脱离弹装部后移动的距离更远。(The invention discloses a bullet chain type launcher toy, which comprises a launcher and a bullet chain; the ammunition chain is formed by connecting a plurality of ammunition parts into a chain shape, and each ammunition part can be connected with a driven toy; the emitter comprises an emitting shell, a stepping control piece, a driving piece and an unlocking piece; the launching shell is provided with a connecting port, and the stepping control piece, the driving piece and the unlocking piece are arranged on the launching shell; after the elastic chain is inserted into the connecting port, the step control element can be used for carrying out step operation on the elastic chain, and one elastic loading part is switched to enter the connecting port every step; the driving piece can carry out power driving on the driven toy on the elastic loading part in the connecting port; the unlocking piece can unlock the driven toy on the elastic loading part in the connecting port so as to enable the driven toy to be separated from the elastic loading part. The launcher of the elastic chain type launcher toy can continuously release the driven toy, and the continuity and the fun of playing are improved. The driving piece provides power for the driven toy, so that the driven toy moves farther after being separated from the elastic part.)

1. A chain-elastic launcher toy (10) is characterized by comprising a launcher (1) and a chain-elastic (2);

the elastic chain (2) is connected into a chain shape by a plurality of elastic loading parts (21), and each elastic loading part (21) can be connected with one driven toy (3);

the launcher (1) comprises a launching shell (11), a stepping control piece (12), a driving piece (13) and an unlocking piece (14);

a connecting port (111) is arranged on the launching shell (11), and the stepping control piece (12), the driving piece (13) and the unlocking piece (14) are arranged on the launching shell (11);

after the bullet chain (2) is inserted into the connecting port (111), the bullet chain (2) can be operated in a stepping mode through the stepping control piece (12), and the bullet loading parts (21) are switched to enter the connecting port (111) one time in each stepping mode;

the driving member (13) can power-drive the driven toy (3) on the loading portion (21) in the connection port (111);

after the driven toy (3) is driven, the unlocking piece (14) can unlock the driven toy (3) on the elastic loading part (21) in the connecting port (111) so as to enable the driven toy (3) to be separated from the elastic loading part (21) and the launching shell (11);

the driven toy (3) executes actions under the driving of power after being disengaged.

2. The chain launcher toy (10) of claim 1, wherein the step control member (12) includes a control rod (121) and a step mechanism (123) for moving the loading portion (21);

the control rod (121) is movably connected with the emission shell (11) and can drive the stepping mechanism (123) to move;

when the control rod (121) is operated each time, the control rod (121) drives the stepping mechanism (123), and the stepping mechanism (123) moves out the loading part (21) in the connecting port (111) and moves the other adjacent loading part (21) into the connecting port (111).

3. The chain launcher toy (10) according to claim 2, wherein the stepping mechanism (123) comprises a transmission and a stepping output for moving the loading portion (21);

the transmission piece is connected with the stepping output piece, and the stepping output piece is connected with the elastic loading part (21) in the connecting port (111);

when the control rod (121) is operated each time, the control rod (121) triggers the transmission piece to output the stepping output piece, and the stepping output piece moves out the loading part (21) in the connecting port (111) and moves the other adjacent loading part (21) into the connecting port (111).

4. The chain launcher toy (10) according to claim 3, wherein the transmission member is a transmission toothed bar (122), the transmission toothed bar (122) being slidably connected within the launching housing (11) and in meshing connection with the step output member;

when the control rod (121) is operated each time, the control rod (121) pushes the transmission toothed bar (122), and the transmission toothed bar (122) drives the stepping output piece to output.

5. The chain launcher toy (10) of claim 3, wherein the step output includes a connecting toothed bar (1231), a driving wheel (1232), and a driven wheel (1233) connected to the driving wheel (1232);

the connecting toothed bar (1231) is rotatably connected in the launching shell (11), and the transmission toothed bar (122) drives the connecting toothed bar (1231) to rotate;

the driving wheel (1232) is connected with the connecting toothed bar (1231), and the driven wheel (1233) is connected with the elastic part (21);

when the control rod (121) is operated, the driven wheel (1233) drives the elastic loading part (21) in the connecting port (111) to move.

6. The chain launcher toy (10) of claim 5, wherein the loading portion (21) is provided with a rack (22), and the driven wheel is engaged with the rack (22).

7. The chain launcher toy (10) of claim 2, wherein the step control (12) includes a positioning structure (124), the positioning structure (124) including a positioning rod (1241);

the positioning rod (1241) is telescopically connected to the connecting port (111);

the elastic loading part (21) is correspondingly provided with a positioning groove (215), and when the positioning rod (1241) extends out of the connecting port (111), the positioning rod (1241) is connected with the positioning groove (215) of the elastic loading part (21) in the connecting port (111);

each time the control lever (121) is operated, the positioning rod (1241) is separated from the positioning groove (215) of the loading portion (21) in the connection port (111), and when the control lever (121) returns, the positioning rod (1241) is connected to the positioning groove (215) of the loading portion (21) which enters the connection port (111) next.

8. The chain launcher toy (10) according to claim 7, wherein the positioning structure (124) further comprises a resilient clip (1244), the attachment opening (111) is provided with a mounting groove (112) on the opposite side of the positioning rod (1241), the resilient clip (1244) is disposed in the mounting groove (112) and partially protrudes into the attachment opening (111);

the elastic loading part (21) is correspondingly provided with a clamping groove (216), when the elastic loading part (21) is positioned in the connecting port (111), the extending part of the elastic clamping piece (1244) extends into the clamping groove (216), and when the elastic loading part (21) moves relative to the connecting port (111), the elastic clamping piece (1244) is separated from the clamping groove (216) and is extruded and contracted.

9. The chain launcher toy (10) according to claim 1, wherein the driving member (13) comprises an operating member, a power generating member, and a drive transmission member, the operating member being connected to the power generating member, the power generating member being connected to the drive transmission member;

the operating parts can trigger the power generating parts to generate power, and the power generating parts transmit power to the driven toy (3) through the driving transmission parts.

10. The chain launcher toy (10) of claim 9, wherein the operating member is a slider (131), the power generating member is a sheave (132), and the drive transmission member is a gear set (133);

the sliding block (131) is connected to the launching shell (11) in a sliding mode, and the sliding block (131) is connected with a pull rope (134) on the rope pulley (132);

the rope wheel (132) is meshed with the gear set (133), and the gear set (133) drives the driven toy (3) by pulling the rope wheel (132) through the sliding block (131).

11. The chain launcher toy (10) of claim 9, wherein a drive transfer rod (211) is disposed within the loading portion (21) and connected to the driven toy (3);

the driving transmission rod (211) is connected with a transmission wheel (212), and at least part of the transmission wheel (212) is positioned in the emission shell (11) and is connected with the driving transmission part;

the driving transmission member drives the driven toy (3) through the driving transmission rod (211).

12. The chain launcher toy (10) according to claim 9, wherein the operating member is rotatably connected to the launcher housing (11);

when the operating piece rotates towards the stepping control piece (12), the operating piece triggers the stepping control piece (12), and the stepping control piece (12) performs stepping operation on the elastic chain (2).

13. The chain launcher toy (10) according to claim 1, wherein the loading portion (21) comprises a loading housing (213) for mounting the driven toy (3) and a locking member capable of locking the driven toy (3), the locking member being attached to the loading housing (213);

when the locking piece locks the driven toy (3), the driving piece (13) is used for driving the driven toy (3) installed on the cartridge shell (213) in a power mode;

when the unlocking piece (14) unlocks the locking piece, the locking piece releases the driven toy (3), and the driven toy (3) is separated from the spring-loaded shell (213).

14. The chain launcher toy (10) according to claim 13, wherein the launching section (21) further comprises a launching mechanism (214), the launching mechanism (214) comprising a launching spring (2141) and a pusher (2142), the launching spring (2141) being mounted within the launch housing (213), the pusher (2142) being slidably connected to the launch housing (213) and being connectable to the driven toy (3);

the locking piece locks the driven toy (3) by locking the pushing piece (2142);

when the pushing piece (2142) is locked by the locking piece, the launching spring (2141) is charged with energy, and the pushing piece (2142) is in contact with the launching spring (2141);

when the unlocking piece (14) unlocks the locking piece, the locking piece releases the pushing piece (2142), the launching spring (2141) releases energy, and the pushing piece (2142) pushes the driven toy (3) out of the cartridge housing (213).

Technical Field

The invention relates to the field of toys, in particular to a bullet chain type launcher toy.

Background

With the progress of the times, the types of toys are more and more abundant in order to improve the playing pleasure of people.

At present, a toy piece can be released through the launcher, but the toy piece is generally released only, and the kinetic energy of the toy piece is not increased. Therefore, the toy piece only has large initial acceleration, but the cruising ability of the toy piece is still insufficient, and the racing experience effect is poor. Moreover, the emitter can only release a single toy piece at a time, and cannot continuously emit a plurality of toy pieces, so that the play consistency is poor.

The existing gyro launcher can launch a plurality of gyros, but the maximum launching number is limited, namely how many gyros can be installed on the connecting disc of the launcher are fixed and cannot be increased according to the needs, so that the autonomous operability is poor. Based on the above technical problems, improvements thereof are required.

Disclosure of Invention

The technical scheme of the invention aims to provide the elastic chain type launcher toy which can continuously launch toys, adjust the number of the launched toys, accelerate the toys before launching and improve the playing pleasure.

The technical scheme of the invention provides a bullet chain type launcher toy, which comprises a launcher and a bullet chain; the ammunition chain is formed by connecting a plurality of ammunition parts into a chain shape, and each ammunition part can be connected with a driven toy; the launcher comprises a launching shell, a stepping control piece, a driving piece and an unlocking piece; the launching shell is provided with a connecting port, and the stepping control piece, the driving piece and the unlocking piece are arranged on the launching shell; after the elastic chain is inserted into the connecting port, the elastic chain can be operated in a stepping mode through the stepping control piece, and the elastic parts are switched to enter the connecting port one by one step; the driving piece can carry out power driving on the driven toy on the elastic loading part in the connecting port; after the driven toy is driven, the unlocking piece can unlock the driven toy on the elastic loading part in the connecting port so as to enable the driven toy to be separated from the elastic loading part and the launching shell; the driven toy is driven by power to perform actions after being disengaged.

Further, the stepping control piece comprises a control rod and a stepping mechanism for driving the elastic loading part to move; the control rod is movably connected with the emission shell and can drive the stepping mechanism to move; and when the control rod is operated every time, the control rod drives the stepping mechanism, and the stepping mechanism moves out the elastic loading part in the connecting port and moves the other adjacent elastic loading part into the connecting port.

Further, the stepping mechanism comprises a transmission piece and a stepping output piece for moving the loading part; the transmission piece is connected with the stepping output piece, and the stepping output piece is connected with the elastic loading part in the connecting port; when the control rod is operated every time, the control rod triggers the transmission piece to enable the stepping output piece to output, the stepping output piece moves out the elastic loading part in the connecting port and moves the adjacent elastic loading part into the connecting port.

Further, the transmission part is a transmission toothed bar which is slidably connected in the emission shell and is meshed with the stepping output part; when the control rod is operated every time, the control rod pushes and presses the transmission toothed bar, and the transmission toothed bar drives the stepping output piece to output.

Further, the stepping output piece comprises a connecting toothed bar, a driving wheel and a driven wheel connected with the driving wheel; the connecting toothed bar is rotatably connected in the launching shell, and the transmission toothed bar drives the connecting toothed bar to rotate; the driving wheel is connected with the connecting toothed bar, and the driven wheel is connected with the elastic loading part; when the control rod is operated, the driven wheel drives the elastic loading part in the connecting port to move.

Further, a rack is arranged on the elastic loading part, and the driven wheel is meshed with the rack.

Further, the step control comprises a positioning structure comprising a positioning rod; the positioning rod is telescopically connected to the connecting port; the elastic loading part is correspondingly provided with a positioning groove, and when the positioning rod extends out of the connecting port, the positioning rod is connected with the positioning groove of the elastic loading part in the connecting port; and when the control rod is operated every time, the positioning rod is separated from the positioning groove of the elastic loading part in the connecting port, and when the control rod returns, the positioning rod is connected with the next positioning groove of the elastic loading part entering the connecting port.

Furthermore, the positioning structure further comprises an elastic clamping piece, the connecting port is provided with an installation groove on the opposite surface of the position of the positioning rod, and the elastic clamping piece is arranged in the installation groove and partially extends into the connecting port; the elastic part is correspondingly provided with a clamping groove, when the elastic part is positioned in the connector, the extending part of the elastic clamping piece extends into the clamping groove, and when the elastic part moves relative to the connector, the elastic clamping piece is separated from the clamping groove and is extruded and contracted.

Further, the driving part comprises an operating part, a power generating part and a driving transmission part, the operating part is connected with the power generating part, and the power generating part is connected with the driving transmission part; the operating part can trigger the power generation part to generate power, and the power generation part transmits power to the driven toy through the driving transmission part.

Further, the operating part is a sliding block, the power generating part is a rope wheel, and the driving transmission part is a gear set; the sliding block is connected to the launching shell in a sliding mode and is connected with the pull rope on the rope pulley; the rope wheel is meshed with the gear set, and the pulley wheel is pulled through the sliding block, so that the gear set drives the driven toy.

Furthermore, a driving transmission rod connected with the driven toy is arranged in the elastic loading part; the driving transmission rod is connected with a driving wheel, and at least part of the driving wheel is positioned in the emission shell and is connected with the driving transmission part; the driving transmission member drives the driven toy through the driving transmission rod.

Further, the operating member is rotatably connected to the emission housing; when the operating piece rotates towards the stepping control piece, the operating piece triggers the stepping control piece, and the stepping control piece performs stepping operation on the elastic chain.

Further, the cartridge loading part comprises a cartridge loading shell used for installing the driven toy and a locking piece capable of locking the driven toy, and the locking piece is connected to the cartridge loading shell; when the driven toy is locked by the locking piece, the driving piece is used for driving the driven toy installed on the elastic shell in a power mode; when the unlocking piece unlocks the locking piece, the locking piece releases the driven toy, and the driven toy is separated from the elastic shell.

Furthermore, the ejection part also comprises an ejection mechanism, the ejection mechanism comprises a launching spring and a pushing piece, the launching spring is installed in the ejection shell, and the pushing piece is connected with the ejection shell in a sliding manner and can be connected with the driven toy; the locking piece locks the driven toy by locking the pushing piece; when the pushing piece is locked by the locking piece, the launching spring stores energy, and the pushing piece is in contact with the launching spring; when the unlocking piece unlocks the locking piece, the locking piece releases the pushing piece, the launching spring releases energy, and the pushing piece pushes the driven toy out of the elastic shell.

By adopting the technical scheme, the method has the following beneficial effects:

after the launcher of the elastic chain type launcher toy launches the driven toy on the ejection part in the connecting port, the other ejection part enters the connecting port, so that the launcher can continuously launch the driven toy, and the continuity and the enjoyment of playing are improved. Further because the elastic chain is formed by connecting a plurality of elastic parts into a chain, when playing, the elastic chain can be provided with different numbers of elastic parts according to the requirements, each elastic part is connected with a driven toy, the number of the driven toys is not limited, and the playing autonomy and flexibility are improved. And the elastic chain type launcher toy can also increase the performance of the driven toy through the driving piece. The driven toy can execute actions under the driving of power after being separated from the elastic part, such as enhancing cruising ability, executing rotation action, executing flying action, executing jumping action, executing acousto-optic effect and the like, thereby improving the interest of the toy.

Drawings

FIG. 1 is a perspective view of a chain launcher toy according to one embodiment of the present invention;

FIG. 2 is an exploded view of a chain launcher toy according to one embodiment of the present invention;

FIG. 3 is a schematic diagram of an emitter according to an embodiment of the invention;

FIG. 4 is a schematic view of a loading portion according to an embodiment of the present invention;

FIG. 5 is a cross-sectional view of a loading portion in accordance with an embodiment of the present invention;

FIG. 6 is a schematic view of a step control in accordance with an embodiment of the present invention;

FIG. 7 is a schematic view of a step mechanism according to an embodiment of the present invention;

FIG. 8 is a schematic view of a positioning structure according to an embodiment of the present invention;

FIG. 9 is a diagram illustrating a fastening structure according to an embodiment of the present invention;

FIG. 10 is a schematic view of a driving member according to an embodiment of the present invention;

fig. 11 is a schematic view of an unlocking member in an embodiment of the present invention.

Reference numerals

Elastic chain type launcher toy 10

Mounting groove 112 for connecting port 111 of emission shell 11 of emitter 1

Step control member 12 control rod 121 drive rack bar 122 step mechanism 123

Mechanism housing 1234 connecting toothed bar 1231, driving wheel 1232, driven wheel 1233 and mechanism housing 1234

Positioning rod 1241 and swinging rod 1242 of positioning structure 124 of elastic piece 1235

Elastic clamping piece 1243 of expansion spring 1243 and driving piece 13 of return spring 125

First connecting piece 1331 of pulley 132 gear set 133 of sliding block 131

Second coupling 1332 first gear 1333 second gear 1334 spring element 1335

Pull rope 134 unlocking piece 14 triggering block 141 rotating rod 142

Ejector rod 143 elastic chain 2 elastic loading part 21 drives transfer lever 211

Ejecting spring 2141 of ejecting mechanism 214 of ejecting shell 213 of driving wheel 212

Push member 2142, locking plate 2143, push rod 2144, projection 2145

Elastic clamping plate 2146 pushes spring 2147 to position groove 215 to clamp groove 216

The rack 22 is driven to the toy 3

Detailed Description

The following further describes embodiments of the present invention with reference to the accompanying drawings.

It is easily understood that according to the technical solution of the present invention, those skilled in the art can substitute various structures and implementation manners without changing the spirit of the present invention. Therefore, the following detailed description and the accompanying drawings are merely illustrative of the technical aspects of the present invention, and should not be construed as limiting or restricting the technical aspects of the present invention.

The terms of orientation of up, down, left, right, front, back, top, bottom, and the like referred to or may be referred to in this specification are defined relative to the configuration shown in the drawings, and are relative terms, and thus may be changed correspondingly according to the position and the use state of the device. Therefore, these and other directional terms should not be construed as limiting terms.

As shown in fig. 1 to 5, a chain magazine toy 10 according to an embodiment of the present invention includes a magazine 1 and a chain magazine 2.

The ammunition chain 2 is formed by connecting a plurality of ammunition parts 21 in a chain shape, and each ammunition part 21 can be connected with one driven toy 3.

The launcher 1 includes a launching housing 11, a stepping control 12, a driving member 13, and an unlocking member 14.

A connection port 111 is provided on the shooting case 11, and the stepping control member 12, the driving member 13, and the unlocking member 14 are provided on the shooting case 11.

After the ammunition chain 2 is inserted into the connection port 111, the ammunition chain 2 can be operated by stepping the stepping control member 12, and the ammunition loading part 21 is switched to enter the connection port 111 one step by one step.

The driving member 13 is capable of power-driving the driven toy 3 placed on the loading portion 21 in the connection port 111.

After the driven toy 3 is driven, the unlocking member 14 unlocks the driven toy 3 on the loading portion 21 in the connection port 111 to disengage the driven toy 3 from the loading portion 21 and the launching housing 11.

The driven toy 3 is driven by power to perform actions after being disengaged.

The actions performed by the driven toy 3 may be different depending on the type of the driven toy 3.

The driven toy 3 can be a toy car, a toy train, a toy top, a toy plane, a toy bird, a bouncing toy, an acousto-optic toy and the like, and the abundant appearance and the built-in function enable people to select according to own preference.

When the driven toy 3 is designed into a toy with wheels, such as a toy car, a toy train and the like, the driven toy 3 executes walking action under the driving of power after being separated, and can reach the effect of forward movement continuation under the operation of separating forward movement and driving the walking action, so that the driven toy 3 can walk farther.

When the driven toy 3 is designed as a toy with a rotatable performance such as a toy top, the driven toy 3 is disengaged and then performs a rotating motion under power driving, so that the driven toy 3 can be rotated by itself after being disengaged.

When the driven toy 3 is designed as a toy having flight performance such as a toy airplane, a toy bird, or the like, the driven toy 3 is disengaged and performs a flight motion under power driving, for example, a propeller is rotated at a high speed to cause wings on both sides to be swung up and down, so that the driven toy 3 can fly or glide in the air after being disengaged.

When the driven toy 3 is designed as a bouncing toy or the like having a bottom elastically stretchable, the driven toy 3 is separated and then the bottom member elastically stretchable is performed under power driving, so that the driven toy 3 can realize the bouncing action in the process of the bottom member elastically stretchable up and down after falling to the ground after being separated.

When the driven toy 3 is designed as a toy with electric function such as a sound and light toy, the driving part 13 stores the driving of the driven toy 3 as electric energy, i.e. the kinetic energy of the driving part 13 is converted into electric energy to be stored in a storage battery arranged inside the driven toy 3, and the sound and light part is powered by the storage battery after the driven toy 3 is separated, so that the sound and light effect is executed by the sound and light part.

Therefore, the driving member 13 increases the kinetic energy of the driven toy 3, so that the driven toy 3 can perform different action effects after being separated from the loading part 21, thereby improving the playing pleasure.

The chain launcher toy 10 includes a launcher 1 and a chain 2, the chain 2 includes a plurality of loading portions 21, and each loading portion 21 can be mounted with a driven toy 3. The launcher 1 is used to separate the driven toy 3 from the loading portion 21.

Optionally, two adjacent loading portions 21 are hinged, that is, one of the loading portions 21 can swing relative to the other loading portion 21, so that the whole elastic chain 2 has certain flexibility and is designed to be in flexible connection, the feasibility of connecting more loading portions 21 can be improved, the whole elastic chain 2 can surround the launcher 1, gravity deviation caused by straight line extension cannot occur, and the practicability is higher.

The launcher 1 includes a launching housing 11, and a stepping control member 12, a driving member 13, and an unlocking member 14 mounted on the launching housing 11. The discharge case 11 is provided with a connection port 111, the ammunition chain 2 is connected to the connection port 111, and the ammunition unit 21 can enter the connection port 111. Specifically, the connection port 111 is formed to be recessed inward at the front end of the emission case 11. The left and right sides of the connection port 111 are respectively communicated with the outside, and the elastic chain 2 can pass through the left and right sides of the connection port 111.

In the present embodiment, the shooting casing 11 has a gun model shape, and the connection port 111 is a gun barrel portion of the gun model. Of course, the launching housing 11 may have other shapes, such as launching a toy vehicle or a platform of a toy train, without limitation.

The stepping control member 12 is used to control the movement of the ammunition chain 2, after the launcher 1 launches the driven toy 3 of the loading part 21 in the connection port 111, the loading part 21 of the connection port 111 which is not loaded with the driven toy 3 can be moved out of the connection port 111 and the adjacent loading part 21 loaded with the driven toy 3 can be moved into the connection port 111 through the stepping control member 12, so that the launcher 1 can drive the driven toy 3 in turn and separate the driving toy 3 from the loading part 21.

Alternatively, as shown in fig. 3, the stepping control member 12 includes an operation portion, a control portion, and a moving portion, the operation portion is connected to the control portion, the control portion is connected to the moving portion, and at least a part of the moving portion is exposed in the connection port 111 and connected to the loading portion 21. When the stepping movement is to be performed, the control section is triggered by manipulating the operation section, and the control section causes the moving section to move the loading section 21. The moving part may be a stepping motor, and a moving gear capable of meshing with the loading part 21 is connected to the stepping motor. The stepping motor is connected with the electric wire of the power supply in the transmitting shell 11, and the control part is a touch switch for controlling the stepping motor. When the operation part is controlled, the operation part drives the control part to move, the control part is in contact with the electric wire, so that the stepping motor is electrified with the power supply, and the stepping motor is started to drive the movable gear to rotate. Of course, the step control member 12 may have other structures as long as the loading portion 21 can be driven to move.

In some embodiments, the driving members 13 are used to increase the kinetic energy of the driven toy 3, and the driving members 13 provide the driven toy 3 with kinetic energy. When the driven toy 3 is separated from the loading portion 21 and the launching housing 11, the driven toy 3 can travel a distance.

The driving member 13 includes a driving portion connected to the output portion and an output portion connected to a driven component of the driven toy 3. When the driven toy 3 is driven by the driving member 13, the driving portion is operated by a person, and the driving portion drives the output portion.

The driving part can be a structure which automatically drives the output part, such as a driving motor, so that the operation is convenient.

The driving part can also be a structure for manually driving the output part, such as a spring or a rocker. This increases the interactivity between people and toys. The chain launcher toy 10 may also be used in a mutual competition, for example, to control the driving part to drive the driven toy 3 for a prescribed time, and then to launch the driven toy 3, and to judge a win or a loss by the distance traveled by the driven toy 3. Thus, the interest of playing is increased.

Alternatively, the driven assembly may be a wheel assembly and an air bag assembly. If the driven assembly is in a wheel assembly structure, the output part drives the wheel assembly to rotate, and after the driven toy 3 is launched, the wheel assembly rubs with the ground to drive the driven toy 3 to move. If the driven assembly is in an air bag assembly structure, the output part is used for inflating the air bag assembly, and after the driven toy 3 is launched, the air bag assembly exhausts to push the driven toy 3 to move. Wherein the air bag assembly is filled with pressurized air and then produces a pop-up effect when launching the driven toy 3.

Alternatively, the driving member 13 is an inflator, and the driving member 13 is filled with compressed air in the ejection portion 21, and the compressed air expands to eject the driven toy 3 when the driven toy 3 is launched.

The unlocking member 14 is used for unlocking to disengage the driven toy 3 from the flip-chip portion 21. The elastic loading part 21 is provided with a clamping piece which is clamped with the driven toy 3. When the driven toy 3 is to be launched, the unlocking member 14 is operated to unlock the click member, so that the driven toy 3 is disengaged from the flip portion 21. The driven toy 3 is driven by its own power to travel while the driven toy 3 is disengaged.

Alternatively, a launcher for launching the driven toy 3 is provided in the loading portion 21, the launcher may generate an elastic force to eject the driven toy 3 out of the loading portion 21, and the launcher may be a spring. After the unlocking member 14 is unlocked, the driven toy 3 is ejected by the elastic force generated by the launching member, thereby increasing the speed of the driven toy 3 when it is launched. In one embodiment, as shown in fig. 2-3 and 6-8, the step control member 12 includes a control rod 121, and a step mechanism 123 for moving the loading portion 21, wherein the control rod 121 is movably connected to the launching housing 11 and can drive the step mechanism 123 to move. Each time the control lever 121 is operated, the control lever 121 drives the stepping mechanism 123, and the stepping mechanism 123 moves out one of the loading portions 21 in the connection port 111 and moves another adjacent loading portion 21 into the connection port 111.

Specifically, the stepping mechanism is a moving part of the stepping control member 12, and the stepping mechanism 123 is connected to the loading part 21 located in the connection port 111. The control rod 121 can control the step mechanism 123 to move, and the control rod 121 can be movably connected to the emission housing 11 in a manner of rotating or sliding on the emission housing 11.

When the control rod 121 is operated, the control rod 121 triggers the stepping mechanism 123, and after the stepping mechanism 123 is triggered, the stepping mechanism 123 drives the loading part 21 to move, so that the loading part 21 in the connection port 111 is moved out of the connection port 111, and the next loading part 21 is moved into the connection port 111. The stepping mechanism 123 is controlled by the control rod 121, so that the interactivity of the toy is improved, and the playing pleasure is increased.

Alternatively, the stepping mechanism 123 is a driving motor, the driving motor is connected to the loading unit 21 through a gear, and the control rod 121 is a control switch for controlling the driving motor to start and stop. When the control lever 121 is operated to start the driving motor, the driving motor drives the gear to rotate, and the gear drives the loading portion 21 to move. Of course, the step structure 123 may be another structure as long as it can be triggered by the control rod 121 and drives the loading portion 21 to move.

In one embodiment, as shown in fig. 2-3 and 6-8, the step mechanism 123 includes a drive member and a step output member for moving the loading portion 21. The transmission member is connected to a step output member, and the step output member is connected to the loading portion 21 located in the connection port 111. Each time the control lever 121 is operated, the control lever 121 triggers the transmission member to output a step output member, which moves out one of the loading portions 21 of the connection port 111 and moves the other adjacent loading portion 21 into the connection port 111.

Specifically, the stepping mechanism 123 is composed of a transmission member and a stepping output member. The transmission member is connected between the control lever 121 and the step output member, and the step output member is connected to the loading portion 21. The transmission part can drive the stepping output part to move, so that the stepping output part drives the elastic loading part 21 to move. So set up, when driving medium or step-by-step output spare damaged, only need change one of them, reduced cost of maintenance.

Optionally, the transmission member is a driving motor, and the step output member is a gear or a conveyor belt device, and the step output member is taken as a conveyor belt device for example. The conveyor belt device has a driving roller, a driven roller and a conveyor belt, the driving roller and the driven roller are rotatably connected in the launching shell 11, one end of the conveyor belt is sleeved on the driving roller, the other end of the conveyor belt is sleeved on the driven roller, and at least part of the conveyor belt is exposed in the connecting port 111 and is contacted with the elastic loading part 21.

A motor shaft of the driving motor is connected with the driving roller, when the driving motor is started, the driving motor drives the driving roller to rotate, the driving roller drives the conveying belt, and friction force is generated between the conveying belt and the loading portion 21 so as to drive the loading portion 21 to move.

In one embodiment, as shown in fig. 2-3 and 6-8, the transmission member is a transmission toothed bar 122, and the transmission toothed bar 122 is slidably coupled within the firing housing 11 and is in meshing engagement with the step output member. Each time the control lever 121 is operated, the control lever 121 pushes the transmission rack 122, and the transmission rack 122 drives the stepping output member to output.

Specifically, the transmission rack 122 is slidably connected in the launching housing 11 and can slide in the up-down direction, which can be realized by providing a slide groove or a slide rail in the launching housing 11. The driving rack 122 is provided with teeth, and the step output member is engaged with the teeth of the driving rack 122.

The control lever 121 is rotatably coupled to the transmitting housing 11 and is positioned above the control lever 121. When the operation lever 121 is rotated downward, the control lever 121 comes into contact with the transmission rack 122 and pushes the transmission rack 122 to move downward. When the transmission rack bar 122 moves downwards, the stepping output piece is driven to move. The driving rack 122 has a simple structure and is not easily damaged. The transmission rack bar 122 is connected with the stepping output piece in a meshing mode, so that the connection between the transmission rack bar and the stepping output piece is firmer, and the transmission effect is better.

Alternatively, as shown in fig. 6, a return spring 125 is disposed on the transmission rack 122, and when the control rod 121 swings upward, the return spring 125 pushes the transmission rack 122 to return. In one embodiment, as shown in fig. 2, 4 and 6-7, the step output member includes a connecting toothed bar 1231, a driving wheel 1232 and two driven wheels 1233 engaged with the driving wheel 1232. The connecting rack 1231 is rotatably connected to the launching housing 11, and the driving rack 122 drives the connecting rack 1231 to rotate. The driving pulley 1232 is connected to the connecting rack 1231, and the driven pulley 1233 is connected to the loading unit 21. When the lever 121 is operated, the driven pulley 1233 moves the loading portion 21 of the connection port 111.

Specifically, the connecting rack 1231, the driving pulley 1232, and the driven pulley 1233 are rotatably connected within the transmitting housing 11. The driving wheel 1232 is fitted over the connecting rack 1231, the driven wheel 1233 is located on one side of the driving wheel 1232 and engaged with the driving wheel 1232, and the elastic portion 21 can be connected to the driven wheel 1233.

The driving rack 122 extends vertically and the connecting rack 1231 extends horizontally. The transmission rack bar 122 is provided with transmission teeth, the connecting rack bar 1231 is provided with connecting teeth, and the connecting teeth are meshed with the transmission teeth.

When the elastic part 21 needs to be replaced, the control rod 121 is operated to swing downwards, the control rod 121 pushes the transmission toothed bar 122 to slide downwards, and then the transmission toothed bar 122 drives the connecting toothed bar 1231 to rotate. After the connecting rack 1231 rotates, the driving wheel 1232 is driven to rotate, the driving wheel 1232 drives the two driven wheels 1233 to rotate, and then the driven wheels 1233 drive the elastic part 21 to move.

Optionally, an output roller is connected to the driven wheel 1233, and the loading portion 21 located in the connection port 111 is in contact with the output roller. When the driven wheel 1233 drives the output roller to rotate, the output roller drives the loading portion 21 to move. Preferably, a layer of anti-slip glue is provided on the surface of the output drum, thus increasing the friction with the loading portion 21.

In one embodiment, as shown in fig. 2, 4 and 6-7, the loading portion 21 is provided with a rack 22, and the driven wheel is engaged with the rack 22.

Specifically, a rack 22 is provided on the side of the loading portion 21 facing the driven wheel 1233. At least a portion of the driven pulley 1233 extends into the connection port 111 and engages the rack 22 on the loading portion 21. By the arrangement, the elastic part 21 in the connecting port 111 is firmly connected with the driven wheel 1233, and the transmission efficiency is improved.

In one embodiment, as shown in fig. 2, 4 and 6-7, the step output member includes two driven wheels 1233, and the two driven wheels 1233 are respectively disposed at two sides of the driving wheel 1232. When the lever 121 is operated, the driven pulley 1233 moves the loading portion 21 of the connection port 111 to the outside of the connection port 111, and engages with the rack 22 of the other adjacent loading portion 21.

Specifically, two driven wheels 1233 are respectively located on the left and right sides of the driving wheel 1232, and are engaged with the driving wheel 1232. At least part of the two driven wheels 1233 extends into the connection port 111 and engages with the rack 22 of the loading portion 21.

When the elastic part 21 needs to be replaced, the control rod 121 is operated to swing downwards, the control rod 121 pushes the transmission toothed bar 122 to slide downwards, and then the transmission toothed bar 122 drives the connecting toothed bar 1231 to rotate. After the connecting rack 1231 rotates, the driving wheel 1232 is driven to rotate, the driving wheel 1232 drives the two driven wheels 1233 to rotate, and then the driven wheels 1233 drive the elastic part 21 to move.

In the process that the driven wheels 1233 drive the elastic loading portions 21 to move, the two driven wheels 1233 firstly move the elastic loading portions 21 in the connecting port 111 to the outer side of the connecting port 111, and then one driven wheel 1233 is meshed with the rack 22 of the other elastic loading portion 21. Then, the two driven pulleys 1233 continue to rotate, and after the loading portion 21 in the connection port 111 is completely moved out of the connection port 111, the adjacent other loading portion 21 enters the connection port 111.

The driven wheel 1233 can be engaged with the rack 22 to be connected more firmly, so that the magazine 21 in the connection port 111 can be replaced stably. The whole process of replacing the elastic loading part 21 is realized by adopting a purely mechanical structure and is not easy to damage.

Optionally, the step control member 12 includes two step output members spaced apart in the up-down direction, and the transmission gear rod 122 has two transmission gear portions spaced apart from each other. One rack 22 is provided on each of upper and lower sides of the loading portion 21, wherein the rack 22 on the upper side is engaged with the driven pulley 1233 of the stepping output member located above, and the rack 22 on the lower side is engaged with the driven pulley 1233 of the stepping output member located below.

Alternatively, as shown in fig. 7, the stepping mechanism 123 is provided with a mechanism housing 1234 in which a driving wheel 1232 is slidable, and an elastic member 1235 that is in contact with the driving wheel 1232 is provided in the mechanism housing 1234. The driving wheel 1232 is engaged with the connecting toothed bar 1231 through one-way helical teeth. In the step operation, the driving rack 122 drives the connecting rack 1231 to rotate in the forward direction. When the driving rack 122 is pushed by the return spring 125 to move upward and return, the connecting rack 1231 is driven by the driving rack 122 to rotate reversely. Since the connecting toothed bar 1231 is engaged with the driving wheel 1232 through the one-way helical teeth, when the connecting toothed bar 1231 rotates in the reverse direction, the connecting toothed bar 1231 is separated from the driving wheel 1232, and pushes the driving wheel 1232. The driving wheel 1232 slides forward in the mechanism housing 1234 and presses the elastic member 1235. Thus, the driving gear 1232 and the driven gear 1233 are not reversely rotated in the reset process of the transmission gear 122. When the driving rack 122 moves to the initial position, the elastic member 1235 pushes the driving wheel 1232 to re-engage with the connecting rack 1231.

In one embodiment, as shown in fig. 2-3 and 8, the step control 12 includes a positioning structure 124, and the positioning structure 124 includes a positioning rod 1241. The positioning rod 1241 is telescopically connected at the connection port 111. The elastic loading part 21 is correspondingly provided with a positioning groove 215, and when the positioning rod 1241 extends out of the connecting port 111, the positioning rod 1241 is connected with the positioning groove 215 of the elastic loading part 21 positioned in the connecting port 111; each time the control lever 121 is operated, the positioning rod 1241 is separated from the positioning groove 215 of the loading portion 21 in the connection port 111 and connected to the positioning groove 215 of the loading portion 21 which enters the connection port 111 next.

Specifically, the positioning rod 1241 extends vertically, and is slidable in the up-down direction within the launching housing 11. When the control lever 121 is operated to swing downward, the control lever 121 drives the positioning rod 1241 to slide upward, and the positioning rod 1241 retracts into the launching housing 11, so that the positioning rod 1241 is separated from the positioning groove 215 of the loading portion 21 located in the connection port 111, and the driven wheel 1233 can drive the loading portion 21 to move. When the control lever 121 swings upward, the positioning rod 1241 slides downward and protrudes into the connection port 111, so that the positioning rod 1241 is connected to the positioning groove 215 of the loading portion 21 in the connection port 111, and the loading portion 21 is fixed in the connection port 111.

Optionally, as shown in fig. 8, the positioning structure 124 further includes a swing rod 1242, the swing rod 1242 is rotatably connected in the transmitting housing 11, a first end of the swing rod 1242 can be in contact with the control rod 121, and a second end of the swing rod 1242 can be in contact with the positioning rod 1241. When the control rod 121 moves downward, the control rod 121 presses the first end of the swing rod 1242 downward, and the swing rod 1242 swings upward, so that the second end of the swing rod 1242 is lifted upward, thereby driving the positioning rod 1241 to move upward.

Optionally, as shown in fig. 8, the positioning structure 124 further includes a telescopic spring 1243, and the telescopic spring 1243 is located above the positioning rod 1241. When the positioning rod 1241 moves upward, the expansion spring 1243 is pressed, and the expansion spring 1243 is compressed. When the control lever 121 does not apply a force to the detent lever 1241, the extension spring 1243 extends to push the detent lever 1241 to move downward.

In one embodiment, as shown in fig. 2-3 and 9, the positioning structure 124 further includes an elastic fastener 1244, the connection opening 111 is provided with a mounting groove 112 on an opposite side of the positioning rod 1241, and the elastic fastener 1244 is disposed in the mounting groove 112 and partially extends into the connection opening 111. The elastic clamping piece 1244 is added to make the positioning of the elastic chain 2 on the connection port 111 more firm.

The elastic portion 21 is correspondingly provided with a fastening groove 216, when the elastic portion 21 is located in the connection port 111, the protruding portion of the elastic fastening member 1244 extends into the fastening groove 216, and when the elastic portion 21 moves relative to the connection port 111, the elastic fastening member 1244 is separated from the fastening groove 216 and is compressed and contracted.

Specifically, the positioning structure 124 further includes an elastic fastening member 1244 cooperating with the positioning rod 1241 to position the elastic loading portion 21, and the elastic fastening member 1244 is disposed opposite to the positioning rod 1241. In this example, the positioning rod 1241 is located above the elastic trim 1244.

The emission housing 11 is provided with a mounting groove 112 communicating with the connection port 111, an elastic clamping piece 1244 is connected in the mounting groove 112, and at least a part of the elastic clamping piece 1244 extends into the connection port 111.

The elastic trim 1244 has elasticity, which can be extended and contracted. The elastic portion 21 is provided with a locking groove 216 having an opening facing the elastic locking piece 1244, and when the elastic portion 21 is located in the connection port 111, the elastic locking piece 1244 is in an extended state and locked in the locking groove 216. When the loading portion 21 slides in the attachment port 111, the catching groove 216 is misaligned with respect to the mounting groove 112. At this time, the elastic clamping piece 1244 is pressed by the elastic part 21, and the elastic clamping piece 1244 is in a contracted state and separated from the clamping groove 216. The elastic clamping member 1244 assists the positioning rod 1241 in positioning the loading portion 21, so that the loading portion 21 can be firmly fixed in the connection port 111.

Optionally, the elastic fastener 1244 is an elastic rubber block, so that it is convenient to manufacture.

Alternatively, the elastic trim 1244 includes a connection spring and a latch for cooperating with the loading portion 21. The connecting spring is positioned in the mounting groove 112, the fixture block is connected with the connecting spring, and at least part of the fixture block extends into the connecting port 111. When the elastic part 21 is positioned in the connecting port 111, at least part of the latch extends into the latching groove 216. When the loading portion 21 moves out of the connection port 111, the latch is pressed by the groove wall of the latch groove 216, and the latch moves downward after being pressed, and presses the connection spring downward. When the other elastic part 21 moves into the connection port 111, the latch is aligned with the latching groove 216, and the connection spring pushes the latch to be re-engaged with the latching groove 216.

In one embodiment, as shown in fig. 3 and 10, the driving member 13 includes an operating member, a power generating member and a driving transmission member, the operating member is connected with the power generating member, and the power generating member is connected with the driving transmission member. The operating member can touch the power generating member to generate power, and the power generating member transmits power to the driven toy 3 through the driving transmission member.

Specifically, the operating member is connected on toy housing 11, and power generation piece and driving transmission piece are connected in toy housing 11, and driving transmission piece is connected between power generation piece and driven toy 3. The operating member can trigger the power generating member to generate power, and then the driving transmission member transmits the generated power to the driven toy 3, so that the driven toy 3 has power. This arrangement provides a reliable source of power for the driven toy 3.

Optionally, the power generating component is a power motor, the operating component is a motor switch of the power motor, and a motor shaft of the power motor is connected with the driving transmission component.

Alternatively, the driving transmission member is directly connected to the driven toy 3, thus reducing power loss.

Alternatively, the driving transmission member is indirectly connected to the driven toy 3 through a transmission member.

In one embodiment, as shown in fig. 3 and 10, the operating member is a slider 131, the power generating member is a sheave 132, and the driving transmission member is a gear train 133. A slider 131 is slidably attached to the launching housing 11, the slider 131 being connected to a pull cord 134 on the sheave 132. The sheave 132 is engaged with the gear train 133, and the sheave 132 is pulled by the slider 131, so that the gear train 133 drives the driven toy 3.

Specifically, the emission housing 11 is provided with a housing slide, and the slider 131 is slidably connected to the housing slide. The sheave 132 and gear set 133 are mounted within the projectile housing. A rope 134 is wound around the rope pulley 132, and the rope 134 is connected to the slider 131. The sheave 132 is provided with gear teeth engaged with the gear set 133. When the slider 131 slides, the rope pulley 132 is pulled by the rope 134 to rotate, and the rope pulley rotates to drive the gear set 133 to rotate, thereby driving the driven toy 3.

Optionally, a reset spring is arranged on the rope pulley 132, and the reset spring can pull the pulling rope 134 to reset and wind on the rope pulley 132 again. When the pull rope 134 is reset, the slide block 131 is driven to reset. In this way, the kinetic energy of the driven toy 3 can be continuously increased by sliding the slider 131 back and forth.

In one embodiment, as shown in fig. 3-5, a driving transfer rod 211 is provided in the loading portion 21 to connect with the driven toy 3. A driving wheel 212 is connected to the driving transfer bar 211, and at least a portion of the driving wheel 212 is located in the emission housing 11 and is connected to the driving transfer member. The drive transmission member drives the driven toy 3 through the drive transfer rod 211.

Specifically, the driving transmission member is a gear set 133, and the driven toy 3 is provided with wheels and connecting gears connected to the wheels. One end of the driving transfer lever 211 is engaged with the connecting gear, and the other end is connected with a driving wheel 212, and the driving wheel 212 is inserted into the transmitting housing 11 and engaged with the gear set 133. When the gear set 133 rotates, the driving wheel 212 is driven to rotate, and the driving wheel 212 drives the connecting gear to rotate the wheel. When replacing the loading portion 21, the gear train 133 is separated from the transmission wheel 212 of the loading portion 21 located in the connection port 111 and connected with the transmission wheel 212 of the loading portion 21 that enters next into the connection port 111. So set up, when drive dowel 211 damaged, convenient maintenance and change.

Alternatively, as shown in fig. 10, the gear set 133 includes a first connection 1331, a second connection 1332, a first gear 1333 and a second gear 1334. The first coupling 1331 is engaged with the sheave 132, and one end of the second coupling 1332 is engaged with the first coupling 1331 and the other end is engaged with the first gear 1333. The first gear 1333 and the second gear 1334 are fitted over one gear shaft, and the second gear 1334 is connected to the driven toy 3. The first connecting piece 1331 and the second connecting piece 1332 are vertically arranged, and the first gear 1333 and the second gear 1334 are transversely arranged, so that the arrangement of the gear set 133 in the launching shell 11 is more reasonable, and the space is saved.

Alternatively, as shown in fig. 10, a spring member 1335 is provided above the first connection member 1331, and the first connection member 1331 is connected to the second connection member 1332 by unidirectional helical teeth. During the operation of the sliding block 131 to slide back and forth, the rope wheel 132 can drive the first connection part 1331 to rotate forward and backward. When the first coupling part 1331 is rotated in the forward direction, the second coupling part 1332 is rotated in the forward direction. When the first coupling piece 1331 is rotated reversely, since the first coupling piece 1331 and the second coupling piece 1332 are coupled by the one-way helical teeth, the first coupling piece 1331 is separated from the second coupling piece 1332 at this time and moves upward. The first coupling member 1331 moves upward to compress the spring member 1335 and the spring member 1335 compresses. When the sheave 132 rotates the first connection part 1331 again in the forward direction, the spring part 1335 pushes the first connection part 1331 to move downward and connect with the second connection part 1332 again. So configured, the second connection piece 1332 is prevented from reversely rotating following the first connection piece 1331.

In one embodiment, as shown in FIGS. 3, 6 and 10, the operating member is rotatably coupled to the transmission housing 11. When the operating member is rotated toward the stepping control member 12, the operating member triggers the stepping control member 12, and the stepping control member 12 performs stepping operation on the elastic chain 2.

Specifically, the operating element is a slider 131, the slider 131 is connected to the housing slide via a sliding shaft, and the slider 131 is rotatably connected to the sliding shaft. The slider 131 can rotate towards the step control 12. When the loading portion 21 of the connection port 111 needs to be replaced, the slider 131 is operated to rotate toward the stepping control member 12, and after the slider 131 touches the stepping control member 12, the stepping control member 12 performs stepping operation on the elastic chain 2, the loading portion 21 of the connection port 111 is moved out, and the next loading portion 21 enters the connection port 111. So set up, slider 131 can be used for controlling acceleration, can be used for controlling step-by-step operation again, has reduced the use of part, has practiced thrift manufacturing cost.

Alternatively, as shown in fig. 6 and 10, the control rod 121 is connected to the slider 131. When the slider 131 rotates, the control rod 121 is driven to push the transmission rack 122. So make overall structure compacter, the overall arrangement is more reasonable.

In one embodiment, as shown in fig. 4-5, the loading portion 21 includes a loading housing 213 for mounting the driven toy 3 and a locking member capable of locking the driven toy 3, the locking member being connected to the loading housing 213. When the locking piece locks the driven toy 3, the driving piece 13 is driven by the power of the driven toy 3 mounted on the magazine case 213. When the unlocking member 14 unlocks the locking member, the locking member releases the driven toy 3, and the driven toy 3 is separated from the magazine case 213.

Specifically, the loading section 21 is provided with a loading case 213, and the driven toy 3 is connected to the loading case 213. When the driven toy 3 is mounted on the cartridge case 213, the lock member catches the driven toy 3.

After the driven toy 3 is driven by the driving piece 13 to generate power, the unlocking piece 14 triggers the locking piece to unlock, and the locking piece is separated from the driven toy 3 after unlocking. At this time, the driven toy 3 can run under its own power, thereby disengaging the magazine case 213 and the launching case 11.

In one embodiment, as shown in fig. 4-5, the loading portion 21 further includes an ejection mechanism 214. The ejection mechanism 214 includes an ejection spring 2141 and a pushing member 2142, the ejection spring 2141 is installed in the ejection housing 213, and the pushing member 2142 is slidably connected to the ejection housing 213 and can be connected to the driven toy 3. The locking member locks the driven toy 3 by locking the push member 2142. When the pushing part 2142 is locked by the locking piece, the launching spring 2141 stores energy, and the pushing part 2142 is in contact with the launching spring 2141. When the unlocking member 14 unlocks the stopper, the pushing member 2142 is released by the locking member, the launching spring 2141 is released, and the pushing member 2142 pushes the driven toy 3 out of the cartridge case 213.

Specifically, at least part of the driven toy 3 is located in the cartridge housing 213, the launching spring 2141 and the pushing member 2142 are both located at the rear of the driven toy 3, the pushing member 2142 is slidably connected with the cartridge housing 213, and the locking member can lock the pushing member 2142. When the driven toy 3 is connected to the spring portion 21, the pushing member 2142 presses the launching spring 2141, the launching spring 2141 is compressed, elastic potential energy is generated, the driven toy 3 contacts with the pushing member 2142, and the pushing member 2142 is clamped by the locking member. When the unlocking member 14 is operated to unlock the lock member, the lock member is separated from the push member 2142. After the pushing member 2142 is out of the limit, the launching spring 2141 extends to move the pushing member 2142, the elastic potential energy is converted into the kinetic energy, the pushing member 2142 pushes the driven toy 3, and the driven toy 3 is ejected out of the cartridge case 213. So set up, make driven toy 3 produce the visual effect that pops up, richened the visual sensation when people play, but also increased driven toy 3's speed, make it farther that go.

In one embodiment, as shown in fig. 4-5, the pushing member 2142 has a protrusion 2145 thereon. The locking member includes a locking plate 2143 capable of stopping the protrusion 2145 and a push rod 2144 capable of pushing the locking plate 2143. Pushrod 2144 is slidably connected within the spring loaded housing 213 and the unlocking member 14 can trigger the pushrod 2144 to move. When the push member 2142 is locked by the locking member, the locking plate 2143 abuts against the protrusion 2145. When the unlocking member 14 is unlocked, the push rod 2144 pushes the latch plate 2143, and the latch plate 2143 is separated from the protrusion 2145.

Specifically, the locking plate 2143 is located above the pushing member 2142 and can slide up and down in the cartridge housing 213, and the locking plate 2143 is provided with an inclined hole matching with the push rod 2144. The push rod 2144 is located rearward of the latch plate 2143 and is slidable back and forth within the launching housing 11.

When the push member 2142 is locked by the locking member, the locking plate 2143 slides downward to contact the protrusion 2145, thereby stopping the push member 2142 from moving. When unlocking, the unlocking member 14 pushes the push rod 2144 to move forward, the push rod 2144 is inserted into the inclined hole, the latch plate 2143 is pushed to move upward, the latch plate 2143 moves upward to be separated from the protrusion 2145, so that the pushing member 2142 can be pushed by the launching spring 2141.

Alternatively, as shown in fig. 4 to 5, a push spring 2147 is provided above the latch plate 2143, and when the latch plate 2143 moves upward, the push spring 2147 is compressed and shortened. When the push rod 2144 is separated from the latch plate 2143, the push spring 2147 extends, pushing the latch plate 2143 to move downward.

Alternatively, as shown in fig. 3 and 11, the unlocking member 14 includes a trigger block 141, a lever 142, and an ejector rod 143. The trigger block 141 is slidably connected to the launching housing 11, the rotating rod 142 is rotatably connected to the launching housing 11, and the pushing rod 143 is slidably connected to the launching housing 11. When the unlocking is needed, the trigger block 141 is pushed to slide, the trigger block 141 pushes the rotating rod 142 to swing, and the rotating rod 142 swings and then pushes the pushing rod 143 to slide forwards. In this embodiment, the firing housing 11 is a gun model, and the trigger block 141 is a trigger of the gun model.

In one embodiment, as shown in fig. 4-5, the pusher 2142 has a resilient catch plate 2146 that engages the driven toy 3. When the push member 2142 is locked by the locking member, the locking resilient catch plate 2146 is connected to the driven toy 3. When the push member 2142 is released by the locking member, the resilient catch plate 2146 disengages from the driven toy 3.

Specifically, the pushing member 2142 has a cylindrical shape, and at least a portion of the driven toy 3 protrudes into the pushing member 2142. The pushing member 2142 has a connecting opening, and an elastic clamping plate 2146 is connected in the connecting opening. When the driven toy 3 is mounted on the loading portion 21, the pushing member 2142 is located in the loading housing 213, at least a portion of the driven toy 3 is located in the pushing member 2142, and the elastic clamping plate 2146 is pressed by the loading housing 213 to extend into the pushing member 2142, and is clamped with the driven toy 3. During the process that the pushing member 2142 pushes the driven toy 3 out of the magazine housing 213, the pushing member 2142 slides forward, and when sliding until the elastic clamping plates 2146 are exposed to the outside of the magazine housing 213, the elastic clamping plates 2146 are deformed again and moved outward through the connecting openings, thereby separating from the driven toy 3.

In summary, the present invention discloses a toy with a spring chain type launcher 10, which comprises a launcher 1 and a spring chain 2. The ammunition chain 2 is formed by connecting a plurality of ammunition parts 21 in a chain shape, and each ammunition part 21 can be connected with one driven toy 3. The launcher 1 includes a launching housing 11, a stepping control 12, a driving member 13, and an unlocking member 14. A connection port 111 is provided on the shooting case 11, and the stepping control member 12, the driving member 13, and the unlocking member 14 are provided on the shooting case 11. After the ammunition chain 2 is inserted into the connection port 111, the ammunition chain 2 can be operated by stepping the stepping control member 12, and the ammunition loading part 21 is switched to enter the connection port 111 one step by one step. The driving member 13 is capable of power-driving the driven toy 3 placed on the loading portion 21 in the connection port 111. After the driven toy 3 is driven, the unlocking member 14 unlocks the driven toy 3 on the loading portion 21 in the connection port 111 to disengage the driven toy 3 from the loading portion 21 and the launching housing 11. The driven toy 3 is driven by power to perform actions after being disengaged. After the launcher 1 of the chain launcher toy 10 releases the driven toy 3 on the loading part 21 in the connection port 111, the other loading part 21 enters the connection port 111, so that the launcher 1 can continuously launch the driven toy 3, and the continuity and the enjoyment of playing are improved. And the chain launcher toy 10 can also increase the performance of the driven toy 3 through the driving member 13. After the driven toy 3 is separated from the elastic part 21, the driven toy can perform actions under the driving of power, such as enhancing the cruising ability, performing rotation actions, performing flying actions, performing jumping actions, performing acousto-optic effects and the like, thereby improving the interest of the toy. Further because the elastic chain 2 is formed by connecting a plurality of elastic parts 21 into a chain, when playing, different numbers of elastic parts 21 can be installed according to the needs of the user, each elastic part 21 is connected with one driven toy 3, the number of the driven toys 3 is not limited by the structure of the emitter 1, the autonomy and flexibility of playing are improved, and the fun of playing is further improved.

According to the needs, the above technical schemes can be combined to achieve the best technical effect.

The foregoing is considered as illustrative only of the principles and preferred embodiments of the invention. It should be noted that, for those skilled in the art, several other modifications can be made on the basis of the principle of the present invention, and the protection scope of the present invention should be regarded.