EP2092968B1 - Toy vehicle component - Google Patents

Abstract

The component (1) has a rotating distributing device (2) for distributing a free-flowing distributing medium e.g. sand. A rotation drive (4) comprises a friction-wheel (5) that is shiftable between an operation position and a resting position of the spreader device by a shifting mechanism (21), where the friction wheel lies at a running wheel (7) of the component in the working position and is spaced apart from the running wheel at the resting position. The friction wheel is pre-stressed against the running wheel in the operating position by a pre-stressing spring (25) e.g. torsional spring.

Description

The invention relates to a toy vehicle assembly with a rotating spreader. Furthermore, the invention relates to a toy vehicle with such an assembly.

The DE 201 01 665 U1 describes a toy vehicle assembly with two swather gyros whose rotors are driven by a friction wheel drive.

For children, the game experience is particularly attractive when real-life situations can be replayed as faithfully as possible and thus imitated. This experience ensures playing with a scatter vehicle in particular.

It is an object of the present invention, a toy vehicle assembly of the type mentioned in such a way that a real scattering vehicle is modeled realistic, the assembly should be easy and safe playable on the one hand and on the other hand should be inexpensive to manufacture.

This object is achieved by a toy vehicle assembly having the features specified in claim 1.

According to the invention, it has been recognized that a drive for the scattering device can be derived from an impeller of the assembly, which rotates when driving from it anyway. An independent driving of the assembly drive the spreader deleted. The Umstellmechanik Ensures that the assembly can be moved even without operation of the spreader.

A bias of the friction wheel according to claim 2 ensures that this follow in particular a vertical spring movement of the impeller can. Regardless of a spring movement of the impeller, therefore, an interaction of the friction wheel with the impeller to drive the spreader is maintained in the operating position of the friction wheel.

A torsion spring according to claim 3 is an inexpensive embodiment of the biasing spring. The torsion spring may have a cross-section. This serves in particular to increase the flexural rigidity of the torsion spring.

A changeover lever according to claim 4 ensures that no undesired changeover of the Umstellmechanik can take place. The latching device can be realized for example via a slotted guide, wherein in each case at the two ends of the backdrop-guided movement a dead center position is still overcome by the switching lever. The Umstellhebel may have a jacket wall with a truss structure, resulting in a high torsional stiffness of the changeover lever. Even with greater application of force is then ensured that the shift lever undergoes no torsion, which increases the precision of the Umstellvorgangs.

A slotted guide according to claim 5 ensures a safe and at the same time structurally less complex operative connection of the change lever with the friction wheel.

The same applies to a connection by means of a transmission lever according to claim 6.

A deflection gear according to claim 7 ensures a safe power transmission between the friction wheel and the spreader of the spreader. Preferably, the reversing gear is designed as a transmission gear, so a scattering device distributing the scattering medium rotates faster than the friction wheel.

An arrangement according to claim 8 ensures that a rotational movement of the screw conveyor in the container is not unduly impeded or inhibited by the stray medium present in the container between the outer wall of the screw conveyor and the container sidewalls.

A plastic embodiment according to claims 9 and / or 10 allows a cost-effective production of the toy vehicle assembly. In particular, the friction wheel can be made of plastic.

The advantages of a toy vehicle according to claim 11 correspond to those which have already been discussed above with reference to the toy vehicle assembly according to claims 1 to 10.

Fig. 1

perspektivisch eine Spielfahrzeug-Baugruppe mit einer umstellbaren Streuvorrichtung in einer Ruhestellung von dieser;

Fig. 2

die Spielfahrzeug-Baugruppe nach Fig. 1 in einer Zwischenstellung einer Umstellmechanik zum Umstellen der Streuvorrichtung;

Fig. 3

die Spielfahrzeug-Baugruppe nach Fig. 1 in einer Betriebsstellung der Streuvorrichtung;

Fig. 4

die Umstellmechanik der Spielfahrzeug-Baugruppe in der Ruhestel- lung, wobei Führungskomponenten im Bereich einer Hebelwelle ei- nes Umstellhebels der Umstellmechanik weggelassen sind;

Fig. 5

in einer zu Fig. 4 ähnlichen Darstellung die Umstellmechanik in der Betriebsstellung; und

Fig. 6

eine Aufsicht auf einen Behälter für Streumedium der Spielfahr- zeug-Baugruppe mit einer im Behälter laufenden Förderschnecke.

An embodiment of the invention will be explained in more detail with reference to the drawing. In this show:

Fig. 1

in perspective, a toy vehicle assembly with a convertible spreader in a rest position of this;

Fig. 2

the toy vehicle assembly after Fig. 1 in an intermediate position of a Umstellmechanik for switching the spreader;

Fig. 3

the toy vehicle assembly after Fig. 1 in an operating position of the spreader;

Fig. 4

the Umstellmechanik the toy vehicle assembly in the rest position, wherein guide components are omitted in the region of a lever shaft of a Umhebhebels the Umstellmechanik;

Fig. 5

in one too Fig. 4 similar representation of the Umstellmechanik in the operating position; and

Fig. 6

a view of a container for scattering medium of the toy vehicle assembly with a running in the container screw conveyor.

A toy vehicle assembly 1 is for example part of a game truck or a trailer of this. The assembly 1 has a rotating spreader 2 with a disc spreader 3 in the manner of a spreader, as used in "real" gritting vehicles. The scattering device 2 is used to scatter a free-flowing scattering medium, not shown in the drawing, for example, of sand or granules.

In order to set the spatula 3 of the spreader 2 in rotation, the assembly 1 has a rotary drive 4 for the spreader 2. The rotary drive 4 has a friction wheel 5 with a fluted to increase the friction and slightly conical outward, so the vehicle exterior, tapered shell wall 6. In one in the Fig. 1 shown rest position, the friction wheel 5 is spaced from an impeller 7 of the assembly 1. In one in the Fig. 3 shown operating position is the friction wheel 5 frictionally to drive the spreader 2 on the impeller 7 at.

A Reibradwelle 8 is rotatably mounted in a friction wheel 9. The friction wheel carrier 9 in turn is about a horizontal and perpendicular to the longitudinal axis of the Reibradwelle 8 extending pivot axis S (see. Fig. 4 ) hingedly connected to a frame 10 of the assembly 1.

On the friction wheel 5 opposite end of the Reibradwelle 8, a gear 11 is arranged, which meshes with a gear 12, which in turn rotatably connected to a worm shaft 13 of a screw conveyor 14 of the spreader 2 is connected. The number of teeth of the gear 11 corresponds approximately to the number of teeth of the gear 12. The screw conveyor 14 has to increase its bending stiffness a cross-section. The screw conveyor 14 is mounted about an axis which is parallel to the direction of travel of the assembly 1, in a container 15 for the scattering medium. Opposite and parallel to the worm shaft 13 extending side walls 16 of the container 15 have to each other a distance A, which is significantly larger than the outer diameter D of the screw conveyor 14 (see. Fig. 6 ).

On the gear 12 opposite end of the worm shaft 13 is rotatably connected to this another gear 17. The latter meshes with a gear 18 which is rotatably connected to a plate shaft 19 which is rotatably mounted about a vertical axis. The gear transmission via the gears 11, 12 and 17 and 18 represents a deflection gear, via which the friction wheel 5 is connected to the disc spreader 3 of the spreader 2. The number of teeth of the gear 17 corresponds to the number of teeth of the gear 18. The gear 12 is larger than the gear 17 and has significantly more teeth than this. Accordingly, the worm shaft 13 with the two gears 12, 17 serves as a translation element. The Tellerstreuer 3 rotates at a significantly higher speed than the friction wheel 5th At the Gear 18 opposite end of the plate shaft 19 is rotatably connected to the disc spreader 3. The plate shaft 19 is mounted in a conically tapered to the plate spreader 3 chute 20, which communicates with the container 15 in conveying connection for the scattering medium.

The friction wheel 5 is switchable between the rest position and the operating position via a Umstellmechanik 21. The latter has a hand-operated change lever 22 which is pivotally mounted on the frame 10 and can be fixed by a latching device in two lever positions, which in the Fig. 1 and 2 are shown and the rest position and the operating position of the friction wheel 5 are assigned.

About a slide guide with a crank lever 23 and a link 24 is the change lever 22 with a biasing spring 25 in rotary joint. The biasing spring 25 is designed as a torsion spring and serves to bias the friction wheel 5 against the impeller 7 in the operating position. The torsion spring 25 has a cross-section. The torsion spring 25 is rotatably connected to the gate 24. The longitudinal axis of the torsion spring 25 extends horizontally and transversely to the direction of travel of the assembly 1. The torsion spring 25 is pivotally mounted on the frame 10 for twisting and twisting about its longitudinal axis. The gate 24 opposite end of the biasing spring 25 is rotatably connected to a transmission lever 26, whose spaced from the biasing spring 25 end is hinged to the friction wheel 9.

Fig. 2 shows the Umstellmechanik 21 of the assembly 1 in an intermediate position between the rest position Fig. 1 and the operating position Fig. 3 , In this intermediate position, the friction wheel 5 is located on the impeller. 7 without that the friction wheel 5 is biased against the impeller 7 via the biasing spring 25.

Of the Fig. 3 a twist of the biasing spring 25 can be seen. This torsion provides the bias of the friction wheel 5 against the impeller. 7

The scattering device 2 of the assembly 1 can be operated as follows. When the user the change lever 22 from the rest position to Fig. 1 into the operating position Fig. 3 surrounded, the friction wheel 5 is pressed against the impeller 7 and biased against this via the slotted guide 23, 24, the biasing spring 25 and the changeover lever 26. The friction wheel 5 is then frictionally engaged with the impeller 7 in operative connection. A rotation of the impeller 7 while driving the assembly 1 is transmitted in a rotation of the friction wheel 5 and thus on the reversing gear in a rotation of the screw conveyor 14 and the disc spreader 3. In the container 15 located scattering medium is conveyed by the screw conveyor 14 to the chute 20 and distributed over the Tellerstreuer 3 on a roadway behind the module 1. Since the side walls of the container 15 to each other have a distance A, which is significantly larger than the outer diameter D of the screw conveyor 14, is prevented that between the outer periphery of the screw conveyor 14 and the side walls 16 of the container 15 present scattering medium, the rotational movement of the screw conveyor 14 excessively inhibits ,

Due to the bias of the torsion spring 25 ensures that the friction wheel 5 remains in the operating position its frictional connection with the impeller 7 even when the impeller 7 on or springs, for example, when the impeller 7 drives over an obstacle such as a curb.

The spreader 2 is made entirely of plastic. In particular, the Umstellmechanik 21 is completely made of plastic mechanics. The friction wheel 5 is made of plastic.

Fig. 4 shows the Umstellmechanik 21 more in detail. In this illustration, guide components for a lever shaft 27 of the shift lever 22 are omitted, so that the shape of the lever shaft 27 is visible. A jacket wall of the lever shaft 27 has a plurality of recesses 28, so that the lever shaft 27 receives a kind of truss structure. This truss structure causes the lever shaft 27 undergoes virtually no torsion even with stronger application of force. The recesses 28 may be shaped so that they form together with corresponding counter-bodies of the guide means for the lever shaft 27, the latching device for fixing the lever shaft 27 on the one hand in the operating position and on the other hand in the detent position of the friction wheel.

In the illustrated embodiment, however, not the truss structure of the lifting shaft 27 is responsible for the fact that the change lever is secured on the one hand in the operating position and on the other hand in the locking position, but the slide guide with the crank lever 23 and the gate 24. This slotted guide is designed so that briefly before reaching the one hand, the operating position and on the other hand, the locking position of the change lever 22 each overcomes a dead center, so that the torsion spring 25 ensures the fixing of the shift lever 22 with the slide guide beyond this respective dead center.

Claims (11)

1. Toy vehicle assembly (1)

   - with a rotating dispersing device (2) for dispersing a free-flowing dispersing medium,

   - a rotation drive (4) for the dispersing device (2),

   - wherein the rotation drive (4) comprises:

   -- a friction wheel (5) which can be shifted by a shifting mechanism (21) between

   -- an operating position of the dispersing device (2), in which the friction wheel (5) rests with frictional grip against a running wheel (7) of the toy vehicle assembly (1), and

   -- and a position of rest of the dispersing device (2), in which the friction wheel (5) is spaced apart from the running wheel (7).
2. Assembly according to claim 1, characterised in that the friction wheel (5) is biased in the operating position by means of a biasing spring (25) against the running wheel (7).
3. Assembly according to claim 2, characterised in that the biasing spring (25) is in the form of a torsion spring.
4. Assembly according to one of claims 1 to 3, characterised in that a shifting lever (22) of the shifting mechanism (21) can be fixed by a locking device in two positions, which are assigned to the operating position and the locked position of the friction wheel (5).
5. Assembly according to one of claims 1 to 4, characterised in that a or the shifting lever (22) is connected to a part (25, 26) of the shifting mechanism (21) assigned to the friction wheel (5) by means of a link guide (23, 24).
6. Assembly according to one of claims 1 to 5, characterised in that a support (9) of the friction wheel (5) is connected by articulation to a frame (10) of the assembly (1), wherein a transfer lever (26) of the shifting mechanism (21) is articulated onto the support (9).
7. Assembly according to one of claims 1 to 6, characterised in that the friction wheel (5) is connected via a corner gear (8, 11, 12, 13, 17, 18, 19) to a disperser (3) of the dispersing device (2).
8. Assembly according to one of claims 1 to 7, characterised in that the dispersing device (2) comprises a screw conveyor (14), which runs in a container (15) for dispersing medium, wherein the side walls (16) of the container (15) are spaced apart by a distance which is significantly greater than the external diameter of the screw conveyor (14).
9. Assembly according to one of claims 1 to 8, characterised in that the dispersing device (2) is made of plastic.
10. Assembly according to one of claims 1 to 9, characterised in that the shifting mechanism (21) is made of plastic.
11. Toy vehicle with an assembly according to one of claims 1 to 10.

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