DE2825610A1 - Motor driven toy with solar cell attachment - has solar cells attached to inclined surface behind light collecting lens - Google Patents

Abstract

The toy model has a drive housing for a motor, possibly connected to gearing. At least one solar cell with an electric connection for the motor is located on the housing (1). The solar cell or cells (2) are attached to an inclined surface which forms an angle of 30 degrees with the horizontal and which incorporates a mirror of funnel or curved shape and attached to a hollow element. A lens to collect the rays of light is positioned in front of the solar cell or cells and is made as a Fresnel lens. The position of the solar cell or cells can be adjusted relative to the drive housing and/or may be lined up with a light source.

Description

Model toy with drive housing.

The invention relates to toys and, more particularly, to toys Toys that have moving parts or are movable as a whole. Included the invention deals with the design of the associated drive, wherein The aim is to replace the previous batteries or the supply for this drive draw energy sources from an electrical mains voltage source via wires, which are not mechanically or otherwise connected to the toy.

Accordingly, toys should be created, their movable Parts rotated, swiveled or otherwise moved with the help of an electric drive without the need for an electric battery or a connection to the Mains voltage is required and this is to be achieved by using toy models the rotating or moving Part with the help of one of one Solar cell powered motor or drive can be driven.

Toys should also be created that can move around, whereby a solar cell is used to drive the motor. In particular can be achieved that as much energy as possible hits the solar cells, namely regardless of the place and place where the moving toy is with respect to the light source or the sun.

Solutions to the aforementioned problems can be found in the appendix Claims.

The invention relates in particular to a drive housing, in which an electric motor with output shaft possibly in connection with a Gearbox is housed, which is designed for a relatively small performance are in order to be able to adhere to the small dimensions of the motor, housing and the like. That Drive housing can be associated with any toy, which a wheel, a shaft, an eccentric, a lever or the like. Contains.

The drive housing can be made up of individual parts as a building block Composable toys and other elements as you wish be put together.

According to the invention, at least one outer surface is on the drive housing arranged a solar cell electrically connected to the motor.

Further advantageous configurations of the drive housing according to FIG Invention emerge from the claims.

According to a preferred embodiment of the invention, the solar cells inclined with respect to the base of the drive housing or on a curved surface arranged so that an optimal alignment of the solar cells the sun is possible, specifically for the area of Central Europe, the solar cells have to the horizontal an inclination of about 300. They can too Solar cells can be arranged adjustable on the drive housing, so that a time of day Adaptation to the position of the sun or to another moving light source is possible.

To enlarge the collecting area for the sun's rays can after According to a preferred embodiment, a mirror is arranged around the solar cells be. A light collector can be used to increase the intensity of the incident light rays be provided above the solar cells.

In order to direct such rays of light onto the solar cells, which are in a Angle would impinge on the surface of the solar cells, at which a total reflection takes place, a multitude of prismatic shapes can appear on the surface of the solar cells or lenticular protrusions. With the help of these protrusions become those Rays of light that are totally reflected in the direction of a flat surface broken on the solar cells.

The solar cell itself can be designed in the form of an individual component so that these can be used individually or together with a large number of other cells at random Place on the drive housing with the help of known fasteners can / can.

The present invention also relates to the use of a Drive powered by a solar cell on a wide variety of toys. A mill, a radar tower, a conveyor belt and a lifting ladder have been described.

Serves as a preferred material for toys according to the invention Wood, preferably in the form of panels with a thickness of a few millimeters, which consist of balsa or abachi. Here, the outlines can be applied to such a plate the required individual parts of the toy models drawn and by means of be punched out using a suitable tool. After lifting out the punched Parts of these can be joined together by gluing or the like, whereby he is introductory Drive described attached to any suitable location on the toy model can be.

Advantageous embodiments can be found in the following description and the corresponding claims.

The invention is illustrated below with reference to the drawing, for example explained.

Fig. 1 shows a perspective view of a drive housing according to the invention.

FIG. 2 shows a side view of two drive housings according to FIG Invention, which are arranged side by side.

3 to 5 show side views of various embodiments of drive housings according to the invention.

6 and 7 show the spatial arrangement of the motors in one Drive housing according to the invention.

8 shows an exploded view of a toy model of a Mill.

9 shows an exploded view of a toy model of a Radar tower.

Fig. 10 shows an exploded view of a toy model of a Conveyor belt.

Fig. 11 shows the essential drive parts of a toy model a lifting ladder.

Fig. 12 shows an electric solar cell circuit according to the invention.

1 shows an essentially cube-shaped drive housing 1, which is cut off at an angle, with solar cells 2 are located. The solar cells are made of an inclined or slightly curved Mirror 3 surrounded so that light hitting the mirror in the direction of is deflected onto the solar cells 2.

3 to 5 show essentially cube-shaped housing, wherein the solar cells 2 are attached to a suitable location on the housing, the location the solar cells are selected in the way that is most favorable for the associated toy model is.

In Figs. 6 and 7, motors are schematically within the housing 4 and 5, with most of the motor housing within the drive housing 1 is arranged and only the output shaft protrudes. It can be seen that the motor can be attached to any point of the housing, so that the cheapest Drive connection between the output shaft of the motor and the one to be driven Sharing is made possible.

Of course, more than one motor, in particular two Motors 4 and 5 are housed within a drive housing 1, if this is required for some reason, this can be done by these motors together from the solar cells 2 or from separate solar cells 2 are fed.

In Fig. 2, two drive housings 1 are attached to each other so that d5e associated solar cells 42 and 43 with respect to the center between the two Solar cells are arranged in ascending order. Does the incoming light have the direction of the arrow 6, the solar cell 42 is fully hit by the light, while no The light beam hits the solar cell 43. The opposite applies to the direction of incidence of light 8 that the solar cell 43 is fully hit while no light beam hits the solar cell 42 falls. Due to this fact, the two solar cells 42 and 43 can be used are to align both solar cells 42 and 43 so that the same amount on both Light falls when the light is in the direction of arrow 7 on the solar cells 42 and 43 falls or the solar cells 42 and 43 are placed so that the incident Light takes the direction of arrow 7.

The two solar cells 42 and 43 are expediently switched in such a way that as shown in FIG. In other words, the two solar cells, which are shown as DC voltage batteries in FIG. 12, connected to one another. There is a motor 44 or between the connections of the two solar cells another electric drive, a relay or the like. This motor 44 by a compensating current from one or the other solar cell 42 or 43 be fed. For example, if the solar cell 42 is hit by the incident light, for example, the motor 44 rotates to the left, whereas the motor executes a clockwise rotation when the solar cell 43 is struck by the incident light will.

If you now connect the motor 44 with an actuator, which the position of the solar cells 42 and 43 can change with respect to the incident light, so can be achieved due to the circuit of FIG. 12 that the motor so long Current receives until it aligns the solar cells 42 and 43 so that the light, like shown in Fig. 2 by the arrow 7, impinges on the solar cells.

One uses a pair of such solar cells 42 and 43 for the adjustment in one direction and another pair for adjustment in the first mentioned direction perpendicular direction, so these two pairs of solar cells can be in each other perpendicular direction can be spatially aligned on a moving light source. If several other solar cells are used at the same time in connection with the aforementioned In this way it can be ensured that solar cells are paired these other solar cells always in the optimal alignment with respect to the light source are arranged.

The aforementioned effect can be enhanced by the fact that between A relatively narrow partition 45 is arranged between the two solar cells 42 and 43 is, so that even with small deviations in the position of the solar cells with respect to the arrow 7 a shadow falls on the remote solar cell, so that the servomotor 44 is rotated accordingly.

In Fig. 8 a toy model of a mill is shown, this Mill is connected to a drive housing 1, which is located on the upper part of the Mill housing is attached. The drive housing 1 is only schematic reproduced, in particular the motor and the solar cells have been omitted, However, it is essential that the shaft protruding from the drive housing 1 with the Mill shaft is connected.

Fig. 9 shows a toy model of a radar tower, with the radar antenna is rotatably mounted and the drive for rotating the radar antenna from one Drive housing 1 is derived, which in turn is only shown schematically is.

A pinion 10 is located on the output shaft of the motor six projections 11. This pinion 10 is in rotational engagement with a pin wheel 12 arranged. This is essentially a disk from which in a distance corresponding pins protrude parallel to the axis of rotation of the disc. On the other end of the shaft of the pin wheel 12 is a pinion 15, which essentially the pinion 10 is formed accordingly. However, four are of the total six evenly spaced protrusions have been removed, allowing for forwarding the rotational movement of the pin wheel 12 through the pinion 15 only has two projections be available. Above and below the pin wheel 15 there are two further pinions 13 and 14, which correspond to pinion 10.

Both pinions 13 and 14 are rigidly connected to the shaft of the radar antenna.

By rotating the motor, not shown, a rotary movement is from Pinion 10 translated to pin wheel 12 and transferred to pinion 15. The pinion 15 is initially in rotational engagement, for example, with the pinion 14 and rotates it by two parts of its circumference in a first direction. Then the two arrive Projections of the pinion 15 engage with the pinion 13 and rotate it accordingly by two parts of its circumference. This results in a back and forth for the radar antenna forward pivoting movement around part of its circumference, so that the impression is given is that the radar antenna is aimed at a specific distant target.

Of course, that instead of four projections fewer projections are removed from the pinion 15, a different type of pivoting movement generated by the radar antenna. Not shown is a lock that prevents that the radar antenna performs more than the desired rotational movement, which is easy It may be the case that the pinion 15 causes excessive movement on the radar antenna is exercised.

In Fig. 10 is a model of a conveyor belt is shown, which is also driven with the help of a solar drive. The drive housing 1 is only shown schematically, on the output shaft of the corresponding Motor is a drive pinion 16, which with a crank 17 in rotational engagement is arranged. The crank 17 is mounted on a shaft, which in turn is eccentric is stored in parts 19 and 20. These parts 19 and 20 are in turn on one Plate 21 attached and can when rotating the shaft of the crank part 17 after move up and down so that consequently the plate 21 is raised and lowered will.

There is also a pinion on the shaft of the crank part 17 18 that in turn is arranged in rotational engagement with a pinion 22. The pinion 22 is on one Shaft 23 attached, which on the opposite End of an eccentric 24 carries. This eccentric is in engagement with a lever 25, so that depending on the radial extent of the eccentric 24, the lever 25 is raised and is lowered. On the other hand, the plate 21 rests on the lever 25 so that by rotation of the pinion 22 or the shaft 23 and the eccentric 24 one up and down directed movement on the plate 21 is transmitted. Overall is through rotation the crank 17 raised the plate 21 at the front end when it was at the rear end is lowered and the plate 21 is raised at the rear end when it is at the front The end is lowered.

If you now place a box-shaped object on a guide screw 26, which assumes the height of the middle position of the plate 21 in the rest state, wherein a corresponding guide 26 is provided on the opposite side of the plate 21 is, the box-shaped object with the help of the plate 21 from one to other end are moved as the plate 21 is cyclically raised, in the longitudinal direction is moved towards, lowered and moved back in the longitudinal direction.

In Fig. 11 parts of a lifting ladder are shown, the essentials Parts are shown only schematically.

A pin wheel 30 is fed with the aid of a solar cell Motor set in rotation in the direction of the indicated arrow.

The pin wheel 30 has six projections 31, which only a part of the circumference of the pin wheel 30 are provided and either with a Pinion 32 or can be brought into engagement with a pinion 33. The pinion 32 and 33 have six projections so that the six pins 31 each have a complete one Rotation of the pinion 32 resp.

of the pinion 33 cause.

A crank 34 is rotatably attached to the pinion 32, which at its the other end has a pin to which a link 35 is pivotably articulated is. At the other end, the link 35 can be pivoted with one end of a lever 36 tied together. The lever 36 is pivotable about a stationary pin 37 and has at its other end a pin to which a conductor 38 is attached. The ladder 38 consists of two side parts, between which cylindrical Rungs 43 are located. The conductor 39 is designed in a corresponding manner, both Ladders 38 and 39 are in the rest position on the indicated foundation. The rungs of the two ladders are offset relative to one another by half the rung spacing.

In the corresponding way as this in connection with the motion drive has been teschildert for the conductor 38, the conductor 39 is connected to the pinion 33.

The two ladders 38 and 39 are in a shaft 40, of only Lwei lateral boundaries are shown. The shaft essentially has the shape of a cuboid and, like the conductors 38 and 39, is also arranged vertically.

When the pin wheel 30 is rotated, its pins 31 arrive with the projections of the pinion 32 in rotational engagement and turn the crank 34 in the direction of the arrow. Through this Rotational movement, the lever 36 is pivoted, a; that the ladder 38 is raised. On the rung 43 is a ball or something else schematically in cross section spherical roller body 42 reproduced. This rolling body is due to the further Movement of the ladder 38 raised upwards, he finally arrives in one Height that he performs a movement directed to the right and on a rung the ladder 39 is lifted. The pinion 32 is moved further until it reaches the position shown in FIG. 11 assumes the position shown, i.e. the ladder 38 is lowered into the initial position.

The pin wheel 30 continues to rotate so that the pins 31 with the pinion 33 come into engagement and now the conductors 39 in corresponding Way is raised, so that now the roller body 42 is raised a further piece is and finally executes a movement to the left and on the next higher Rung to rung 43 comes to rest. Now the ladder 39 is in the initial position lowered. The process described at the beginning is then repeated. With the help of described device, it is possible to use a rolling body 42 in the vertical direction to be lifted, with bodies other than balls or cylindrical rollers being lifted can be made if the ladders or their rungs are designed appropriately. For example, cylindrical sockets could be attached to the rungs 43, to move the body to be lifted to the left or to the right facilitate.

It should be noted that not only the toy models described above can be powered by a single solar cell, but that it is possible is to use the arrangement shown in Fig. 2 in order to generate motions on which the drive energy generating solar cell, so that it is always optimal to a moving one Light source is aligned.

Claims (23)

Model toys with drive housing, in which a Motor with output shaft is optionally arranged in connection with a transmission, thereby characterized in that on the drive housing (1) at least one with the motor (5) electrically connected solar cell (2) is arranged. 2. model toy according to claim 1, characterized in that the Drive housing (1) columnar with any base area, in particular with circular, Polygonal or oval surface, or cuboid, prismatic or the like. is trained. 3. Model toy according to claim 2, characterized by an in inclined surface with respect to the base. 4. model toy according to claim 3, characterized in that this Inclined surface with respect to the horizontal or the base at an angle of 300 is inclined. 5. Model toy according to one of claims 3 or 4, characterized in that that the solar cell or the solar cells (2) is attached to the inclined surface. 6. Model toy according to one of claims 1 to 5, characterized by a mirror (3) attached to the hollow element. 7. model toy according to claim 6, characterized in that the Mirror (3) is designed to surround the solar cell or the solar cells (2). 8. Model toy according to one of claims 6 or 7, characterized in that that the mirror (3) is funnel-shaped. 9. Model toy according to one of claims 6 to 8, characterized in that that the mirror (3) is curved or has a hollow shape. 10. Model toy according to one of claims 1 to 9, characterized in that A light beam collector is arranged in front of the solar cell or solar cells (2) is. 11. ModelAspielzeug according to claim 10, characterized in that the light beam collector is designed as a Fresnel lens. 12. Model toy according to one of claims 1 to 11, characterized in that that the solar cell or the solar cells (2) with respect to the drive housing (1) adjustable or is arranged alignable to a light source. 13. Model toy according to one of claims 6 to 11, characterized in that that the mirror, the light collector or the Fresnel lens are adjustable. 14. Model toy according to one of claims 1 to 13, characterized in that that the surface of the solar cell or the solar cells (2) has a multitude of prismatic, having tetrahedral or lenticular projections. 15. Model toy according to one of claims 1 to 14, characterized in that that on or in the drive housing (1) connected to the solar cell or the solar cells (2) electrical connection parts are arranged. 16. Model toy according to one of claims 1 to 15, characterized in that that the wall of the drive housing made of plastic, wood, metal or the like. Preferably is formed from stamped parts made of balsa or abachi. 17. Model toy according to one of claims 1 to 16, characterized in that that the drive shaft of the motor (5) with a pinion (10, 16), a crank, a Lever or the like is provided, which in turn drives movable parts (12, 17, 30) of the model toy (Fig. 8, 9, 10, 11) are used. 18. Model toy according to claim 17, characterized in that the pinion (10) is arranged in driving engagement with a pin thread (12), a Shaft of pin wheel (12) is provided with a pinion (15), which has only two, three or fewer projections than the pinion (10) above and below the pinion (15) pinions (13 and 14) in driving engagement with the pinion (15) are arranged, the pinion (13 and 14) with the rotating shaft of the radar antenna connected, the pinion (15) either with the pinion (13, left-hand rotation) or with the pinion (14, clockwise rotation) during one revolution of the pin wheel (12) is engageable. 19. Model toy according to claim 17, characterized in that the pinion (16) is arranged in rotational engagement with a crank (17) that engages the crank (17) bearing shaft is eccentrically mounted in bearing parts (19 and 20), the Bearing parts (19, 20) are connected to raise and lower a plate (21), furthermore on / the crank (17) supporting shaft a pinion (18) is arranged, which with a further pinion (22) is arranged in rotational engagement, the pinion (22) on one Shaft (23) is attached to the other end of the plate (21) with an eccentric (24) is connected, which raises and lowers the plate (21) at its other end connected is. 20. Model toy according to claim 17, characterized in that a pin wheel (30) driven by a motor (5) with a limited number of pins (31) is provided on part of the circumference, either with a pinion (32) or with a pinion (33) during one revolution of the pin wheel (30) in drive engagement are arranged, the pinion (32) is attached to a crank (34), the crank (34) is connected to a link (35), the link (35) is articulated on a lever (36) is, which in turn is pivotable about a fixed pin (37), the other arm of the lever (36) with a ladder (38), this is connected to move up and down, another conductor (39) is connected in a corresponding manner to the pinion (33) and the ladders (38, 39) in a shaft (40) apply a lifting force to a rolling body (42) are arranged exercising. 21. Model toy according to claim 20, characterized in that the conductors (38) at the opposite end with respect to the attachment point of the Lever (36) is provided with a parallel guide lever (41) and that the ladder (39) is stored accordingly. 22. Model toy according to one of claims 1 to 21, characterized in that that the solar cells (42, 43) of two drive housings are electrically connected in anti-parallel and an adjusting drive (44) for changing the position of the solar cells (42, 43) of both drive housings are electrically connected to this anti-parallel circuit is. 23. Model toy according to claim 22, characterized in that the drives are motors that connect the solar cells (42, 43) with one another rotating, swiveling or pivoting vertical planes. in relation to a moving light source tracking are connected.