DE9010048U1 - Movable ornament - Google Patents

Description

IRON FEED, FEEDER & STROSSE. .. RlmiMi. Uftiw-tvm · * * t · · ·

Munich

Uu iüchep

Our Zcfcitsn European Patent Attorneys
DIpI-ed. Gunter EJsenführ T614 Dtpl-in& JoacHtn Strassc ·
Dt-me-Wtexner W Rrtus DtpL-CrieraDr.Waker MarwakT *iSnc>wn TAKARA CO. LTD.
ttsua nme !dung July 2, 1990

TAKARA CO., LTD., Ho. 19-io, 4-chome, AotO Katsushika-ku, :c:,yo, ^APAN

Movable ornament

The invention relates to a movable ornamental object with a drive unit having a motor and optionally a gear, a motor control circuit and a movement mechanism driven by the drive unit.

A movable ornamental object is already known from DE-GM 89 Ol 807, which normally has the shape of a flower or similar when stationary and is normally used for decorative purposes in apartments or houses. This known object is equipped with a sound sensor,

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which responds to sound signals with a predetermined level above it. Such sound signals can be caused by the voice of an observer, by clapping hands, background music or the like. When such sound signals are received, a switching element is switched on and energizes a drive motor. This motor sets a core element in rotation, on which a tube element sits, which has the appearance of an imitation of a flower, for example. The core element is bent so that when it rotates, the tube element, ie the flower, performs a swinging movement.

The present invention is based on the object of creating a movable decorative object that executes a movement that was previously unknown and thus has a surprising effect on the observer.

This object is achieved in a movable decorative object of the type mentioned at the beginning in that the decorative object has a deformable container in which the drive unit, the motor control circuit and the movement mechanism are housed, and that the movement mechanism acts on the container to deform and return to the normal shape. In this way, the movable decorative object changes its otherwise usual shape when the motor is switched on, which leads to considerable surprise effects. The container preferably has an approximately cylindrical shape and the peripheral wall of the container is made of flexible material.

In particular, the container in its undeformed state has the shape of a beverage can, e.g. a beer can. If such a beverage can according to the invention is placed near normal beverage cans of the same appearance, the decorative object according to the invention is not initially noticeable. However, if the drive of the decorative object is switched on unnoticed, the movement generated, i.e. the deformation of the decorative object, triggers considerable surprise effects.

According to an advantageous embodiment of the invention, the motor control circuit of the decorative object contains a sensor that responds to an external stimulus, e.g. a sound sensor, for controlling the motor. If sound signals occur continuously, the decorative object continuously performs a deforming movement, which leads to great surprises, especially in comparison to immobile containers of a similar type. If the peeling signals only occur sporadically, e.g. through conversations, the surprise effect is particularly great. So that such a movable decorative object does not stand out in its rest position compared to similar, immobile objects, according to a further advantageous embodiment of the invention, a rest position return mechanism is provided for automatically returning the movement mechanism to the rest position, so that the container then automatically assumes the undeformed position. Only when an external stimulus occurs does the decorative object deform and automatically returns to the rest position after the stimulus has subsided.

Further advantageous embodiments of the invention can be found in the subclaims.

The invention is explained in more detail below using exemplary embodiments with reference to the accompanying drawings. Similar parts in the drawings are shown with the same reference numerals.

Show it:

Fig. 1 is a vertical section of an embodiment of the movable ornament according to the invention;

Fig. 2 is an exploded perspective view of a bending mechanism of the movable ornament according to Fig. 1;

Fig. 3A

to 3C each show a schematic, perspective view to illustrate different phases of the bending movement of the movable decorative element

Fig. 4 the circuit diagram of a motor control circuit

the movable ornamental object according to Fig. 1;

Fig. 5 is a perspective view of the movable ornamental article according to Fig. 1 with additional parts;

Fig. 6 shows a partial section in schematic

Representation of a modification of a reduction gear arranged between a motor and a bending mechanism of the ornamental article according to Fig. 1;

Fig. 7 is a schematic representation of the transmission according to Fig. 6;

Fig. B is an exploded perspective view of another embodiment of the movable ornament according to the invention;

Fig. 9 is a vertical section through the ornamental article according to Fig. 8;

Fig.1OA

to IOC each show a schematic representation of the different movement phases of the ornamental object according to Fig. 8;

Fig. ii the switching case of another engine—

Control circuit for a movable ornament according to the present invention;

Fig. 12 is a pulse diagram of the motor control circuit according to Fig. 11; and

Fig. 13 is a circuit diagram of another motor control circuit for use in a movable ornament according to the present invention.

In the following, an embodiment of the movable decorative object will be described in connection with Figures 1 to 3.

The movable ornamental object 20 contains a casing or a container 22 of cylindrical shape. In the present embodiment, the container 22 is designed as an imitation of a beverage can, e.g. beer can, with a base 24, a peripheral wall or a barrel section 26 _and a lid 28. An insert 30 is provided in the container 22.

v aesehen, which has a power supply 32 in the form of

J batteries or similar. The insert 30 is in

' the bottom 24 of the container 22 so that the

·;' Batteries 32 can be replaced. For this

For this purpose, the bottom 24 is designed so that a part

can be opened. In addition, the

A main switch 34 and a sound sensor 36 for motor control are provided on the base 24. The main switch 34 has an operating lever 38 which protrudes from the base 24 and can be operated from the outside to switch on the movable object.

A box-shaped housing is provided in the container 22 and is arranged above the insert 30. In the present embodiment, the housing 40 can be considered as a pedestal or base. A motor 42 and a reduction gear 44 are provided in the housing 40, which consists of a worm gear, an overload friction clutch and a spur gear. The gear 44 supports an output shaft 46 which projects upwards from the housing 40. On this part of the output shaft, a cam disk 48 is attached as a rotary member, which is provided on the upper surface with an eccentrically mounted drive pin 50 which points upwards. The housing 40 is provided on both sides in the upper region of its side walls with bearing pins 52 which extend outwards through the housing 40. Above the housing 40, a vibration member 54 is provided 3 -, which has two arm sections 56 that overlap the upper part of the housing 40, as well as a connecting section 58 that connects the two arm sections 56 to one another. The arm sections 56 are both provided in their lower area with a through hole 60 into which the bearing pins 52 loosely engage, so that the vibration member 54 can rotate around the bearing pins

·

can be pivoted relative to the housing 40. The connecting section 58 is provided on its underside with an elongated recess 62 which extends in the longitudinal direction. The eccentrically arranged drive pin 50 of the cam disk 48 engages in this recess.

With such an arrangement of the cam disk 48 and the vibrating member 54, rotation of the cam disk 48 in the direction of the arrow 64 (see Fig. 2) causes the vibrating member 54 to pivot about the bearing pins 52 in the direction of the arrows 66. The vibrating member 54 is provided with a cylindrical section 68 which is integrally formed on the vibrating member 54. The cylindrical section 68 has an annular bead 70 on its outer circumference which extends in the transverse direction. In the cylindrical section 68 there is also provided a projection 72 which is arranged concentrically and extends in the axial direction of the cylindrical section 68. This projection has a blind hole 74 which extends in the axial direction and is open at the top.

Furthermore, a support member 76 is provided in the container 22, which is arranged between the lid 28 and the vibration member 54. The support member 76 engages the container 22 for support and transfers the oscillating movement of the vibration member 54 to the container 22, as described below. In the present embodiment, the support member 76 engages the peripheral wall 26 of the container

and for this reason has a circular shape with approximately the same diameter as the peripheral wall 26 of the container 22. The support member 76 thus touches the entire circumference of the peripheral wall 26. A helical spring 78 is arranged between the support member 76 and the oscillating member 54 as an elastic intermediate member in such a way that a part is arranged in the t. _x i-hydraulic cut 68 and sits on the projection 72, so that a constant spring preload is exerted between the support member 76 and the oscillating member 54, and both are pressed apart from one another. The support member 76 carries a guide pin 80 in the middle, which extends downwards and engages in the blind hole 74 of the projection 72. In addition, the support $

member 76 with a plurality of downward- "·

extending arms 82, which are arranged circumferentially from one another and enclose the cylindrical section 68. The arms 82 each have a claw 84 at the free end, which extends inwards.

stretch and engage the annular bead 70 of the cylindrical section in such a way that the support member 76, which is constantly pre-tensioned upwards by the coil spring 78, does not come free from the cylindrical section 68, i.e. the claws 84 and the annular bead 70 act as stops to limit the upward movement. In this way the support member 76 can move resiliently relative to the oscillating member 54 without both coming free from each other.

A bending mechanism is created which is operated by the motor and the generated

Tilting movement is transferred to the container so that it executes a bending or buckling movement.

For this purpose, the container 22 is designed to be flexible and this flexibility is represented by the peripheral wall 26 of the container 22. The peripheral wall 26 is made of flexible material such as flexible plastic film. The peripheral wall 26 thus designed is attached to the support member 76 by gluing or welding in a manner which compresses the spring 78 so that the movable ornament 20 normally assumes the shape shown in Fig. 3 (rest position) since the container is under tension. In the embodiment described, the upper end of the peripheral wall 26 is bent inward so that it comes to lie between the support member 76 and the lid 28 placed on the peripheral wall 26.

The movable object 20 of the present embodiment includes a position switch 86 as part of the motor control circuit and is arranged in the housing 40 for detecting a predetermined position of the movable ornament. The switch 86 is arranged on the outside of the housing 40 opposite the outer circumference of the cam disk 48. It detects the inclination angle of the bending mechanism and thus of the movable ornament 20. In particular, the switch 86 is designed and arranged so that it switches on when the movable ornament 20 is in the inclined positions of Figs. 3B and 3C, i.e.

in a position other than the upright position shown in Figs. 1 and 3A. The switch* switches off when the ornament is in the upright position (Figs. 1 and 3A). The reference numeral 88 designates a control circuit for the drive motor.

Fig. 4 now shows the motor control circuit below. Control of the motor 42. The reference numeral 90 is a switching element in the form of a transistor which is switched on when the sound sensor 36 emits an output signal. The switching element 90 is connected in series with the control circuit 88, the power supply or battery 32 and the main switch 34.

The operation of the movable ornament of the present embodiment will now be described in conjunction with Figs. 1 to 5.

The movable ornament, which is in the form of an imitation of a beer can, moves to the normal position according to Fig. 3A when the main switch 34 is turned on by the operating lever 38. When the sound sensor 36 detects a sound signal of a predetermined level or above, e.g. clapping, music, speech or the like, the switching element 90 switches on or off with the main switch 34 turned on, depending on the amplitude of the sound signal, in order to supply electrical energy from the power supply or battery 32 to the photoelectric control circuit 88. This drives the motor 47.

switched on and causes the cam disk 48 to rotate via the gear 44, whereby the drive pin 50 moves in the recess 62 and the vibrating member 44 performs a tilting movement about the bearing pins 52. This results in the movable ornamental object 20, i.e. the beer can, being deformed in one direction or the other from the upright position according to Fig. 3A into the bent position according to Fig. 3B or 3C, returning to the upright position according to Fig. 3A and then being further deformed in the opposite direction into the bent position according to Fig. 3C or 3B. This bending process of the ornamental object 20 takes place as long as sound signals are detected.

If the movable ornamental object 20 is in the upright position (Fig. 3A) when the sound signal stops, the position switch 86 is switched off, so that the supply of electrical energy from the battery 32 to the control circuit 88 and thus the movement of the ornamental object 20 also stops. However, if the beer can 20 is in the bent position when the sound signal stops, the position switch is in the switched on state and maintains this switching state until the vibration member 54 has been swung back into the upright position. This also occurs when the switching element is already switched off, and the beer can 20 automatically reaches the upright position according to Fig. 3A, at which further movement is stopped. This leads to the

Tensioned peripheral wall of the beer can 20 has the natural appearance of a beer can.

In the drawings, reference numeral 94 refers to accessories in the form of glasses and headphones which are removably attached to the periphery of the cover 28 by retaining clips 94.

Fig. 6 and 7 show a modification of the gear 44 of the described embodiment of the movable ornament 20. The gear 44 contains a pinion 96 fixed to the output shaft 98 of the motor 42, a gear 100 mounted on a shaft 102 which engages the pinion 96, a gear 104 integrally combined with the gear 100, a gear 106 engaging with the gear 104, a gear 108 integrally combined with the gear 106, a gear 110 engaging with the gear 108, a gear 112 integrally combined with the gear 110, a gear 114 engaging with the gear 112 and a bevel gear 116 coupled to the gear 114. On the A further bevel gear 118 is arranged on the output shaft 46 of the gear 44. If the motor 42 is switched on, the rotary motion is transmitted via the gear 44 to the output shaft 46 in order to drive the cam disk 48, whereby the eccentrically arranged drive pin 50 executes a crank movement. This leads to the oscillating member 54 pivoting and the position switch 86 being actuated.

The movable ornament of the described embodiment is designed to receive sound signals. However, it is also possible to provide other sensors, e.g. for static electricity, light, pressure, infrared rays, smell, temperature or the like. For example, a pressure sensor can be used to determine the weight of a person approaching the movable ornament. In the present embodiment, the movable ornament is designed in the form of an imitation of a beer can, but it is also possible to design the ornament as an imitation of a doll, a bottle, a monster or the like.

form.

As is clear from the above, the movable ornament of the described embodiment is designed to remain stationary when the sensor does not receive an external stimulus, e.g. sound, so that it ^is therefore normally not noticeable.

Decorative object receives an external stimulus,

: it performs a deformation or bending movement,

which is perceived by a viewer with interest and surprise, so that a communication is established between the viewer and the ornament. The arrangement of the position \, switch in the ornament allows that

This always returns to the normal resting position

1; returns when no external stimulus is present. In

In this position, the peripheral wall or the box

elastically stretched in the upright position.

Fig. 8 to 10 show another embodiment of the movable ornamental object according to the present invention. In particular, this ornamental object performs a more uniform bending movement. In the embodiment according to Fig. 1 to 7, it can happen that the support member exerts too high a tension on the container, which leads to the risk of it becoming permanently deformed and slack. It can also happen that the container tears or detaches from the support member.

In the ornamental article according to Figs. 8 to 10, the connection between the vibrating member and the support member is improved in order to avoid excessive tension or force against the container and to ensure a natural movement of the support member. In addition, the possibility of repair should be facilitated and the pivoting movement of the vibrating member should be safely transmitted to the support member in order to increase the movement of the stand against it.

The movable ornament of this embodiment includes a container 22 in the form of an imitation of a beer can. The container has a bottom ²⁴ , a peripheral wall 26 made of flexible material, e.g. flexible vinyl resin film, and a lid. In the container 22, a housing 40 as a base body, a vibration member 54, a coil spring 78 and a support member 76 of approximately cylindrical shape are provided. These parts can be arranged in approximately the same manner as in the previously

described embodiment. A ball joint 120 is provided between the oscillating member 54 and the support member 76 in order to couple the two together.

An insert 30 is arranged in the container 22, which receives batteries or the like. The insert is removably attached in the bottom 24 of the container 22 so that the batteries 32 can be replaced. For this purpose, the peripheral wall 26 of the container 22 is bent inward at the lower end and forms an inner flange 122 onto which the insert 30 can be placed. The bottom 24 is designed such that a part 124 can be opened. The insert is attached to the flange 122 by screws 126, which are inserted through the bottom 24. In the embodiment shown, the insert can be integrally formed on the housing 40.

A sensor 36 is attached to the housing 40 and is designed to receive an external stimulus such as light, sound, infrared rays or the like and to actuate a switching element (not shown) of a control circuit 88 arranged in the housing 40. The sensor 36 protrudes through a through hole 128 when the housing 40 is inserted into the container 22. A motor (not shown) is also arranged in the housing 40 and is switched on when electrical power is supplied from the power supply via the switching element. A reduction gear (not shown) is coupled to the motor and has a

- 16 -

Output shaft (not shown) on which a rotating part or cam disk 48 is arranged. The reference number 52 indicates bearings which protrude outwards through the housing 40. All of these parts can be constructed in a similar way.

be as in the first described embodiment I

form. The rotary member or cam disk 48 ]

contains an eccentrically arranged drive pin j

5u. j

The vibrating member 54 has a pair of armrests \

sections 56 and a connecting section 58 between them. A cylindrical section 68 is arranged on the connecting section, which serves as a spring holder. The connecting section is provided on its lower surface with an elongated recess 62, which projects into the cylindrical section 68. The arm sections 56 each have a through hole 60 through which bearing pins 52 extend in order to pivotally mount the oscillating member 54 on the housing 40 in such a way that it can be pivoted about the bearing pins 52. The eccentrically arranged drive pin 50 of the cam disk 48 engages in the recess 62, so that when the cam disk rotates, the oscillating member 54 is pivoted about the bearing pins 52.

The ball joint 120 already briefly mentioned contains a ball 130 which is attached to the oscillating member 54 and a ball socket 132 which is attached to the support member 76. The arrangement of the

The connection between the ball 130 and the ball socket 132 can also be made in the reverse manner on the parts 54 and 76. In particular, the ball 130 is attached to the distal end of a guide pin 80, the proximal end of which is located at the central region of the bottom of the cylindrical portion 68 and extends upwards. The ball socket 122 is located on the central portion of the lower surface of the support member 76. The ball socket 132 is provided on its outer surface with a plurality of retaining openings 134, while the support member 76 has a plurality of through holes 136 which correspond in position to the retaining openings 134. The reference symbol &lgr;&aacgr;&idigr; denotes a fastening which consists of a flat support portion y 140 and a plurality of claws 142, which

jj arranged on the underside of the carrier section

and extend downwards from there. These

Claws 142 are inserted through the retaining openings 134 and

'&igr; 136 to secure the ball socket 132 to the support

link 76.

The coil spring 78 is arranged between the support member 76 and the vibration member 54 in order to permanently press them apart. The coil spring 78 is held with its lower part on the cylindrical section 78 and engages with its upper part on the ball socket 132.

In this way, a bending mechanism is created that transmits the output power of the motor to the peripheral wall of the container 22.

- 18 -

In the bending mechanism described, the coil spring 78 is arranged with its lower section in the cylindrical section 68, and the ball of the ball joint 120 slides, with force, into the ball socket 132 on the underside of the support member 76, whereby the oscillating member E>4 and the support member 76 are coupled to one another and the upper end of the coil spring 78 engages in the force loop on the lower surface of the support member 76.

This assembled bending mechanism is then inserted into the container, with the housing 40 and the support member 76 forming a unit. The housing 40 is then secured to the container, the peripheral wall 26 of the container 22 is folded inward at the upper end as indicated by the reference numeral 144 so that the folded upper end securely supports the upper end 145 of the annular support member 76. The lid 28 is then placed on the support member 76, thereby firmly connecting the container to the support member 76 in the upright position.

In the embodiment according to Figs. 8 and 9, the cam disk 48 contains a cam as described above and a microswitch 146 which is arranged near the cam disk 48 and is connected in the control circuit 88 in parallel with the switching element which is connected to the sensor 36. In this way, a rest position return mechanism is formed with which the motor

returns the ornamental object to the upright position whenever no external stimulus is detected in the area of the bent position.

If an external stimulus such as sound, light, infrared rays, smell, heat or the like is detected in the embodiment according to Figs. 8 and 9, the switching element is switched on to excite the motor. This leads to a rotation of the cam disk 48 and to a pivoting movement of the vibrating member 54, the movement of which is transmitted to the support member 76 via the ball joint 120. This causes the container 22, and in particular the peripheral wall 76, to continuously execute a bending movement as shown in Figs. 10A to 10C. During the bending movement, one side of the peripheral wall 76 successively contracts and expands, while the other side is subjected to expansion and contraction. The reaction of the contraction is successively applied to the support member 76, but the ball joint pivots so that no excessive stress is applied to the peripheral wall 26 of the container 22, and the support member 76 perfectly determines the range of motion in which it is pivotally moved to the natural position. This effectively prevents damage to the container 22, particularly to the peripheral wall 26, regardless of the repeated bending motion of the container 22.

If the oscillating member 54 is moved back to the upright position, the coil spring

78, that the support member 76 is separated from the oscillating member 54 by the corresponding pre-tension upwards, whereby the movable ornamental object is returned to the upright position and held in the tensioned position.

The home position return mechanism assembly in the present embodiment includes the cam 48 and the microswitch 146, whereby the motor remains energized until the ornament is returned to the upright position when the external stimulus is removed during a bending movement. Therefore, when the ornament is stationary, the observer would not believe that a bending movement could occur, so that if such a bending movement does occur due to an external stimulus, it causes great surprise to the observer.

As is apparent from the above, the movable ornamental article according to Figs. 8 and 9 is constructed in such a way that the ball joint is arranged between the vibrating member and the supporting member and the spring also engages between both parts to bias them away from each other. Such a construction enables the supporting member to smoothly change position and effectively prevents undue forces from being exerted on the peripheral wall of the container when the vibrating member performs a pivoting movement. In this way, the movable ornamental article can perform a smooth

and perform gentle movement without weakening, damaging or tearing the peripheral wall.

The remaining parts of the embodiment according to Figs. 8 and 9 can be designed in the same way as in the embodiment according to Figs. 1 to 7.

The motor control circuit for use in connection with any of the above-described embodiments may be constructed as shown in Fig. 11. This motor control circuit is designated by the reference numeral 148 in Fig. 11 and operates in such a way that when the motor is switched off due to the absence of an external stimulus, it also acts as a brake so that the movable ornament according to the present invention can be stopped in a predetermined position and then gives the impression of a stationary ornament. This stopping in the rest position is carried out with the greatest precision.

For this purpose, the motor control circuit 148 contains a sound sensor or microphone 36, which then emits an output signal when a sound signal of a predetermined level or higher arrives. This output signal is fed to a circuit element 90 in the form of an NPN transistor and from there to a terminal of a first NAND circuit 150. The reference numeral 152 refers to a selection circuit which is designed in the form of a known flip-flop which has two

cross-coupled NAND circuits. The flip-flop 152 uses the signal supplied from the NAND circuit 150 as a start signal to turn on a motor switching element 154. Another signal from the NAND circuit 150 is used to reset the flip-flop 152 and turn on a short-circuit element 158. In this way, the flip-flop 152 serves to selectively operate the switching elements 154 and 158.

The second NAND circuit 156 is supplied with a signal via a blocking circuit 160 which is generated by the position switch 86 under the action of the cam disk 48 which rotates synchronously with the motor 42. The blocking circuit 160 can be constructed in the form of a known differentiating element, with a capacitor 162 and a resistor 164. The output signal of the NAND circuit ISi is delayed in time with respect to the signal of the position switch 86 due to the time constant of the blocking circuit 16Ö. In other words, for this period of time the flip-flop 152 prevents switching, even if the NAND circuit 150 supplies a signal to the flip-flop 152. Both switching elements 154 and 158 can each contain a PNP transistor, the bases of which are connected to the outputs of the two ΔΔΔΝ transistors. i*_.»altungen which form the flip-flop 152 or the selection circuit.

The collector-emitter path of the switching element 154 of the motor drive is connected to a feed line of the power supply 32. We&agr; from the

If flip-flop 152 sends a signal to motor switching element 154, this element excites motor 42. The collector-emitter path of switching element 158 serves as a short-circuit element and is connected to the two terminals of a capacitor 166, which is parallel to the driver winding of motor 42. If flip-flop 152 sends a signal to the base of short-circuit element 158, the driver winding of motor 42 is short-circuited, thereby braking motor 42.

The operation of the motor control circuit in connection with the tig. Il and 12 is described below.

As soon as the sound sensor or microphone 36 receives a sound signal of a predetermined level or above and the main switch 34 is switched on, the NAND circuit 150 causes the flip-flop 152 to be set. The flip-flop 152 actuates the motor switching element 154 so that the motor 42 is switched on. The rotating motor 42 causes (via the reduction gear) a rotation of the cam disk 48 and this actuates the position switch 86. As soon as the movable ornament has reached a predetermined position, e.g. the upright position (rest position), it is necessary that the motor 42 be stopped at that time. If the position switch 86 is still switched on, the second NAND circuit 156 causes the output signal of the position switch 86 to be reversed and delayed by a time corresponding to

• · · - &igr;&igr;

the time constant T is generated. This causes the flip-flop 152 to interrupt the operation of the motor switching element 154 and to operate the short-circuit element 158. The switching on of the short-circuit element 158 causes a short-circuit of the excitation winding of the motor 42, so that it is braked and stops immediately.

The motor 42 thus acts as a brake when the movable ornamental object has reached a predetermined position, so that the movement of the ornamental object remains in this predetermined position, even if the flywheel mass of the movable ornamental object changes or a load is applied to the peripheral wall of the container of the ornamental object .

Such load changes can occur due to the flexibility of the peripheral wall of the decorative object and due to temperature fluctuations.

The time constant T, which corresponds to the reversal time of the NAND circuit 156, is set longer than the time required for the terminal voltage of the motor 42 to drop to zero after its shutdown. During the reversal time of the second NAND circuit 156, the flip-flop 152 keeps the motor 42 in ;

stopped state, even if the sound sensor 36 <

an output signal to the first NAND circuit 150 i

Accordingly, the bending movement of the movable ornament is momentarily stopped in the upright position (Fig. 3A, 10A), although the sound sensor continuously records sound signals.

- 25 -

In this way, the bending movement of the movable ornamental object has a satisfactory course.

The motor control circuit according to Fig. 11 contains a sound sensor 36. However, it is also possible to use other sensors which detect external stimuli other than sound, e.g. light, infrared radiation , temperature, pressure, static electricity, odors, smoke or the like.

Fig. 13 shows a further embodiment of the motor control circuit. In this motor control circuit, a position switch 86 is provided, which is switched off when the movable ornament is in an upright position. As soon as a sensor or microphone 36 detects switching signals with a predetermined level or above,

^&uacgr; and the main switch 34 is switched on,

q: the movable ornament is in the

upright position so that the position switch is open. A transistor Q3 is switched on and ., energizes the motor 42 so that the moving

- decorative object performs a bending movement.

; The ornament continues to move as long as

■■: a sound signal is present. If the decorative

&eeacgr; object in a bent position, the

Position switch 86 is switched on, so that even if there is no sound signal at the sensor 36, the

Ornament continues its movement until

it reaches the upright position. At this moment, the position switch 86 is switched off and prevents any further bending movement of the ornament.

Claims (13)

-PATENT CLAIMS 1. Movable ornament with a drive unit having a motor and optionally a transmission, a motor control circuit and a movement mechanism driven by the drive unit, characterized in that the ornamental object has a deformable container (22) in which the drive unit (42, 44), the motor control circuit (88) and the movement mechanism (48, 50, 62, 54) are housed, and that the movement mechanism for deformation and return to the normal shape acts on the container (22). 2. Ornamental article according to claim 1, characterized in that the container (22) has an approximately cylindrical shape and the peripheral wall (26) is made of flexible material. 3. Ornamental article according to claim 2, characterized in that the container (22) in the undeformed state has the shape of a beverage can, e.g. a beer can. 4. Ornamental article according to claim 2 or 3, characterized in that the peripheral wall (26) is suspended between a base body (40, 24) and a support member (76) and is secured by an elastic intermediate member (7B) is tensioned, and that between the base body (40, 24) and the support member (76) the movement mechanism (48, 50, 62, 54) engages. 5. Ornamental article according to one of the preceding claims, thereby denoted; the third RnuegiinasroRrhanism (48, ^O, 62, 54) contains the following parts: - a rotary member (48) coupled to the drive unit (42, 44) for rotation; - a vibrating member (54) pivotably mounted within the container (22) and operatively connected to the rotary member (48) for generating a pivoting movement; and - a support member (76) arranged above the vibrating member (54), which is movably mounted on the vibrating member (54) and is connected to the container (22). 6. Ornamental article according to claim 5, characterized in that the rotary member (48) is a crank or eccentric element (48, 50). 7. Ornamental object according to claim 5 or 6/ characterized in that the support member (76) is slidably mounted on the vibration member (54). Ü. Ornamental article according to claim 5 or 6, characterized in that the support member (76) and the oscillation member (54) are coupled to one another by a ball joint (120). 9. Ornamental article according to one or more of the preceding claims. characterized in that the motor control circuit (88) has a sensor (36) responsive to an external stimulus, e.g. a sound sensor, for controlling the motor (42). 10. Ornamental article according to one or more of the preceding claims, characterized by a rest position return mechanism (48, 86) for automatically returning the movement mechanism (48, 50, 62, 54) to the rest position and thus the container (22) to the undeformed position. 11. Ornamental article according to claims 5 and 10, characterized in that the rest position return mechanism consists of a position switch (86) controlled by the rotary member (48), which keeps the motor (42) switched on until the rest position of the oscillating member (54) is reached. 12. Ornamental article according to claims 9 and 11, characterized in that the motor control circuit (88, 148) contains a motor switching element (154) for supplying motor current and a short-circuit switching element (158) for short-circuiting the winding of the motor (42); that a selection circuit (152) is provided which switches on the motor switching element (154) when the sensor (36) receives an external stimulus, and which switches off the motor switching element (154) and switches on the short-circuit switching element (158) when the position switch (86) detects the predetermined rest position; 13. Ornamental article according to claim 12, characterized by a blocking circuit (160) which prevents the switching on of the motor switching element (154) by the selection circuit (152) for a certain period of time after the switching on of the short-circuit switching element (158).