RU2068727C1 - Knock-up model of toy electromechanical vehicle - Google Patents

Abstract

FIELD: toys. SUBSTANCE: knock-up model of toy electromechanical vehicle incorporates chassis, axles, joining members made in the form of protrusions and grooves of corresponding profiles. Chassis is built collapsible and includes power supply units with switch, reduction gear units connected by means of axles of driving wheels to holders of microelectric motors. Power supply units are connected to reduction gear units by joining members in the form of dovetail arranged over perimeter of case. Joining members are positioned on opposite walls of case in inverted order. EFFECT: simplified design, increased operational reliability. 3 cl, 5 dwg

Description

 The invention relates to the field of entertaining children’s games, in particular to toys of a structural type.

 A known design kit for assembling vehicle models containing connecting elements in the form of grooves and protrusions and elements imitating a transport platform with a trailer having axles (USSR patent N 795439, 1976).

 The disadvantage of this model is the limited gaming capabilities.

 Known electromechanical toy containing a microelectric motor, gearbox, chassis and switch connected to a source of electricity; the gearbox is pivotally mounted on the axis of the driving wheels of the chassis and has a lever that interacts with the switch, while the electric motor is mounted on the gearbox (AS USSR N 592418, 1974).

 The disadvantage of this toy is its inseparability.

 The closest analogue is the prefabricated model of a toy vehicle (USSR patent N 671705 B.I.N. 24, 1979), containing a chassis made in one piece with the axles, connecting elements consisting of protrusions with longitudinal slots made in one piece with the chassis coaxially with the axles, and grooves made in the tuning details and having a profile corresponding to the profile of the protrusions.

 The disadvantage of the prototype is the limited gaming capabilities due to the small variability of the assembly model and the fragility of the connections of the assembly elements.

 The task to which the invention is directed is to expand gaming capabilities by designing various types of vehicles when changing chassis assembly options and improving the reliability of the assembly of the assembly elements.

 The problem is solved in that in the proposed prefabricated model of a toy electromechanical vehicle containing a chassis, axles, connecting elements that consist of protrusions and grooves of the corresponding profiles, according to the invention, the chassis is prefabricated and contains power supplies (PSUs) with a switch, gear units ( BR), connected by the axles of the driving wheels to the holders of microelectric motors, while the BP is connected to the BR by connecting elements in the form of protrusions and grooves with a dovetail profile on the outer surfaces of the walls of the PSU case and around the perimeter of the BR case. At the same time, the connecting elements are located on opposite walls of the PSU case inversely. The prefabricated model contains independent connecting elements with grooves corresponding to the protrusions on the walls of the BP and BR housings, and through holes in the protruding part for the axles of the driven wheels. Wheel disks are made with a gear rim in a circle protruding beyond the tire.

 The implementation of the chassis by a combined team consisting of interconnected PSUs with a circuit breaker, BR, microelectric motor holders and the presence of independent connecting elements suggests the construction of various types of vehicles when changing the chassis assembly options, which expands the gaming capabilities of the combined model.

 In this case, independent connecting elements with grooves corresponding to protrusions on the walls of the BP and BR enclosures also affect the expansion of gaming capabilities, as allow them to be fixed, for example, independent suspensions or axles of the driven wheels, which increase the stability and maneuverability of the model.

 Connecting elements with a dovetail profile increase the reliability of the connection, and their execution on the outer walls of the PSU case and along the perimeter of the BR case expands the gaming capabilities of the combined model. The inverse location of the connecting elements on opposite walls of the PSU allows you to connect the PSU cases to each other, which increases the amusement of the toy.

 The places provided in the BP and BR cases for placing microelectric motors, batteries, a switch engine, as well as making a wheel disk with a gear rim protruding outside the tire and meshed with one of the gears of the gearbox, allows you to use the toy in the electromechanical version, t .e. increase its gaming properties.

 In FIG. 1 shows a prefabricated chassis (top view); in FIG. 2 rear view of the central part of the chassis with 1/2 cutout of the PSU case and in the context of a driven wheel with a suspension attached by an independent connecting element to the PSU case; in FIG. 3 microelectric motor holder, independent connecting element and power supply cover; in FIG. 4 switch, power supply unit cell with battery at two positions of the switch "on" and "off"; in FIG. 5 is a schematic illustration of chassis assembly options.

 The prefabricated chassis consists of two BP-1 cases (Fig. 1) with a cover 2 (Fig. 3) for one of them, two gear units (BR) 3 (Fig. 1) with gears inside, two holders 4 of microelectric motors 5 (Fig. . 1) two axles 6 (Fig. 1) of the driving wheels 7 (Fig. 1), two independent connecting elements 8 (Fig. 1, 3) with independent suspension brackets 9 fixed on them (Fig. 2) with driven wheels 10 (Fig. . 1). On the outer surfaces of the opposite walls of the PSU case 1 (Fig. 1), inverted protrusions and grooves of the dovetail type 11 are made. Inside the PSU case 1, dividing protrusions 12 (Fig. 1) are made, forming cells for the batteries 13 (Fig. 4), in each of which an elastic protrusion 14 is made on the same side with the housing (Fig. 1, 4), and on the opposite groove 15 (Fig. 1, 4) with contact plates 16, 17 (Fig. 1, 4) fixed to them, the ends of which are bent and soldered to the printed circuit board 18 (Fig. 1), mounted on the upper closed side of the power supply unit 1 .

 In the upper part of the dividing protrusions 12 in places of contact with the wall of the PSU case, grooves 19 are provided (Fig. 4), and in the lower hole 20 (Fig. 4) for the possibility of moving the switch engine 21 installed in them to the right and left (Fig. 4), made in the form of a figured plate with a conical hole corresponding to the size of the contact protrusion on the battery. In the upper part of the PSU case 1, protrusions 22 (Fig. 1) are made for fastening the cover 2 (Fig. 3), and on the cover 2, respectively, protrusions 22 (Fig. 1), L-shaped mounting protrusions 23 (Fig. 3) are made , as well as a through hole 24 (Fig. 3) for output to the lid protrusion of the engine of the switch 21 (Fig. 4).

 A printed circuit board 18 with sockets of the connector 25 (Fig. 1) for connecting the terminals of the microelectric motor with batteries is located on the upper (closed) side of the power supply unit 1.

 In FIG. 1 shows a gear unit 3 with drive wheels 7. The wheel disk is made with a gear rim 26 around the circumference. On the outer surface of the BR 3 case one of its gears 27 is installed, which is meshed with the gear rim around the circumference of the drives of the drive wheels 7. A connecting protrusion with a dovetail type profile 11 is made along the perimeter of the BR 3 case (Fig. 1-3) A hole 28 is made on the inside of the BR 3 case for mounting the micro-electric motor 5. On the holders 4 of the micro-electric motor 5 (Fig. 3), projections 29 are made with holes for the axles of the driving wheels 7 and the rack 30 with holes in the upper part for mounting the micro-electric motors 5. N large outer sides of the holder 4 made microelectric chamfer 31 corresponding to the profile of the groove formed by coupling protrusion "dovetail" 11, located on the perimeter BR housing 3 (FIG. 3).

 The independent connecting element 8 (Fig. 3) is made in the form of a plate with a dovetail groove corresponding to the extreme connecting protrusions on the walls of the PSU and BR cases, and a protrusion with an opening for fixing independent suspensions 9 using the axle shafts 32 (Fig. 2) driven wheels 10.

 Wheels 7, 10 (Fig. 2) contain a disk 33 made with a gear rim around the circumference, a tire 34, a sleeve 35 for mounting the disk on an axis and a cap 36.

 A model, such as a tractor, is assembled as follows. The holders 4 of the micro-electric motors 5 are interconnected so that the holes in the protrusions 29 of the holders 4 are aligned, and the axles 6 of the driving wheels 7 are installed in them. Then, the BR 3 housings are mounted on the axis 6 on both sides, setting the sides with chamfers 31 of the holders 4 of the micro-electric motors in the grooves formed by the connecting protrusion 11 and the housing of the BR 3, while simultaneously installing microelectromotors 5 in the holes of the struts 30 of the holders 4 and in the holes 28 of the housings of the BR 3. The driving wheels 7 are mounted on the protruding parts of the axles 6, fixed with bushes 35 and sun ulation caps 36.

 On the connecting protrusions 11 around the perimeter of the enclosures BR 3 fit on the corresponding grooves of the housing BP 1.

 The driven wheels 10 are mounted on independent suspensions 9, which are fixed in the holes of the protrusions of the independent connecting elements 8 with the help of half shafts 33, for example pins, and the assembled unit is mounted on the extreme connecting protrusions of the walls of the PSU 1.

 The cells 13, for example, type A 343 batteries, are installed in the cells of one of the BP 1 casings, positioning them so that the “-” adjoins the elastic protrusion 14 with the contact plate 16. The “+” of the battery at the position of the slide switch 21 is “off.” isolated from the contact plate 17. The pins of the conclusions of the electric motors are inserted into the sockets of the connector 25 of the printed circuit board 18.

 The cover 2 is fixed with mounting tabs 23 on the open bottom side of the PSU case.

 The tractor cab is installed on a PSU with a printed circuit board, and the rest of the chassis (BP and BR housings) is covered with the tractor body.

 The model works as follows. Installing the switch engine 21 in the working position ("on"), close the electric circuit: microelectric motors 5 batteries 13. The torque from the microelectric motor shaft through the gearbox located in the BR 3 housing and gear 27 is transmitted to the drive wheels 7, the model starts to move .

 The use of additional BP enclosures allows the assembly of new chassis and vehicles of various types.

 In FIG. 5.1 a chassis is shown schematically, consisting of two BR cases (in the center) with two symmetrically located PSU cases; in FIG. 5.2 chassis, consisting of two power supplies and two gear units connected in series; in FIG. 5.3 chassis, consisting of one power supply and two gear units; in FIG. 5.4 chassis, consisting of two gear units with two power supplies located on top.

 The advantage of the model is that with the release of its various modifications (new products) does not require a significant change in technological equipment. Re-equipment is carried out by about 3% by replacing molds for the manufacture of a new housing. The elements of the chassis do not change. Due to this, the production time is reduced and the cost of the new model is reduced. YYY1 YYY2 YYY3 YYY4

Claims (3)

 1. A prefabricated model of a toy electromechanical vehicle containing a chassis, axles and connecting elements, consisting of protrusions and grooves of the corresponding profiles, characterized in that the chassis is prefabricated and contains power supplies with a switch and gear units connected by axles of the driving wheels to the holders of microelectric motors, wherein the power supplies are connected to the gear units by connecting elements, the protrusions and grooves of which are made according to the dovetail type and are located on the outer surfaces of the approx housings power units and gear unit housing perimeter.  2. The model according to claim 1, characterized in that the connecting elements are located on opposite walls of the housing of the power supplies inverted.  3. The model according to claim 1, characterized in that it contains additional connecting elements with grooves corresponding to the protrusions on the walls of the housings of the power supplies and gear units, and through holes in the protruding part for the axles of the driven wheels.

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