JP3122808U - Automatic DC power supply voltage adjustment device for running model railway vehicles - Google Patents

Abstract

A power supply voltage that enables power supply so that when a plurality of model railway vehicles having different speeds travel on the same track in the same direction, the plurality of model railway vehicles can travel without colliding with each other. Provide an automatic adjustment device.
When a traveling track of a railway model vehicle is electrically divided into a plurality of blocks and the traveling block of the railway model vehicle traveling at a low speed in advance detects the traveling of the railway model vehicle, the railway model vehicle Provides a power supply voltage automatic adjustment device with a function to reduce the power supply voltage to the adjacent track block on the opposite side of the traveling direction of the vehicle, and the traveling speed of the model train vehicle that travels at a high speed on the adjacent track block It is possible to avoid a collision with a model train that travels at a low speed in advance.
[Selection] Figure 4

Description

  The present invention relates to an apparatus for automatically adjusting the output voltage of a DC power supply for running a model train.

  More specifically, when a plurality of model trains are traveling in the same direction on a single track, the output voltage of the DC power supply for supplying power to the track is automatically adjusted so that the plurality of model trains collide with each other. The present invention relates to a direct-current power supply voltage automatic adjustment device that enables power supply to travel without running.

  In the model railroad, the power supplied to the left and right rails constituting the track is mainly supplied from the DC power source to the model train vehicle via the wheels, and the wheels are driven by the driving DC motor mounted on the model train vehicle. It is configured to run, and the speed control of the model railway vehicle is performed by raising and lowering the voltage of the DC power source that supplies power to the rail. Therefore, a plurality of model railway vehicles traveling on one track fed by one DC power source are controlled by the same voltage and cannot be controlled independently of each other. If the speed characteristics with respect to the received voltage differ, they will collide with each other and cannot be operated.

  As a prior art, in order to run a plurality of model railway vehicles arranged on this track, a control signal based on a different radio wave or signal current is transmitted to each model railway vehicle from a transmitter, etc. Is controlling each. As another method, the track is divided into a plurality of blocks, and a signal is transmitted to each of these blocks to control the plurality of model railway vehicles.

  However, in order to control a plurality of model railway vehicles using a control signal, environmental equipment such as a transmitter and a computer is required. Further, a receiver, a signal decoding device, and a control device are also provided on the model railcar side. Etc., and an expensive and complicated device is required.

  For convenience of explanation, in the conventional simple model train vehicle traveling system, the reason why a plurality of model train vehicles cannot travel in the same direction without colliding with each other on one track is shown in FIGS. b) It demonstrates with reference. FIG. 1 (a) shows an example of a conventional simple model train vehicle traveling system. When the voltages supplied to the two model train vehicles arranged in FIG. It is assumed that the model vehicle 12 is a vehicle having a low traveling speed and the model vehicle 13 is a vehicle having a high traveling speed.

  The DC power supply device 2 for running the model railway vehicle rectifies the power supplied from the AC plug 1 from AC to DC, and controls the DC power that is voltage-controlled in the range of about 0V to about 12V via the feeder lines 3 and 4. Is supplied to the outer peripheral rail 5 and the inner peripheral rail 6 respectively. Further, the DC power supply device 2 for running the model train has a DC output potential such that the feeder line 4 has a negative potential if the feeder line 3 is a positive potential, and the feeder line 4 has a positive potential if the feeder line 3 is a negative potential. Has polarity reversal function.

  FIG. 1 (b) shows an electrical connection structure of the model train, where the wheels 7 of the model train are electrically connected to the outer rail 5 and the wheels 8 are electrically connected to the inner rail 6. Each is connected to a driving motor 9 via wires 10 and 11.

  Therefore, if the feeder line 3 is a positive potential and the feeder line 4 is a negative potential, the wire 10 is a positive potential and the wire 11 is a negative potential. It has a structure that moves forward in the direction of the arrow shown in FIG. Further, if the feeder line 3 is a negative potential and the feeder line 4 is a positive potential, the wire 10 is a negative potential and the wire 11 is a positive potential. It is structured to run backward in the direction of the arrow shown in FIG. From the above description, if the power transmission loss due to the feeder lines 3 and 4 and the outer rail 5 and the inner rail 6 is ignored, the model train vehicles 12 and 13 both receive power of the same voltage and travel.

  The travel speed characteristics with respect to the received voltage of the model train that is driven by the drive motor 9 tend to be different for each model train, and the model travels by receiving the same voltage supplied by the model model vehicle DC power supply 2. There is a difference in traveling speed between the model train cars 12 and 13, and in the system shown in FIG. 1 (a), even if the track composed of the outer peripheral rail 5 and the inner peripheral rail 6 travels in the same direction, they will eventually collide. Become.

  Therefore, the problem to be solved by the present invention is that a plurality of model trains travel in the same direction on one track without colliding with each other by an inexpensive and simple method without modifying conventional model trains. An object of the present invention is to provide an apparatus that enables the above.

  The means of the present invention will be described with reference to FIGS. In order to avoid confusion, it is assumed that the feeder line 3 shown in FIG. 1A is a positive potential, the feeder line 4 is a negative potential, the feeder line 16 shown in FIG. 2 is a positive potential, and the feeder line 4 is a negative potential. A description will be given by comparing FIG. Moreover, the position of the model train vehicles 12 and 13 shown in FIG. 1A and FIG. 2 indicates the position where each model train is traveling and traveling.

  As an example of means for solving the above problems, in the present invention, first, the outer peripheral rail 5 shown in FIG. 1A is electrically divided into three blocks using rail gaps 24, 25 and 26 as shown in FIG. Divided into the outer rail 21, the outer rail 22, and the outer rail 23, and then, instead of the feeder wire 3 for connecting the DC power supply device 2 for running the model train and the outer rail 5 shown in FIG. As shown, the feeder line 16 connects the DC power supply device 2 for running the model train and the DC power supply voltage automatic adjustment device 17, and further, the feeder wire 18 and the feeder wire 19 connected to the DC power supply voltage automatic adjustment device 17, Feeder wires 20 are connected to an outer rail 21, an outer rail 22, and an outer rail 23, respectively. That is, in the conventional system shown in FIG. 1 (a), the positive potential side of the DC power supply device 2 for running a model train is a system in which power is supplied to the outer rail 5 via the feeder line 3. In the embodiment of the apparatus, as shown in FIG. 2, the positive potential side power of the DC power supply device 2 for running a model train is supplied to the outer rail 21, the outer rail 22, and the like via the feeder line 16 and the DC power supply voltage automatic adjusting device 17. In this system, power is supplied to each of the outer peripheral rails 23.

  The positive potential side power is supplied to each of the outer rail 21, outer rail 22 and outer rail 23 from the DC power supply voltage automatic adjusting device 17 which is the device of the present invention via the feeder wire 18, feeder wire 19 and feeder wire 20. However, the power feeding methods to these three rails are different from each other and have the characteristics described below. The positive potential side power fed from the feeder line 20 to the outer rail 23 passes through the feeder line 3 except that there is a voltage loss due to a diode (details will be described later) built in the DC power supply voltage automatic adjustment device 17. It is the same as the positive potential side power supplied to the outer rail 5 and the traveling speed difference between the model train 12 and the model train 13 on the track constituted by the outer rail 5 and the inner rail 6 in FIG. In FIG. 2, the traveling speed difference between the model train 12 and the model train 13 on the track constituted by the outer rail 23 and the inner rail 6 is substantially the same. The positive potential side power supplied from the feeder line 18 to the outer rail 21 is substantially the same as the positive potential side power supplied from the feeder line 20 to the outer rail 23 (details will be described later). In addition to the function of supplying power from the feeder line 18 to the outer peripheral rail 21, the adjusting device 17 includes whether the model train 12 or the model train 13 exists on the track constituted by the outer periphery rail 21 and the inner periphery rail 6. Has a detection function. Therefore, the traveling speed of the model train vehicles 12 and 13 on the track constituted by the outer peripheral rail 21 and the inner peripheral rail 6 is the same as the traveling speed on the track constituted by the outer peripheral rail 23 and the inner peripheral rail 6, respectively. is there. With respect to the positive potential side electric power fed from the feeder line 19 to the outer rail 22, when either the model train 12 or the model train 13 does not exist on the track constituted by the outer rail 21 and the inner rail 6. Electric power equivalent to that of the feeder line 18 or the feeder line 20 is supplied, and the traveling speeds of the model train cars 12 and 13 are the same as the traveling speeds on the track constituted by the outer peripheral rail 23 and the inner peripheral rail 6, respectively. When either the model train vehicle 12 or the model train vehicle 13 exists on the track formed by the outer rail 21 and the inner rail 6, the positive potential side voltage is reduced to reduce the power supply. , 13 travel speed is lower than the travel speed on the track constituted by the outer peripheral rail 23 and the inner peripheral rail 6. In the following description, this reduced speed travel is referred to as deceleration travel, and the other travel that is not decelerated is referred to as normal travel.

  The effect of the deceleration traveling by the control of the DC power supply automatic adjusting device 17 described above will be described with reference to FIGS.

  Assuming that the model train 12 and the model train 13 are both moving forward in the direction of the model train travel 14 at the position shown in FIG. 2, the travel speed of the model train 13 is as follows. Since it is assumed that the traveling speed is higher than the traveling speed, the distance between the model train 12 and the model train 13 decreases as the vehicle travels, and the positional relationship shown in FIG. 3 is obtained. At this time, the model railway vehicle 12 is traveling on the track constituted by the outer peripheral rail 22 and the inner peripheral rail 6, but there is no model railway vehicle on the track constituted by the outer peripheral rail 21 and the inner peripheral rail 6. To drive normally.

  Further, as shown in FIG. 4, the train model vehicle 12 travels on a track composed of the outer peripheral rail 21 and the inner peripheral rail 6, and the model train vehicle 13 is composed of the outer peripheral rail 22 and the inner peripheral rail 6. If the DC power supply voltage automatic adjusting device 17 detects that the model railway vehicle 12 is on the track constituted by the outer peripheral rail 21 and the inner peripheral rail 6 via the feeder line 18, As a result of lowering the positive potential side voltage supplied to the outer rail 22 and reducing the supplied power, the model train 13 traveling on the track constituted by the outer rail 22 and the inner rail 6 decelerates. On the other hand, the model train 12 is traveling normally, and the deceleration travel speed of the model train 13 can be set lower than the normal travel speed of the model train 12 (details will be described later). The distance from the vehicle 13 is increased.

  Further, as shown in FIG. 5, the train model vehicle 12 moves on a track constituted by the outer peripheral rail 23 and the inner peripheral rail 6, and the model train vehicle 13 is constituted by the outer peripheral rail 22 and the inner peripheral rail 6. If it is on the track, there is no model railway vehicle on the track constituted by the outer peripheral rail 21 and the inner peripheral rail 6, and the DC power supply voltage automatic adjusting device 17 supplies the outer rail 22 from the feeder line 19 with a positive potential side voltage. As a result of recovering the decrease, the power supplied is restored. As a result, the power supplied to the track constituted by the outer peripheral rail 22 and the inner peripheral rail 6 is also recovered, and the model railway vehicle 13 shifts from the deceleration travel to the normal travel.

  FIG. 6 shows that the train model vehicle 12 further traveled is on a track composed of the outer peripheral rail 23 and the inner peripheral rail 6, and the model train vehicle 13 is on a track composed of the outer peripheral rail 21 and the inner peripheral rail 6. In this case, both the model train 12 and the model train 13 travel normally. In this way, even if the high-speed model railway vehicle 13 narrows the distance from the model railway vehicle 12, if the positional relationship between the two models is as shown in FIG. Because it spreads, you can continue endless running while avoiding collisions.

  As described above, according to the present invention, when a plurality of model trains are driven in the same direction on one track, the distance between the model train 12 having a low speed and the model train 13 having a high speed is reduced. However, since the distance between the model train 13 and the model train 13 can be increased when the model train 12 passes on the track formed by the outer peripheral rail 21 and the inner track 6, the model train 13 having a higher speed can be used as a model train with a lower speed. A direct-current power supply voltage automatic adjustment device 17 that enables traveling to avoid catching up with 12 is provided.

  In the description so far, it is assumed that the feeder line 16 shown in FIG. 2 is a positive potential and the feeder line 4 is a negative potential. However, if the feeder line 16 is a negative potential and the feeder line 4 is a positive potential, the railway model is assumed. Both the vehicle 12 and the model train 13 travel backward in the direction 15 of the model train travel. At this time, the function of changing the DC power supply output voltage with respect to the feeder line 19 of the DC power supply voltage automatic adjusting device 17 does not operate, and both model trains only run normally, so the model train 13 having a high speed has a low speed. At this time, the inner rail 6 is electrically divided into three blocks, and a DC power supply voltage automatic adjusting device 17 is separately added to the feeder line 4 side. Since it can solve, description is abbreviate | omitted.

  As described above in detail, according to the present invention, a plurality of model railway vehicles having different traveling speeds on one track can be driven in the same direction without colliding with each other.

  An automatic DC power supply voltage adjusting apparatus for running a model railway vehicle according to the present invention will be described with reference to FIG.

  First, the operation of the internal circuit of the DC power supply voltage automatic adjusting device 17 shown in FIG. 7 will be described. In order to avoid confusion, a case will be described in which the power output feeder line 16 of the DC power supply device 2 for running the model train vehicle outputs a positive potential power and the feeder line 4 outputs a negative potential power. The resistors 39, 40, and 41 are equivalent resistors that consume power equivalent to that of the model railway vehicle. The outer peripheral rails 21, 22, 23 and the inner peripheral rail 6 are not only rails but also electric wirings. In this case, the model train travels forward in the direction 14 of the model train travel.

  Under the above premise, the power source current paths in the circuit shown in FIG. 7 are the five paths described below. In the first route, the positive potential output of the DC power supply device 2 for running the model train is sequentially supplied from the feeder line 16 via the diode 36, the feeder line 20, the outer rail 23, the resistor 41, the inner rail 6, and the feeder line 4. This is a route leading to a negative potential output of the DC power supply device 2 for running the model train. In the second route, the positive potential output of the DC power supply device 2 for running the model train is connected in order from the feeder line 16 to the diode 36, the diode 35, the feeder line 18, the outer rail 21, the resistor 39, the inner rail 6, and the feeder line 4. This is a route that leads to the negative potential output of the DC power supply device 2 for traveling the model train. The third route is that the plus potential output of the DC power supply device 2 for running the model train is sequentially from the feeder line 16 via the resistor 32, the feeder line 19, the outer rail 22, the resistor 40, the inner rail 6, and the feeder line 4. This is a route leading to a negative potential output of the DC power supply device 2 for running the model train. The fourth path is that the positive potential output of the DC power supply device 2 for running the model train is connected to the transistor line 28, the resistor 29, the feeder line 18, the outer rail 21, the resistor 39, the inner rail 6, and the feeder line 4 sequentially from the feeder line 16. This is a route that leads to the negative potential output of the DC power supply device 2 for traveling the model train. The fifth path is that the positive potential output of the DC power supply device 2 for running the model train is connected to the resistor 30, the transistor 27, the feeder line 19, the outer rail 22, the resistor 40, the inner rail 6, and the feeder line 4 sequentially from the feeder line 16. This is a route that leads to the negative potential output of the DC power supply device 2 for traveling the model train.

  When the railway model vehicle (indicated by the resistor 41) is on the track composed of the outer peripheral rail 23 and the inner peripheral rail 6, the power supply current flows through the first path. The power supply voltage to the vehicle is a voltage obtained by subtracting the voltage drop due to the diode 36 from the output voltage of the DC power supply device 2 for running the model train. Further, when the model railway vehicle (indicated by the resistor 39) is on the track constituted by the outer peripheral rail 21 and the inner peripheral rail 6, the power source current flows through the second path. The power supply voltage to the model train is a voltage obtained by subtracting the voltage drop caused by the diodes 36 and 35 from the output voltage of the model model vehicle DC power supply 2, and a small value resistor 34 is connected in parallel with the diode 35. Therefore, the voltage drop of the diode 35 is negligible, and the power supply voltage to the model train is almost the same as that in the first route.

  When the model railway vehicle (indicated by resistance 40) is on a track composed of the outer peripheral rail 22 and the inner peripheral rail 6, another model railway vehicle (indicated by resistance 39) is on the outer rail. Since the power supply voltage to the model railway vehicle (indicated by the resistance 40) varies depending on whether or not the vehicle is on the track composed of the inner rail 21 and the inner rail 6, the circuit operation at this time will be described next. explain. First, when another model railway vehicle (indicated by the resistor 39) is not on the track formed by the outer peripheral rail 21 and the inner peripheral rail 6, the resistor 39 is removed from the outer peripheral rail 21 and the inner peripheral rail 6. The power supply current does not flow through the fourth path, which is equal to the state of being turned on, the transistor 28 is turned off and the transistor 27 is turned on. Therefore, in the model train vehicle (indicated by the resistor 40) on the track constituted by the outer peripheral rail 22 and the inner peripheral rail 6, the power source flowing through both the third route and the fifth route is provided. The sum of current flows, and at this time, the power supply voltage to the model railway vehicle (indicated by the resistor 40) is almost the same as that in the first route. Next, when another railway model vehicle (indicated by the resistor 39) is on a track constituted by the outer peripheral rail 21 and the inner peripheral rail 6, the resistor 39 is applied to the outer peripheral rail 21 and the inner peripheral rail 6. Since it is equal to the connected state, a power supply current flows through the fourth path, the transistor 28 is turned on, and the transistor 27 is turned off. Therefore, in the model train vehicle (indicated by the resistor 40) on the track composed of the outer peripheral rail 22 and the inner peripheral rail 6, no current flows through the fifth path, and the third path Only the power supply current via At this time, the voltage supplied to the model railway vehicle (indicated by the resistor 40) can be adjusted by selecting the value of the resistor 32. In other words, when the model railway vehicle (indicated by the resistor 39) is on the track composed of the outer peripheral rail 21 and the inner peripheral rail 6, it is on the track composed of the outer peripheral rail 22 and the inner peripheral rail 6. The traveling speed of a certain model railway vehicle (indicated by the resistance 40) can be adjusted by selecting the value of the resistance 32.

  The DC power supply voltage automatic adjusting device 17 according to the present invention is configured by one transistor 28, one resistor 29, and two diodes 35 and 36 for detecting a current generated by the running of the model train. I am trying. This circuit operation will be described in detail. The anode of the diode 36 is connected to the emitter of the transistor 28, and the cathode of the diode 35 is connected to the other end of the resistor 29 whose one end is connected to the base of the transistor 28. When the directional current flows, a forward voltage is generated between the cathode of the diode 35 and the anode of the diode 36, and the transistor 28 can be turned on. When no forward current flows through the diodes 35 and 36, no voltage is generated between the cathode of the diode 35 and the anode of the diode 36, so that the transistor 28 is turned off. In this system, the diode 35 is present when there is a railway model vehicle (indicated by the resistor 39) and when it does not exist on the track constituted by the outer peripheral rail 21 and the inner peripheral rail 6. 36, the forward current flows, so that the transistor 28 is turned on. When there is no forward current, the forward current does not flow through the diodes 35, 36, so that the transistor 28 is turned off. The detection of the current generated by is realized.

  Furthermore, the DC power supply voltage automatic adjusting device 17 of the present invention has a function of changing a DC power supply voltage supplied to the track block by one transistor 27 and three resistors 30, 31, 32. It is said. This circuit operation will be described in detail. The amount of current flowing in from the feeder line 16 and flowing out of the feeder line 19 is equal to the sum of the amount of current passing through the resistor 32 and the amount of current passing through the transistor 27, and is the output voltage and load of the DC power supply device 2 for running the model train. Under the condition in which the value of the resistor 40 is determined, the current passing through the resistor 32 is uniquely determined by the value of the resistor 32. However, the amount of current passing through the transistor 27 is determined when the transistor 27 is in the on state. 27 is sufficiently saturated and the value of the resistor 30 is sufficiently small, the amount of current passing through the transistor 27 is close to the amount of current uniquely determined by the value of the resistor 30, and the transistor 27 is turned off. Since the amount of current flowing through the transistor 27 and the resistor 30 is 0, the transistor 27 is turned on and off. As a result, a large difference is obtained in the amount of current passing through the transistor 27 from the state of the state. As a result, there is a difference in the amount of current flowing from the feeder line 16 and flowing out of the feeder line 19 when the transistor 27 is on. appear. That is, the transistor 28 is turned on when there is a model railway vehicle (indicated by the resistor 39) and when it does not exist on the track constituted by the outer rail 21 and the inner rail 6. Since the transistor 27 is turned off and the transistor 27 is turned off, the amount of current flowing in from the feeder line 16 and flowing out of the feeder line 19 is reduced, and the voltage applied to the resistor 40 as a load is also reduced. Since the transistor 27 is turned on, the amount of current flowing in from the feeder line 16 and flowing out from the feeder line 19 is increased, and the voltage applied to the model railway vehicle is changed by utilizing the increase in the voltage applied to the resistor 40 as a load. To achieve the purpose of adjusting the speed.

  In the above description, the case where the power output feeder line 16 of the DC power supply device 2 for driving the model train vehicle outputs a positive potential power and the feeder line 4 outputs a negative potential power is described. A case will be described in which the power output feeder line 16 of the DC power supply device 2 for running a model train vehicle outputs a negative potential power and the feeder line 4 outputs a positive potential power. In this case, the model train travels backward in the direction 15 of the model train travel.

  Under this premise, the power source current path in the circuit shown in FIG. 8 has three paths, a sixth path, a seventh path, and an eighth path described below. The sixth route is that the plus potential output of the DC power supply device 2 for running the model train is sequentially fed from the feeder line 4 through the inner peripheral rail 6, the resistor 39, the outer peripheral rail 21, the feeder line 18, the diode 37, and the feeder line 16. This is a route leading to a negative potential output of the DC power supply device 2 for running the model train. In the seventh route, the positive potential output of the DC power supply device 2 for running the model train is sequentially supplied from the feeder line 4 via the inner rail 6, the resistor 40, the outer rail 22, the feeder line 19, the diode 38, and the feeder line 16. This is a route leading to a negative potential output of the DC power supply device 2 for running the model train. In the eighth route, the positive potential output of the DC power supply device 2 for running the model train is connected to the inner rail 6, the resistor 41, the outer rail 23, the feeder wire 20, the diode 35, the diode 37, and the feeder wire 16 sequentially from the feeder line 4. This is a route that leads to the negative potential output of the DC power supply device 2 for traveling the model train. In other words, even if the model railway vehicle (indicated by the resistor 39) is on the track composed of the outer peripheral rail 21 and the inner peripheral rail 6, it is on the track composed of the outer peripheral rail 22 and the inner peripheral rail 6. Although the traveling speed of a certain model railway vehicle (indicated by the resistance 40) cannot be adjusted, it is possible to travel backward in normal traveling.

(A), (b) is a system diagram which shows an example of the conventional system for a simple model train vehicle running. (A) is a system diagram for comparing with the system diagram according to the embodiment of the device of the present invention, (b) is a system diagram showing the electrical connection of a conventional simple model railway vehicle. It is a system diagram showing an embodiment of the device of the present invention. It is a system diagram similarly, and is a diagram showing a state in which the model railway vehicle has moved from the position shown in FIG. It is a system diagram similarly, and is a diagram showing a state where the model railway vehicle has moved from the position shown in FIG. FIG. 5 is also a system diagram, and shows a state where the model railway vehicle has moved from the position shown in FIG. 4. FIG. 6 is also a system diagram showing a state in which the model railway vehicle has moved from the position shown in FIG. 5. It is a circuit diagram which shows the detail of the Example concerning this invention apparatus. (During forward travel) It is a circuit diagram which shows the detail of the Example concerning this invention apparatus. (During reverse travel)

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 AC plug 2 DC power supply device for model railway vehicle travel 3 Feeder line 4 Feeder line 5 Outer rail 6 Inner rail 7 Wheel 8 Wheel 9 Driving motor 10 Wire 11 Wire 12 Model train (low travel speed) vehicle)
13 Model train (vehicle with high running speed)
14 Direction of model train travel (forward, proceed in the direction of the arrow)
15 Direction of model train travel (retreat, proceed in the direction of the arrow)
16 Feeder line 17 DC power supply voltage automatic adjustment device 18 Feeder line 19 Feeder line 20 Feeder line 21 Outer rail 22 Outer rail 23 Outer rail 24 Rail gap 25 Rail gap 26 Rail gap 27 Transistor 28 Transistor 29 Resistance 30 Resistance 31 Resistance 32 Resistance 34 Resistance 35 Diode 36 Diode 37 Diode 38 Diode 39 Resistance (Equivalent resistance to model vehicle load)
40 Resistance (Equivalent resistance to model vehicle load)
41 Resistance (Equivalent resistance to model vehicle load)

Claims (4)

  A model train vehicle that travels on a track for traveling on a model train that consists of a pair of left and right rails and that is driven by power supplied from a rail that has a built-in DC motor for driving and is connected to a DC power supply. Forming multiple track blocks that can be cut by a length longer than the total length of a single train, and electrically connecting these track blocks together to connect them one after another. Detection of current generated by the running of a model railway vehicle between a DC power supply that supplies power to a plurality of track blocks constituting the track and each track block that receives power supply. A device having a function of changing a DC power supply voltage supplied to a circuit and a track block, in which the model railcar runs When the current generated by the model vehicle is detected, the direct current power supply voltage supplied to other track blocks can be changed to change the travel speed of the model train vehicle traveling on the track block. Automatic power supply voltage adjustment device. A direct current power supply voltage automatic adjustment device comprising a transistor, a resistor, and a diode as a detection circuit for a current generated by running the model railway vehicle. A direct-current power supply voltage automatic adjustment device comprising a transistor and a resistor for changing the direct-current power supply voltage supplied to the track block. A direct-current power supply voltage automatic adjusting device comprising a function of changing a direct-current power supply voltage supplied to the track block by an electromagnetic relay and a resistor.

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