KR100580148B1 - A coin hopper - Google Patents

Abstract

[Solution]

It is an object of the present invention to prevent coin detection errors.

[Means for solving the problem]

Coiled core,

In a coin sensor having a detection circuit connected to the coil,

The relative surface of the core with respect to the coin is rectangular, and its long axis is orthogonal to the direction of coin movement.

Bulkhead, Bimetal Coin, Comparator, Reference Level Setting Circuit, Transistor, Discrimination Circuit, High-Pass Filter, Capacitor, Diode

Description

Coin Hopper {A COIN HOPPER}

1 is a perspective view of a coin sensor with a sensor unit of an embodiment of the invention.

2 is a detection circuit diagram of a coin sensor of an embodiment of the present invention.

3 is an explanatory diagram illustrating a relationship between a coin and a core according to the embodiment of the present invention.

4 is an explanatory view of the operation of FIG. 2.

5 is a perspective view of a coin hopper equipped with a conventional coin sensor.

6 is a schematic diagram of a conventional coin sensor and a detection circuit.

7 is an explanatory diagram of a relationship between a conventional coin and a core.

8 is an explanatory view of the operation of a conventional detection circuit.

[Description of the code]

1A ， 1B core 3 long axis

4A ， 4B Coil 5A ， 5B Bulkhead

6A, 6B Base 18 Detection Circuit

105 Coins 116 Direction

118 coin passage

The present invention relates to a coin sensor for non-contact detection of a coin moving along the coin passage.

In particular, the present invention relates to a coin sensor for detecting bimetallic coins without physical contact.

The term " coin " as used herein is a generic term for not only coins but also medals and tokens.

A coin hopper is known as a device for dispensing coins one by one.

As shown in FIG. 5, the coin hopper 101 dispenses the coins C stored in the bowl 104 one by one from the outlet 106 by the rotating disk 103 rotating over the base 102. .

The coin C withdrawn from the exit 106 passes after the coin sensor 107 and is withdrawn from the dispensing slot 108.

The coin sensor 107 uses a proximity sensor, for example, a coil connected to an oscillation circuit.

In such a sensor, it is known that when a metal approaches a coil, a reduced high frequency current is detected in the coil (see JP-A-7-311273).

In this prior art, a pair of coils formed in a spiral shape are spaced apart from the substrate at predetermined intervals, and a high frequency current flows between these coils.

Pachinko beads, tokens, and the like that pass between these coils are detected in a non-contact manner.

In this structure, the coil is not wound around the core.

Thus, the magnetic flux is circular on the end face.

As a result, the focusing of the magnetic flux is insufficient.

Therefore, more power is used, that is, a significant amount of power is required.

As for focusing the magnetic flux, a coin sensor as shown in Fig. 6 is known.

The sensor 114 is wound around the coil 113 around the winding portion 112 in the form of a magnetic body.

The winding part 112 has a rectangular pillar shape, and as shown in FIG. 7, the longitudinal axis is parallel to the traveling direction 116 of the coin 105.

The sensors 114 are arranged to face each other to constitute the sensor unit 117.

The area between these sensors 114 is the coin passage 118.

These coils 113 are connected in a cumulative mode and connected to the high frequency oscillation circuit 119.

The high frequency oscillation circuit 119 is connected to the transistor 122 which is a switching circuit via the detection circuit 121.

In this structure, when the coin 100 is made of a single material, an eddy current is generated in the coin 105 depending on the material.

As a result, since the oscillation energy is attenuated, oscillation of the coil 113 stops.

As a result, the coin 105 is detected because the transistor 122 is turned "on".

Bimetallic coin 105 is known, which consists of a disc 123 located at the center of ring 124.

Thus, the disc 123 is fitted to the ring 124.

Although the bimetallic coin 105 is apparently integrated, electrical characteristics are separated.

That is, when there is a gap between the outer edge of the disc 123 and the inner edge of the ring 124, the gap is electrically insulated.

This gap sometimes faces the end face of the winding part 112.

In this situation, since the end face of the winding part 112 faces the ring 124 as shown in FIG. 8, the output voltage of the detection circuit l21 drops from VO to V1 at a predetermined level. .

Subsequently, because the gap of the junction 125 faces the end face, the attenuation is temporarily weakened, and the output voltage rises to V2.

Next, since the end faces of the ring 124 and the winding portion 112 face each other, the ring 124 is lowered to a predetermined voltage V1.

The length of the junction of a conventional coin sensor with respect to the area of the end face is quite long.

This is because in the conventional sensor, as shown in FIG. 7, the long axis 115 of the end face of the winding part 112 is disposed in parallel with the traveling direction of the coin 105.

In other words, the area was large and the conventional sensor was greatly influenced by the junction 125.

If the length of the junction 125 is longer, the effect of this area is greater.

As a result, the output voltage V2 exceeds the reference voltage VB.

Thus, transistor 122 is temporarily turned "off" and the collector voltage is divided into two.

When the collector voltage is divided, the coin detection signal is not output because the output voltage V2 exceeds the reference voltage VB and the transistor 122 is temporarily turned "off".

In addition, since only one coin has passed, the divided signal is counted as a separate signal, resulting in two detection signals.

As a result, a count error for the coin occurs.

It is an object of the present invention to prevent coin detection errors.

More specifically, it is an object of the present invention to prevent the detection error of bimetallic coins.

The present invention includes the following configuration to solve the above problems.

Coil wound core ，

In a coin sensor comprising a detection circuit connected to the coil,

The relative surface of the core with respect to the coin is rectangular, and the long axis is orthogonal to the direction of movement of the coin.

In addition, a "rectangle" means a quadrangular shape having a long axis and a short axis.

For example, at least one side of the rectangle includes a rectangle having an arc shape.

In such a configuration, the joining portion of the bimetallic coin moves perpendicular to the long axis of the rectangular core.

In other words, the short axis of the core faces the junction.

Thus, the length of the joint to the opposite face of the core is significantly shorter than in the prior art.

Therefore, when there is a gap in the junction, the influence on the attenuation of the oscillation coil is reduced.

As a result, a detection error of the sensor does not occur.

The present invention is preferable because a partition wall made of magnetic material is disposed around the coil.

In this configuration, there is a partition of magnetic material around the coil.

The magnetic flux passing through the core passes through the partition wall to form a loop.

Therefore, when there is a metal around the core, no magnetic flux leaks out of the metal.

As a result, the detection error of the coin sensor is reduced.

In addition, the arrangement of the sensors is not limited.

This invention is preferable because the said core and the said partition are connected by the base.

In this configuration, the magnetic flux passing through the core passes through the core, the base and the partition wall to form a loop.

Therefore, leakage of magnetic flux is further reduced.

In addition, the arrangement of the sensors is not limited.

The present invention is preferable because a sensor having the core and the partition wall and a sensor of the same type are spaced apart from the sensor at predetermined intervals, and a coin passage is disposed between these sensors.

In such a configuration, the magnetic flux passes through a gap disposed between the facing cores.

The gaps are also arranged between opposite bulkheads.

Therefore, the magnetic flux density becomes higher.

As a result, energy efficiency is higher and energy consumption is reduced.

(Example)

1 is a perspective view of a coin sensor with a sensor unit of an embodiment of the invention.

2 is a detection circuit diagram of a coin sensor of an embodiment of the present invention.

3 is an explanatory diagram illustrating a relationship between a coin and a core according to the embodiment of the present invention.

4 is an explanatory view of the operation of FIG. 2.

The core 1A is formed of a ferromagnetic material and has a square pillar shape as shown in FIG. 1.

The end surface 2A of the core 1A is a rectangle, and the long axis 3 of this rectangle is orthogonal to the traveling direction 116 of the coin l05.

A coil wire is wound around the core 1A to form a coil 4A.

The coil 4A wound in a rectangular shape can be attached around the core 1A and fixed to the core 1A with an adhesive. However, when the copper wire is wound and closely adhered to the core 1A, the magnetic flux generating efficiency is high.

A rectangular ring-shaped partition 5A is located around the coil 4A.

In other words, the partition 5A surrounds the coil 4A.

The partition 5A is connected to the core 1A by the base 6A.

In other words, the core 1A, the partition 5A, and the base 6A are made by integral molding.

The sensor 7A includes a core 1A, a partition 5A, a base 6A, and a coil 4A.

The present invention includes at least a core 1A having a rectangular end face 2A and a coil 4A wound around the core 1A.

However, in the case of surrounding the coil 4A with the partition 5A, the magnetic flux focuses on the core 1A and forms a loop through the partition 5A.

Therefore, even if the metal is arrange | positioned around 5 A of partitions, detection accuracy is not influenced.

In addition, since the core 1A and the partition 5A are connected by the base 6A, and the magnetic flux forms a loop through the base 6A, the detection accuracy is not affected.

The sensor 7B is of the same shape as the sensor 7A and is arranged above the zone located opposite to the coin passage 118.

The constituent parts of the sensor 7B are replaced by B, which replaces A of the reference symbol of the sensor 7A.

In other words, the sensor 7A and the sensor 7B are relatively spaced apart from each other by a predetermined distance to constitute the sensor unit 9.

The sensor unit 9 is made of resin and is fixed to the recess 12 of the case 11 in the form of a pot, and the end faces 2A and 2B are disposed to face each other.

The recessed portion 12 is attached with a substrate 13 on which the detection circuit 16 is mounted.

The recess 12 is covered by a lid 14.

The board 15 is fixed with a connector 15 for communication with a control device (not shown).

Next, the detection circuit 16 will be described with reference to FIG. 2.

The coil 4B of the sensor 7B is connected to the oscillation circuit 17 of the Colpitt type.

The coil 4A of the sensor 7A is connected to the detection circuit 18.

The output of the detection circuit 18 is connected to the input terminal of the comparator 21.

The other input terminal of the comparator 21 is connected to the reference level setting circuit 22.

The output terminal of the comparator 21 is connected to the base terminal of the transistor which is the switching circuit 23.

The collector terminal of the transistor 23 is connected to a discriminating circuit (not shown).

The high-pass filter 24 is connected in parallel with a comparator 21 positioned between the detection circuit 18 and the transistor 23.

The high-pass filter 24 includes a resistor 25, a capacitor 26 connected in parallel to the resistor 25, and a diode 27 connected in series with the resistor 25.

Next, the operation will be described with reference to FIGS. 3 and 4.

First, the situation in which the coin C does not exist in the coin passage 118 and the high-pass filter 24 does not operate will be described.

Based on the high frequency current, the magnetic flux generated in the coil 4B of the sensor 7B is focused on the rectangular end face 2B of the core 1B and forms a loop through the partition 5B and the base 6B. .

The magnetic flux of the core 1A based on the magnetic flux is focused on the rectangular end face 2A of the core 1A of the sensor 7A, and forms a loop through the partition 5A and the base 6A.

Therefore, an induced current is generated in the coil 4A, and the detection circuit 18 outputs a predetermined voltage VO.

This voltage VO is higher than the reference voltage VB of the reference level setting circuit 22, so that the output of the comparator 21 is at a high level.

Thus, the transistor 23 is in the "on" state.

When the coin 105 is discharged from the outlet 106, almost half of the diameter of the coin 105 passes through the coin passage 118 located between the sensor 7A and the sensor 7B.

In other words, as shown in FIG. 3, the coin 105 moves in a direction orthogonal to the long axis 3 of the rectangular end face 2A of the core 1A.

Therefore, the junction part 125 of the bimetallic coin 105 moves in the direction orthogonal to the long axis 3.

In this movement process, the ring 124 of the coin 105 first faces the rectangular end faces 2A and 2B.

Therefore, induction current is generated in the coil 4A according to the material of the ring 124.

The detection circuit 18 outputs the voltage V1 based on the induced current.

The comparator 21 compares this voltage V1 with the reference voltage VB of the reference level setting circuit 22.

When the voltage V1 is lower than the reference voltage VB, the output becomes "low".

When the output goes low, the transistor 23 is turned "off" and a coin detection signal is output.

In this situation, since the voltage V1 is lower than the reference voltage VB, the output of the comparator 21 goes low.

Next, the joining portions 125 face the rectangular end surfaces 2A and 2B.

In this situation, the junction 125 is orthogonal to the long axis 3 of the end faces 2A and 2B.

The opposing length of the junction part 125 and the end faces 2A and 2B is about the same length as the short axis of the end faces 2A and 2B.

Therefore, when there is a gap in the junction part 125, the eddy current according to the magnetic flux which passes through the coin 105 other than the junction part 125 generate | occur | produces in the coin 105.

The length of the junction part 125 is extremely shorter than the area of 2 A of end surfaces.

Eddy current is generated in accordance with the magnetic flux passing through the disk 123 and the ring 124.

In addition, induction current according to the reduced magnetic flux is generated in the coil 4A.

The output of the detection circuit 18 instantly rises to the voltage V2, but the amount of change is small.

Because the change amount of this voltage V2 is small. The voltage V2 does not rise to the reference voltage VB, and the transistor 23 continues in the "off" state.

The ring 124 then faces the rectangular end faces 2A and 2B and the output of the detection circuit 18 drops to the voltage V1.

After the coin 105 passes, the output of the detection circuit 18 returns to the voltage VO.

Therefore, the collector voltage E1 of the transistor 23 is in the form of one pulse, and as a result, no count error occurs.

Next, the operation when the high-pass filter 24 is operated will be described.

When there is a gap, the output voltage of the detection circuit 18 instantly rises to the voltage V2.

In other words, the input of the comparator 21 rises instantaneously.

However, immediately after the input of the comparator 21 rises, current flows through the capacitor 26 and the diode 27.

As a result, current is stored in the capacitor 26.

Therefore, as shown by the dashed line 29 in FIG. 4, the base voltage of the transistor 23 gradually rises.

In this ascending situation, the junction 125 is also out of the rectangular end faces 2A, 2B.

Therefore, the base voltage of the transistor 23 falls back to V1.

The base voltage rises only to V3, which is lower than V2.

As a result, it does not exceed the reference voltage VB.

In addition, when the high-pass filter 24 is added, since the amount of change in the input voltage becomes smaller, the output voltage does not exceed the reference voltage VB.

Therefore, the collector voltage of the transistor 23 continues in the "on" state even when there is a gap in the junction 125.

As a result, detection accuracy is further improved.

In the present invention, the detection circuit can be changed into coils 4A and 4B which are connected in a copper copper manner and connected to a conventional oscillation circuit and a switching circuit (for example, the circuit of FIG. 5 of JP-A-7-311273). have.

The same effect can be obtained even if comprised in this way.

According to the above structure, the detection error of a coin, more specifically, a bimetallic coin can be prevented.

Claims (4)

The rotary disk 103 arranges the ring 124 around the disc 123 and divides one unified bimetal coin from the outlet 106, and the coin discharged from the said outlet is coil 4A. In the coin hopper 101 which detects by the coin sensor including the core 1A wound up and the detection circuit 18 connected to the said coil 4A, and discharges it from the dispensing slot 108, The mating surface of the core 1A with respect to the coin is made rectangular, the long axis 3 is orthogonal to the coin moving direction 116, and the central portion of the long axis of the core is the A coin hopper, which is disposed so as to face the joint between the disc and the ring. The coin hopper according to claim 1, wherein a partition (5A) made of magnetic material is located around the coil (4A). The coin hopper according to claim 2, wherein the core (1A) and the partition wall (5A) are connected by a base (6A). 4. The sensor 4A having the core 1A and the partition wall 5A and a sensor 4B of the same type are spaced apart from the sensor 4A at predetermined intervals, Coin hopper, characterized in that the coin passage 118 is located between the sensors (4B).

Images