JP3917203B2 - Pachinko ball detection device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a pachinko ball detection device that detects whether a pachinko ball has passed or not using a coil.
[0002]
[Prior art]
In pachinko machines, it is common to provide a proximity switch as a pachinko ball detection device for detecting pachinko balls won in the safe hole in a non-contact state. In this case, depending on the proximity of the pachinko balls Therefore, the use of a detection coil arranged so that the inductance changes is performed.
[0003]
Specifically, a conventional proximity switch includes a detection coil disposed in proximity to a passage portion through which a pachinko ball passes and an electronic circuit that detects an inductance change of the detection coil. The electronic circuit includes an oscillation circuit having a detection coil and a capacitor as a resonance element, a frequency detection circuit (detection circuit) capable of detecting a change in oscillation frequency of the oscillation circuit, A signal generation circuit that receives the output of the frequency detection circuit is included.
[0004]
In this case, generally, the oscillation circuit exhibits a resonance state in a state in which no pachinko ball is present in the passage hole, and is in an oscillation stopped state in accordance with a change in inductance of the detection coil when the pachinko ball passes through the passage hole. And a pachinko ball detection signal is output from the signal generation circuit when a change in the oscillation frequency of such an oscillation circuit is detected through the frequency detection means.
[0005]
[Problems to be solved by the invention]
In the proximity switch as described above, it is necessary to take measures against noise due to an external radio wave or the like because the detection coil is used. For this reason, conventionally, the whole is shielded by a shield member, or the oscillation frequency of the oscillation circuit is set to a band that is not easily affected by external radio waves.
[0006]
However, in the method using the shield member, a portion corresponding to the passage hole, that is, a portion corresponding to the detection coil must be opened, and a sufficient noise shielding effect cannot be expected. In addition, when the shield member has a shape close to the detection coil, the amount of change in the inductance of the detection coil when the pachinko ball passes through the passage hole is small, leading to a decrease in detection resolution. However, when the shield member is separated from the detection coil, there arises a new problem of increasing the overall size.
[0007]
Even when the oscillation frequency of the oscillation circuit is set to the above-described band, the following problems occur. In other words, in recent years, the spread of mobile phones has been remarkable, and it is not uncommon for pachinko gaming machine players to carry them. Accordingly, the proximity switch may malfunction due to the use of the mobile phone in the vicinity of the pachinko gaming machine. The cause of such a malfunction is that the radio waves (fundamental wave and harmonics) from the mobile phone are in a wide range, so the oscillation frequency of the oscillation circuit is set to a band that is not easily affected by external radio waves as described above. Even in this case, it interferes with the oscillation output of the oscillation circuit through the detection coil, the oscillation circuit is in a pseudo oscillation stop state in response to such interference, and the detection signal is erroneously output from the signal generation circuit. Conceivable.
[0008]
The present invention has been made in view of the above circumstances, and its purpose is to increase the overall size of malfunctions caused by external radio waves while being configured to detect a passing pachinko ball by changing the inductance of a detection coil. An object of the present invention is to provide a pachinko ball detection device that can effectively prevent the above-described problem while suppressing the above-described problem.
[0009]
[Means for Solving the Problems]
  In order to achieve the above object, a pachinko ball detection device according to the present invention is provided.A main body case, a pachinko ball passage that is provided in the main body case and through which the pachinko balls pass, and thisInstalled to correspond to pachinko ball passageFirstDetection coil and thisFirstThe detection coil is a resonant elementFirstOscillator circuitWhen, When the pachinko ball passes through the pachinko ball passageFirstChange of oscillation frequency of oscillation circuitA first frequency detection means for detecting the second detection coil, a second detection coil installed at a position facing the first detection coil across the pachinko ball path, and the second detection coil as a resonance element and the first A second oscillation circuit set to an oscillation frequency different from the oscillation circuit, a second frequency detection means for detecting a change in the oscillation frequency of the second oscillation circuit when the pachinko ball passes through the pachinko ball path, Due to the provision of signal generation means for outputting a pachinko ball detection signal only when both the first frequency detection means and the second frequency detection means are in a detection state, the signal is caused by an external radio wave without using a shield member. Prevented malfunctionIs.
[0014]
  According to this configuration, when the pachinko ball passes through the pachinko ball passage, the oscillation frequencies of the first oscillation circuit and the second oscillation circuit change according to the inductance change of the first detection coil and the second detection coil, These change states are detected by the first frequency detection means and the second frequency detection means. Thus, when both the first frequency detecting means and the second frequency detecting means are in the detection state, the signal generating means outputs a pachinko ball detection signal, so that the pachinko balls pass through the pachinko ball path. Detection of passing through is performed.In this case, since the first detection coil and the second detection coil are installed at positions facing each other across the pachinko ball passage, mutual induction between the first detection coil and the second detection coil. This reduces the influence of this and can suppress a decrease in resolution of pachinko ball detection.
[0015]
  UpSince the first oscillation circuit and the second oscillation circuit are configured so that their oscillation frequencies are different from each other, when an external radio wave interferes with the oscillation output of each oscillation circuit through the first detection coil and the second detection coil. Since the possibility that the oscillation frequencies change at the same time is reduced and the possibility that the detection signal is output from the signal generating means is reduced, it is possible to effectively prevent malfunction caused by the external radio wave as a result. Become. Further, since it is not necessary to provide a shield member as in the conventional configuration for noise countermeasures, it is possible to suppress the situation where the entire apparatus is enlarged due to the presence of the shield member..
[0021]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, the present invention is applied to a proximity sensor used in a pachinko machine.Is a reference example in caseA first embodiment will be described with reference to FIGS.
  FIG. 2 shows the appearance of the proximity sensor 1 (corresponding to a pachinko ball detection device). In FIG. 2, the proximity sensor 1 has a rectangular main body case 2, and the main body case 2 is provided with a passage hole 3 (corresponding to a pachinko ball passage) through which a pachinko ball passes.NoThe From the end surface of the main body case 2 opposite to the passage hole 3, an end portion of the printed wiring board 4 accommodated therein protrudes, and a pair of terminals (reference numeral 4a in FIG. 4b).
[0022]
FIG. 1 shows the electrical configuration of the proximity sensor 1 and the signal processing circuit 5 that receives the output thereof, which will be described below. The proximity sensor 1 is configured in a so-called DC two-wire system that receives power supply between the terminals 4a and 4b and outputs a sensing signal from the terminal 4b.
[0023]
The detection coil 6 is composed of, for example, a chip inductor, and is installed at a position corresponding to the passage hole 3 from the side as shown in FIG. The oscillation circuit 7 uses the detection coil 6 and a capacitor (not shown) as a resonance element. The oscillation circuit 7 exhibits a resonance state when no pachinko ball is present in the passage hole 3 and detects when the pachinko ball passes through the passage hole 3. The oscillation stop state is set according to the inductance change of the coil 6.
[0024]
The detection circuit 8 is provided so as to detect the change state of the oscillation frequency of the oscillation circuit 7, and the envelope output waveform is converted into a rectangular wave signal by the waveform shaping circuit 9, and its conversion output Is configured to be applied to the input terminal Q1 of the determination circuit 10 serving as invalidating means.
[0025]
Accordingly, when the oscillation circuit 7 is in a resonance state, that is, in a normal state where no pachinko balls are present in the passage hole 3, a high level signal is output from the waveform shaping circuit 9 and the input terminal Q1 of the determination circuit 10 Given to. Further, when the oscillation circuit 7 is in an oscillation stop state, that is, when the pachinko ball is in a state of passing through the passage hole 3, a low level signal is output from the waveform shaping circuit 9 and the input terminal of the determination circuit 10 It will be given to Q1.
[0026]
The auxiliary detection coil 11 is also constituted by a chip inductor, and is installed at a position spaced apart from the passage hole 3 and the detection coil 6 by a predetermined dimension or more as shown in FIG. In this case, the detection coil 6 and the auxiliary detection coil 11 are installed in a positional relationship in which mutual induction is unlikely to occur between them, for example, in a positional relationship in which the central axes of the coils 6 and 11 are orthogonal to each other.
[0027]
The auxiliary oscillation circuit 12 uses the auxiliary detection coil 11 and a capacitor (not shown) as resonance elements, and the oscillation frequency is set to be in a range equivalent to the oscillation frequency of the oscillation circuit 7.
[0028]
The auxiliary detection circuit 13 (corresponding to the frequency detection means) is provided so as to detect the change state of the oscillation frequency of the auxiliary oscillation circuit 12, and the envelope output waveform is converted into a rectangular wave signal by the auxiliary waveform shaping circuit 14. The conversion output is provided to the input terminal Q2 of the determination circuit 10.
[0029]
Therefore, when the auxiliary oscillation circuit 12 is in the resonance state, a high level signal is output from the auxiliary waveform shaping circuit 14 and is given to the input terminal Q2 of the determination circuit 10, and the auxiliary oscillation circuit 12 is in the oscillation stopped state. In this case, a low level signal is output from the auxiliary waveform shaping circuit 14 and is given to the input terminal Q2 of the determination circuit 10.
[0030]
The determination circuit 10 outputs a low level signal from the output terminal P only when a low level signal is applied to the input terminal Q1 while a high level signal is applied to the input terminal Q2. The high-level signal is output from the output terminal P, and the output signal from the terminal P of the determination circuit 10 is provided to the signal processing circuit 5 through the terminal 4b.
[0031]
The signal processing circuit 5 includes a voltage dividing circuit 5a that divides the output signal from the terminal 4b, an integration circuit 5b that receives the output of the voltage dividing circuit 5a, and an AND that receives the output of the integration circuit 5b and a reference voltage (5V). The circuit 5c is provided. In this case, the AND circuit 5c outputs a high level signal when a high level signal is output from the terminal 4b, but comprises a low level signal when a low level signal is output from the terminal 4b. A pachinko ball detection signal is output.
[0032]
Next, the operation of the above configuration will be described. That is, when the pachinko ball is not present in the passage hole 3, since the oscillation circuit 7 is in a resonance state, a high level signal is output from the waveform shaping circuit 9 and applied to the input terminal Q1 of the determination circuit 10. It has been. Further, since the auxiliary oscillation circuit 12 is also in a resonance state, a high level signal is output from the auxiliary waveform shaping circuit 14 and applied to the input terminal Q2 of the determination circuit 10. For this reason, the determination circuit 10 holds the state in which the high level signal is output from the output terminal P, and the signal processing circuit 5 that has received the high level signal through the terminal 4b outputs the high level signal. Will hold the state.
[0033]
From this state, when the pachinko ball passes through the passage hole 3, the oscillation circuit 7 comes into an oscillation stop state according to the inductance change of the detection coil 6 accompanying this, so that the waveform shaping circuit 9 makes a low level. A signal is output and applied to the input terminal Q1 of the determination circuit 10. In this case, the auxiliary detection coil 11 arranged at a predetermined distance or more away from the passage hole 3 is not affected by the passage of the pachinko ball, so that the auxiliary oscillation circuit 12 maintains the resonance state. For this reason, a high level signal is output from the auxiliary waveform shaping circuit 14 and applied to the input terminal Q2 of the determination circuit 10.
[0034]
The determination circuit 10 is configured to output a low level signal from the output terminal P only when a high level signal is applied to the input terminal Q2 as described above and a low level signal is applied to the input terminal Q1. The signal processing circuit 5 that has received the low level signal through the terminal 4b outputs a pachinko ball detection signal composed of the low level signal, so that it is detected that the pachinko ball has passed through the passage hole 3. Become.
[0035]
On the other hand, when an external radio wave interferes with the oscillation output of the oscillation circuit 7 through the detection coil 6 in the state where there is no pachinko ball in the passage hole 3, the oscillation frequency of the oscillation circuit 7 may change. In this case, normally, since the low-level signal is output from the waveform shaping circuit 9 and the low-level signal is output from the determination circuit 19, the proximity sensor 1 malfunctions. Become.
[0036]
However, according to the configuration of the present embodiment in which the auxiliary oscillation circuit 12 set to an oscillation frequency equivalent to that of the oscillation circuit 7 is provided, when the oscillation frequency of the oscillation circuit 7 changes due to external radio waves, Since the external radio wave interferes with the oscillation output of the auxiliary oscillation circuit 12 through the auxiliary detection coil 11 and the oscillation frequency of the auxiliary oscillation circuit 12 changes in the same manner as the oscillation circuit 7, the auxiliary waveform shaping circuit 14 Will output a low level signal.
[0037]
Then, the determination circuit 10 that has received the low-level signal at the output terminal Q2 holds the state in which the high-level signal is output from the output terminal P, so that the pachinko ball detection signal is output from the signal processing circuit 5. Nothing will happen. That is, since the determination circuit 10 invalidates the output from the waveform shaping circuit 9, as a result, there is no possibility that the proximity sensor 1 malfunctions due to the influence of external radio waves. In this case, in addition to the relatively weak radio waves from a mobile phone or the like, there is no possibility of malfunctioning with respect to intentionally radiated high-power external radio waves. Moreover, since it is not necessary to use a shield member as in the prior art, the overall size can be suppressed as much as possible.
[0038]
In the above embodiment, the passage hole 3 is provided in the main body case 2. However, the passage hole 3 may be provided if necessary, and in short, the detection coil 6 is located at a position corresponding to the pachinko ball passage. It only has to exist.
[0039]
Here, in the first embodiment, the detection coil 6 made of a chip inductor is used. However, as shown in FIG. 4, a loop coil arranged so as to surround the passage hole 3 is used as the detection coil 6. It is good also as a structure utilized as'. Also in this case, the auxiliary detection coil 11 is installed in a positional relationship in which mutual induction phenomenon is unlikely to occur with the detection coil 6 '.
[0040]
  5 and 6 show the present invention.Is an embodiment in which is applied to a proximity sensor used in a pachinko machineA second embodiment is shown, and only parts different from the first embodiment will be described below.
  As shown in FIG. 6, the proximity sensor 1 ′ according to the second embodiment places the first detection coil 15 and the second detection coil 16 each formed of a chip inductor at positions facing each other across the passage hole 3. It has an installed configuration.
[0041]
FIG. 5 shows the electrical configuration of the proximity sensor 1 ′ and the signal processing circuit 5 that receives the output from the proximity sensor 1 ′. Also in the present embodiment, the proximity sensor 1 'is configured in a DC two-wire system that receives power supply from between the terminals 4a and 4b and outputs a sensing signal from the terminal 4b.
[0042]
The first oscillation circuit 17 uses the first detection coil 15 and a capacitor (not shown) as a resonance element. The first oscillation circuit 17 exhibits a resonance state when no pachinko ball is present in the passage hole 3 and the pachinko ball passes through the passage hole 3. The oscillation is stopped according to the inductance change of the first detection coil 15 at the time.
[0043]
The first detection circuit 18 (corresponding to the first frequency detection means) is provided so as to detect the change state of the oscillation frequency of the first oscillation circuit 17, and the envelope output waveform is rectangular by the first waveform shaping circuit 19. The signal is converted into a wave signal, and the converted output is applied to the input terminal Q1 of the determination circuit 20 serving as a signal generating means.
[0044]
Therefore, when the first oscillation circuit 17 is in a resonance state, that is, in a normal state where no pachinko balls are present in the passage hole 3, a high level signal is output from the first waveform shaping circuit 19 and the determination circuit 20 Input terminal Q1. Further, when the first oscillation circuit 17 is in the oscillation stop state, that is, when the pachinko ball is in the state of passing through the passage hole 3, a low level signal is output from the first waveform shaping circuit 19 and the determination circuit 20 input terminals Q1.
[0045]
The second oscillation circuit 21 uses the second detection coil 16 and a capacitor (not shown) as a resonance element. The second oscillation circuit 21 exhibits a resonance state when no pachinko ball is present in the passage hole 3, and the pachinko ball passes through the passage hole 3. The oscillation is stopped according to the inductance change of the second detection coil 16 at the time.
[0046]
In this case, the second oscillation circuit 21 is set to have an oscillation frequency different from that of the first oscillation circuit 17. Specifically, the oscillation frequencies of the first oscillation circuit 17 and the second oscillation circuit 21 are set so as to have a non-integer multiple relationship.
[0047]
The second detection circuit 22 (corresponding to the second frequency detection means) is provided so as to detect the change state of the oscillation frequency of the second oscillation circuit 21, and its envelope output waveform is rectangular by the second waveform shaping circuit 23. The signal is converted into a wave signal, and the converted output is applied to the input terminal Q2 of the determination circuit 20.
[0048]
Accordingly, when the second oscillation circuit 21 is in a resonance state, that is, in a normal state where no pachinko balls are present in the passage hole 3, a high level signal is output from the second waveform shaping circuit 23 and the determination circuit 20 To the input terminal Q2. Further, when the second oscillation circuit 21 is in an oscillation stop state, that is, when the pachinko ball is in a state of passing through the passage hole 3, a low level signal is output from the second waveform shaping circuit 23, and the determination circuit 20 input terminals Q2.
[0049]
The determination circuit 20 is configured to output a low level signal from the output terminal P only when a high level signal is applied to both of the input terminals Q1 and Q2. In other states, the determination circuit 20 outputs a high level signal from the output terminal P. The level signal is output, and the output signal from the terminal P of the determination circuit 20 is provided to the signal processing circuit 5 through the terminal 4b.
[0050]
As a result of this configuration, the signal processing circuit 5 outputs a pachinko ball detection signal composed of a low level signal only when both the first oscillation circuit 19 and the second oscillation circuit 21 are in an oscillation stop state. .
[0051]
Next, the operation of the above configuration will be described. That is, when the pachinko ball is not present in the passage hole 3, the first waveform shaping circuit 19 and the second waveform shaping circuit 23 are in the resonance state because the first oscillation circuit 17 and the second oscillation circuit 21 are in a resonance state. High level signals are output from both of them.
[0052]
Accordingly, since the determination circuit 20 receives the high level signal at the input terminals Q1 and Q2, the determination circuit 20 holds the state where the high level signal is output from the output terminal P, and this high level signal is transmitted through the terminal 4b. The received signal processing circuit 5 holds the state in which the high level signal is output.
[0053]
When the pachinko ball passes through the passage hole 3 from such a state, the first oscillation circuit 17 and the second oscillation circuit 21 are changed according to the inductance change of the first detection coil 15 and the second detection coil 16 accompanying this. Since the oscillation is stopped, a low level signal is output from both the first waveform shaping circuit 19 and the second waveform shaping circuit 21 and is supplied to the input terminals Q1 and Q2 of the determination circuit 20.
[0054]
Then, since a low level signal is output from the determination circuit 20, the signal processing circuit 5 that has received this low level signal through the terminal 4b outputs a pachinko ball detection signal composed of the low level signal. A state where the ball has passed through the passage hole 3 is detected.
[0055]
In this case, since the first oscillation circuit 17 and the second oscillation circuit 21 are configured so that the respective oscillation frequencies are different from each other, external radio waves are transmitted through the first detection coil 15 and the second detection coil 16 and In the case of interfering with the 21 oscillation outputs, the possibility that those oscillation frequencies change simultaneously is reduced. For this reason, the possibility that a pachinko ball detection signal is output from the determination circuit 20 is reduced, and as a result, malfunction due to external radio waves can be effectively prevented.
Further, since the oscillation frequencies of the first oscillation circuit 17 and the second oscillation circuit 21 are set to have a non-integer multiple relationship, the first oscillation circuit 17 and the second oscillation circuit 21 are affected by the harmonics of external radio waves. The situation in which the oscillation frequency of the second oscillation circuit 21 changes at the same time is prevented in advance, so that the function of preventing malfunction caused by external radio waves can be reliably exhibited.
[0056]
Further, since the first detection coil 15 and the second detection coil 16 are installed at positions facing each other with the passage hole 3 therebetween, the influence of mutual induction between the first detection coil 15 and the second detection coil 16 is achieved. As a result, the resolution of pachinko ball detection can be suppressed. Further, as in the first embodiment, since it is not necessary to use a shield member, the overall enlargement can be suppressed as much as possible.
[0057]
Here, in the said 2nd Example, although the 1st detection coil 15 and the 2nd detection coil 16 both comprised with the chip inductor, the figure which represented the coil arrangement | positioning in the state which looked at the proximity sensor 1 'from the side. As shown in FIG. 7, instead of the second detection coil 16, a second detection coil 16 'constituted by a loop-shaped coil arranged so as to surround the passage hole 3 may be provided.
[0058]
In this case, the first detection coil 15 is installed in a positional relationship in which mutual induction phenomenon is unlikely to occur with the second detection coil 16 ′. Due to the mutual induction between the detection coil 15 and the second detection coil 16 ', a situation in which the resolution of the pachinko ball detection is lowered can be prevented in advance.
[0059]
  When the first detection coil 15 and the second detection coil 16 'are provided as described above, the present invention shown in FIGS.It is another Example which applied this to a proximity sensorThis may be configured as in the third embodiment, and only the parts different from the first embodiment will be described below.
[0060]
As shown in FIG. 9, in the proximity sensor 1 ″ according to the third embodiment, the third detection coil 24 constituted by a chip inductor is separated from the passage hole 3 and the detection coils 15 and 16 ′ by a predetermined dimension or more. In this case, the first to third detection coils 15, 16 ′ and 24 are in a positional relationship in which mutual induction phenomenon is unlikely to occur between each other, for example, the coils 15, 16 ′ and 24. The central axes are installed so as to be orthogonal to each other.
[0061]
FIG. 8 shows the electrical configuration of the proximity sensor 1 ″ and the signal processing circuit 5 that receives the output thereof. This will be described below. In this embodiment, the proximity sensor 1 ″ is also a terminal. The power source is supplied from between 4a and 4b, and a DC two-wire system is configured to output a sensing signal from the terminal 4b.
[0062]
The third oscillation circuit 25 uses the third detection coil 24 and a capacitor (not shown) as a resonance element. The third oscillation circuit 25 exhibits a resonance state in the absence of a pachinko ball in the passage hole 3 and the pachinko ball passes through the passage hole 3. The oscillation is stopped according to the inductance change of the third detection coil 24 at the time.
[0063]
The third detection circuit 26 (corresponding to the third frequency detection means) is provided so as to detect the change state of the oscillation frequency of the third oscillation circuit 25, and its envelope output waveform is rectangular by the third waveform shaping circuit 27. The signal is converted into a wave signal, and the converted output is applied to the input terminal Q3 of the determination circuit 20 'serving as a signal generating means.
[0064]
Therefore, when the third oscillation circuit 25 is in a resonance state, a high level signal is output from the third waveform shaping circuit 27 and is given to the input terminal Q3 of the determination circuit 20 ′, and the third oscillation circuit 25 is When the oscillation is stopped, a low level signal is output from the third waveform shaping circuit 27 and applied to the input terminal Q3 of the determination circuit 20 ′.
[0065]
In this case, in the determination circuit 20 ', a high level signal is applied to both the input terminals Q1 and Q2 in a state where a low level signal is applied to the input terminal Q3 (non-detection state of the third detection circuit 26). Only in this case, a low level signal is output from the output terminal P. In other states, a high level signal is output from the output terminal P.
[0066]
Therefore, according to this configuration, when the oscillation frequencies of the first oscillation circuit 17 and the second oscillation circuit 21 are changed simultaneously due to a high-power external radio wave, the oscillation frequency of the third oscillation circuit 25 also changes. Therefore, there is no possibility that a low level signal indicating the detection of the pachinko ball is output from the determination circuit 20 '. Therefore, in addition to a relatively weak radio wave from a mobile phone or the like, a high power radio wave is intentionally generated. It is possible to reliably prevent malfunction caused by radiation.
[0067]
【The invention's effect】
According to the present invention, as is apparent from the above description, the configuration is such that a plurality of detection coils and an oscillation circuit are provided while detecting the passing pachinko ball by the inductance change of the detection coil. Thus, it is possible to effectively prevent malfunction caused by external radio waves while suppressing the increase in the overall size.
[Brief description of the drawings]
FIG. 1 of the present inventionReference exampleElectrical configuration diagram showing the first embodiment
FIG. 2 is a perspective view of a proximity sensor.
FIG. 3 is a schematic plan view for explaining a coil arrangement.
FIG. 4 is a view corresponding to FIG.
FIG. 5 shows the present invention.Is an embodiment in which is applied to a proximity sensor used in a pachinko machineFIG. 1 equivalent view showing the second embodiment
6 is a view corresponding to FIG.
FIG. 7 is a schematic side view for explaining a coil arrangement.
FIG. 8It is another embodiment in which is applied to a proximity sensor used in a pachinko machine.FIG. 1 equivalent view showing the third embodiment
FIG. 9 is a view corresponding to FIG.
[Explanation of symbols]
In the drawing, 1, 1 ', 1 "are proximity sensors (pachinko ball detection devices), 2 is a main body case, 3 is a passage hole (pachinko ball passage), 5 is a signal processing circuit, 6 and 6' are detection coils, 7 Is an oscillation circuit, 10 is a determination circuit (invalidation means), 11 is an auxiliary detection coil, 12 is an auxiliary oscillation circuit, 13 is an auxiliary detection circuit (frequency detection means), 15 is a first detection coil, and 16 and 16 'are first detection coils. 2 detection coils, 17 is a first oscillation circuit, 18 is a first detection circuit (first frequency detection means), 20 and 20 'are determination circuits (signal generation means), 21 is a second oscillation circuit, and 22 is a second detection circuit. A circuit (second frequency detection means), 24 is a third detection coil, 25 is a third oscillation circuit, and 26 is a third detection circuit (third frequency detection means).

Claims (1)

A body case,
Pachinko ball passages that are provided in this main body case and through which pachinko balls pass,
A first detection coil installed to correspond to this pachinko ball path;
A first oscillation circuit using the first detection coil as a resonance element ;
First frequency detection means for detecting a change in oscillation frequency of the first oscillation circuit when the pachinko ball passes through the pachinko ball passage ;
A second detection coil installed at a position facing the first detection coil across the pachinko ball passage;
A second oscillation circuit having the second detection coil as a resonance element and set to an oscillation frequency different from that of the first oscillation circuit;
Second frequency detection means for detecting a change in oscillation frequency of the second oscillation circuit when the pachinko ball passes through the pachinko ball passage;
A signal generating means for outputting a pachinko ball detection signal only when both the first frequency detecting means and the second frequency detecting means are in a detection state;
Thus, a pachinko ball detecting apparatus characterized in that malfunction caused by external radio waves can be prevented without using a shield member .

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