JP2020040837A - Sheet transport device and image reader - Google Patents

Abstract

To make it possible to detect multi-feed with further good accuracy than a conventional one.SOLUTION: When deciding a threshold for detection of multi-feed, supersonic waves are dispatched at a first burst interval. When deciding multi-feed of a sheet, ultrasonic waves are dispatched at a second burst interval shorter than the first burst interval. In the state that there is no sheet on a transportation path, ultrasonic waves, which are dispatched at the first interval, are received, and a threshold, by which multi-feed and single feed can be discriminated based on an amplitude level of an outputted output signal, is decided.SELECTED DRAWING: Figure 12

Description

  The present invention relates to a technique for detecting the overlap of a plurality of sheets with a sheet conveying device or the like.

  In an image forming apparatus and an image reading apparatus, a sheet conveying apparatus for conveying a sheet is used. It is assumed that the sheets are conveyed one by one (referred to as “single feed”), and when a plurality of sheets are conveyed in an overlapping manner (referred to as “multi feed”), the conveyance of the sheets is stopped. You. According to Patent Literature 1, an ultrasonic sensor for detecting a double feed has been proposed. In particular, Patent Literature 1 proposes changing the degree of amplification of a received signal according to the sensitivity variation of the ultrasonic sensor.

JP 2012-188177 A

  By the way, the signal output from the ultrasonic sensor is amplified by the amplifier circuit, but the detection accuracy may be reduced by noise components such as external noise and semiconductor noise. In order to reduce the influence of noise, it is effective to transmit ultrasonic waves in bursts a plurality of times and average the detection results. However, when a burst transmission is performed, reverberation remains for a certain period of time, so that the next burst transmission cannot be performed until the reverberation disappears. The time interval between the preceding burst transmission and the subsequent burst transmission is called a burst interval. When the burst interval is set long, the effect of reverberation on subsequent burst transmissions is reduced. However, it may not be possible to detect double feed (double feed) in which the amount of overlap between the preceding sheet and the succeeding sheet is small. This is because, as the burst interval becomes longer, the number of times that the double feed detection can be performed during the conveyance of one sheet decreases. The threshold used to detect double feed is determined by performing burst transmission in the absence of a sheet. In the absence of a sheet, reverberation occurs for a long time, so the burst interval has to be lengthened. On the other hand, reverberation occurs over a shorter time in the presence of a sheet. Therefore, if the burst interval with sheets can be set shorter than the burst interval without sheets, the number of burst transmissions for one sheet can be increased, and the accuracy of double feed detection will be improved. . For example, it will be possible to detect even double feed. Therefore, an object of the present invention is to make it possible to detect a double feed more accurately than in the past.

The present invention provides, for example,
Conveying means for conveying the sheet in the conveying path,
Transmitting means that is mounted obliquely to the transport path and transmits ultrasonic waves,
Receiving means attached at an angle to the transport path, and attached to face the transmitting means, receiving the ultrasonic waves transmitted from the transmitting means,
Double feed detection means for detecting whether a plurality of sheets are multi-fed in the conveyance path by comparing the amplitude level of the output signal output from the reception means with a threshold,
When determining the threshold, the transmitting means transmits ultrasonic waves at a first burst interval, and when detecting double feeding of the sheet, the transmitting means at a second burst interval shorter than the first burst interval. Control means for transmitting ultrasonic waves to
It is possible to distinguish between double feed and single feed based on the amplitude level of the output signal output by the receiving unit receiving the ultrasonic wave transmitted by the transmitting unit at the first burst interval in a state where there is no sheet in the transport path. And a determining means for determining the threshold value.

  According to the present invention, double feed can be detected more accurately than in the past.

Diagram showing the configuration of the sheet conveying device Block diagram showing controller Diagram showing details near the ultrasonic sensor Diagram showing the principle of double feed detection Diagram showing details of amplifier and AD converter Diagram showing an example of an amplitude value of an output signal according to the presence or absence of a document Diagram showing the relationship between attenuation, amplitude value and ratio of ultrasonic waves Diagram explaining sampling points Diagram explaining the effects of reverberation Diagram explaining how to determine the amplitude Flow chart showing double feed detection Diagram explaining the difference between burst intervals Diagram explaining the principle of reverberation

  An embodiment of an image reading device will be described with reference to the drawings. Note that the image reading device may be a stand-alone image scanner, an image scanner connected to a network, a facsimile machine, a copier, or a multifunction peripheral. Further, the sheet conveying device may be mounted on the image forming apparatus.

<Image reading device>
In FIG. 1, the image reading device 115 has a sheet conveying device 100. The document tray 101 is a document table on which one or more sheets (documents 102) are placed. A paper feed roller 103 is provided downstream of the document tray 101 in the direction in which the document 102 is transported. The paper feed roller 103 is connected to the same drive source as the separation roller 104, rotates with the rotation, and feeds the document 102. The driven roller 105 is disposed to face the separation roller 104 and is pressed against the separation roller 104. The driven roller 105 may be formed of, for example, a rubber material having slightly less friction than the separation roller 104. The driven roller 105 cooperates with the separation roller 104 to separate and transport the document 102 fed by the sheet feeding roller 103 one by one.

  The sheet sensor S2 is a sensor for detecting the timing at which the document 102 has passed the driven roller 105 and the separation roller 104. The ultrasonic wave transmitting unit T1 and the ultrasonic wave receiving unit T2 are arranged so as to face each other across the transport path. When the ultrasonic wave transmitted by the ultrasonic wave transmitting unit T1 is received by the ultrasonic wave receiving unit T2, the presence or absence of the overlap of the originals 102 is detected.

  The registration roller pair 106 is a conveyance roller that corrects the skew of the document 102. The read roller pair 108 is a transport roller that transports the original 102 toward the reading glass 116. The platen guide 110 is arranged so as to face the drift reading glass 116. The image sensor 126 reads the image information of the surface of the document 102 passing over the drift reading glass 116. When the image sensor 126 finishes reading the document 102, the lead discharge roller pair 111 is a transport roller that transports the document 102 toward the discharge roller pair 113. The discharge roller pair 113 is a transport roller that discharges the document 102 to the discharge tray 114. Note that these transport rollers function as transport means for transporting the sheet in the transport path.

  The main body of the image reading device 115 includes a document table glass 118, a first mirror table 123, a second mirror table 124, a lens 125, an image sensor 126, and the like. The first mirror base 123 has a light source 119 for irradiating light to the surface to be read of the document 102, and a mirror 120 for guiding the reflected light from the document 102 to the image sensor 126. The second mirror stand 124 has mirrors 121 and 122 for guiding the reflected light from the document 102 to the image sensor 126. The first mirror table 123 and the second mirror table 124 read the document 102 placed on the document table glass 118 by moving in parallel with the document table glass 118. The image sensor 126 photoelectrically converts the reflected light imaged through the lens 125 with the light receiving element, and outputs an electric signal corresponding to the amount of incident light.

<Controller>
A controller that controls the image reading device 115 will be described with reference to FIG. The CPU 201 controls the image reading device 115 according to a control program stored in the ROM of the memory 206. The memory 206 also has a RAM. The CPU 201 drives various conveyance rollers in the sheet conveyance device 100 by controlling the motor 202. The CPU 201 detects the arrival timing of the document 102 using the sheet sensor S2, and controls the operation timing of the ultrasonic wave transmitting unit T1, the ultrasonic wave receiving unit T2, the AD converter 205, and the like.

  The ultrasonic transmission system has a drive circuit 203 and an ultrasonic transmission unit T1. The driving circuit 203 receives from the CPU 201 a burst signal having a frequency (300 kHz in this embodiment) close to the resonance frequency of the ultrasonic transmission unit T1 and the ultrasonic reception unit T2, and bursts a voltage necessary for driving the ultrasonic transmission unit T1. Convert to a signal. The ultrasonic transmitter T1 transmits an ultrasonic wave according to a burst signal from the drive circuit 203.

  The ultrasonic receiving system has an ultrasonic receiving unit T2, an amplifier 204, and an AD converter 205. The ultrasonic receiving unit T2 receives the ultrasonic waves transmitted from the ultrasonic transmitting unit T1, generates an electric signal corresponding to the amplitude of the received ultrasonic waves, and outputs the electric signal to the amplifier 204. The amplifier 204 amplifies the signal output from the ultrasonic receiving unit T2 and outputs the amplified signal to the AD converter 205. The AD converter 205 performs AD conversion on the signal amplified by the amplifier 204 according to the timing signal output from the CPU 201, and outputs the result to the CPU 201.

  The CPU 201 calculates the amplitude level of the received ultrasonic wave from the output of the AD converter 205, and detects double feeding of the document 102 based on the amplitude level. For example, by executing the control program, the CPU 201 functions as the ultrasonic control unit 211, the double feed detection unit 212, and the threshold value determination unit 213. When determining the threshold, the ultrasonic controller 211 causes the ultrasonic transmitter T1 to transmit an ultrasonic wave at the first burst interval. Further, when detecting the double feeding of the sheet, the ultrasonic controller 211 causes the ultrasonic transmitter T1 to transmit the ultrasonic wave at the second burst interval shorter than the first burst interval. The double feed detection unit 212 detects whether a plurality of sheets are multi-fed in the transport path by comparing the amplitude level of the output signal output from the ultrasonic receiving system with a threshold. The threshold value determining unit 213 performs double feed and single feed based on the amplitude level of the output signal output by the receiving system receiving the ultrasonic wave transmitted by the ultrasonic transmitting unit T1 at the first burst interval in a state where there is no sheet in the conveyance path. Is determined. Note that these functions may be implemented by hardware such as an ASIC or an FPGA. The memory 206 stores data necessary for control (threshold for double feed determination, coefficient for calculating the threshold, and the like).

<Installation angle of ultrasonic sensor>
FIG. 3 is an enlarged view of the vicinity of the ultrasonic sensor including the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2. In the present embodiment, the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2 are fixed to be inclined with respect to the transport path 301 on which the document 102 is transported. As shown in FIG. 3, an angle between a straight line (the output axis of the ultrasonic wave) connecting the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2 and the transport path 301 is the installation angle θ. That is, the ultrasonic wave transmitting unit T1 is an example of a transmitting unit that is mounted obliquely with respect to the transport path and transmits ultrasonic waves. Further, the ultrasonic receiving unit T2 is attached obliquely to the transport path, and is attached to face the ultrasonic transmitting unit T1, and receives an ultrasonic wave transmitted from the ultrasonic transmitting unit T1. (An output unit that outputs an output signal corresponding to the amplitude of a sound wave). Compared to the arrangement in which the emission axis (incident axis) is orthogonal to the transport path 301, the influence of reverberation is reduced in this inclined arrangement, so that the accuracy of double feed detection is improved. In the orthogonal arrangement, the reverberation is likely to continue because the ultrasonic wave is repeatedly reflected between the ultrasonic receiving unit T2 and the document 102. The installation angle θ is determined by experiments and simulations so as to maximize the detection accuracy.

  The ultrasonic waves transmitted from the ultrasonic transmitting unit T1 penetrate the document 102 and propagate to the ultrasonic receiving unit T2. The ultrasonic receiver T2 converts the intensity of the received ultrasonic wave into a voltage amplitude and outputs the voltage amplitude to the amplifier 204. The amplifier 204 amplifies the output signal from the ultrasonic receiving unit T2, and the CPU 201 receives the digital value obtained by AD conversion by the AD converter 205. The CPU 201 detects the presence or absence of double feeding of the document 102 by comparing a digital value indicating the amplitude level with a predetermined threshold.

<Double feed detection method>
FIGS. 4A to 4C are diagrams illustrating a mechanism for distinguishing between “single feed” and “double feed” of a document using an ultrasonic sensor. FIG. 4A shows the drive signal IN_T1 and the output signal OUT_T2 when there is no document between the ultrasonic wave transmission unit T1 and the ultrasonic wave reception unit T2. The drive signal IN_T1 is a signal input from the drive circuit 203 to the ultrasonic transmission unit T1. The drive signal IN_T1 is a burst signal including a continuous rectangular wave. The output signal OUT_T2 is a signal output from the ultrasonic receiving unit T2 to the amplifier 204. FIG. 4B shows the drive signal IN_T1 and the output signal OUT_T2 in a state where one document exists between the ultrasonic wave transmission unit T1 and the ultrasonic wave reception unit T2. FIG. 4C shows the drive signal IN_T1 and the output signal OUT_T2 in a state where there are two originals between the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2.

  A delay time Td is generated from the start timing of the burst signal of the drive signal IN_T1 to the start timing of the output signal OUT_T2. The delay time Td is a propagation time required for an ultrasonic wave to propagate from the ultrasonic wave transmitting unit T1 to the ultrasonic wave receiving unit T2.

  As can be seen from a comparison between FIG. 4A and FIG. 4B, when one document 102 exists between the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2, the ultrasonic waves are attenuated. The amplitude of the output signal OUT_T2 decreases. As can be seen from a comparison between FIG. 4B and FIG. 4C, when two originals 102 exist between the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2, the ultrasonic waves penetrate the original. Since the ultrasonic wave is attenuated every time, the amplitude of the output signal OUT_T2 further decreases. Therefore, by comparing the amplitude of the output signal OUT_T2 with a predetermined threshold, the CPU 201 can distinguish between “single feed” and “double feed”.

  Note that the amount of attenuation of the ultrasonic waves also differs depending on the thickness and type of the document 102. However, the difference in the amount of attenuation due to the difference in the number of sheets (one sheet or a plurality of sheets) of the document 102 is significantly larger than the change in the amount of attenuation due to the thickness and type of the document 102. Therefore, regardless of the thickness and type of the document 102, the CPU 201 can detect the double feed.

<Amplifier and AD converter>
FIG. 5 is a diagram showing details of the amplifier 204 and the AD converter 205. The amplifier 204 includes a plurality of stages of amplifier circuits in order to greatly amplify the minute output signal OUT_T2 from the ultrasonic receiving unit T2. According to FIG. 5, the amplifier 204 is constituted by a two-stage amplifier circuit such as inverting amplifier circuits 501 and 502 as an example. Note that the insides of the inverting amplifier circuits 501 and 502 may each be configured by a multi-stage amplifier circuit. The output of the inverting amplifier 501 is input to the AD converter 503, and the output of the inverting amplifier 502 is input to the AD converter 504. The attenuation amount and propagation time of the ultrasonic wave change due to the sensitivity variation of the ultrasonic sensor, the ambient temperature of the ultrasonic sensor, and the mounting error between the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2. Therefore, the CPU 201 detects the amplitude level of the ultrasonic wave when there is no document between the ultrasonic wave transmitting unit T1 and the ultrasonic wave receiving unit T2, and adjusts the threshold value according to the amplitude level. Further, the CPU 201 may adjust the sampling timing of the ultrasonic wave according to the reception timing of the ultrasonic wave at this time.

  However, as shown in FIGS. 4A to 4C, the amount of attenuation of the ultrasonic wave greatly differs between the state where there is no original and the state where there is an original as described above. Therefore, if the output signal OUT_T2 is amplified with the same amplification degree, the output signal in a state where there is no original may be saturated. That is, the amplitude of the output signal is too large and exceeds the output voltage range of the amplifier 204, or exceeds the input voltage range of the AD converter 205. In this case, the threshold cannot be determined correctly. Alternatively, the amplitude of the output signal OUT_T2 in a state where a document is present is too small and is buried in dark noise. In this case, it becomes impossible to distinguish between single feeding and double feeding of originals.

  By the way, the detection of the ultrasonic wave in a state where there is no document for determining the threshold value may be executed immediately before detecting the document. This may be advantageous in that the ambient temperature and the positional relationship between the ultrasonic sensors are the same between when the document is detected and when the threshold value is determined. Considering these, the configurations of the amplifier 204 and the AD converter 205 shown in FIG. 5 are advantageous.

  FIG. 6 is a diagram illustrating an example of an output signal output from the amplifier 204 to the AD converter 205. The input signal IN_AD1 is a signal output from the inverting amplification circuit 501 and input to the AD conversion circuit 503 when there is no document between the ultrasonic transmission unit T1 and the ultrasonic reception unit T2. The input signal IN_AD2 is a signal output from the inverting amplification circuit 502 and input to the AD conversion circuit 504 when there is no original between the ultrasonic transmission unit T1 and the ultrasonic reception unit T2. The input signal IN_AD1 is not saturated because it is amplified by the one-stage inverting amplifier circuit. On the other hand, since the input signal IN_AD2 is amplified by the two-stage inverting amplifier circuit, it is saturated. Therefore, when determining the threshold, the input signal IN_AD1 is employed. That is, the CPU 201 determines the threshold value using the output of the AD conversion circuit 503.

  The input signal IN_AD3 is a signal output from the inverting amplification circuit 501 and input to the AD conversion circuit 503 in a state where one document exists between the ultrasonic transmission unit T1 and the ultrasonic reception unit T2. The input signal IN_AD4 is a signal output from the inverting amplification circuit 502 and input to the AD conversion circuit 504 in a state where one document exists between the ultrasonic transmission unit T1 and the ultrasonic reception unit T2. Since the input signal IN_AD3 is amplified by the one-stage inverting amplifier circuit, it is not amplified to a sufficient amplitude level. On the other hand, since the input signal IN_AD4 is amplified by the two-stage inverting amplifier circuit, it is amplified to a sufficient amplitude level. Therefore, when detecting double feed, the input signal IN_AD4 is employed. That is, the CPU 201 detects the double feed using the output of the AD conversion circuit 504. Note that the polarity of the signal is inverted by the inverting amplifier circuits 501 and 502. However, since the signal amplitude is used in the double feed detection, reversal of the polarity is not a problem.

  With reference to FIGS. 7A and 7B, a description will be given of the characteristics of the ultrasonic wave and the method of detecting the double feed. As described above, the attenuation amount of the ultrasonic wave varies depending on the sensitivity variation (individual difference) of the ultrasonic sensor, the ambient temperature, the mounting error, and the like. Therefore, it is necessary to correct the threshold value for double feed detection according to the variation in the amount of attenuation. The CPU 201 determines a correction coefficient for correcting the threshold value using the amplitude level of the ultrasonic wave (the output of the AD conversion circuit 503) when there is no original between the ultrasonic wave transmitting unit T1 and the ultrasonic wave receiving unit T2. .

  FIG. 7A shows the relationship between the amount of attenuation of the ultrasonic wave transmitted from the ultrasonic wave transmission unit T1 to the ultrasonic wave reception unit T2 and the amplitude value of the signal input to the AD converter 205. C1 indicates an amplitude characteristic of a signal input to the AD conversion circuit 503 in a state where there is no document between the ultrasonic wave transmitting unit T1 and the ultrasonic wave receiving unit T2. C2 indicates an amplitude characteristic of a signal input to the AD conversion circuit 504 in a state where one document exists between the ultrasonic wave transmitting unit T1 and the ultrasonic wave receiving unit T2. In each case, the amplitude value decreases as the attenuation amount of the ultrasonic wave increases, and the amplitude value increases as the attenuation amount of the ultrasonic wave decreases.

  FIG. 7B is a diagram showing a ratio R between C1 and C2. As shown in FIG. 7B, even when the amount of attenuation of the ultrasonic wave fluctuates, the ratio between the amplitude value when there is no original and the amplitude value when there is the original becomes almost constant. That is, the CPU 201 can calculate the amplitude value with the original document with high accuracy by determining the amplitude value without the original document. Therefore, the CPU 201 can accurately determine a threshold value for distinguishing between “single feed” and “multiple feed” by acquiring an amplitude value in a state where there is no original. The threshold is determined or corrected to be between the amplitude value for “single feed” and the amplitude value for “double feed”.

  FIG. 8 is a diagram illustrating details of the amplitude calculation. The signal IN_AD amplified by the amplifier 204 is input to the AD converter 205 and sampled. The CPU 201 outputs an operation start signal to the AD converter 205 at a timing when a predetermined time has elapsed from the timing when the drive circuit 203 is instructed to start outputting the drive signal. Upon receiving the operation start signal, the AD converter 205 samples the signal IN_AD at a predetermined sampling interval, converts the signal IN_AD into a digital value, and outputs the digital value to the CPU 201. As shown in FIG. 8, sampling is performed over one cycle of the ultrasonic wave (drive signal). For example, for a drive signal of 300 [KHz], one cycle is 3.3 [μs]. As shown in FIG. 8, the start timing of the AD conversion is a timing at which the amplitude of the signal IN_AD becomes maximum. The period during which sampling is performed may be called a detection window or an amplitude detection period.

  In order to correctly detect the amplitude, the sampling interval needs to be sufficiently small with respect to the driving cycle of the ultrasonic wave (the cycle of the driving signal). In this embodiment, since the ultrasonic wave is generated by the driving signal of 300 [KHz], the period is 3.3 [μs]. When sampling is performed eight times for this cycle, the sampling interval is set to 0.41 [μs]. In this way, sampling is performed at a sufficiently small sampling interval with respect to the driving cycle of the ultrasonic wave, the minimum value and the maximum value are determined among the sampled values, and the difference is obtained, so that the arbitrary value of the received ultrasonic wave can be obtained. Is obtained for one wave.

Amplitude = MAX (A, B, C, D, E, F, G, H)-MIN (A, B, C, D, E, F, G, H) ... (1)
In FIG. 8, eight sample values A to H are obtained. MAX () is a function for determining the maximum value, and MIN () is a function for determining the minimum value. In FIG. 8, the sampling point A has the minimum voltage value of the signal IN_AD, and the sampling point E has the maximum voltage value. Therefore, the amplitude is determined by subtracting the voltage value of sampling point A from the voltage value of sampling point E.

  As described above, since the level of the output signal of the ultrasonic receiving unit T2 is very small, the amplification of the amplifier 204 is set to a large amplification. Therefore, the influence of external noise is large. Accurate amplitude may not be obtained with only one cycle of sampling results. Therefore, the CPU 201 obtains N sampling results for each sampling point by performing ultrasonic burst transmission N times, and performs statistical processing (eg, calculation of an average value) for each sampling point. For example, N may be set to eight. The CPU 201 determines the maximum value and the minimum value among the average values for each sampling point, and determines the difference as the amplitude.

  The shorter the burst interval, the shorter the time required for sampling, and the shorter the detection time required for one double feed detection. However, a problem arises when the burst interval is too short. As shown in FIG. 9, the subsequent ultrasonic wave is output while the reverberation generated by the output of the preceding ultrasonic wave remains, so that the reverberation is superimposed on the subsequent ultrasonic wave. This lowers the accuracy of the detection result (amplitude) of the ultrasonic wave. Therefore, the burst interval needs to be set to a time at which the reverberation of the ultrasonic wave immediately before the burst drive becomes sufficiently small. Note that the burst interval can be set at the time of shipment of the image reading apparatus from the factory by experiment or simulation.

  FIG. 10 shows an example in which a received ultrasonic wave is sampled at K sampling points (eg, eight locations) within one detection window. At each sampling point, the voltage value is sampled N times (eg, eight times). That is, N burst transmissions are performed.

  The CPU 201 executes sampling at the same sampling point for each of N burst transmissions, and averages the results. That is, in each of the N burst transmissions, the CPU 201 starts sampling after a predetermined period from the timing when the output of the drive signal is generated to the drive circuit 203. As a result, the phases (positions) of the sampling points coincide with each other N times. According to FIG. 10, at sampling point A, sample values of A [1] to A [8] are obtained, and they are averaged to obtain A [ave].

A [ave] = (A [1] + A [2] + A [3] + A [4] + A [5] + A [6] + A [7] + A [8]) / 8・ (2)
Even if ultrasonic waves are transmitted and detected a plurality of times, the sampling points hardly vary in the time direction. Therefore, external noise (variation in the amplitude direction) is reduced by the averaging.

<Flow chart>
FIG. 11 is a flowchart showing double feed detection. This flow is executed by the CPU 201 unless otherwise specified. When instructed to start reading the document 102 from the operation unit or the like, the CPU 201 executes the following processing.

  In step S101, the CPU 201 reads out and sets the first burst interval from the memory 206 as a burst interval of ultrasonic waves to determine a threshold for double feed detection, and outputs a burst signal at each first burst interval. The first burst interval is adjusted so that reverberation is less than an allowable limit in consideration of variations in the sensitivity of the ultrasonic sensor, the relative mounting positional relationship between the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2, temperature, atmospheric pressure, and the like. Is determined. As described above, the first burst interval is determined by experiment and simulation at the time of shipment from the factory. The drive circuit 203 converts the burst signal input from the CPU 201, generates a drive signal IN_T1, and outputs the drive signal IN_T1 to the ultrasonic transmission unit T1. The ultrasonic transmission unit T1 is driven by the drive signal IN_T1, and starts transmitting ultrasonic waves.

  In step S102, the CPU 201 starts detecting an ultrasonic wave. The CPU 201 sets a detection window at a timing when a predetermined time has elapsed from the timing at which the output of the burst signal is started, and causes the AD conversion circuit 503 to perform sampling at M sampling points. As described above, this processing is repeated N times, and the CPU 201 calculates the average value of the N sample values obtained at each sampling point, further determines the maximum value and the minimum value, and determines the maximum value and the minimum value. The amplitude is determined from the difference between The CPU 201 stores the amplitude in the RAM of the memory 206. Note that the signal sampled by the AD conversion circuit 503 is a signal amplified by the inverting amplifier circuit 501. Thus, saturation of the signal input to the AD conversion circuit 503 can be suppressed.

  In S103, the CPU 201 determines a threshold value for double feed detection based on the determined amplitude. As described with reference to FIG. 7B, even if the attenuation amount of the ultrasonic wave varies, the ratio R between the amplitude in the presence of the original and the amplitude in the absence of the original is constant. Therefore, the CPU 201 determines a threshold value by multiplying the amplitude value stored in the memory 206 by a predetermined correction coefficient, and stores the threshold value in the memory 206. The correction coefficient is, for example, 0.7. In order to determine the correction coefficient, among the various original documents available on the market, the original document with the largest amount of attenuation of the ultrasonic wave (the one with the smallest amplitude value of the output signal) is experimentally determined. The amplitude of the original with and without the original is measured, and the ratio R is obtained. The ratio R is multiplied by the margin Mg to determine the correction coefficient E. By using the margin Mg, even if the thick paper is conveyed, the possibility of being erroneously detected as a double feed is reduced.

  In step S <b> 104, the CPU 201 drives the motor 202 for rotating various transport rollers to start feeding and transporting the document 102. In step S105, the CPU 201 determines whether the leading edge of the document 102 has arrived at the sheet sensor S2 based on the detection signal of the sheet sensor S2. When the leading edge of the document 102 arrives at the sheet sensor S2, the CPU 201 proceeds to S106. In S106, the CPU 201 waits for a predetermined time Tw to elapse using a counter or a timer. This is to wait for the document 102 to move from the detection position of the sheet sensor S2 to the detection position of the ultrasonic sensor. Therefore, the CPU 201 waits for the elapse of the predetermined time Tw before proceeding to S107.

  In step S107, the CPU 201 reads out and sets a second burst interval from the memory 206 as a burst interval of the ultrasonic wave for double feed detection, and outputs a burst signal at each second burst interval. The second burst interval is shorter than the first burst interval. As described above, the second burst interval is also determined at the time of factory shipment by experiments and simulations. The first burst interval is determined by performing an experiment in the presence of a document, while the second burst interval is determined by performing an experiment in the absence of a document. The second burst interval also takes into account the variation in sensitivity of the ultrasonic sensor, the relative mounting positional relationship between the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2, the temperature, the atmospheric pressure, etc., so that the reverberation is below the allowable limit. It is determined. The drive circuit 203 converts the burst signal input from the CPU 201, generates a drive signal IN_T1, and outputs the drive signal IN_T1 to the ultrasonic transmission unit T1. The ultrasonic transmission unit T1 is driven by the drive signal IN_T1, and starts transmitting ultrasonic waves.

  In S108, the CPU 201 starts detecting the ultrasonic wave. The CPU 201 sets a detection window at a timing when a predetermined time has elapsed from the timing when the output of the burst signal is started, and causes the AD conversion circuit 504 to execute sampling at M sampling points. The AD conversion circuit 504 performs the sampling because the amplitude of the output signal OUT_T1 is reduced when the document 102 is present, so that a large amplification degree is required. As described above, this processing is repeated N times, and the CPU 201 obtains an average value from the N sample values obtained at each of the M sampling points, and calculates the maximum value and the minimum value among the M average values. Is determined, and the amplitude is determined from the difference between the maximum value and the minimum value.

  In step S109, the CPU 201 determines the presence or absence of the double feed based on whether the amplitude value exceeds the threshold. If the amplitude value exceeds the threshold value, the CPU 201 determines that the single feed is performed, and if the amplitude value does not exceed the threshold value, determines that the double feed is performed. Upon detecting single feed, the CPU 201 skips S110 and ends double feed detection. That is, an image is read for the sheet. On the other hand, if the double feed is detected, the CPU 201 proceeds to S110. In step S110, the CPU 201 stops the motor 202 and stops the conveyance of the document 102.

  By shortening the burst interval when there is a document compared to when there is no document, the double feed detection time can be reduced. Further, even when double feed occurs with a small overlap amount between originals, the CPU 201 can detect this.

  FIG. 12A is a diagram illustrating a relationship between the drive signal IN_T1 and the output signal OUT_T2 from the ultrasonic receiving unit T2 in the “document absence state”. FIG. 12B is a diagram illustrating a relationship between the drive signal IN_T1 and the output signal OUT_T2 from the ultrasonic receiving unit T2 in the “document present state”. Comparing FIG. 12A and FIG. 12B, the second burst interval in the “document present state” is shorter than the first burst interval in the “document non-present state”. Therefore, the ultrasonic detection can be completed in a shorter time in the “document present state” than in the “document non-present state”.

  By employing the second burst interval, the double feed detection time can be made shorter than before. When the double feed detection time can be shortened, a double feed with a small overlapping amount can be detected, such as a double feed in which the trailing edge of the preceding document overlaps the leading edge of the subsequent document. Conventionally, double feed detection cannot be completed while the portion where the trailing edge of the preceding document and the leading edge of the subsequent document overlap with each other passes the ultrasonic sensor, and the double feed may not be accurately detected. . On the other hand, in the present embodiment, the double feed can be detected with high accuracy.

<Reason for shortening burst interval>
12 (A), 12 (B), 13 (A) and 13 (B), the reason why the second burst interval in the state with the original can be shorter than the first burst interval in the state without the original. Will be described. According to FIGS. 12A and 12B, it can be seen that the reverberation duration in the state with the original is shorter than that in the state without the original. The reverberation is caused by multiple reflections of the ultrasonic waves generated between the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2. In particular, since the ultrasonic wave receiving unit T2 that has received the ultrasonic waves reflects the ultrasonic waves, it functions as a secondary wave source.

  FIG. 13A shows a state of propagation of ultrasonic waves in a state where there is no original. FIG. 13B shows a state of propagation of ultrasonic waves in a state where a document is present. In any case, the ultrasonic wave transmitting unit T1 and the ultrasonic wave receiving unit T2 are mounted obliquely with respect to the transport path 301 on which the document 102 is transported.

  As shown in FIG. 13A, in the absence of a document, first, an ultrasonic wave (primary wave) transmitted from the ultrasonic transmitting unit T1 reaches the ultrasonic receiving unit T2. When the ultrasonic wave reaches the ultrasonic receiving unit T2, the diaphragm provided in the ultrasonic receiving unit T2 vibrates, and this vibration is converted into electric energy, and the output signal OUT_T2 is generated. At the same time, the vibrating plate becomes a secondary wave source, and an ultrasonic wave is output (reflected) in the direction of the ultrasonic wave transmitting unit T1. This ultrasonic wave is reflected by the ultrasonic wave transmitting unit T1 and returns to the ultrasonic wave receiving unit T2. This action is repeated, and the reverberation continues until the ultrasonic wave is sufficiently attenuated by the energy loss at the time of reflection and the attenuation in the air.

  On the other hand, as shown in FIG. 13B, in the state where the original is present, part of the ultrasonic wave (primary wave) transmitted by the ultrasonic transmission unit T1 is reflected by the original 102, and the other part is transmitted and received. It reaches the section T2. When the ultrasonic wave reaches the ultrasonic receiving unit T2, the diaphragm of the ultrasonic receiving unit T2 vibrates, and an output signal OUT_T2 is generated. At the same time, the diaphragm becomes a secondary wave source, and an ultrasonic wave is output (reflected). The reflected ultrasonic waves reach the document 102, a part of which is reflected, and the remaining part is transmitted. The reflected ultrasonic wave propagates in another direction different from the direction of the ultrasonic wave transmitting unit T1 and the direction of the ultrasonic wave receiving unit T2. This is because the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2 are mounted obliquely with respect to the transport path 301. As described above, since only a part of the ultrasonic wave which travels in the direction of the ultrasonic transmitting unit T1 which may cause reverberation passes through the document 102, the intensity of the ultrasonic wave reaching the ultrasonic transmitting unit T1 is considerably reduced. That is, reverberation is sufficiently reduced in the document presence state in a shorter time than in the document absence state. As a result, the second burst interval in the document presence state can be set shorter than the first burst interval in the document absence state.

<Summary>
According to the present embodiment, the CPU 201 functions as the ultrasonic control unit 211, the double feed detection unit 212, and the threshold value determination unit 213 by executing the control program. When determining the threshold, the ultrasonic controller 211 causes the ultrasonic transmitter T1 to transmit an ultrasonic wave at the first burst interval. Further, when detecting the double feeding of the sheet, the ultrasonic controller 211 causes the ultrasonic transmitter T1 to transmit the ultrasonic wave at the second burst interval shorter than the first burst interval. The double feed detection unit 212 detects whether a plurality of sheets are multi-fed in the transport path by comparing the amplitude level of the output signal output from the ultrasonic receiving system with a threshold. The threshold value determining unit 213 performs double feed and single feed based on the amplitude level of the output signal output by the receiving system receiving the ultrasonic wave transmitted by the ultrasonic transmitting unit T1 at the first burst interval in a state where there is no sheet in the conveyance path. Is determined. In particular, the ultrasonic controller 211 causes the ultrasonic transmitter T1 to transmit an ultrasonic wave at the first burst interval when determining the threshold value, and the ultrasonic controller 211 detects the first sheet when detecting the double feed of the sheet. The ultrasonic transmitter T1 transmits ultrasonic waves at a second burst interval shorter than the burst interval. This makes it possible to increase the number of times multi-feed detection is performed per sheet as compared with the related art, thereby enabling more accurate multi-feed detection than before. For example, double feed can be detected even if the overlapping area is small, such as double feed, which is a phenomenon in which the trailing edge of the preceding sheet overlaps the leading edge of the succeeding sheet.

  The ultrasonic control unit 211 may determine a threshold value and perform double feed detection in one transport job. That is, the ultrasonic controller 211 controls the ultrasonic wave from the timing when the sheet is instructed to be conveyed until the sheet arrives between the ultrasonic transmitting unit T1 and the ultrasonic receiving unit T2 (with no sheet in the conveying path). The ultrasonic wave is transmitted from the transmitting unit T1, and the threshold value determining unit 213 determines the threshold value. When the sheet arrives between the ultrasonic transmitting section T1 and the ultrasonic receiving section T2, the double feed detecting section 212 uses the threshold value determined by the threshold value determining section 213 to determine whether or not multiple sheets are multi-fed. judge. Thereby, the state of the ultrasonic sensor at the time of determining the threshold can be made close to the state of the ultrasonic sensor at the time of double feed detection, and the accuracy of double feed detection is improved.

  As described with reference to FIG. 12A, the first burst interval is a time required for the reverberation of the ultrasonic wave transmitted from the ultrasonic transmitting unit T1 to be equal to or less than a predetermined allowable limit. As a result, the threshold value can be determined accurately. As described with reference to FIG. 12B, the second burst interval is a time required for the reverberation of the ultrasonic wave transmitted from the ultrasonic transmitting unit T1 to be equal to or less than a predetermined allowable limit. This makes it possible to accurately detect double feed.

  As described with respect to S103, the threshold value determination unit 213 may determine the threshold value by multiplying the amplitude level acquired in a state where there is no sheet in the transport path by the correction coefficient. Further, the threshold value determination unit 213 may determine the threshold value by multiplying the amplitude level acquired in a state where there is no sheet on the conveyance path by a correction coefficient and a margin. This makes it possible to determine the threshold value with high accuracy.

  As described with reference to FIG. 2, the ultrasonic receiving system includes the ultrasonic receiving unit T2, the amplifier 204, and the AD converter 205. The ultrasonic receiving unit T2 outputs an output signal corresponding to the amplitude of the ultrasonic wave transmitted by the ultrasonic transmitting unit T1. The amplifier 204 amplifies the output signal output from the ultrasonic receiving unit T2. The AD converter 205 converts the output signal amplified by the amplifier 204 from analog to digital. In particular, the amplifier 204 amplifies the output signal from the ultrasonic receiving unit T2 with the first amplification degree when determining the threshold value, and performs the first amplification when detecting whether a plurality of sheets are multi-fed. The output signal from the ultrasonic receiver T2 is amplified at a second amplification degree larger than the degree. This makes it possible to suppress saturation of the amplitude of the output signal when determining the threshold. Further, when detecting a double feed, even if the ultrasonic wave is attenuated by the sheet and the amplitude of the output signal from the ultrasonic receiving unit T2 becomes small, it is possible to amplify the double feed so that the double feed can be detected. .

  As described with reference to FIG. 5, the amplifier 204 includes the inverting amplifier circuit 501, which is the first amplifier stage, and the inverting amplifier circuit 502, which is the second amplifier stage connected after the first amplifier stage. May be. The AD converter 205 may include an AD conversion circuit 503 as a first conversion circuit that performs analog-to-digital conversion on the output signal amplified by the first amplification stage. In addition, the AD converter 205 may include an AD conversion circuit 504 as a second conversion circuit that performs analog-to-digital conversion of the output signal amplified by the first amplification stage and amplified by the second amplification stage. In this case, the threshold value determination unit 213 determines a threshold value using the amplitude level of the output signal output from the AD conversion circuit 503. As a result, the threshold value is determined using an amplitude level that is not saturated due to a small amplification degree. The double feed detection unit 212 detects whether a plurality of sheets are multi-feeding using the amplitude level of the output signal output from the AD conversion circuit 504. This makes it possible to detect a double feed even at an amplitude level reduced due to sheet attenuation.

  100: sheet conveying device, 115: image reading device, T1: ultrasonic transmitting unit, T2: ultrasonic receiving unit

The present invention provides, for example,
Conveying means for conveying the sheet in the conveying path,
And transmission means for transmitting an ultrasonic wave,
It mounted opposite before Symbol transmission means, receiving means for receiving the ultrasonic wave transmitted from said transmitting means,
Double feed detection means for detecting whether a plurality of sheets are multi-fed in the conveyance path by comparing the amplitude level of the output signal output from the reception means with a threshold,
A sheet detection unit that is disposed upstream of the transmission unit in the sheet conveyance direction and detects a sheet conveyed by the conveyance unit;
When determining the threshold, in the state where there is no sheet between the transmitting means and the receiving means, to transmit ultrasonic waves to the transmitting means at the first burst interval, and to detect the double feed of the sheet Control means for transmitting ultrasonic waves to the transmitting means at a second burst interval shorter than the first burst interval in a state where there is a sheet between the transmitting means and the receiving means ,
Double feed based on the amplitude level of the output signal output by the receiving means receiving the ultrasonic wave transmitted by the transmitting means at the first burst interval in a state where there is no sheet between the transmitting means and the receiving means. Determining means for determining the threshold that can distinguish between and single transmission,
Has,
The control means transmits ultrasonic waves to the transmitting means in a state where the sheet is not present between the transmitting means and the receiving means before the sheet reaches between the transmitting means and the receiving means. And causing the determination means to determine the threshold value, wherein the double feed detection means determines that the sheet is between the transmission means and the reception means a predetermined time after the sheet is detected by the sheet detection means. And detecting whether or not a plurality of sheets are multi-fed using the threshold value determined by the determination means .

Claims (9)

Conveying means for conveying the sheet in the conveying path,
Transmitting means that is mounted obliquely to the transport path and transmits ultrasonic waves,
Receiving means attached at an angle to the transport path, and attached to face the transmitting means, receiving the ultrasonic waves transmitted from the transmitting means,
Double feed detection means for detecting whether a plurality of sheets are multi-fed in the conveyance path by comparing the amplitude level of the output signal output from the reception means with a threshold,
When determining the threshold, the transmitting means transmits ultrasonic waves at a first burst interval, and when detecting double feeding of the sheet, the transmitting means at a second burst interval shorter than the first burst interval. Control means for transmitting ultrasonic waves to
It is possible to distinguish between double feed and single feed based on the amplitude level of the output signal output by the receiving unit receiving the ultrasonic wave transmitted by the transmitting unit at the first burst interval in a state where there is no sheet in the transport path. Determining means for determining the threshold value. The control unit transmits an ultrasonic wave to the transmission unit in a state where there is no sheet in the conveyance path from the timing when the conveyance of the sheet is instructed until the sheet reaches between the transmission unit and the reception unit. And causing the determination means to determine the threshold value,
The multi-feed detecting means, when the sheet reaches between the transmitting means and the receiving means, detects whether a plurality of sheets are multi-fed using the threshold determined by the determining means. The sheet conveying device according to claim 1, wherein:   3. The sheet conveying apparatus according to claim 1, wherein the first burst interval is a time required for the reverberation of the ultrasonic wave transmitted from the transmitting unit to be less than a predetermined allowable limit.   3. The sheet conveying apparatus according to claim 1, wherein the second burst interval is a time required for the reverberation of the ultrasonic wave transmitted from the transmitting unit to be less than a predetermined allowable limit.   5. The apparatus according to claim 1, wherein the determining unit determines the threshold by multiplying an amplitude level acquired in a state where there is no sheet in the transport path by a correction coefficient. 6. Sheet transport device.   5. The apparatus according to claim 1, wherein the determining unit determines the threshold by multiplying an amplitude level acquired in a state where there is no sheet in the conveyance path by a correction coefficient and a margin. The sheet conveying device as described in the above. The receiving means,
An output unit that is attached obliquely to the conveyance path, and is installed to face the transmission unit, and outputs an output signal corresponding to the amplitude of the ultrasonic wave.
Amplifying means for amplifying an output signal output from the output means,
Conversion means for converting the output signal amplified by the amplification means from analog to digital,
The amplification means amplifies the output signal from the output means at a first amplification degree when determining the threshold value, and detects the first amplification degree when detecting whether a plurality of sheets are multi-fed. The sheet conveying apparatus according to any one of claims 1 to 6, wherein an output signal from the output unit is amplified with a second amplification degree larger than the second amplification degree. The amplification means has a first amplification stage and a second amplification stage connected to a stage subsequent to the first amplification stage,
The conversion means, a first conversion circuit for analog-to-digital conversion of the output signal amplified in the first amplification stage, and an analog-to-digital output signal amplified in the first amplification stage and amplified in the second amplification stage A second conversion circuit for converting,
The determining means determines the threshold using an amplitude level of the output signal output by the first conversion circuit,
The sheet according to claim 7, wherein the double feed detecting unit detects whether or not a plurality of sheets are multi-fed using an amplitude level of the output signal output by the second conversion circuit. Transport device. Conveying means for conveying the sheet in the conveying path,
Transmitting means that is mounted obliquely to the transport path and transmits ultrasonic waves,
Receiving means attached at an angle to the transport path, and attached to face the transmitting means, receiving the ultrasonic waves transmitted from the transmitting means,
Double feed detection means for detecting whether a plurality of sheets are multi-fed in the conveyance path by comparing the amplitude level of the output signal output from the reception means with a threshold,
When determining the threshold, the transmitting means transmits ultrasonic waves at a first burst interval, and when detecting double feeding of the sheet, the transmitting means at a second burst interval shorter than the first burst interval. Control means for transmitting ultrasonic waves to
It is possible to distinguish between double feed and single feed based on the amplitude level of the output signal output by the receiving unit receiving the ultrasonic wave transmitted by the transmitting unit at the first burst interval in a state where there is no sheet in the transport path. Determining means for determining the threshold value;
Reading means for reading an image formed on the sheet unless the double feed detecting means detects double feed.

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