JP5362525B2 - Vibration conveying apparatus and combination weigher using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vibrating conveying apparatus capable of finding the weight of an article loaded thereon without using a weight sensor such as a load cell while reducing electric power consumption. <P>SOLUTION: This vibrating conveying apparatus includes: a vibrating feeder 12 comprising a vibrator structured so as to make vibrating motion for vibrating an article loader through intermittent energization given to an electromagnet 24; a feeder main control means 191 for repeatedly impressing drive voltage pulses on the electromagnet 24 at a frequency equating with the characteristic frequency of the vibrating feeder 12 and controlling the pulse width of the voltage pulses so that the vibration amplitude of the article loader coincides with a target amplitude; an amplitude detection means 30 for detecting the vibration amplitude of the article loader; and a weight calculation means 191 for calculating the weight of an article on the article loader based on the pulse width of a drive voltage pulse impressed thereon immediately before the time when a detected vibration amplitude is the target amplitude. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a vibration conveying device that conveys an article on a trough by vibrating a trough (article loading portion) using an attractive force of an electromagnet and a restoring force of a spring, and a combination balance using the vibration conveying apparatus.

  2. Description of the Related Art Conventionally, a combination weigher uses a plurality of linear feeders that convey articles by vibrating a trough (see, for example, Patent Document 1).

  In the combination weigher, for example, a dispersion feeder is disposed at the upper center, and a plurality of linear feeders are radially arranged around the dispersion feeder. A collecting chute is disposed below the weighing hopper. For example, an article is supplied from an external supply device to the central part of the dispersion feeder, and the article is conveyed to the linear feeder by sending the article toward the peripheral edge by vibration. Each linear feeder conveys articles by vibrating the trough and conveys them to the supply hopper. Each supply hopper temporarily holds the article, and supplies the article to a weighing hopper disposed below the article. Each weighing hopper weighs the supplied article. By performing a combination calculation based on the measurement value, a combination of the measurement hoppers whose total of the measurement values matches or matches the target combination weight is obtained, and the article is discharged from the measurement hopper selected for this combination. This discharged article slides down on the collecting chute and is loaded into, for example, a packaging machine.

  In the combination weigher as described above, in order to improve the combination weighing accuracy, as is well known, the weight of the articles supplied to the weighing hopper participating in the combination calculation becomes a weight that increases the number of combinations. It is necessary to control the weight of the articles conveyed from the linear feeder to the supply hopper.

  The weight of the article conveyed from the linear feeder to the supply hopper depends on the weight of the article placed on the linear feeder, the vibration amplitude of the linear feeder, the vibration time (operation time) of the linear feeder, and the like. In order to detect the weight of the article placed on the linear feeder, a method is known in which the linear feeder itself is placed on a weight sensor such as a load cell to detect the weight of the article on the trough of the linear feeder. Since the feeder itself is quite heavy, a large weight sensor is required, and the cost of the weight sensor is high. Therefore, the vibration transfer device including the weight sensor is increased in size and cost.

  On the other hand, in Patent Document 1, a strain gauge is attached to the spring member of the linear feeder, and the weight of the article on the trough and the amplitude of the trough are detected based on the electrical output of the strain gauge. A configuration is disclosed in which a transport amount per unit time is calculated from the amplitude, and the transport device is controlled based on the transport amount. In the case of this configuration, the natural frequency of the linear feeder is set to be a frequency close to the power supply frequency.

JP-A-11-193002

  As described above, when the linear feeder itself is placed on the weight sensor and the weight of the article on the linear feeder is detected, the vibration transfer device including the weight sensor is increased in size and cost. In the case of the configuration disclosed in Patent Document 1, it is not necessary to use an expensive and large-sized weight sensor. However, since the natural frequency of the linear feeder is set to a frequency close to the power supply frequency, The number and the drive frequency (= power supply frequency) are slightly different, and the power consumption is larger than the resonance vibration.

  The present invention has been made to solve the above-described problems, and can vibrate and convey the weight of an article loaded without using a weight sensor such as a load cell and reduce power consumption. It aims at providing an apparatus and a combination scale using the same.

  In order to achieve the above object, the vibration conveying device of the present invention supports an article loading section for conveying an article in one direction when the article is loaded and vibrated, and supports the article loading section. A vibration feeder having a vibration device portion configured to perform a vibration operation that vibrates the article loading portion when intermittently energized, and a drive voltage pulse corresponds to the natural frequency of the vibration feeder. Voltage application control means for repeatedly applying to the electromagnet at a predetermined frequency and controlling the pulse width of the drive voltage pulse so that the vibration amplitude of the article loading section becomes a preset target amplitude; and the article loading section An amplitude detection means for detecting the vibration amplitude of the drive voltage pulse applied most recently when the vibration amplitude detected by the amplitude detection means is the target amplitude. And a weight calculating means for calculating the weight of the article on the article loading portion on the basis of the width.

  According to this configuration, the weight of the article on the article loading section can be calculated without using a weight sensor. In addition, since the drive voltage pulse is applied to the electromagnet at a frequency corresponding to the natural frequency of the vibration feeder, resonance vibration can be achieved and power consumption can be reduced.

  In addition, the weight calculating unit is configured to determine a relationship between a pulse width of the driving voltage pulse and a weight of an article on the article loading section, which is predetermined for each of a plurality of vibration amplitudes of the article loading section. The weight of the article on the article loading portion is calculated from the pulse width of the drive voltage pulse applied most recently using the pulse width weight information corresponding to the target amplitude in the indicated pulse width weight information May be.

  According to this configuration, one of a plurality of vibration amplitudes corresponding to each pulse width weight information can be selected and set as a target amplitude.

  In addition, the combination weigher of the present invention includes a plurality of vibration conveyance devices having the above-described configuration, is provided corresponding to each of the vibration conveyance devices, and an article discharged from an article loading portion of the vibration conveyance device is supplied. A combination calculation is performed based on the weights of the articles weighed by the weight sensors and a plurality of weighing hoppers attached to the weight sensors for weighing the supplied articles, and the total weight of the articles is within a predetermined weight range. And a ratio of a weight of an article weighed by a weight sensor attached to the weighing hopper corresponding to the vibration conveying device with respect to a target supply weight of the article supplied to the weighing hopper. A ratio calculating means, wherein the weight calculating means of the vibration conveying device obtains the article mounted after the ratio is calculated by the ratio calculating means. An article on the article loading section calculated by the target supply weight and the weight calculation means is configured to correct the weight of the article on the section using the ratio. And calculating the total number of the driving pulses to be applied in order to make the weight of the articles discharged from the article loading section equal to the target supply weight, and the number of the driving voltage pulses equal to the total number is calculated. When applied, the application of the drive voltage pulse is terminated.

  According to this configuration, the weight of the article on the article loading portion of the vibration transfer device can be calculated without using a weight sensor. Since the weight sensor is not used, the vibration conveying device is not increased in size and cost, and the combination scale is not increased in size and cost. Further, by correcting the weight of the article on the article loading portion using the above ratio, the weight of the article can be accurately obtained even when an error due to a temperature change of the electromagnet of the vibration transfer device occurs. Then, the total number of driving voltage pulses applied is calculated based on the weight of the article on the accurate article loading section and the target supply weight of the weighing hopper, and when the number of driving voltage pulses equal to the total number is applied, By terminating the application, the accuracy of the amount of articles supplied to the weighing hopper can be improved, and the accuracy of combination weighing can be improved.

  Note that “vibration amplitude” or “amplitude” described in the claims and in this specification means the width of vibration (peak-to-peak value).

  The present invention has the above-described configuration, and can use the vibration conveyance device that can determine the weight of an article loaded without using a weight sensor such as a load cell and can reduce power consumption. It is possible to provide the combination weigher.

It is sectional drawing which looked at the schematic structure of an example of the combination weigher provided with the vibration conveying apparatus in embodiment of this invention from the side. (A) is a perspective view which shows an example of the rectilinear feeder which comprises the vibration conveyance apparatus in embodiment of this invention, (b) is a side view of the rectilinear feeder. It is a block diagram which shows the structure of the control system about arbitrary one vibration conveying apparatus in embodiment of this invention. It is a figure which shows the drive voltage waveform applied to the electromagnet of the vibration conveyance apparatus of embodiment of this invention, and the vibration displacement of the article loading part (trough) at that time. It is a figure which shows the drive pulse in the application period of a drive pulse, the electric current which flows into the coil of an electromagnet, and the vibration displacement of a trough. It is a figure which shows an example of the relationship between the article | item weight corresponding to each of several predetermined amplitude, and a pulse width. It is a flowchart which shows an example of operation | movement of the arbitrary one vibration conveying apparatus in this embodiment.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. In the following description, the same or corresponding elements are denoted by the same reference symbols throughout all the drawings, and redundant description thereof is omitted. Further, the present invention is not limited to the following embodiment.

(Embodiment)
FIG. 1 is a cross-sectional view of a schematic configuration of an example of a combination weigher provided with a vibration conveyance device according to an embodiment of the present invention as viewed from the side.

  In this combination weigher, a conical dispersion feeder 11 is provided on an upper portion of a center base body (body) 1 disposed in the center of the apparatus to disperse articles supplied from an external supply apparatus 10 radially by vibration. Yes. The dispersion feeder 11 includes a conical dispersion table 11a on which an article is placed, and a vibration device 11b that vibrates the dispersion table 11a. The article supplied from the supply device 10 to the central portion thereof is vibrated toward the periphery. Send it out. Around the dispersion feeder 11, a plurality of rectilinear feeders 12 are provided in a radial pattern for conveying articles sent from the dispersion feeder 11 by vibration and feeding them to the respective supply hoppers 13. Each rectilinear feeder 12 is provided with a trough 12a for loading and transporting articles and a vibration device 12b for vibrating the trough 12a. Under each linear feeder 12, a supply hopper 13 and a weighing hopper 14 are provided correspondingly and arranged in a circular shape. The supply hopper 13 receives the articles fed from the linear feeder 12, and opens the discharge gate 13g and puts the articles into the weighing hopper 14 when the weighing hopper 14 arranged below the empty hopper 13 becomes empty. Each weighing hopper 14 is provided with a weight sensor 15 such as a load cell, and the weight sensor 15 measures the weight of the article in the weighing hopper 14. The measurement value of each weight sensor 15 is output to the control device 19. Below the weighing hoppers 14 arranged in a circle, a substantially inverted truncated cone-shaped collecting chute 16 is disposed, and below the collecting chute 16 a funnel-shaped discharge chute 17 is provided. The weighing hopper 14 selected as a discharge combination to be described later by the control device 19 opens its discharge gate 14g and discharges the articles. The discharged articles slide down on the collecting chute 16 and are packaged via the discharge chute 17, for example. Discharged to a machine (not shown).

  Further, a level detector 18 for detecting the amount of articles on the dispersion feeder 11 is provided. For example, an ultrasonic sensor is used for the level detector 18, the layer thickness of the article on the dispersion feeder 11 is detected, and the detection signal is output to the control device 19. The control device 19 controls the supply device 10 so as to keep the article on the dispersion feeder 11 at a constant amount based on the layer thickness of the article on the dispersion feeder 11 detected by the level detector 18.

  The control device 19 is configured by, for example, a microcomputer having an arithmetic control unit 19a and a storage unit 19b. For example, a CPU of this microcomputer is used for the arithmetic control unit 19a. The storage unit 19b stores a control program and further stores various data. Further, when the CPU of the arithmetic control unit 19a executes the control program stored in the storage unit 19b, the control device 19 controls the overall operation of the supply device 10 and the combination weigher and performs the combination processing described later. Do.

  That is, the control device 19 performs control of the supply device 10, control of the vibration device 11b of the dispersion feeder 11, control of the vibration device 12b of each linear feeder 12, opening / closing control of the discharge gates of the supply hopper 13 and the weighing hopper 14, and the like. . Further, in the combination process, a combination calculation is performed based on the weight values of the articles measured by the respective weight sensors 15, and the total of the weight values of the articles supplied from the plurality of weighing hoppers 14 is determined in advance. One combination of the weighing hoppers 14 that falls within the predetermined weight range (allowable range with respect to the target combination weight) is obtained, and the combination is set as a combination (discharge combination) of the weighing hoppers 14 to discharge the articles.

  The control device 19 does not necessarily need to be configured as a single control device, and a plurality of control devices are arranged in a distributed manner so that they can cooperate to control the combination weigher and the supply device 10. May be.

  The operation indicator 20 includes, for example, a touch screen type display screen, and has a function as input means for operating the combination weigher and setting operation parameters thereof.

  This combination weigher is provided with a plurality of sets of weighing units including a linear feeder 12, a supply hopper 13, a weighing hopper 14, and a weight sensor 15.

  Fig.2 (a) is a perspective view which shows an example of the rectilinear feeder 12 in embodiment of this invention, FIG.2 (b) is a side view of the rectilinear feeder.

  The linear feeder 12 includes a trough 12a that is an article loading portion, and a vibration device (vibration device portion) 12b that vibrates the trough 12a. The article is supplied to the base end portion (rear part) of the trough 12a, and the article is conveyed forward by vibrating the trough 12a, and is discharged from the front end portion of the trough 12a.

  In the vibration device 12b, a movable plate 22 is attached to a fixed frame 21 so as to be swingable via elastic members 23a and 23b made of, for example, carbon leaf springs. The elastic members 23a and 23b are attached between the fixed frame 21 and the movable plate 22 so that the upper end side thereof is inclined rearward.

  An adsorbed member (armature) 25 is fixed to the fixed frame 21 so that the electromagnet 24 has a predetermined angle with respect to the horizontal plane, and the movable plate 22 faces the electromagnet 24 with a predetermined interval. It is attached. The fixed frame 21 is attached to the center base 1 (FIG. 1) via a vibration-proof spring 26.

  An attachment portion 27 is fixed to the upper surface of the movable plate 22 of the vibration device 12b, and the trough 12a is detachably attached to the attachment portion 27 by an attachment fitting 28 provided on the lower surface thereof.

  The vibration mechanism of the linear feeder 12 will be described. In the following description, applying a voltage to the electromagnet means applying a voltage to the coil of the electromagnet.

  When a voltage is applied to the electromagnet 24, the electromagnet 24 attracts the attracted member 25 fixed to the movable plate 22. At this time, the movable plate 22 moves to the electromagnet 24 side, that is, rearward and obliquely downward, by elastic deformation of the elastic members 23a and 23b connecting the movable plate 22 and the fixed frame 21. Next, when the application of the voltage to the electromagnet 24 is stopped, the attractive force generated in the electromagnet 24 is released, and the movable plate 22 moves obliquely upward in the forward direction by the elastic repulsive force of the elastic members 23a and 23b. Since the trough 12a moves together with the movable plate 22, by repeating the above operation, the trough 12a vibrates and the articles on the trough 12a are conveyed forward.

  The shapes and arrangements of the fixed frame 21, the movable plate 22, the elastic members 23a and 23b, the electromagnet 24, and the attracted member 25 constituting the vibration device 12b are not limited to those shown in FIG. Can be used.

  Further, in the present embodiment, the amplitude detection unit 29 is provided in one of the elastic members 23a and 23b (in this example, the elastic member 23a). The amplitude detection unit 29 is constituted by, for example, a piezoelectric element such as a piezo film attached to the elastic member 23a. The amplitude detector 29 is distorted in accordance with the elastic deformation of the elastic member 23a, and outputs an output corresponding to the distortion to the control device 19 (FIG. 1).

  FIG. 3 is a block diagram showing a configuration of a control system related to one arbitrary linear feeder 12. This configuration is the same for the individual linear feeders 12 provided in the combination weigher.

  That is, linear feeder control means 190 </ b> B is provided corresponding to each of the plurality of linear feeders 12. The plurality of linear feeder control units 190B are realized by the function of the control device 19 in the present embodiment, but may be provided separately from the control device 19. The scale control means 190A is a means for realizing functions other than the plurality of linear feeder control means 190B in the control device 19. That is, the control device 19 includes a scale control unit 190A and a plurality of linear feeder control units 190B.

  The vibration conveyance device of the present embodiment is configured by the linear feeder 12 and the linear feeder control means 190B. The straight feeder control means 190B has a feeder main control means 191, an amplitude calculation means 192, and a weight calculation means 193. The feeder main control means 191 also has a function as voltage application control means.

  The feeder main control means 191 applies an initial attraction pulse Po and a drive pulse (drive voltage pulse) Ps (Ps1, Ps2, Ps3,...) Shown in FIG. A rectangular wave voltage is applied. The feeder main control means 191 controls the pulse width (T1 to T4, etc.) of the drive pulse Ps so that the trough 12a has the target amplitude. Therefore, during the drive period, the pulse width of the drive pulse Ps to be applied next is changed when the vibration amplitude of the trough 12a calculated by the amplitude calculating means 192 becomes an amplitude other than the target amplitude. Yes.

  The amplitude calculator 192 receives the output voltage of the amplitude detector 29, calculates the vibration amplitude of the trough 12a based on the output voltage, and provides it to the feeder main controller 191. The amplitude detector 29 and the amplitude calculator 192 constitute an amplitude detector 30 that detects the vibration amplitude of the trough 12a.

  Note that information indicating the relationship between the output voltage of the amplitude detection unit 29 and the vibration amplitude of the trough 12a (for example, an approximate expression indicating the above relationship) is obtained and stored in the storage unit 19b in advance through experiments or the like. The amplitude calculation means 192 is configured to calculate the vibration amplitude of the trough 12a from the output voltage of the amplitude detector 29 based on the above.

  It should be noted that both the elastic members 23 a and 23 b are provided with the amplitude detection unit 29, and the output voltages of the two amplitude detection units 29 are input to the amplitude calculation unit 192, and the amplitude calculation unit 192 An average value of the output voltage may be calculated, and the vibration amplitude of the trough 12a may be calculated based on the average value.

  In this embodiment, the amplitude detection unit 30 is configured by using a piezo film for the amplitude detection unit 29. However, the amplitude detection unit 30 may be configured by using a strain gauge or the like for the amplitude detection unit 29.

  When the vibration amplitude of the trough 12a calculated by the amplitude calculating means 192 is the target amplitude during the driving period, the weight calculating means 193 receives the target amplitude and the driving pulse Ps in response to an instruction from the feeder main control means 191. An article weight on the trough 12a is calculated based on the width, and the calculated article weight is provided to the feeder main control means 191.

  The feeder main control unit 191 drives the linear feeder 12 based on, for example, an instruction from the scale control unit 190A. Here, the scale control unit 190A is configured to control each linear feeder control unit 190B and to instruct the start of driving of each linear feeder 12, for example.

  FIG. 4 is a diagram showing a driving voltage waveform applied to the electromagnet 24 of the vibration conveyance device of the present embodiment and the vibration displacement of the trough 12a at that time.

  In this embodiment, an initial suction pulse Po having a voltage Va and a pulse width (application time) Tp is applied at the start of driving, and thereafter, after the time Ts has elapsed and until the end of driving, the driving pulse Ps ( Ps1, Ps2, Ps3,...) Are applied at a period T (drive frequency f = 1 / T). Here, the application time Tp is set so that the trough 12a has a vibration displacement corresponding to the target amplitude (target vibration width) At by applying the initial attraction pulse Po to the electromagnet 24. That is, by applying the initial suction pulse Po with the pulse width Tp, the position of the trough 12a becomes a position corresponding to the target amplitude At, and a very excellent amplitude rising characteristic is obtained. The position corresponding to the target amplitude At corresponds to the lower end position of vibration when the trough 12a vibrates with the target amplitude At. The target amplitude At is a target value of the vibration amplitude of the trough 12, and is set in consideration of the type of transport article, the transport amount, and the like.

  The voltage Va is a predetermined voltage determined in advance as a drive voltage, and may be a rated voltage of the electromagnet 24, for example.

  The pulse width Tp of the initial suction pulse Po, times To and Ts, the frequency f and period T of the drive pulse Ps, and the standard pulse width Ta of the drive pulse Ps are determined as follows from experimental results and the like.

  First, the pulse width (application time) Tp of the initial suction pulse Po is determined. For example, an experiment is performed in which the voltage Va is applied to the electromagnet 24 for each of a predetermined number of voltage application times (time during which the voltage Va is applied), and the amplitude of the trough 12a is measured. Here, the difference between the highest position and the lowest position of the trough 12a when the trough 12a vibrates due to voltage application is measured as the amplitude of the trough 12a using, for example, a laser displacement meter. Based on the measurement result, a relational expression between the voltage application time and the amplitude is obtained. Using this relational expression, a voltage application time corresponding to the target amplitude At is obtained, and the time is determined as the time Tp.

  Next, the repetition frequency (drive frequency) f and the period T of the drive pulse Ps are determined. The drive frequency f is determined to be equal to the natural frequency of the linear feeder 12 obtained. For example, by applying the voltage Va to the electromagnet 24 only for the voltage application time Tp determined above, the temporal change of the vibration displacement of the trough 12a is measured using, for example, a laser displacement meter, and this measurement data is analyzed by FFT. The natural frequency of the linear feeder 12 is obtained. This natural frequency is determined as the drive frequency f, and the drive pulse period T is determined as 1 / f. Further, at the time of the above measurement, the time from the end of application of the voltage Va to the time when the vibration displacement of the trough 12a becomes 0 for the second time is measured, and the time is defined as To.

  Next, the standard pulse width Ta of the drive pulse Ps is determined. For example, for each of a predetermined number of pulse widths, the amplitude of the trough 12a when a pulse of the voltage Va is applied at the driving frequency f is measured using, for example, a laser displacement meter, and the pulse width and amplitude are determined based on the measurement result. And the pulse width corresponding to the target amplitude At is obtained using this relational expression, and this is determined as the standard pulse width Ta of the drive pulse Ps.

  Next, the standard pulse width Ta is subtracted from the previously obtained time To, and the subtraction result is determined as the time Ts from the voltage application end time of the initial suction pulse Po to the application start time of the first drive pulse Ps1. In this case, the first drive pulse Ps1 is a pulse having a standard pulse width Ta.

  In the above description, when measuring the amplitude and vibration displacement of the trough 12a, the amplitude and vibration displacement of the trough 12a in the vertical direction (vertical direction) are measured. The amplitude and vibration displacement in the direction) may be measured. Alternatively, the amplitude and vibration displacement of the attracted member 25 in the direction facing the electromagnet 24 may be measured and used as the amplitude and vibration displacement of the trough 12a. Further, although the amplitude and vibration displacement of the trough 12a are measured using a laser displacement meter, they may be calculated from the output of the amplitude detector 29. In addition, when measuring the amplitude and vibration displacement of the trough 12a, it is preferable to perform the measurement with an average amount of articles expected to be placed on the trough 12a during operation.

  In the present embodiment, based on the times Tp, To, Ts, Ta, the period T, and the like determined as described above, the initial suction pulse Po and the drive pulse Ps are applied as shown in FIG. 4, for example, within the drive period.

  In this embodiment, by applying one initial suction pulse Po at the start of driving, the article loading portion (trough 12a) is shifted to a position corresponding to the target amplitude At. A voltage is applied to the electromagnet so as to shift from a position before the start of the vibration operation (that is, a stationary position where the vibration displacement is 0) to a position corresponding to the target amplitude At without returning to the position before the start of the vibration operation. What should I do? For example, as shown by a chain line in FIG. 4, two initial suction pulses Po1 and Po2 may be applied instead of one initial suction pulse Po.

  Further, in the present embodiment, as shown in FIG. 4, the time point when the drive pulse Ps falls (the time point when the application ends) coincides with the time point when the vibration displacement becomes 0 (position when stationary). This is the same even when the pulse width of the drive pulse Ps is changed, and the drive pulse Ps is applied so that the falling point is a constant interval (cycle T). This will be described with reference to FIG.

  FIG. 5 is a diagram showing the drive pulse Ps during the application period of the drive pulse Ps, the current (excitation current) I flowing through the coil of the electromagnet 24 during that period, and the vibration displacement Aw of the trough 12a.

  The drive pulse Ps is desirably applied so that the attractive force of the electromagnet 24 is most efficiently reflected in the amplitude. That is, in order to reduce power consumption, it is desirable to apply the drive pulse Ps so that the attractive force of the electromagnet 24 is generated before the vibration displacement Aw reaches the minimum value AL from the maximum value AH. Furthermore, it is desirable to apply the drive pulse Ps so that the maximum attraction force of the electromagnet 24 occurs between the vibration displacement Aw and the minimum value AL.

  The attractive force F of the electromagnet is proportional to the square of the current I, and increases as the current I increases. As shown in FIG. 5, the current I starts to flow from the rising point of the driving pulse Ps, and becomes maximum after a predetermined time from the falling point of the driving pulse Ps. In the present embodiment, the time point when the drive pulse Ps falls is set to coincide with the time point when the vibration displacement Aw becomes zero. That is, here, the drive pulse Ps is applied until the trough 12a changes from the upper end position of vibration (vibration displacement Aw is the maximum value AH) to the rest position (vibration displacement Aw is 0), and the trough 12a The drive pulse Ps is applied so that the drive pulse Ps falls when it passes through the stationary position (application end time). In this way, the attraction force of the electromagnet 24 is generated until the vibration displacement Aw changes from the maximum value AH to the minimum value AL, and the maximum attraction force increases until the vibration displacement Aw changes from 0 to the minimum value AL. Can occur between.

  In the present embodiment, the amplitude detecting means 30 and the weight calculating means 193 (FIG. 3) are provided so that the amplitude of the trough 12a during the driving period is made constant and the weight of the article and the transport weight on the trough 12a are calculated. It is configured. This will be described below.

  During the drive period, the amplitude detector 30 sequentially detects the amplitudes A1, A2, A3,... (See FIG. 4) of the trough 12a each time the drive pulse Ps is applied.

  The feeder main control unit 191 adjusts the pulse width so as to be the target amplitude At based on the amplitude detected by the amplitude detection unit 30 during the drive period, and applies the drive pulse Ps. The feeder main control unit 191 provides the value of the pulse width of the drive pulse Ps to the weight calculation unit 193.

  When the amplitude detected by the amplitude detection unit 30 is the target amplitude At, the weight calculation unit 193 determines the article on the trough 12a based on the pulse width of the drive pulse Ps applied most recently and the target amplitude At. Calculate the weight. An example of an article weight calculation method by the weight calculation means 193 will be described.

  First, for each of the plurality of vibration amplitudes, information indicating the relationship between the pulse width and the weight of the article (for example, a pulse width / weight relational expression described later) is created in advance and stored in the storage unit 19b. This information is obtained, for example, by placing an article of a predetermined weight on the trough 12a, applying a driving pulse Ps of voltage Va at a driving frequency f, and measuring the amplitude of the trough 12a using, for example, a laser displacement meter. The pulse width at which the trough 12a has a predetermined amplitude is obtained. Similarly, an article having a weight different from that described above is placed on the trough 12a, a drive pulse Ps of voltage Va is applied at the drive frequency f, and a pulse width at which the amplitude of the trough 12a becomes the predetermined amplitude is obtained. In this way, several pieces of measurement data of the weight and pulse width of the article when the amplitude of the trough 12a becomes a predetermined amplitude are obtained, and the weight of the article on the trough 12a is obtained, for example, by the least square method based on the measurement data. An approximate expression indicating the relationship between the pulse width and the pulse width is obtained, and this approximate expression is defined as a pulse width / weight relational expression. Such a pulse width / weight relational expression is obtained for each of a plurality of predetermined amplitudes, and the obtained plurality of pulse width / weight relational expressions are stored in the storage unit 19b in advance.

  FIG. 6 shows the measurement results when measuring a plurality of article weights by applying a driving pulse Ps of voltage Va at a driving frequency f and adjusting the pulse width so that the amplitude of the trough 12a becomes a predetermined amplitude. It is based on this, and is a figure which shows an example of the relationship between the article | item weight and pulse width corresponding to each case where predetermined amplitude is 2.0 mm, 1.5 mm, 1.0 mm, and 0.5 mm. Information indicating the relationship between the article weight and the pulse width (hereinafter referred to as “pulse width weight information”) is obtained and stored in advance for each of a plurality of predetermined amplitudes.

  In other words, pulse width weight information (for example, the aforementioned pulse width / weight relational expression described above) corresponding to each of a plurality of predetermined amplitudes of the trough 12a is stored in the storage unit 19b. The plurality of predetermined amplitudes are amplitudes that can be set as target amplitudes. In the combination weigher of this embodiment, for example, before the start of operation, the operation indicator 20 is operated to set one target amplitude At. Are stored in the storage unit 19b. Then, the weight calculating unit 193 corresponds to the target amplitude At when the amplitude detected by the amplitude detecting unit 30 becomes the target amplitude At from the plurality of pulse width weight information stored in the storage unit 19b. The article weight on the trough 12a is calculated from the pulse width of the drive pulse Ps applied most recently using the pulse width weight information. The feeder main control means 191 provides this to the weight calculation means 193 when the amplitude detected by the amplitude detection means 30 reaches the target amplitude At.

  FIG. 7 is a flowchart showing an example of the operation of any one vibration transfer device of the present embodiment. This operation is performed by the operation of the straight feeder control means 190B of the control device 19. The storage unit 19b of the control device 19 stores all information necessary for driving the linear feeder. For example, the pulse width (application time) Tp of the initial suction pulse Po, the time Ts from the end of application of the initial suction pulse to the start of application of the first drive pulse Ps1, and the first drive pulse Ps1 from the end of application of the initial suction pulse In addition to the time To until the end of the application, the period T of the drive pulse Ps, the standard pulse width Ta, the target amplitude At, the pulse width / weight relational expression, and the like are stored.

  Here, in the combination weigher in the present embodiment, the dispersion feeder 11 and the rectilinear feeder 12 are configured to be driven synchronously, and the article is driven from the rectilinear feeder 12 to the empty supply hopper 13 by driving the rectilinear feeder 12. Since the article is supplied from the dispersion feeder 11 to the linear feeder 12 that is being driven while the supply is being carried out, in the case of a normal operation state except for an abnormal case such as no article on the dispersion feeder 11. A substantially constant amount of articles are loaded on the linear feeder 12. The article discharged from the linear feeder 12 is temporarily held by the supply hopper 13 below the article, and then supplied to the weighing hopper 14, and the weight value of the article is measured by the weight sensor 15.

  The rectilinear feeder control means 190B executes the operation of the flowchart shown in FIG. 7 in response to an instruction to start driving from the scale control means 190A, for example.

  First, in step S1, 0 is set to a counter value Ct for counting the number of drive pulse outputs, and an initial suction pulse Po having a voltage Va and a pulse width Tp is applied (step S2).

  Next, when the application timing of the drive pulse Ps is reached in step S3, one drive pulse Ps having a voltage Va and a set pulse width is applied (step S4), and a counter value for counting the number of applied drive pulses Ps is applied. The value of Ct is increased by 1 (step S5). In step S4 described above, the set pulse width of the drive pulse Ps is initially set to the standard pulse width Ta, but when changed in steps S9 and S10 described later, this is the changed pulse width.

  Next, in step S6, the amplitude calculating means 192 detects the amplitude of the trough 12a.

  Next, in step S7, the amplitude (detected amplitude value) detected in step S6 is compared with the target amplitude At. If the detected amplitude value is equal to the target amplitude At, the process proceeds to step S11. Proceed to S8. Here, if the detected amplitude value is within a range of ± e with respect to the target amplitude At (e is an allowable detection error set in advance), the detected amplitude value may be regarded as being equal to the target amplitude At. .

  In step S8, the detected amplitude value is compared with the target amplitude At. If the detected amplitude value is smaller than the target amplitude At, the process proceeds to step S9, and the pulse width is larger than the drive pulse Ps applied immediately before in step S4. Change the setting pulse width. In step S8, if the detected amplitude value is not smaller than the target amplitude At (that is, larger), the process proceeds to step S10, and the set pulse width is changed to a pulse width larger than the drive pulse Ps applied immediately before in step S3. . As a more specific example, when the detected amplitude value is smaller than the target amplitude At, the set pulse width is changed to a pulse width 1.1 times the pulse width of the drive pulse Ps applied immediately before the target amplitude At. If it is larger than At, the set pulse width is changed to a pulse width 0.9 times the pulse width of the drive pulse Ps applied immediately before. In steps S9 and S10, the set pulse width of the drive pulse Ps is changed so that the amplitude of the trough 12a becomes the target amplitude At (that is, the difference from the target amplitude At is reduced), and the process returns to step S3.

  In step S7, if the detected amplitude value is equal to the target amplitude At, the process proceeds to step S11. Based on the pulse width of the drive pulse Ps applied immediately before in step S4 and the target amplitude At, the weight calculating means 193 The article weight Wc on the trough 12a is calculated by the method described above.

  Next, in step S12, based on the article weight Wc calculated in step S11 and the target supply weight R of the weighing hopper, the total number N of applied driving pulses Ps is calculated by the following equation.

N = u × R / Wc
Here, the values of u and R are stored in the storage unit 19b in advance. The target supply weight R of the weighing hopper is a target transport weight of articles discharged from the linear feeder 12 by one drive of the linear feeder 12, and in this embodiment, the target weight of articles supplied to each weighing hopper 14, That is, the weight is set so that the number of combinations is increased in the combination calculation. Further, u is a value obtained in advance by experiments or the like. The weight of the article on the trough 12a is Wc, and the pulse width of the drive pulse Ps is adjusted so as to vibrate with the target amplitude At. The value is determined so that the transported weight of the articles discharged from the trough 12a becomes the target supply weight R of the weighing hopper when applied twice. That is, the total number N of drive pulses Ps to be applied is calculated as the total number of drive pulses Ps to be applied in order to make the weight of articles (conveyed weight) discharged from the linear feeder 12 equal to the target supply weight R.

  Next, in step S13, the remaining application number n of the drive pulse Ps is calculated by subtracting the counter value Ct from the application total number N.

  Thereafter, the remaining number n of drive pulses Ps are sequentially applied when the application timing is reached (step S14). Thus, one-time driving of the linear feeder 12 is completed.

  In the above operation, step S6 is performed by the amplitude calculator 192, and step S11 is performed by the weight calculator 193. The other processing of FIG. 7 is performed by the feeder main control means 191. The feeder main control means 191 has a time measuring function, and the first drive pulse Ps (Ps1 in FIG. 4) applied in step S4 is applied for a time Ts (FIG. 4) from the end of the application of the initial suction pulse Po. ). Further, the second and subsequent drive pulses Ps applied in step S4 and step S14 are performed after a lapse of time (T-Tn) from the end of application of the drive pulse Ps applied immediately before. Here, T is the period of the drive pulse Ps as shown in FIG. 4, and Tn is the pulse width of the drive pulse Ps to be applied next.

  The feeder main control unit 191 and the weight calculation unit 193 are configured to mutually exchange information necessary for each other, for example, information such as the determination result in step S7 and the article weight Wc.

  In addition, during the period in which the process of step S14 is performed, the amplitude calculation unit 192 detects the amplitude of the trough 12a every time the drive pulse Ps is applied, and the feeder main control unit 191 detects the amplitude. Based on the detected amplitude value of the calculating means 192, it is comprised so that the process similar to step S8-S10 may be performed.

  In the present embodiment, in each weighing unit including the linear feeder 12, the supply hopper 13, the weighing hopper 14, and the weight sensor 15 provided correspondingly, articles in the weighing hopper 14 measured by the weight sensor 15 are provided. The article weight Wc obtained in step S11 may be corrected based on the measured weight value.

  In this case, if the weight of the article after correction is Wcc, it is calculated as Wcc = k × Wc. Here, k is a correction ratio. This correction ratio k is set to 1 as an initial value at the start of operation of the combination weigher, and is calculated by the following formula every time an article is newly supplied to the weighing hopper 14 and its weight is measured by the weight sensor 15. Has been updated.

k = Z / R
R is a target supply weight (target transport weight) of the weighing hopper as described above, and Z is a measured value of the article weight measured by the weight sensor 15 in the weighing hopper 14.

  In this case, in step S11, the weight calculation means 193 obtains the article weight Wc as described above, and further obtains the article weight Wcc multiplied by the correction ratio k. In step S12, the feeder main control means 191 The total number N of driving pulses Ps applied may be calculated as N = u × R / Wcc using the article weight Wcc.

  Thus, by multiplying the correction ratio k to calculate the article weight Wcc on the trough 12, even when an error due to a temperature change of the electromagnet of the linear feeder 12 occurs, the exact load loaded on the trough 12 can be accurately calculated. The weight of the article can be obtained, the conveyance weight by one drive of the linear feeder 12 can be brought closer to the target supply weight R of the weighing hopper, and the accuracy of the supply quantity of the article to the weighing hopper 14 can be further improved.

  The calculation of the correction ratio k may be performed by, for example, the feeder main control unit 191 of each linear feeder control unit 190B or the balance control unit 190A. Information necessary for calculating the correction ratio k is exchanged between the feeder main control means 191 and the scale control means 190A of each linear feed control means 190B.

  In this embodiment, the weight of the article on the trough 12 can be calculated without using a weight sensor. Since an expensive weight sensor is not used, the vibration conveying device is not increased in size and cost. Therefore, an increase in size and cost of a combination weigher using a plurality of vibration transfer devices is not caused.

  In the present embodiment, since the drive pulse Ps is applied to cause the natural frequency of the rectilinear feeder 12 to be the drive frequency f and the resonance vibration is applied, the power consumption can be reduced. In the combination weigher, since a plurality of linear feeders 12 are used, the effect of reducing power consumption is greater.

  Further, in the present embodiment, the total number of application of the drive pulses Ps is determined based on the calculated article weight on the trough 12 and the target supply weight R of the weighing hopper, and the drive is terminated when the drive pulses Ps equal to the total number are applied. As a result, it is possible to improve the accuracy of the conveyance weight by one driving, that is, the accuracy of the supply amount of the articles to the weighing hopper 14, and to improve the combination weighing accuracy. Further, by calculating the article weight Wcc using the correction ratio k as described above, the accurate article weight Wcc can be obtained even when an error due to a temperature change of the electromagnet of the vibration transfer device occurs. The accuracy of the amount of articles supplied to the hopper 14 can be further improved, and the accuracy of combination weighing can be further improved.

  Note that the combination weigher to which the present invention is applied is not limited to the combination weigher shown in FIG. For example, in the combination weigher shown in the present embodiment, the plurality of weighing hoppers 14 and the like are arranged in a circle, but may be arranged in other modes (elliptical, linear, etc.). Further, in the present embodiment, an example of a combination weigher in which only the weighing hopper 14 is used as a hopper in which the weight of the supplied article is used for the combination calculation is shown, but the present invention is not limited to such an example. For example, a memory hopper that can temporarily hold the articles supplied from the weighing hoppers and discharge them to the collecting chute is arranged obliquely below each weighing hopper, and the weight of the articles held in each of the weighing hopper and the memory hopper You may comprise so that it may be used for a combination calculation. In addition to this, the hopper configuration and the like may be variously changed.

  INDUSTRIAL APPLICABILITY The present invention is useful as a vibration transfer device that can calculate the load amount of an article and a combination weigher using the vibration transfer device.

DESCRIPTION OF SYMBOLS 11 Dispersing feeder 11a Dispersing table 11b Vibrating device 12 Straight advance feeder 12a Trough 12b Vibrating device 13 Supply hopper 14 Weighing hopper 15 Weight sensor 19 Control device 24 Electromagnet 29 Amplitude detecting unit 30 Amplitude detecting unit 190A Weighing control unit 190B Linear feed control unit 191 Feeder Main control means 192 Amplitude calculation means 193 Weight calculation means

Claims (3)

When an article is loaded and vibrated, the article loading section for conveying the article in one direction and the article loading section are supported, and the electromagnet is intermittently energized to vibrate the article loading section. A vibration feeder having a vibration device portion configured to perform a vibration operation;
The drive voltage pulse is repeatedly applied to the electromagnet at a predetermined frequency corresponding to the natural frequency of the vibration feeder so that the vibration amplitude of the article loading portion becomes a preset target amplitude. Voltage application control means for controlling the width;
Amplitude detecting means for detecting the vibration amplitude of the article loading section;
Weight calculating means for calculating the weight of the article on the article loading section based on the pulse width of the drive voltage pulse applied most recently when the vibration amplitude detected by the amplitude detecting means is the target amplitude; A vibration conveying device provided. The weight calculating means includes
The pulse width weight information indicating the relationship between the pulse width of the drive voltage pulse and the weight of the article on the article loading section, which is predetermined corresponding to each of the plurality of vibration amplitudes of the article loading section. The weight of the article on the article loading section is calculated from the pulse width of the drive voltage pulse applied most recently using pulse width weight information corresponding to the target amplitude. Vibration transfer device. While comprising a plurality of vibration conveying devices according to claim 1 or 2,
A plurality of weighing hoppers provided corresponding to each of the vibration conveying devices, to which articles discharged from the article loading portion of the vibration conveying device are supplied, and weight sensors for measuring the weight of the supplied articles are attached; ,
Combination calculation means for performing a combination calculation based on the weight of the article weighed by the weight sensor, and obtaining a combination in which the total weight of the articles is within a predetermined weight range;
A ratio calculating means for obtaining a ratio of the weight of an article weighed by a weight sensor attached to the weighing hopper corresponding to the vibration conveying device to a target supply weight of the article supplied to the weighing hopper;
The weight calculation unit of the vibration transfer device is configured to correct the weight of the article on the article loading unit obtained after the ratio is obtained by the ratio calculation unit using the ratio.
The voltage application control unit of the vibration transfer device is configured to determine the weight of the article discharged from the article loading unit based on the target supply weight and the weight of the article on the article loading unit calculated by the weight calculation unit. A combination scale configured to calculate a total number of the driving pulses to be applied to be equal to a target supply weight, and to end the application of the driving voltage pulses when a number of the driving voltage pulses equal to the total number is applied. .

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