JP4884076B2 - Combination scale - Google Patents

Description

  The present invention relates to a combination weigher that puts a weighed object into a packaging machine or the like.

  Generally, objects to be weighed such as detergents and confectionery, which are weighed with a combination weigher and have a predetermined weight, are packaged by a packaging machine. Such a combination weigher for weighing an object to be weighed has a configuration corresponding to two packaging machines or a twin type packaging machine having two input ports for an object to be weighed (for example, Patent Document 1). reference). FIG. 11 shows a schematic configuration of the conventional combination weigher.

  FIG. 11A is a schematic schematic view of a partial cross section of a conventional combination weigher as viewed from the side, and FIG. 11B is a collection chute (inner chute and outer chute) and weighing of the same combination weigher. It is the schematic diagram which looked at the hopper from the upper part.

  In this combination weigher, a conical dispersion feeder 1 is provided above the center base body (body) 5 disposed in the center of the apparatus to disperse the objects to be weighed supplied from an external supply device radially by vibration. Yes. Around the dispersion feeder 1, a linear feeder 2 is provided for feeding an object to be weighed sent from the dispersion feeder 1 to each supply hopper 3 by vibration. A plurality of supply hoppers 3 and weighing hoppers 4 are respectively provided below the linear feeder 2 and arranged in a circular shape. The supply hopper 3 receives the object to be weighed sent from the linear feeder 2, and when the weighing hopper 4 disposed below it is empty, the gate is opened and the object to be weighed is put into the weighing hopper 4. Below the weighing hopper 4, two collective chutes, an inner chute 6g and an outer chute 6h, are disposed, and each weighing hopper 4 can selectively discharge an object to be measured to the inner chute 6a and the outer chute 6h. In this way, two gates (not shown) are provided. A collecting hopper 7g that temporarily holds and discharges the objects to be weighed is disposed at the lower discharge port 6ge of the inner chute 6g, and the objects to be weighed are temporarily held and discharged at the lower discharge port 6he of the outer chute 6h. A collecting hopper 7h is provided.

  Each weighing hopper 4 is provided with a weight sensor 41 such as a load cell. The weight sensor 41 measures the weight of the object to be weighed in the weighing hopper 4 and sends the measured value to the control unit 31. .

The operation of the entire combination weigher is controlled by the control unit 31 and the combination calculation is performed. This combination weigher is configured to perform a so-called double shift operation in which, for example, a combination operation and a discharge operation are performed twice within one weighing cycle time. The objects to be weighed are alternately discharged to the outer chute 6h, and the objects to be weighed are alternately discharged from the collecting hopper 7g and the collecting hopper 7h. Below this combination weigher, two packaging machines or twin type packaging machines having two input ports for the objects to be weighed are arranged, and the objects to be weighed discharged from the respective collecting hoppers 7g and 7h are respectively It is put into the input port of the packaging machine.
JP 57-125322 A

  In the above-described conventional configuration, the discharge ports 6ge and 6he of the inner and outer chutes 6g and 6h where the collecting hoppers 7g and 7h are provided are arranged off the center of the circle that is an array of the weighing hoppers 4. In addition, the weighing hopper 4 (for example, the weighing hopper 4 arranged on the right side in FIG. 11A) located at a position far from the discharge port 6he of the outer chute 6h (that is, a position far from the collecting hopper 7h) is moved to the outer chute 6h. The inner and outer chutes 6g and 6h are arranged so that the discharged objects to be weighed are transferred to the collecting hopper 7h while bypassing the inner chutes 6g. Therefore, the arrival time of the objects to be weighed discharged from the weighing hopper 4 at a position far from the collecting hopper 7h to the outer chute 6h to the collecting hopper 7h is the same as that of the weighing hopper 4 (for example, FIG. 11A). The objects to be weighed discharged from the weighing hopper 4) arranged on the left side to the outer chute 6h are particularly late compared to the time when the objects to be weighed reach the collecting hopper 7h, and the objects discharged from the plurality of weighing hoppers 4 to the outer chute 6h simultaneously. It takes a long time from the time when the weighing object arrives at the beginning of the collecting hopper 7h to the time when it reaches the end. Therefore, in this case, depending on the property of the object to be weighed, such as the object to be weighed is high (bulk density is small), the object to be weighed first on the outer chute 6h and the object to be weighed must be slowed down. Next, a sufficient distance from the discharged objects to be weighed cannot be obtained or mixed, and high speed operation becomes difficult.

  Therefore, for example, when obtaining a combination to be discharged to the outer chute 6h, the measurement values of some of the weighing hoppers 4 are not used so that some of the weighing hoppers 4 located far from the collecting hopper 7h are not selected. When the combination calculation is performed so that the objects to be weighed in a part of the weighing hopper 4 are not discharged to the outer chute 6h, the part of the weighing hopper 4 and parts corresponding to the weighing hopper 4 (weight sensor) 41, the supply hopper 3 and the linear feeder 2) will function only once for two combinations and discharge operations, reducing their usage rate. Therefore, in this case, it becomes an uneconomical device (combination scale).

  The present invention has been made in order to solve the above-described problems, and does not reduce the usage rate of combination hoppers such as some weighing hoppers, and does not reduce the usage rate of most objects to be weighed. It is an object of the present invention to provide a combination weigher capable of transferring an object to be weighed in a short time and capable of high speed operation (high speed operation).

To achieve the above object, set combined balance Ru engaged to the present invention is arrayed in a second arc having a shape excluding the first arc from a circle, the objects to be weighed which have been supplied, the second A plurality of combination hoppers configured to selectively discharge the object to be measured in two directions inside and outside the arc, and a right conical shape disposed below the combination hopper upside down. The first chute portion having the shape is provided with a notch portion having a predetermined portion located below the first arc, and the object to be weighed discharged outward from the combination hopper An outer chute that collects and discharges from a lower discharge port, a receiving port that is positioned above the inner side of the outer chute and receives an object to be discharged inward from the combination hopper, and an outer side of the outer chute And located below the notch And an inner chute that is disposed so as to pass through the notch portion of the outer chute and collects the objects to be weighed received from the receiving inlet and discharges them from the outlet. Combination calculating means for obtaining a first discharge combination and a second discharge combination composed of the combination hopper combinations in which a combined weight value, which is a total weight of objects to be weighed, becomes a value within an allowable range with respect to a target weight value; The combination object belonging to the second discharge combination is discharged to the inner chute by discharging the object to be measured inward in the combination hopper belonging to the first discharge combination. and control means for discharging the objects to be weighed to the outer chute on by discharging the objects to be weighed to the outer direction with respect to the use hopper, the inner chute, the outer A second chute having an upside-down shape with a right conical shape disposed inside the chute, which constitutes the receiving port and collects the objects to be weighed received from the receiving port and sends them out from the lower opening. And a cylindrical portion that is disposed so as to pass through the notch portion of the outer chute, and that transfers the object to be weighed delivered from the lower opening of the second chute portion to the discharge port of the inner chute. And the opening at the bottom of the second chute is positioned directly above the outlet at the bottom of the outer chute.

Also, the outlet of the pre-Symbol inner chute, the first collecting hopper to discharge temporarily holds the objects to be weighed is provided which is discharged from the discharge port, each of the outlet of the outer chute, the A second collecting hopper for temporarily holding and discharging the objects to be weighed discharged from the discharge port is provided, and the control means holds the first objects to be weighed discharged from the combination hopper. The first weighing unit is discharged to the collection hopper and the second collection hopper holding the measurement object discharged from the combination hopper is discharged from the first hopper. And the second set hopper are also controlled.

  According to this configuration, since the first and second collective hoppers are provided, the objects to be weighed are discharged together, so that the packaging machine for packaging the objects to be weighed easily performs the packaging operation.

  In the combination weigher described above, the combination hopper includes two weighing chambers arranged side by side in the row direction of the combination hopper, and the weight of the objects to be weighed supplied to the weighing chambers is measured. A weighing hopper capable of weighing and selectively discharging an object to be weighed in each of the weighing chambers in the inner direction and the outer direction, and the combination calculating means includes the first and second discharge combinations The total weight of the objects to be weighed may be determined to be a combination of the weighing chambers having a value within an allowable range with respect to the target weight value.

  According to this configuration, since the weighing hopper having two weighing chambers is provided as the combination hopper, the number of weight values used for the combination calculation can be suppressed while suppressing an increase in the diameter of the arc that is an array of the combination hoppers. It is possible to improve the accuracy of combination weighing by increasing the number.

  In the combination weigher, a plurality of weighing hoppers for weighing the weight of the objects to be supplied are disposed above the combination hoppers corresponding to the respective combination hoppers, and the combination hoppers Is provided with two storage chambers, and the objects to be weighed by the weighing hopper are supplied to the respective storage chambers, and the objects to be weighed are selectively selected in the inner direction and the outer direction for each of the storage chambers. The weighing hopper is configured to selectively discharge the objects to be measured into the two storage chambers of the corresponding memory hopper, and the combination calculation means includes the first and second combination hoppers. The discharge combination of 2 may be determined so as to include the combination of the storage chambers in which the total weight of the objects to be weighed is a value within an allowable range with respect to the target weight value.

  According to this configuration, since the memory hopper having the two storage chambers is provided as the combination hopper, the number of weight values used for the combination calculation is suppressed while suppressing an increase in the diameter of the arc that is an array of the combination hoppers. It is possible to improve the accuracy of combination weighing by increasing the number.

  In the combination weigher described above, the combination hoppers are arranged in two upper rows and one lower row, and the upper two rows of the combination hoppers are respectively weights of the objects to be weighed. The lower one row of the combination hoppers is a memory hopper provided corresponding to each of the two weighing hoppers and supplied with an object to be weighed by the weighing hopper. Yes, the objects to be weighed discharged from the weighing hopper in the inner row of the upper two rows to the inner chute are discharged to the inner chute, and the items to be weighed discharged to the outer direction correspond to the corresponding items. The objects to be weighed discharged to the memory hopper and discharged from the weighing hopper in the outer row of the upper two rows to the inner direction are discharged to the corresponding memory hopper and discharged to the outer direction. Measurement It may be configured so as to be discharged to the outer chute.

  According to this configuration, since the weighing hoppers in the upper two rows and the memory hopper in the lower row are provided as the combination hoppers, an increase in the diameter of the circular arc, which is the arrangement shape of the combination hoppers, is suppressed, and the combination calculation is performed. It is possible to increase the accuracy of the combination weighing by increasing the number of weight values used for.

  In the combination weigher, it is preferable that the first circular arc has a central angle of 180 degrees or less.

  Thus, by setting the center angle of the first arc to 180 degrees or less and making it as small as possible, if the number of combination hoppers is the same, the diameter of the second arc that is an array of the combination hoppers is reduced. Thus, the apparatus can be miniaturized.

  The present invention has the configuration described above, and in a combination weigher, on the collective chute, regardless of the properties of most objects to be weighed, without reducing the usage rate of some combination hoppers such as weighing hoppers. It is possible to transfer the object to be weighed in a short time and to achieve an effect that high speed operation can be performed.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 (a) is a schematic schematic view of a partial cross section of the combination weigher according to Embodiment 1 of the present invention viewed from the side, and FIG. 1 (b) shows an inner chute, an outer chute, and It is the schematic diagram which looked at the measurement hopper from the upper part. FIG. 2A is a perspective view of the inner chute and the outer chute of the combination weigher, and FIG. 2B is a perspective view of the inner chute of the combination weigher.

  In this combination weigher, as shown in FIG. 1 (a), a center base body (body) 5 is supported at the center of the apparatus by, for example, four legs (not shown), and an upper portion is provided with an external supply. A conical dispersion feeder 1 that disperses the object to be weighed supplied from the apparatus radially by vibration is provided. Around the dispersion feeder 1, a plurality of linear feeders 2 are provided for feeding an object to be weighed sent from the dispersion feeder 1 to each supply hopper 3 by vibration. Below each linear feeder 2, a supply hopper 3 and a weighing hopper 4 are provided correspondingly, and the plurality of supply hoppers 3 and the weighing hoppers 4 are arranged around the center base body 5 in an arc shape. The dispersion feeder 1, the linear feeder 2, the supply hopper 3, and the weighing hopper 4 are attached to the center base 5, and the drive unit (the vibration device of the dispersion feeder 1 and the linear feeder 2, the supply hopper 3, and the like) A gate opening / closing device of the weighing hopper 4) is accommodated. Each weighing hopper 4 is attached with a weight sensor 41 such as a load cell for measuring the weight of an object to be weighed in the weighing hopper 4. The measurement value by each weight sensor 41 is output to the control unit 20.

  In the region excluding the region corresponding to the central angle θ shown in FIG. 1B, the supply hopper 3 and the weighing hopper 4 are arranged in an arc shape, and each linear feeder 2 is arranged corresponding to each supply hopper 3. It is installed.

  An inner chute 6a and an outer chute 6b are arranged below the weighing hoppers 4 arranged in an arc shape, and each weighing hopper 4 selectively sends an object to be weighed to the inner chute 6a and the outer chute 6b. This is a configuration in which a gate is provided so as to allow discharge. In the circle 21 in FIG. 1 (a), the shape and gate close to the actual one of the weighing hopper 4 are schematically shown. Each weighing hopper 4 has a gate (hereinafter referred to as “inner gate”) 22 for discharging the object to be measured to the inner chute 6a and a gate (hereinafter referred to as “outer side” for discharging the object to be measured to the outer chute 6b. 23) (referred to as “gate”).

  The outer chute 6b has a configuration in which a notch 6bx is provided corresponding to a portion where the weighing hopper 4 is not arranged in a chute having a substantially conical shape upside down, and a discharge port 6be below the chute 6bx. A collecting hopper 7b is provided in the case. The object to be weighed discharged from the weighing hopper 4 to the outer chute 6b slides down the outer chute 6b, is temporarily held by the collecting hopper 7b, and then discharged.

  The inner chute 6a includes a chute 61 having a substantially conical shape disposed inside the outer chute 6b and upside down, and a pipe 62 that is a cylindrical chute disposed at the discharge port 61e of the chute 61. Consists of. The pipe 62 is disposed so that its outlet 62e passes through the notch 6bx of the outer chute 6b and is positioned below the notch 6bx outside the outer chute 6b. A collecting hopper 7 a is disposed at the discharge port 62 e of the pipe 62. The object to be weighed discharged from the weighing hopper 4 to the inner chute 6a slides down the chute 61, passes through the pipe 62, is temporarily held by the collecting hopper 7a, and then discharged. Here, by providing the pipe 62 with an appropriate inclination (for example, an inclination equivalent to the chute surface of the inner chute 6a or the outer chute 6b), the object to be weighed passes smoothly through the pipe 62.

  The chute 61 of the inner chute 6a is provided with a discharge port 61e in a portion near the apex of the right cone shape, and a portion corresponding to the bottom surface of the right cone shape is opened to serve as an inlet for the object to be weighed. Further, the outer chute 6b is provided with a discharge port 6be in the vicinity of the apex of the right cone, and a portion corresponding to the bottom of the right cone (however, the notch 6bx is present) is opened to receive the object to be weighed. It is an entrance. Here, the center of the arc of the shape of the receiving port of the outer chute 6b and the center of the circle of the shape of the receiving port of the inner chute 6a coincide with each other or are positioned on the same vertical line. . In addition, as shown in FIG. 2, a partition wall 10 is provided between the outer chute 6b and the inner chute 6a so that the object to be weighed does not jump out from the notch 6bx of the outer chute 6b. The partition wall 10 and the notch 6bx are formed according to the shape of the inner chute 6a.

  The notch 6bx is provided in a region corresponding to the central angle θ of the circular conical bottom surface (receiving port) of the outer chute 6b, and the inner chute 6a passes through the notch 6bx. Is arranged. The center angle θ corresponding to the region where the notch 6bx is provided may be an appropriate angle, but is preferably 180 ° or less. The central angle θ is, for example, 180 °, 120 °, 90 °, 60 °, 45 °, 30 °, and the like, and when the number of the weighing hoppers 4 is the same, the arrangement shape of the weighing hoppers 4 is as small as possible. This is preferable because the diameter of the arc can be reduced to reduce the size of the apparatus. However, when the object to be weighed discharged from the weighing hopper 4 slides down on the outer chute 6b, the notch 6bx is provided so that the inner chute 6a does not interfere with the object to be weighed down. The same applies to the notch 6Bx when inner and outer chutes 6A and 6B shown in FIG. 3 described later are used.

  Below this combination weigher, two unillustrated wrapping machines or twin type wrapping machines having two input ports for objects to be weighed are arranged and weighed to be discharged from each of the collecting hoppers 7a and 7b. The articles are put into the corresponding inlets 8a and 8b of the packaging machine, and are packed while being packed by the packaging machine.

  Instead of the inner chute 6a and the outer chute 6b, an inner chute 6A and an outer chute 6B shown in FIG. 3 may be used. FIG. 3 is a perspective view showing another configuration example of the inner chute and the outer chute of the combination weigher of the present embodiment.

  In the case of this configuration, the inner chute 6A includes a chute 63 having a substantially conical shape upside down, and a pipe 64 that is a cylindrical chute disposed substantially perpendicularly to the discharge port 63e of the chute 63. . The chute 63 in this case has an oblique cone shape, and a discharge port 63e is provided in the vicinity of the apex of the oblique cone, and a portion corresponding to the bottom surface of the oblique cone is opened to serve as an inlet for the object to be weighed. Yes. The chute 63 is disposed so that the discharge port 63e is located outside the outer chute 6B through the cutout portion 6Bx of the outer chute 6B. A collecting hopper 7 a (FIG. 1) is disposed at the discharge port 64 e of the pipe 64. The object to be weighed discharged from the weighing hopper 4 to the inner chute 6A slides down the chute 63, passes through the pipe 64, is temporarily held by the collecting hopper 7a, and then discharged.

  The outer chute 6B has the same configuration as the outer chute 6b described above. However, the partition wall 10 and the notch 6Bx between the outer chute 6B and the inner chute 6A are formed according to the shape of the inner chute 6A. A collecting hopper 7b (FIG. 1) is disposed at the discharge port 6Be below the outer chute 6B. The object to be weighed discharged from the weighing hopper 4 to the outer chute 6b slides down the outer chute 6B, is temporarily held by the collecting hopper 7b, and then discharged.

  The control unit 20 includes a control unit and a combination calculation unit, and controls the operation of the entire combination weigher and performs a combination process for determining a combination (discharge combination) of the weighing hoppers 4 to discharge the objects to be weighed. In the combination processing, a combination calculation is performed based on the measurement value of the weighing hopper 4 (measured value of the weight of the object to be weighed in the weighing hopper 4 by the weight sensor 41), and the combined weight value which is the sum of the measured values is the target weight value. One combination of the weighing hoppers 4 within a permissible range (predetermined weight range) is obtained and determined as an appropriate combination. When there are a plurality of combinations that are within the allowable range for the target weight value, for example, the combination in which the total of the measured values is the closest to the target weight value (if there is a combination that matches the target weight value), that is, the weighing The combination having the smallest absolute value of the difference between the sum of the values and the target weight value is determined as an appropriate amount combination. In the case of the first embodiment, an appropriate amount combination is a discharge combination. In the combination weigher, a target weight value and an allowable range for the target weight value are determined in advance. The allowable range is determined, for example, with a target weight value as a lower limit value and a value larger than the target weight value as an upper limit value. For example, the target weight value is set to 400 g, and the allowable range is set to 400 g whose lower limit value is the target weight value, and its upper limit value is set to 420 g that is larger than the target weight value. In addition, the allowable range may be a value lower than the target weight value as the lower limit value, and the upper limit value may not be determined (in this case, the upper limit value may be considered infinite).

  The operation of the combination weigher configured as described above will be described. The following description is based on the configuration using the inner chute 6a and the outer chute 6b shown in FIG. 2, but the same applies to the configuration using the inner chute 6A and the outer chute 6B shown in FIG. It is.

  First, an outline of the operation of the combination weigher will be described.

  The objects to be weighed supplied from the external supply device to the dispersion feeder 1 are supplied from the dispersion feeder 1 to each supply hopper 3 via each linear feeder 2, and the objects to be weighed are input from each supply hopper 3 to each weighing hopper 4. Is done. The weight of an object to be weighed in each weighing hopper 4 is measured by each weight sensor 41, and the measured value is sent to the control unit 20. Then, the above combination processing is performed to determine an appropriate amount combination. Then, the objects to be weighed are discharged from the weighing hopper 4 selected as an appropriate combination, and the objects to be weighed are fed from the supply hopper 3 to the weighing hopper 4 which has become empty. Further, an object to be weighed is supplied from the linear feeder 2 to the empty supply hopper 3.

  In the present embodiment, the combination processing is sequentially performed and the objects to be weighed are discharged from the weighing hopper 4, but the discharge direction from the weighing hopper 4 is switched for each appropriate amount combination determined in the combination processing. That is, the objects to be weighed are discharged alternately from the weighing hopper 4 to the inner chute 6a and the outer chute 6b for each appropriate combination determined in sequence. In accordance with this, the objects to be weighed are alternately discharged from the inner chute collecting hopper 7a and the outer chute collecting hopper 7b.

  Next, the operation in the case of the double shift operation will be described in detail. In the case of the double shift operation, for example, the total number of weighing hoppers 4 may be set to 14, and the planned selection number by the combination process (the planned number of weighing hoppers 4 selected for the appropriate amount combination) may be set to four. By configuring in this way, the total number of weighing hoppers 4 is set to 10 and the planned selection number by the combination process is set to 4, so that the weighing accuracy equivalent to the case of the single shift operation can be obtained. When the number of scheduled selections by the combination processing is set to four, the target input amount of the objects to be weighed at one time from each supply hopper 3 to the weighing hopper 4 becomes approximately ¼ of the target weight value. Thus, the operation settings of the linear feeder 2 and the like are made.

  FIG. 4 is a timing chart when the combination weigher of this embodiment is configured to perform a double shift operation.

  One weighing cycle time Tw is, for example, from when the object to be weighed begins to be discharged from the weighing hopper 4 of the discharge combination (appropriate amount combination) determined by the combination processing in the immediately preceding measurement cycle, and then the discharge combination. An object to be weighed is put into the weighing hopper 4, and after the stabilization time of the weight sensor 41 has elapsed and the weight of the object to be weighed is measured, a combination process is performed using at least the weighing value of the weighing hopper 4. This is the time required for determining the discharge combination. In the example of FIG. 4, one metering cycle time Tw is equal to one operation cycle time. Here, the one operation cycle time is, for example, immediately after the discharge combination is determined by the combination process in the immediately preceding operation cycle, and the object to be weighed is discharged from the weighing hopper 4 selected for the discharge combination. After the weighing object is put into the weighing hopper 4 of the discharge combination, and the weight of the weighing object is measured after the stabilization time of the weight sensor 41 has elapsed, the combination processing is performed using at least the weighing value of the weighing hopper 4. This is the time it takes to take an emission combination. Therefore, one weighing cycle time Tw is zero in the margin time or waiting time until the object to be weighed starts to be discharged from the weighing hopper 4 selected for the discharging combination after the discharging combination is determined by the combination processing. FIG. 4 shows the case where the above-described margin time or waiting time is zero.

  In the double shift operation in the present embodiment, combination processing is performed every Tw / 2 hours, and the objects to be weighed are discharged from the weighing hopper 4 of an appropriate combination selected in the combination processing. The combination processing in this double shift operation is performed by measuring the weighing value of the weighing hopper 4 having the weight value measured by each weight sensor 41 among all the weighing hoppers 4 (weight value of the weighing object). Is used to calculate one combination of the weighing hoppers 4 in which the total of the measured values is within a predetermined weight range, and the combination is determined as an appropriate combination. A metric value of 4 is used. The discharge of the objects to be weighed from the weighing hopper 4 of the appropriate amount combination that is sequentially selected by repeating the combination process every Tw / 2 hours is alternately performed to the inner chute 6a and the outer chute 6b for each appropriate amount combination. In addition, the objects to be weighed are discharged alternately from the collecting hopper 7a and the collecting hopper 7b. As a result, the object to be weighed is loaded into the packaging machine twice within one weighing cycle time Tw. In this case, one discharge cycle time Td1 of the combination weigher is a time that is ½ of one measurement cycle time Tw. One discharge cycle time Td1 is the same as one packaging cycle time Tp1 of the packaging machine. Here, the measurement values of all the weighing hoppers 4 are used by the combination calculation in the two consecutive combination processes, but the measurement values of all the weighing hoppers 4 are not necessarily used. For example, when the total number of weighing hoppers 4 is large, by limiting the number of measurement values used in one combination calculation, that is, by predetermining the number, all weighings are performed by two consecutive combination calculations. The measured value of the hopper 4 may not be used.

  For example, when an input command signal is input from the packaging machine, the controller 20 opens the gate of the inner chute collecting hopper 7a in response to the input command signal and discharges the objects to be measured to the packaging machine (time t1). . Then, the inner gate 22 of the weighing hopper 4 selected as an appropriate combination based on the operation timing of the gates of the collecting hopper 7a is opened, and the object to be weighed is discharged from the weighing hopper 4 to the inner chute 6a (time t1). When the next input command signal is input, the gate of the outer chute collecting hopper 7b is opened in response to the input command signal, and the objects to be weighed are discharged to the packaging machine (time t2). Then, the outer gate 23 of the weighing hopper 4 selected as an appropriate combination based on the operation timing of the gate of the collecting hopper 7b is opened, and the object to be weighed is discharged from the weighing hopper 4 to the outer chute 6b (time t2). When the next charging command signal is further input, the gate of the inner chute collecting hopper 7a is opened in response to the charging command signal, and the objects to be weighed are discharged to the packaging machine. 4 is opened, and the object to be weighed is discharged from the weighing hopper 4 to the inner chute 6a (time t3). Thereafter, the same is repeated.

  In the case of FIG. 4, the objects to be weighed discharged from the weighing hopper 4 when the inner gate 22 is opened at time t1 are collected and held in the inner chute collecting hopper 7a until time t3. Then, the gate of the collecting hopper 7a is opened and discharged to the packaging machine. Similarly, the objects to be weighed discharged from the weighing hopper 4 by opening the outer gate 23 at time t2 are collected and held in the outer chute collecting hopper 7b until time t4, and are collected at time t4. The gate 7b is opened and discharged to the packaging machine.

  In this way, the objects to be weighed are alternately discharged from the weighing hopper 4 of the appropriate amount combination to the inner chute 6a and the outer chute 6b, and accordingly, the inner chute collective hopper 7a and the outer chute collective hopper 7b alternately. To discharge the object to be weighed to the packaging machine. In the case of FIG. 4, the opening / closing timing of the gate of the collecting hopper 7a is the same as the opening / closing timing of the inner gate 22 of the weighing hopper 4, and the opening / closing timing of the collecting hopper 7b and the opening / closing timing of the outer gate 23 of the weighing hopper 4 are. Is the same, but is not limited to this. For example, the control unit 20 controls the opening / closing timings of the gates 22 and 23 of the weighing hopper 4 based on the opening / closing timings of the gates of the collecting hoppers 7a and 7b, thereby making the opening / closing timings of the respective gates different. You can also.

  By performing the double shift operation as described above, the discharge to the packaging machine is performed every Tw / 2 hours, and the high-speed discharge at twice the speed in the case of the single shift operation is possible, and the packaging machine operates at high speed. It can correspond to.

  Next, the operation when configured to perform a triple shift operation will be described in detail. When the triple shift operation is performed, for example, the total number of weighing hoppers 4 may be 18, and the planned selection number by the combination process may be 4. With this configuration, the total number of the weighing hoppers 4 is set to 10, and the planned selection number by the combination process is set to 4, so that the weighing accuracy equivalent to the case of the single shift operation can be obtained.

  FIG. 5 is a timing chart when the combination weigher of the present embodiment is configured to perform a triple shift operation. Also in the example of FIG. 5, the case where one metering cycle time Tw is equal to one operation cycle time is shown as in the case of FIG.

  In the triple shift operation in the present embodiment, combination processing is performed every Tw / 3 hours, and an object to be weighed is discharged from the weighing hopper 4 of an appropriate amount combination selected in the combination processing. The combination processing in this triple shift operation is performed by measuring the weighing value of the weighing hopper 4 having the weight value measured by each weight sensor 41 among all the weighing hoppers 4 (weight value of the weighing object). Is used to calculate one combination of the weighing hoppers 4 in which the total of the measured values is within the predetermined weight range to obtain an appropriate combination, and all the weighing hoppers are subjected to combination calculation in three consecutive combination processes. A metric value of 4 is used. The combination process is repeated every Tw / 3 hours, and the objects to be weighed are discharged from the weighing hopper 4 of the appropriate amount combination selected in sequence to the inner chute 6a and the outer chute 6b alternately for each appropriate amount combination. In addition, the objects to be weighed are discharged alternately from the collecting hopper 7a and the collecting hopper 7b. As a result, the object to be weighed is put into the packaging machine three times within one weighing cycle time Tw. In this case, one discharge cycle time Td2 of the combination weigher is 1/3 of one measurement cycle time Tw. One discharge cycle time Td2 is the same as one packaging cycle time Tp2 of the packaging machine. Here, the measurement values of all the weighing hoppers 4 are used by the combination calculation in three consecutive combination processes, but the measurement values of all the weighing hoppers 4 are not necessarily used. For example, when the total number of weighing hoppers 4 is large, by limiting the number of measurement values used in one combination calculation, that is, by predetermining the number, all the measurement is performed by three consecutive combination calculations. The measured value of the hopper 4 may not be used.

  For example, when an input command signal is input from the packaging machine, the controller 20 opens the gate of the inner chute collecting hopper 7a in response to the input command signal and discharges the objects to be measured to the packaging machine (time t11). . Then, the inner gate 22 of the weighing hopper 4 selected as an appropriate combination based on the operation timing of the gates of the collecting hopper 7a is opened, and the object to be weighed is discharged from the weighing hopper 4 to the inner chute 6a (time t11). When the next input command signal is input, the gate of the outer chute collecting hopper 7b is opened in response to the input command signal, and the objects to be weighed are discharged to the packaging machine (time t12). Then, the outer gate 23 of the weighing hopper 4 selected as an appropriate combination based on the operation timing of the gates of the collecting hopper 7b is opened, and the object to be weighed is discharged from the weighing hopper 4 to the outer chute 6b (time t12). When the next charging command signal is further input, the gate of the inner chute collecting hopper 7a is opened in response to the charging command signal, and the objects to be weighed are discharged to the packaging machine. 4 is opened, and the object to be weighed is discharged from the weighing hopper 4 to the inner chute 6a (time t13). Thereafter, the same is repeated.

  In the case of FIG. 5, the objects to be weighed discharged from the weighing hopper 4 by opening the inner gate 22 at time t11 are collected and held in the inner chute collecting hopper 7a until time t13, and time t13. Then, the gate of the collecting hopper 7a is opened and discharged to the packaging machine. Similarly, the objects to be weighed discharged from the weighing hopper 4 by opening the outer gate 23 at time t12 are collected and held in the outer chute collecting hopper 7b until time t14, and are collected at time t14. The gate 7b is opened and discharged to the packaging machine.

  As described above, each time the combination calculation is performed, the objects to be weighed are alternately discharged from the weighing hopper 4 selected as an appropriate combination to the inner chute 6a and the outer chute 6b, and the inner chute collective hopper is accordingly adjusted. The objects to be weighed are alternately discharged from the collecting hopper 7b and the outer chute collecting hopper 7b to the packaging machine. In the case of FIG. 5, the opening / closing timing of the collecting hopper 7a is the same as the opening / closing timing of the inner gate 22 of the weighing hopper 4, and the opening / closing timing of the collecting hopper 7b and the opening / closing timing of the outer gate 23 of the weighing hopper 4 are the same. Is the same, but is not limited to this. For example, the control unit 20 controls the opening / closing timings of the gates 22 and 23 of the weighing hopper 4 based on the opening / closing timings of the gates of the collecting hoppers 7a and 7b, thereby making the opening / closing timings of the respective gates different. You can also.

  By performing the triple shift operation as described above, discharge to the packaging machine is performed every Tw / 3 hours, enabling high-speed discharge at a speed three times that of the single shift operation, and a high-speed packaging machine. It can correspond to.

  In the present embodiment, it is naturally possible to employ a single shift operation with a slow operation speed (discharge speed). In the case of the configuration in which the single shift operation is performed, for example, the total number of the weighing hoppers 4 is set to 10, the planned selection number by the combination processing is set to 4, and the combination operation is performed once within one weighing cycle time Tw and The discharging operation by No. 4 is performed once, and the discharging operation from the collecting hopper to the packaging machine is performed once. In this case, one discharge cycle time of the combination weigher is the same as one measurement cycle time Tw. Also in this case, discharge of the objects to be weighed from the weighing hopper 4 selected as an appropriate amount combination is alternately performed to the inner chute 6a and the outer chute 6b every time the combination calculation is performed.

  In the first embodiment, the weighing hoppers 4 are arranged in a circular arc shape, and the outer chute 6b is provided with a notch 6bx corresponding to the area where the weighing hopper 4 is not arranged, and the notch 6bx is connected to the notch 6bx. Since the inner chute 6a is disposed so as to pass through, the object to be weighed discharged to the outer chute 6b slides down the outer chute 6b without detouring around the inner chute 6a as in the prior art. It reaches the collecting hopper 7b via the outlet 6be. The object to be weighed discharged to the inner chute 6a slides down the inner chute 6a passing through the notch 6bx of the outer chute 6b and reaches the collecting hopper 7a through the discharge port 62e. Therefore, the objects to be weighed can be transferred on the collecting chute (the inner chute 6a and the outer chute 6b) in a short time regardless of the properties of most of the objects to be weighed, and high speed operation can be performed. In addition, since the weighing hopper 4 is not disposed above the notch 6bx of the outer chute 6b, the outer chute is used by using the weight of the objects to be weighed supplied to all the weighing hoppers 4 disposed. Since the combination discharged to 6b can be obtained and discharged to the outer chute 6b, the usage rates of some weighing hoppers 4, weight sensors 41, supply hoppers 3 and linear feeders 2 are not reduced. Further, by performing the above-described double shift operation or triple shift operation, it is possible to improve the production amount (total number of discharges from the combination weigher to the packaging machine) within a predetermined time. The same applies to the case where the inner chute 6A and the outer chute 6B of FIG. 3 are used.

  Further, in the present embodiment, the inner chute collecting hopper 7a may be provided at the outlet 61e of the chute 61 instead of being provided at the outlet 62e of the pipe 62 of the inner chute 6a. In this case, the objects to be weighed discharged from the inner chute collecting hopper pass through the pipe 62 and are discharged to the packaging machine inlet 8a.

  If necessary, inner chute collecting hoppers may be provided at both the outlet 61e of the chute 61 and the outlet 62e of the pipe 62. In this case, the objects to be weighed discharged from the weighing hopper 4 to the inner chute 6a are temporarily held by the collecting hopper (upper collecting hopper) provided at the discharge port 61e of the chute 61, and then discharged to the pipe 62. After being temporarily held by a collecting hopper (lower collecting hopper) provided at the discharge port 62e of the pipe 62, it is discharged to the packaging machine input port 8a. In this case, for example, when the double shift operation is performed as shown in FIG. 4, the objects to be weighed discharged from the weighing hopper 4 when the inner gate 22 is opened at time t1 are collected in the upper collecting hopper until time t3. The objects to be weighed held and discharged from the upper collecting hopper at time t3 are collected and held in the lower collecting hopper until time t5, and the gate of the lower collecting hopper is opened at time t5 and loaded into the packaging machine. It is discharged to the mouth 8a. On the other hand, the objects to be weighed discharged from the weighing hopper 4 when the outer gate 23 is opened at time t2 are collected and held in the outer chute collecting hopper 7b until time t4, and are moved to the outer side at time t4. The gate of the chute collecting hopper 7b is opened and discharged to the packaging machine inlet 8b. In this way, the objects to be weighed discharged to the outer chute 6b are held once by the collecting hopper 7b and then discharged to the packaging machine, whereas the objects to be weighed discharged to the inner chute 6a are the upper and lower parts. After being held twice in total by the two collecting hoppers, it is discharged to the packaging machine. This is the same for both the triple shift operation and the single shift operation.

  Further, in the present embodiment, when all of the objects to be weighed discharged from the weighing hopper 4 slide down on the collecting chute (inner and outer chute) in a short time and do not hinder the packaging operation of the packaging machine. The collecting hoppers 7a and 7b may be omitted. In this case, by not providing the collecting hopper, the configuration becomes simple and the control thereof becomes unnecessary. For example, the control unit 20 is selected as an appropriate combination (discharge combination) in response to the input command signal from the packaging machine. It is only necessary to discharge the objects to be weighed from the weighing hopper 4, and the objects to be weighed discharged from the weighing hopper 4 are directly input from the discharge ports 62e and 6be of the collecting chutes 6a and 6b to the input ports 8a and 8b of the packaging machine. Is discharged. In the present embodiment, the inner chute 6a may be provided with either the upper or lower collecting hopper, and the outer chute 6b may not be provided with the collecting hopper.

  As described above, the position of the collecting hopper provided on the inner chute 6a may be changed, the number of collecting hoppers provided on the inner chute 6a may be two, and the inner and outer chutes 6a and 6b. The fact that the collecting hopper may not be provided only on both or the outer chutes 6b is the same as when the inner chutes 6A and the outer chutes 6B in FIG. 3 are used.

  In addition, when the inner chute 6A and the outer chute 6B of FIG. 3 are used, the inner chute 6A may be configured without the pipe 64. In this case, the inner chute 6A is constituted only by the chute 63. When the collecting hopper is provided on the inner chute 6A, the collecting hopper is attached to the discharge port 63e of the chute 63 so that the objects to be weighed discharged from the collecting hopper are fed into the packaging machine loading port 8a (FIG. 1). What is necessary is just to set it as the structure by which the machine inlet 8a has been arrange | positioned or extended upwards from the other packaging machine inlet 8b. The same applies to the case where the collecting hopper is not provided on the inner chute 6A constituted only by the chute 63.

  Further, in the present embodiment, one set of the objects to be weighed discharged from the collection hopper 7a and the collection hopper 7b is received below the collection hopper 7a and the collection hopper 7b and discharged from one discharge port provided in the lower part. It is good also as a structure which arrange | positions the lower chute and arrange | positions the one packaging machine with one insertion port below this lower chute. In this case, the objects to be weighed that are alternately discharged from the collecting hopper 7a and the collecting hopper 7b are fed into one packaging machine inlet through the lower chute. Further, the objects to be weighed are alternately discharged from the discharge port 62e (64e) of the inner chute 6a (6A) and the discharge port 6be (6Be) of the outer chute 6b (6B) without providing the collecting hopper 7a and the collecting hopper 7b. However, you may be comprised so that it may throw in into one packaging machine inlet through the lower chute similar to the above.

(Embodiment 2)
The combination weigher of the second embodiment is the same as the configuration of the first embodiment shown in FIGS. 1 to 3, and the description thereof is omitted. However, in the second embodiment, the combination processing and operation timing by the control unit 20 are different from those in the first embodiment.

  The control unit 20 includes a control unit and a combination calculation unit, and controls the operation of the entire combination weigher and performs a combination process for determining a combination of the weighing hoppers 4 to discharge the objects to be weighed. In the combination processing, a combination calculation is performed based on the measurement value of the weighing hopper 4 (measured value of the weight of the object to be weighed in the weighing hopper 4 by the weight sensor 41), and the combined weight value which is the sum of the measured values is the target weight value. Two combinations of the weighing hoppers 4 within a permissible range (predetermined weight range) are obtained, and each is determined as a discharge combination. Details of this combination processing will be described later.

  The outline of the operation of the combination weigher configured as described above will be described first.

  The objects to be weighed supplied from the external supply device to the dispersion feeder 1 are supplied from the dispersion feeder 1 to each supply hopper 3 via each linear feeder 2, and the objects to be weighed are input from each supply hopper 3 to each weighing hopper 4. Is done. The weight of an object to be weighed in each weighing hopper 4 is measured by each weight sensor 41, and the measured value is sent to the control unit 20. Then, a combination process by the control unit 20 is performed, and two discharge combinations are determined simultaneously. The objects to be weighed are simultaneously discharged from the weighing hopper 4 selected as the two discharge combinations, and the objects to be weighed are supplied from the supply hopper 3 to the empty weighing hopper 4. Further, an object to be weighed is supplied from the linear feeder 2 to the empty supply hopper 3.

  In the above, the discharge directions from the weighing hopper 4 of the two discharge combinations determined simultaneously in the combination process are made different. That is, the object to be weighed is discharged from the weighing hopper 4 of one of the two discharge combinations to the inner chute 6a, and at the same time, the object to be weighed from the weighing hopper 4 of the other discharge combination to the outer chute 6b. Is discharged. Further, the objects to be weighed are simultaneously discharged from the inner chute collecting hopper 7a and the outer chute collecting hopper 7b.

  Next, details of the combination processing in the present embodiment will be described. FIG. 6 is a flowchart showing combination processing in the present embodiment.

  In step S1, a combination calculation is performed using the measurement value (weight value of the object to be weighed) of the weighing hopper 4 holding the object whose weight value has been measured by each weight sensor 41. All combinations in which the total combination weight value is within the allowable range with respect to the target weight value are obtained, and each combination is determined as an appropriate combination.

  In step S2, an appropriate amount combination pair obtained by combining two appropriate amount combinations not including the same weighing hopper 4 is obtained.

  In step S3, for each appropriate combination pair, the absolute value of the difference between the combination weight value of each appropriate combination and the target weight value constituting the appropriate combination pair is obtained, and the sum of the absolute values of these differences is calculated. . The absolute value of the difference between the combination weight value and the target weight value is an absolute value obtained by subtracting the target weight value from the combination weight value, or an absolute value obtained by subtracting the combination weight value from the target weight value. Will be zero or positive.

  In step S4, one appropriate combination combination having the minimum absolute value of the differences obtained in step 3 is selected, and one of the two appropriate combinations constituting the pair is discharged to the inner chute 6a. The combination (first discharge combination) is determined, and the other is determined as the discharge combination (second discharge combination) for discharging to the outer chute 6b. Here, the determination method of the first discharge combination and the second discharge combination is determined in advance, and any method may be used. For example, numbers are assigned to the weighing hoppers 4 in order, the proper combination of the weighing hoppers 4 with the smallest number is determined as the first discharge combination, and the other proper combination is set as the second discharge combination. It may be determined or vice versa. Or you may make it determine with the magnitude of a combination weight value. For example, an appropriate amount combination having a larger combination weight value may be determined as the first discharge combination, and an appropriate amount combination having a smaller combination weight value may be determined as the second discharge combination, and vice versa. But you can. Alternatively, each time the combination process is performed, an appropriate combination with a larger combination weight value and an appropriate combination with a smaller combination weight are alternately determined as the first discharge combination and the second discharge combination. Also good.

  In steps S3 and S4, for each appropriate combination pair, the sum of the absolute values of the differences between the combination weight value of each appropriate combination and the target weight value is calculated, and the appropriate amount with the minimum sum of the absolute values of the differences is calculated. One combination pair was selected to determine two discharge combinations. For each proper combination pair, the sum of the squares of the difference between the combination weight value of each proper combination and the target weight value is calculated. It is also possible to calculate and select one appropriate combination pair having the smallest sum of the squares of the differences to determine two discharge combinations.

  As described above, two discharge combinations are obtained by one combination process.

  FIG. 7 is a timing chart showing a first operation example of the combination weigher of the present embodiment. In the example of FIG. 7 as well, as in the case of FIG. 4, a case where one metering cycle time Tw is equal to one operation cycle time is shown. However, here, two discharge combinations are obtained by a single combination process, and discharged at the same time.

  In the first operation example in the present embodiment, combination processing for simultaneously determining two sets of discharge combinations is performed every Tw time, and the two sets of discharge combinations determined by the combination processing are used from the weighing hopper 4 of the two combinations. At the same time, the objects to be weighed are discharged. In addition, the objects to be weighed are simultaneously discharged from the collecting hopper 7a and the collecting hopper 7b every Tw time. As a result, the objects to be weighed in two sets of discharge combinations are put into the packaging machine within one weighing cycle time Tw. In this case, one discharge cycle time Td3 of the combination weigher is the same as one measurement cycle time Tw. One discharge cycle time Td3 is the same as one packaging cycle time Tp3 of the packaging machine. As a configuration in this case, for example, as in the case where the double shift operation is performed in the first embodiment, the total number of the weighing hoppers 4 is set to 14, and the planned selection number selected for one set of appropriate amount combinations. If the number is four, good combination weighing accuracy can be obtained.

  For example, when an input command signal is input from the packaging machine, the controller 20 simultaneously opens the gates of the inner chute collect hopper 7a and the outer chute collect hopper 7b in response to the input command signal, and packages the objects to be weighed. The machine is discharged (time t21). Based on the operation timing of the gates of the collecting hoppers 7a and 7b, the inner gate 22 of the weighing hopper 4 selected as one of the discharge combinations is opened, and the objects to be weighed are discharged from the weighing hopper 4 to the inner chute 6a. At the same time, the outer gate 23 of the weighing hopper 4 selected as the other discharge combination is opened, and the object to be weighed is discharged from the weighing hopper 4 to the outer chute 6b (time t21). The above operation is repeated each time a closing command signal is input (time t22, t23).

  In the case of FIG. 7, the objects to be weighed discharged from the weighing hopper 4 by opening the inner gate 22 at time t21 are collected and held in the inner chute collecting hopper 7a until time t22, and time t22. Thus, the gate of the collecting hopper 7a is opened, and the objects to be weighed in the collecting hopper 7a are discharged to the packaging machine inlet 8a. Similarly, the objects to be weighed discharged from the weighing hopper 4 when the outer gate 23 is opened at time t21 are collected and held in the outer chute collecting hopper 7b until time t22, and are collected at time t22. The gate 7b is opened, and the objects to be weighed in the collecting hopper 7b are discharged to the packaging machine inlet 8b.

  In the case of FIG. 7, the opening / closing timings of the gates of the collecting hoppers 7a, 7b and the opening / closing timings of the inner gate 22 and the outer gate 23 of the weighing hopper 4 are the same, but this is not restrictive. The control unit 20 controls the opening / closing timing of the inner gate 22 and the outer gate 23 of the weighing hopper 4 based on, for example, the opening / closing timing of the gates of the collecting hoppers 7a, 7b, whereby the collecting hoppers 7a, 7b and the weighing hoppers are controlled. The timing of opening and closing the gates 4 can also be varied.

  By operating as described above, the objects to be weighed are discharged to the two input ports of the packaging machine once every weighing cycle time, and the production amount within the predetermined time (total from the combination weigher to the packaging machine). The number of discharges can be improved.

  FIG. 8 is a timing chart showing a second operation example of the combination weigher of the present embodiment. In the example of FIG. 8, as in the case of FIG. 4, the case where one metering cycle time Tw is equal to one operation cycle time is shown. However, here, two discharge combinations are obtained by a single combination process, and discharged at the same time.

  In the second operation example in the present embodiment, a combination process for simultaneously determining two sets of discharge combinations is performed every Tw / 2 hours, and the weighing hoppers of the two sets of discharge combinations determined in the combination process The objects to be weighed are simultaneously discharged from 4. In addition, the objects to be weighed are simultaneously discharged from the collecting hopper 7a and the collecting hopper 7b every Tw / 2 hours. As a result, the objects to be weighed in two sets of discharge combinations are loaded into the packaging machine twice within one weighing cycle time Tw. In this case, one discharge cycle time Td1 of the combination weigher is a time that is ½ of one measurement cycle time Tw. One discharge cycle time Td1 is the same as one packaging cycle time Tp1 of the packaging machine. As a configuration in this case, for example, if the total number of weighing hoppers 4 is 22 and the planned selection number selected for one set of appropriate combinations is 4, a good combination weighing accuracy can be obtained.

  For example, when an input command signal is input from the packaging machine, the controller 20 simultaneously opens the gates of the inner chute collect hopper 7a and the outer chute collect hopper 7b in response to the input command signal, and packages the objects to be weighed. The machine is discharged (time t1). Based on the operation timing of the gates of the collecting hoppers 7a and 7b, the inner gate 22 of the weighing hopper 4 selected as one of the discharge combinations is opened, and the objects to be weighed are discharged from the weighing hopper 4 to the inner chute 6a. At the same time, the outer gate 23 of the weighing hopper 4 selected as the other discharge combination is opened, and the object to be weighed is discharged from the weighing hopper 4 to the outer chute 6b (time t1). The above operation is repeated every time a closing command signal is input (time t2, t3,...).

  In the case of FIG. 8, the objects to be weighed discharged from the weighing hopper 4 by opening the inner gate 22 at time t1 are collected and held in the inner chute collecting hopper 7a until time t2, and time t2 Thus, the gate of the collecting hopper 7a is opened, and the objects to be weighed in the collecting hopper 7a are discharged to the packaging machine. Similarly, the objects to be weighed discharged from the weighing hopper 4 by opening the outer gate 23 at time t1 are collected and held in the outer chute collecting hopper 7b until time t2, and are collected at time t2. The gate 7b is opened, and the objects to be weighed in the collecting hopper 7b are discharged to the packaging machine.

  In the case of FIG. 8, the opening / closing timings of the gates of the collecting hoppers 7a, 7b and the opening / closing timings of the inner gate 22 and the outer gate 23 of the weighing hopper 4 are the same, but this is not restrictive. The control unit 20 controls the opening / closing timing of the inner gate 22 and the outer gate 23 of the weighing hopper 4 based on, for example, the opening / closing timing of the gates of the collecting hoppers 7a, 7b, whereby the collecting hoppers 7a, 7b and the weighing hoppers are controlled. The timing of opening and closing the gates 4 can also be varied.

  By operating as described above, the objects to be weighed are discharged to the two input ports of the packaging machine once every Tw / 2 hours, and the production volume can be further improved within a predetermined time period. For example, it can cope with a twin type packaging machine that operates at high speed.

  In addition, a combination process of simultaneously determining two discharge combinations using the measurement value of the weighing hopper 4 that holds the weighing object whose weight value has been measured by each weight sensor 41 is performed every Tw / 3 hours. At the same time, the objects to be weighed are discharged simultaneously from the weighing hoppers 4 of the two discharge combinations determined in the combination processing, and correspondingly, the collecting hopper 7a and the collecting hopper 7b The objects to be weighed may be discharged at the same time. In this case, every Tw / 3 hours, the objects to be weighed are discharged once to each of the two input ports of the packaging machine, and the production amount can be further improved within a predetermined time, for example, operating at a higher speed. Compatible with twin type packaging machines.

  In the present embodiment, as in the case of the first embodiment, the objects to be weighed can be transferred in a short time on the collective chute (the inner chute 6a and the outer chute 6b) regardless of the properties of most of the objects to be weighed. And high speed operation is possible. Further, the usage rates of some weighing hoppers 4, weight sensors 41, supply hoppers 3 and linear feeders 2 are not reduced. In addition, as described above, by performing the operation of simultaneously discharging the objects to be weighed in two discharge combinations every Tw time, every Tw / 2 hours, or every Tw / 3 hours, the production amount can be improved within a predetermined time. Can be achieved.

  Further, in the combination process (first combination process) shown in the flowchart of FIG. 6, an appropriate combination pair having a minimum sum of absolute values of the difference between the combination weight value of each appropriate combination and the target weight value is selected. Since each of the two proper amount combinations included in the proper amount combination pair is determined to be the discharge combination, it is possible to improve the combination weighing accuracy as a whole of the discharged objects to be weighed.

  Further, instead of the first combination process shown in the flowchart of FIG. 6, a second or third combination process described below may be performed.

  First, the second combination process will be described. FIG. 9 is a flowchart showing the second combination processing in the present embodiment.

  In step S11, a combination calculation is performed using the measurement value (weight value of the object to be measured) of the weighing hopper 4 holding the object whose weight value has been measured by each weight sensor 41. All combinations in which the combined combination weight value is a value within an allowable range with respect to the target weight value are obtained, and each combination is set as an allowable combination. The processing in step 11 is the same as the processing in step S1 in FIG. 6, and the appropriate amount combination obtained in step 1 corresponds to the allowable combination obtained in step 11.

  In step S12, a predetermined m number (m is a plurality), for example, 10 is selected and selected, giving priority to the one having the smallest absolute value of the difference between the combination weight value and the target weight value, from among all the allowable combinations. Each allowable combination is defined as a first appropriate amount combination.

  In step S13, the absolute value of the difference between the combination weight value and the target weight value is the smallest among the allowable combinations formed by combinations of the weighing hoppers 4 other than the weighing hopper 4 belonging to one arbitrary first appropriate amount combination. One permissible combination is selected, and this permissible combination is set as a second appropriate amount combination corresponding to any one of the first appropriate amount combinations. Similarly, the second appropriate amount combination corresponding to each of the m first appropriate amount combinations is obtained. In this way, the second appropriate amount combination corresponding to each of the m first appropriate amount combinations is obtained, and m appropriate amount combination pairs each including the corresponding first appropriate amount combination and second appropriate amount combination are obtained.

  In step S14, for each appropriate amount combination pair, the absolute value of the difference between the combination weight value of each of the first and second appropriate amount combinations constituting the appropriate amount combination pair and the target weight value is obtained, and the absolute value of the difference is obtained. Calculate the sum of the values.

  In step S15, one appropriate combination combination having the minimum absolute value of the differences obtained in step 14 is selected, and either one of the two appropriate combination combinations constituting the pair is discharged to the inner chute 6a. The combination (first discharge combination) is determined, and the other is determined as the discharge combination (second discharge combination) for discharging to the outer chute 6b. Here, the determination method of the first discharge combination and the second discharge combination is determined in advance, and any method may be used. For example, the first appropriate amount combination may be determined as the first discharge combination, and the second appropriate amount combination may be determined as the second discharge combination, or vice versa. Alternatively, each weighing hopper 4 is numbered in turn, and the appropriate combination of the weighing hoppers 4 with the smallest number is determined as the first discharge combination, and the other appropriate combination is set as the second discharge combination. It may be determined or vice versa. Or you may make it determine with the magnitude of a combination weight value. For example, an appropriate amount combination having a larger combination weight value may be determined as the first discharge combination, and an appropriate amount combination having a smaller combination weight value may be determined as the second discharge combination, and vice versa. But you can. Alternatively, each time the combination process is performed, an appropriate combination with a larger combination weight value and an appropriate combination with a smaller combination weight are alternately determined as the first discharge combination and the second discharge combination. Also good.

  In steps S14 and S15, for each appropriate combination pair, the sum of the absolute values of the differences between the combination weight value of each appropriate combination and the target weight value is calculated, and the appropriate amount with the minimum sum of the absolute values of the differences is the minimum. One combination pair was selected to determine two discharge combinations. For each proper combination pair, the sum of the squares of the difference between the combination weight value of each proper combination and the target weight value is calculated. It is also possible to calculate and select one appropriate combination pair having the smallest sum of the squares of the differences to determine two discharge combinations.

  Next, the third combination process will be described.

  First, by performing a combination operation using the measurement value of the weighing hopper 4 (weight value of the object to be weighed) holding the object whose weight value has been measured by each weight sensor 41, the total of the measured values is obtained. All combinations in which a certain combination weight value falls within the allowable range with respect to the target weight value are obtained, and each combination is set as an allowable combination. Then, one allowable combination having the smallest absolute value of the difference between the combination weight value and the target weight value is selected from all the allowable combinations, and this selected allowable combination is set as the first appropriate amount combination.

  Next, one allowable combination in which the absolute value of the difference between the combination weight value and the target weight value is minimum is selected from the allowable combinations formed by combinations of the weighing hoppers 4 other than the weighing hopper 4 belonging to the first appropriate amount combination. The selected allowable combination is set as the second appropriate amount combination. Then, one of the first proper amount combination and the second proper amount combination is determined as a discharge combination for discharging to the inner chute (first discharge combination), and the other is discharged to the outer chute (second discharge) Determined to be a combination). Here, the determination method of the first discharge combination and the second discharge combination is predetermined in the same manner as in the case of the second combination process described above.

  Here, for example, a case is considered where the total number of weighing hoppers 4 is 14 and the selected number selected for one discharge combination by the combination process is 4. In this case, if the double shift operation described in the first embodiment is performed, the combination calculation is performed using the ten measurement values, and the combination weight value becomes a value within an allowable range with respect to the target weight value. And the combination having the smallest absolute value of the difference from the target weight value is selected as the discharge combination (appropriate amount combination).

  On the other hand, in the case of the third combination process, the second appropriate amount combination is selected from 10 measurement values, but the first appropriate amount combination is always among 14 measurement values. Will be selected. It is well known that the greater the number of measurement values used in the combination calculation, the higher the combination weighing accuracy can be. Therefore, if the total number of the weighing hoppers 4 is the same, the third combination process is performed as compared with the case of performing the double shift operation. The combination weighing accuracy as a whole discharged object to be weighed can be improved when using the.

  In the second combination process, in the third combination process, the selection conditions for the first appropriate amount combination are expanded to obtain a plurality of first appropriate amount combinations, and the first combination corresponding to each first appropriate amount combination is obtained. Two appropriate amount combinations are obtained, and the one having the smallest sum of the absolute values of the difference between the combination weight value of the two corresponding appropriate amount combinations and the target weight value is selected. Therefore, when the second combination process is used, it is possible to improve the combination weighing accuracy of the whole object to be discharged as compared with the case where the third combination process is used.

  Further, in the first combination process, two sets of all appropriate combinations are combined, and the difference between the combination weight value of the two appropriate combinations and the target weight value from among the appropriate combination pairs formed by the combination. The one with the smallest absolute value sum is selected. Therefore, when the first combination process is used, it is possible to improve the combination weighing accuracy of the whole object to be discharged, as compared with the case where the third combination process is used.

  According to the first, second, or third combination processing described above, two sets of discharge combinations are simultaneously determined. Therefore, in the combination calculation when obtaining the two sets of discharge combinations, many weighing hoppers 4 are to be weighed. It becomes possible to use the weight, and it becomes possible to improve the combination weighing accuracy as a whole of the objects to be discharged.

  In addition, the processing amount of calculation decreases in the order of the first combination process, the second combination process, and the third combination process, and the time required for the combination process can be reduced in that order.

  In the first and second embodiments described above, when the allowable range for the target weight value is set to a range equal to or greater than the target weight value, that is, the lower limit value of the allowable range is set to a value equal to the target weight value. In this case, the absolute value of the difference between the combination weight value of the appropriate amount combination or the allowable combination and the target weight value is equal to a value (difference) obtained by subtracting the target weight value from the combination weight value. Therefore, in this case, for example, in step S3 of FIG. 6 and step 14 of FIG. 9, calculating the sum of the absolute values of the difference between the combination weight value of each appropriate amount combination and the target weight value is equivalent to each appropriate amount. This is equivalent to calculating the sum of differences obtained by subtracting the target weight value from the combination weight value of the combination.

  If the lower limit value of the allowable range is set to a value equal to the target weight value, an appropriate amount is obtained for each appropriate combination pair instead of steps S3 and S4 in FIG. 6 and steps 14 and S15 in FIG. Calculate the sum of the combination weight values of the two appropriate combinations that make up the combination pair, select one appropriate combination pair whose calculated total is the minimum, and select one of the two appropriate combinations that make up the pair One may be determined as a discharge combination for discharging to the inner chute (first discharge combination), and the other may be determined as a discharge combination for discharging to the outer chute (second discharge combination). Also in this case, the same two discharge combinations as the processing results of steps S3 and S4 and steps 14 and S15 are obtained.

  In the second embodiment, as in the case of the first embodiment, the position of the collecting hopper provided on the inner chute 6a (6A) may be changed or the number may be two. Moreover, you may make it the structure which does not provide a collection hopper only in both the inner side and outer side chute | shoots 6a and 6b (6A, 6B), or the outer side chute | shoot 6b (6B). Further, when the inner chute 6A and the outer chute 6B of FIG. 3 are used, the inner chute 6A may be configured by only the chute 63 and the pipe 64 may not be provided, as in the case of the first embodiment.

  Further, in the second embodiment, one lower chute is disposed below the collective hopper 7a and the collective hopper 7b, and one packaging machine having one input port is disposed below the lower chute. It is good also as a structure. In this case, the control unit 20 controls the collective hopper 7a and the collective hopper 7b to alternately discharge the objects to be weighed. Accordingly, the objects to be weighed simultaneously discharged from the weighing hopper 4 to the inner chute 6a (6A) and the outer chute 6b (6B) are once held by the collecting hopper 7a and the collecting hopper 7b, and are then removed from the collecting hopper 7a and the collecting hopper 7b. The objects to be weighed alternately are put into one packaging machine inlet through the lower chute.

  In the first and second embodiments, the example in which only the weighing hopper 4 is used as the combination hopper that uses the measurement value of the supplied weighing object for the combination calculation is shown. It is not limited to hoppers. FIGS. 10A, 10 </ b> B, 10 </ b> C, and 10 </ b> D are plan views schematically showing a hopper such as a combination hopper in another example. In FIGS. 10A, 10B, 10C, and 10D, the inner chute 6X corresponds to, for example, the inner chute 6a in FIG. 1, and the outer chute 6Y corresponds to, for example, the outer chute 6b in FIG. . Note that one weight sensor 41 (see FIG. 1) is attached to each of the weighing hopper 4 in FIGS. 10 (a) and 10 (b) and the weighing hoppers 4X and 4Y in FIGS. 10 (c) and 10 (d). ing.

  For example, in the case of FIG. 10A, each weighing hopper 4 is configured to have two chambers (weighing chambers) 4a and 4b into which the objects to be weighed are put. The two weighing chambers 4 a and 4 b of each weighing hopper 4 are arranged side by side in substantially the same direction as the arrangement direction (rowing direction) of the plurality of weighing hoppers 4. In this case, the supply hopper 3 is configured to be able to selectively discharge an object to be weighed into the weighing chamber 4a and the weighing chamber 4b of the weighing hopper 4, and the two weighing chambers 4a and 4b of the weighing hopper 4 are respectively connected to the inner chute 6X. And the outer chute 6Y can be selectively discharged to the weighing object. The combination calculation is performed using the weight (measured value) of the objects to be weighed in the weighing chambers 4a and 4b of each weighing hopper 4, and each weighing chamber 4a and 4b is selected as the discharge combination. In each weighing hopper 4, the weight sensor 41 measures the weight of the weighing object in the weighing chamber 4a when the weighing object is supplied only to one weighing chamber, for example, the weighing chamber 4a. Further, when the object to be weighed is supplied to the other weighing chamber 4b, the total weight of the objects to be weighed in the two weighing chambers 4a and 4b is weighed by the weight sensor 41. The control unit 20 (see FIG. 1) subtracts the weight of the object to be weighed in the weighing chamber 4a from the total weight of the objects to be weighed in the two weighing chambers 4a and 4b. Calculate the weight (measured value) of the object.

  In the case of FIG. 10B, a memory hopper 9 having two chambers (accommodating chambers) 9a and 9b to which an object to be weighed is supplied from the weighing hopper 4 is provided below each weighing hopper 4. is there. The two storage chambers 9a and 9b of each memory hopper 9 are arranged side by side in substantially the same direction as the arrangement direction (row arrangement direction) of the plurality of memory hoppers 9. Here, the supply hopper 3 (see FIG. 1) for supplying an object to be weighed to the weighing hopper 4 is not shown. In this case, the weighing hopper 4 is configured to selectively discharge the objects to be weighed to the storage chamber 9a and the storage chamber 9b of the memory hopper 9, and is not discharged from the weighing hopper 4 onto the outer chute 6Y and the inner chute 6X. The two storage chambers 9a and 9b of the memory hopper 9 are configured so that the objects to be weighed can be selectively discharged to the inner chute 6X and the outer chute 6Y, respectively. The combination calculation is performed using, for example, the weight (measurement value) of the objects to be weighed in the storage chambers 9a and 9b of each memory hopper 9, and each of the storage chambers 9a and 9b is selected as a discharge combination. Do not participate in the combination. As the weight of the objects to be weighed in each of the storage chambers 9a and 9b, the weight when weighed in the weighing hopper 4 thereabove is used. Note that the weighing hoppers 4 can be allowed to participate in the combination by making only the combination in which each weighing hopper 4 and one of the storage chambers 9a and 9b of the corresponding memory hopper 9 are simultaneously selected valid. For example, when the corresponding weighing hopper 4 and the storage chamber 9a (or 9b) of the memory hopper 9 are simultaneously selected as the discharge combination, the objects to be weighed in the weighing hopper 4 pass through the storage chamber 9a (or 9b) and go outside. It is discharged onto the chute 6Y or the inner chute 6X.

  In the case of FIG. 10C, the weighing hoppers 4X and 4Y each having the weight sensor 41 attached are arranged in two rows, and the weighing hoppers 4X and 4Y are placed under the weighing hoppers 4X and 4Y. This is a configuration in which a memory hopper 9 having one chamber to which a sample is supplied is provided. In this case, the supply hopper 3 is configured to selectively discharge the object to be weighed to the weighing hopper 4X and the weighing hopper 4Y below, and the one weighing hopper 4X is selectively movable to the memory hopper 9 and the inner chute 6X. The other weighing hopper 4Y is configured to selectively discharge the objects to be measured to the memory hopper 9 and the outer chute 6Y. The combination calculation is performed using the weights (measurement values) of the objects to be weighed in the weighing hoppers 4X and 4Y and the memory hoppers 9. Here, for example, the combination operation is performed so that the weighing hopper 4Y and the memory hopper 9 are selected for the discharge combination of the objects to be discharged onto the inner chute 6X, and the weighing hopper 4X and the memory hopper 9 are selected. The combination calculation is performed so that the weighing hopper 4X and the memory hopper 9 are selected for the discharge combination of the objects to be discharged onto the chute 6Y. The weight of the objects to be weighed in each memory hopper 9 is the weight when weighed in the weighing hoppers 4X and 4Y that have supplied the objects to be weighed to the memory hopper 9. When obtaining the discharge combination discharged onto the inner chute 6X, only the combination in which the memory hopper 9 and the weighing hopper 4Y above it are selected as the discharge combination is valid, and the weighing hopper 4Y is moved onto the inner chute 6X. It can also participate in the combination that is discharged. In this case, the object to be weighed in the weighing hopper 4Y passes through the memory hopper 9 and is discharged onto the inner chute 6X. Similarly, when obtaining a discharge combination to be discharged onto the outer chute 6Y, only the combination in which the memory hopper 9 and the weighing hopper 4X above it are simultaneously selected as the discharge combination is valid, and the weighing hopper 4X is placed on the outer chute 6Y. You can also participate in combinations that are discharged. In this case, the object to be weighed in the weighing hopper 4X passes through the memory hopper 9 and is discharged onto the outer chute 6Y.

  In the case of FIG. 10 (d), two supply hoppers 3X and 3Y are provided instead of the one supply hopper 3 in the configuration of FIG. 10 (c), and the hoppers participating in the combination are shown in FIG. Same as (c). In this case, linear feeders 2X and 2Y are arranged corresponding to the respective supply hoppers 3X and 3Y, and the objects to be weighed are supplied from the respective linear feeders 2X and 2Y to the corresponding supply hoppers 3X and 3Y. The Further, the supply hopper 3X supplies the objects to be weighed to the weighing hopper 4X disposed below the supply hopper 3X, and the supply hopper 3Y supplies the objects to be weighed to the weighing hopper 4Y disposed below the supply hopper 3X. Thus, since the supply hoppers 3X and 3Y are provided corresponding to the weighing hoppers 4X and 4Y, for example, two weighing hoppers 4X and 4Y making a pair are simultaneously selected as the discharge combination and become empty. Can also supply the objects to be weighed to both weighing hoppers 4X, 4Y simultaneously. Thereby, compared with the case of FIG.10 (c), the reduction | decrease of the measurement value which participates in subsequent combination calculation can be suppressed, and the improvement of combination measurement precision can be aimed at.

  In addition to the above, the hopper configuration such as a combination hopper may be variously changed. In the configuration of FIG. 1, one weighing value used in the combination calculation is obtained for one weight sensor 41 attached to the weighing hopper 4. On the other hand, in the case of the configuration of FIG. 10A, two weighing values used in the combination calculation are obtained for one weight sensor 41. In the configuration of FIG. When not participating in the combination, two weight values used in the combination calculation are obtained for one weight sensor 41, and when the weighing hopper 4 is included in the combination, one weight sensor 41 is obtained. Three measurement values used in the combination calculation are obtained. In the case of the configuration shown in FIGS. 10C and 10D, three measurement values used in the combination calculation are obtained for the two weight sensors 41. Therefore, by using the hopper configuration as shown in FIGS. 10A to 10D, the expensive weight sensor 41 can be effectively used. In addition, it is possible to suppress an increase in the diameter of the arc, which is an array of the combination hoppers, and to increase the number of measurement values used for the combination calculation, thereby improving the combination weighing accuracy.

  In the first and second embodiments described above, the control unit 20 does not necessarily have to be composed of a single control device, and a plurality of control devices are dispersedly arranged. It may be configured to control the operation.

  The combination weigher according to the present invention is useful for a combination weigher connected to a twin type packaging machine or the like.

(A) is the schematic schematic diagram of the partial cross section which looked at the combination weigher of Embodiment 1, 2 of this invention from the side, (b) is an assembly chute and weighing hopper of the combination weigher from above. It is the schematic schematic seen. (A) is a perspective view of the inner chute and outer chute of Embodiment 1, 2 of this invention, (b) is a perspective view of the inner chute of the combination scale. It is a perspective view which shows the other structural example of the inner side chute and the outer side chute of the combination balance of Embodiment 1, 2 of this invention. It is a timing chart at the time of comprising so that the combination scale of Embodiment 1 of this invention may be double-shifted. It is a timing chart at the time of comprising so that the combination scale of Embodiment 1 of this invention may carry out a triple shift operation | movement. It is a flowchart which shows the procedure of the 1st combination process in the combination scale of Embodiment 2 of this invention. It is a timing chart which shows the 1st operation example of the combination scale of Embodiment 2 of this invention. It is a timing chart which shows the 2nd operation example of the combination weigher of Embodiment 2 of this invention. It is a flowchart which shows the procedure of the 2nd combination process in the combination scale of Embodiment 2 of this invention. (A)-(d) is the schematic schematic diagram which looked at the other example of the hopper used in the combination weigher of Embodiment 1, 2 of this invention from the upper direction, respectively. (A) is the schematic schematic diagram of the partial cross section which looked at the combination weigher of a prior art example from the side, (b) is the schematic schematic diagram which looked at the collection chute and weighing hopper of the combination weigher from the upper part. .

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Dispersing feeder 2 Linear feeder 3 Feeding hopper 4 Weighing hopper 5 Center base body 6a, 6A Inner chute 6b, 6B Outer chute 6bx, 6Bx Outer chute notch 7a, 7b Collecting hopper 8a, 8b Packaging machine inlet 20 Control unit

Claims (5)

The circles are arranged in the shape of a second arc excluding the first arc from the circle, and the objects to be weighed are selectively discharged in two directions inside and outside the second arc. A plurality of combination hoppers configured as possible;
A first chute portion having a right conical shape arranged upside down disposed below the combination hopper is provided with a notch portion in which a predetermined portion located below the first arc is notched. An outer chute configured to collect the objects to be discharged from the combination hopper in the outer direction and discharge them from the lower discharge port;
A receiving port that is positioned above the inside of the outer chute and receives an object to be discharged inward from the combination hopper, and a discharging port that is outside the outer chute and below the notch And an inner chute that is arranged so as to pass through the notch portion of the outer chute and collects the objects to be weighed received from the receiving port and discharges it from the discharge port,
A combination for obtaining a first discharge combination and a second discharge combination composed of a combination of the combination hoppers in which a combination weight value which is a sum of weights of the supplied objects to be weighed becomes a value within an allowable range with respect to a target weight value. Computing means;
The combination hopper belonging to the first discharge combination discharges the measurement object onto the inner chute by discharging the measurement object inward, and the combination hopper belonging to the second discharge combination. A control means for discharging the object to be weighed onto the outer chute by discharging the object to be weighed toward the outer side with respect to the hopper ,
The inner chute is
A second conical shape that is disposed inside the outer chute, forms the receiving port, collects the objects to be weighed received from the receiving port, and sends the collected objects from the lower opening. A shoot part,
A cylindrical portion disposed so as to pass through the notch portion of the outer chute and for transferring an object to be weighed delivered from an opening at a lower portion of the second chute portion to the discharge port of the inner chute. And
A combination weigher configured such that an opening at a lower portion of the second chute portion is positioned immediately above a discharge port at a lower portion of the outer chute . The outlet of the pre-Symbol inner chute, the first collecting hopper to discharge temporarily holds the objects to be weighed is provided which is discharged from the discharge port, each of the outlet of the outer chute, from the discharge port A second collecting hopper for temporarily holding and discharging the objects to be discharged is provided;
The control means causes the first collective hopper holding the objects to be weighed discharged from the combination hopper to discharge the objects to be weighed and also removes the objects to be weighed from the combination hopper. The said 1st collective hopper and the said 2nd collective hopper are also comprised so that it may discharge | emit a to-be-measured object with respect to the said 2nd collective hopper currently hold | maintained. Combination scale. Before Symbol combination hoppers is provided with two weighing chambers arranged in line arrangement direction of the combination hoppers, weighing the weight of the objects to be weighed which have been supplied to each of the metering chambers, each said metering A weighing hopper capable of selectively discharging objects to be weighed in the inner direction and the outer direction for each chamber;
The combination calculation means may be configured such that the first and second discharge combinations are combinations of the measuring chambers in which the total weight of the objects to be weighed is a value within an allowable range with respect to a target weight value. The combination weigher according to claim 1, wherein the combination weigher is configured to be determined. A plurality of weighing hoppers for weighing the objects to be weighed are disposed above the combination hoppers corresponding to the combination hoppers,
The combination hopper includes two storage chambers, and the objects to be weighed by the weighing hopper are supplied to the respective storage chambers, and the objects to be weighed in each of the storage chambers are arranged in the inner direction and the outer side. A memory hopper that can be discharged selectively in the direction,
The weighing hopper is configured to selectively discharge an object to be measured into the two storage chambers of the corresponding memory hopper,
The combination calculation means may be configured such that the first and second discharge combinations are combinations of the storage chambers in which the total weight of the objects to be weighed is a value within an allowable range with respect to a target weight value. The combination weigher according to claim 1, wherein the combination weigher is configured to be determined. The combination hoppers are arranged in two upper rows and one lower row, and the combination hoppers in the upper two rows are weighing hoppers for weighing the weight of the objects to be weighed respectively. The lower one row of the combination hoppers is a memory hopper provided corresponding to each of the two weighing hoppers and supplied with an object to be weighed by the weighing hopper,
The objects to be weighed discharged from the weighing hopper in the inner row of the upper two rows to the inner chute are discharged to the inner chute, and the items to be weighed discharged to the outer direction correspond to the corresponding memory hopper. Discharged into
The objects to be weighed discharged from the weighing hopper in the outer row of the upper two rows to the inner direction are discharged to the corresponding memory hopper, and the items to be weighed discharged to the outer direction are the outer chute. The combination weigher according to claim 1, wherein the combination weigher is configured to be discharged into the water .

Images