JP4686007B2 - Combination weighing device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a combination weighing device that weighs an input object to be weighed and discharges it to a constant mass, and operates to optimize opening and closing of a hopper according to the type of object to be weighed, particularly weight and volume. The present invention relates to a controllable combination weighing device.
[0002]
[Prior art]
Generally, in a packaging process of a food production line, a weighing device that measures an object to be weighed is used. A combination weighing device that measures a predetermined mass of an object to be weighed at a time when a food having a small lump unit as the object to be packaged is used.
Hereinafter, an example of the combination weighing device shown in the side view of FIG. 6 will be described. As shown in the figure, the combination weighing device 50 includes a supply unit 51 that supplies an object to be weighed and radially distributes, a plurality of stock hoppers 52 arranged circumferentially, and a plurality of weighings provided below the stock hopper 52. A hopper 53 and a funnel-shaped collecting chute 54 provided at the lower portion of the weighing hopper 53 are provided. Each of these parts is arranged on the side part of the central body part 55.
[0003]
The supply unit 51 scatters and supplies the objects to be weighed, which are thrown into the center position of the weighing hoppers 52 arranged circumferentially when viewed on a plane, radially outward. The supply unit 51 includes a conical dispersion unit 51a and a conveyance unit 51b that conveys the dispersed object to be measured to the stock hopper 52 portion. The transport unit 51b includes a trough 51c having both side portions erected, and driving means 51d that vibrates the trough 51c and transports an object to be weighed.
[0004]
The objects to be weighed are dropped into the respective weighing hoppers 53 approximately in the same amount through the stock hoppers 52 provided on the respective weighing hoppers 53, and the respective masses are measured.
The measurement values at the plurality of weighing hoppers 53 usually vary to some extent. Therefore, a desired mass value is obtained by appropriately combining a plurality of weighing values obtained by the plurality of weighing hoppers 53. The plurality of weighing hoppers 53 having such a combination are operated to drop the objects to be weighed onto the collecting chute 54.
[0005]
A discharge hopper (not shown) is provided at the lowest part of the collecting chute 54, and the objects to be weighed that have dropped from the plurality of weighing hoppers 53 are dropped downward at the timing of gathering here.
A packaging device for packaging the objects to be weighed is provided below the collective chute 54, and the objects to be weighed after the combination weighing can be packed in a fixed mass unit.
[0006]
[Problems to be solved by the invention]
The objects to be weighed differ in volume per unit mass, that is, specific volume, depending on the type. For example, in confectionery, potato chips have a large specific volume, and peanuts have a small specific volume.
For this reason, although it was necessary to change the control of each part of the apparatus depending on the type of the object to be weighed, these settings were changed based on experience and the like, and the control was not optimal.
[0007]
For example, in the weighing hopper 53, the objects to be weighed have different volumes even if they have the same mass but differ in type. In consideration of these types of differences, the discharge door at the bottom of the weighing hopper 53 must be opened and closed. However, in the case of an object to be weighed with a large specific volume, the discharge door may be closed before the object is completely discharged, and the object to be weighed may be damaged. On the other hand, the discharge door may close over time after all of the objects to be weighed having a small specific volume are discharged. If the discharge door is not closed at an appropriate time, it is directly affected by the opening and closing of other hoppers, so that the processing efficiency of the entire apparatus cannot be improved.
[0008]
Since the opening and closing of the discharge door is conventionally set while flowing the object to be measured so as to be appropriate for all of the stock hopper 51, the weighing hopper 52, and the discharge hopper, adjustment is troublesome. When a memory hopper is provided between the weighing hopper and the discharge hopper to temporarily store the objects to be weighed and increase the number of combinations, the same opening / closing control is required for the discharge door of the memory hopper. Become.
[0009]
In addition, the objects to be weighed gathered in the discharge hopper are discharged in response to a discharge request from the packaging device. Here, the objects to be weighed fall on a collecting chute having a predetermined length and are collected in the discharge hopper. Therefore, since the time for dropping the collective chute differs depending on the type of the object to be weighed, that is, the volume, the time required for the collection differs.
[0010]
This adjustment requires two settings: a discharge time and a discharge interval. If the discharge time is inappropriate, problems such as pinching the object to be weighed at the discharge door as described above occur. Also, the discharge interval is related to the discharge request of the lower packaging device, and if the setting is inappropriate, for example, when the discharge door of the discharge hopper is opened due to the discharge request, the objects to be weighed are still in the middle of assembly. The object to be weighed may fall to the packaging device at once and break. On the other hand, when already gathered in the discharge hopper, the standby time for discharge is long, and a state where the operation efficiency can be improved is missed.
[0011]
As described above, conventionally, each time the type of the object to be weighed is different, the setting of the open / close control of each hopper of the apparatus is manually performed, and adjustment takes time. In addition, if the type of the object to be weighed is changed, it will take time to make adjustments.
[0012]
The present invention has been made to solve the above-mentioned problems, and can easily and stably perform the weighing operation in response to the change of the type of the object to be weighed, and is adapted to the operation timing with the subsequent apparatus. An object of the present invention is to provide a combination weighing device that can be used.
[0013]
[Means for Solving the Problems]
  In order to achieve the above object, a combination weighing device according to claim 1 of the present invention is provided., ThrowIn a combination weighing device that distributes the objects to be weighed to a plurality of weighing hoppers and combines the weighing hopper weighing values to obtain a weighing object having a predetermined weight.
  A collecting chute for collecting objects to be weighed contained in the selected weighing hoppers among objects to be weighed by the weighing hoppers;
  A discharge hopper provided at the lower end of the collective chute;
  Specific volume setting means for setting a specific volume based on the volume and weight of the object to be weighed;
  Weighing means for detecting the mass of an object to be weighed accommodated in the weighing hopper;
  Based on the set specific volume and the measured value of the weighing means, after the object to be weighed is discharged from the upper hopper, the charging time until the collective chute slides down and is completely accommodated in the discharge hopper is obtained. Control means for controlling the opening and closing timing of the discharge door of the discharge hopper based on the charging time;
WithIt is characterized by that.
[0017]
  Claims2As described, the control means may be configured to obtain an opening / closing cycle of a discharge door provided in the discharge hopper based on the charging time, and to synchronously control the timing with the subsequent apparatus.
[0018]
  Claims3As described above, when the surplus time occurs when the opening / closing timing of the discharge door of the discharge hopper is short with respect to the output cycle of the discharge request output by the subsequent apparatus, the control means inputs from the upper hopper It is also possible to change the timing.
[0019]
  Claims4As described, the control means may be configured to set the opening / closing timing of the discharge door of the upper hopper based on the opening / closing timing of the discharge door of the discharge hopper.
[0020]
  Claims5As described, the specific volume setting means may be configured to calculate and set the specific volume based on the mass and volume of the input object.
[0021]
  Claims6As described, the control means may be configured to store the calculated value for controlling the object to be weighed in the storage means together with the specific volume for each kind of the object to be weighed, so that it can be read and reset when necessary.
[0022]
According to the above configuration, the opening / closing time of the discharge door can be controlled from the loading height of the weighing object in each hopper below the weighing hopper based on the specific volume of the weighing object. Even if the types differ and the specific volume is different, the opening and closing of the discharge door can be controlled optimally, and pinching and useless time can be prevented and efficient weighing operation can be performed.
In addition, by considering the specific volume of the object to be weighed for the discharge door of the discharge hopper, an opening / closing time corresponding to the type of the object to be weighed can be set, and the discharge to the subsequent apparatus can be performed stably. In addition, by matching the opening / closing timing of the discharge door to the discharge request of the subsequent apparatus, the discharge timing to the subsequent apparatus can be synchronized.
As a result, it is possible to facilitate the operation settings for various objects to be weighed, to stabilize the apparatus dispersion and transport operations, and to perform efficient combination weighing while maintaining combination accuracy.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
FIG. 1 is a plan view showing an embodiment of the combination weighing device of the present invention, and FIG. 2 is a side view thereof.
A dispersion supply unit 2 is provided in the center of the upper part of the combination weighing device 1 and at a position immediately below the place where the objects to be weighed are placed. An input unit 13 such as a bucket conveyor is provided at an upper position of the dispersion supply unit 2. The feeding unit 13 is controlled in its feeding operation based on a control signal from the control unit 20 of the combination weighing device 1 to be described later, and feeds and supplies an object to be distributed to the distributed supply unit 2. In the illustrated example, the objects to be weighed accommodated in a plurality of buckets 13a are thrown onto the dispersion supply unit 2 in units of the buckets 13a.
[0024]
The dispersion supply unit 2 is roughly configured by a dispersion unit 3 and a transport unit 4.
The dispersion unit 3 includes a dispersion table 3a formed in a flat conical shape with the center protruding upward, and a driving unit 3b for rotating the dispersion table 3a.
[0025]
When the input means 13 supplies the objects to be weighed onto the dispersion unit 3, a large number of objects to be weighed are constantly stacked on the dispersion unit 3 with a predetermined angle of repose. The objects to be weighed are supplied evenly spilling around.
The weight of the object to be weighed loaded on the dispersion table 3a is detected by a weighing sensor 3f such as a load cell. Of the measured values output from the weighing sensor 3f, the weights of the dispersion table 3a and the driving means 3b are electrically canceled out, and only the measured values are output.
[0026]
Around the dispersion table 3a, a plurality of transport units 4 are provided in a radial arrangement. Each transport unit 4 includes a trough 5 that is a linear transport path having a substantially V-shaped cross section, and a drive unit 6 that reciprocates the trough 5 in the transport direction. The troughs 5 of each transport unit 4 are arranged radially at equal angular intervals in the circumferential direction with the dispersion supply unit 2 as the center. Accordingly, the objects to be weighed supplied to the troughs 5 of the respective transport units 4 are transported toward the outside of the arrangement by the movement of the troughs 5 by the driving means 6.
[0027]
The outer end of the outer side of each trough 5 is in an open state, and the object to be weighed drops from here. A stock hopper 7 is disposed below the outer end of each trough 5. That is, the same number of stock hoppers 7 as the troughs 5 are circumferentially arranged at equal intervals. Each stock hopper 7 is a box having an open top surface, and a discharge door that can be opened and closed is attached to the bottom surface.
[0028]
Below each stock hopper 7, a weighing hopper 8 is arranged. That is, the same number of weighing hoppers 8 as the stock hoppers 7 are circumferentially arranged at equal intervals. The weighing hopper 8 is a box body whose upper surface is open, and a discharge door that can be opened and closed is attached to the lower surface. This weighing hopper 8 is provided with weighing means 8a such as a load cell, and measures the mass of the object to be weighed stored therein. Of the weighing values output from the weighing means 8a, the weight of the weighing hopper 8 or the like is electrically canceled out, and the weighing value of only the object to be weighed is output.
[0029]
A memory hopper 9 is disposed below each weighing hopper 8. That is, the same number of memory hoppers 9 as the weighing hoppers 8 are circumferentially arranged at equal intervals. The memory hopper 9 is a box having an open top surface, and a discharge door that can be opened and closed is attached to the bottom surface. An object to be weighed by the weighing hopper 8 is stored and held in the memory hopper 9. The mass of the object to be weighed stored in the memory hopper 9 is held by the control means of this apparatus.
[0030]
As shown in FIG. 2, the stock hopper 7, the weighing hopper 8, and the memory hopper 9 are arranged vertically from top to bottom in this order, and are arranged inside the apparatus from the top to the bottom, It arrange | positions so that the inclination of the discharge direction of a to-be-measured object may become gentle. The objects to be weighed stored in the memory hopper 9 at the final stage are dropped and discharged by opening the discharge door on the bottom surface.
The memory hopper 9 accommodates an object W to be weighed by the weighing hopper 8. After weighing, the control means selectively combines the weighing values of the objects to be weighed W accommodated in the weighing hoppers 8 and the memory hoppers 9, and selects the combination of the weighing hoppers 8 and the memory hoppers 9 satisfying the target mass. . The selected weighing hopper 8 and memory hopper 9 are discharged to the collecting chute 10 by opening the discharge door.
[0031]
By providing the memory hopper 9 as described above, temporarily storing the weighing result in the weighing hopper 8, and selectively combining the weighing values in the weighing hopper 8 in the upper position and the lower memory hopper 9 The number of selected combinations is increased.
Then, the control means selects a combination of the weighing hopper 8 and the memory hopper 9 that satisfies the target mass. By opening the discharge doors of the selected weighing hopper 8 and memory hopper 9, the objects to be weighed are discharged to the collecting chute 10.
There is a configuration in which the memory hopper 9 is not provided. In this case, the objects to be weighed are discharged directly from the weighing hopper 8 to the collecting chute 10.
[0032]
A funnel-shaped collective chute 10 is provided below the plurality of circumferentially arranged memory hoppers 9. The collecting chute 10 of this example is a hollow truncated cone shape having a relatively large inlet on the upper surface and a relatively small outlet on the lower surface.
The collective chute 10 collects the objects to be weighed discharged from the selected memory hopper 9.
[0033]
A discharge hopper 11 is provided on the lower surface of the collecting chute 1. An object to be weighed with a target mass is accommodated in the discharge hopper 11 and dropped and discharged to the packaging device 17 by opening the lower discharge door.
[0034]
The packaging device 17 packages the object W with a target mass discharged from the discharge hopper 11. For example, a vertical pillow packaging type is used, and a bag with a closed side and bottom is formed to accommodate an object to be weighed, and then discharged after closing the top.
The packaging device 17 outputs a discharge request for opening the discharge door of the discharge hopper 11 to the control means at the timing when the object W is packaged. This discharge request is continuously output at a predetermined cycle along the timing of the packaging operation.
[0035]
Next, FIG. 3 is a block diagram showing an electrical configuration of the apparatus.
The control unit 20 controls the operation of the entire apparatus, and includes a CPU, a ROM, a RAM, and the like, and an operation control program that controls the execution of the CPU. The illustrated control means 20 is a block diagram in which only functions related to the control program for the discharge operation of each hopper, which is the main part of the present invention, are extracted.
The control means 20 is connected with an input means 21 for inputting various parameters and a specific volume setting means 22 for setting and holding the specific volume of the object to be weighed. In addition, a weighing signal from the weighing sensor 3 f that measures the weight of the object to be weighed on the dispersion unit 3 and a discharge request from the packaging device 17 are input.
[0036]
In the specific volume setting means 22, the specific volume of the object to be weighed is set.
The specific volume is set to a value determined by volume (ml) / mass (g). The control unit 20 can calculate the specific volume from the volume and mass input from the input unit 21 and set the specific volume in the specific volume setting unit 22.
[0037]
The control means 20 is roughly composed of means for controlling the opening and closing of each hopper and means for controlling the discharge timing to the packaging device 17. In the first embodiment, the control means 20 controls the opening and closing of the discharge door of the weighing hopper 8. Means 24 are provided.
[0038]
The opening / closing control means 24 obtains and controls the opening / closing time of the weighing hopper 8 by obtaining the specific volume set in the specific volume setting means 22.
[0039]
The storage means 29 can store the obtained opening / closing time for each type of object to be weighed and setting parameters for timing setting described later, and inputs the type of object to be weighed later. Thus, the corresponding setting parameter can be called and set (preset function).
[0040]
Next, the contents of the opening / closing control of the discharge door of the weighing hopper 8 configured as described above will be described with reference to the schematic diagram of FIG.
The open / close control means 24 obtains the volume of the object to be weighed stored in the weighing hopper 8 by referring to the set specific volume of the object to be weighed by the following equation.
Volume A of weighing object W stored in the weighing hopper 8 = weighing value × specific volume
The above measured value is an output value of the weighing means 8 a that measures the mass of the object W in the weighing hopper 8.
[0041]
Next, the height of the workpiece W stored in the weighing hopper 8 is obtained by the following equation.
Height L = volume A / bottom area of the object W stored in the weighing hopper 8
[0042]
The opening / closing time of the discharge door 8b of the weighing hopper 8 is calculated using the following formula based on the height of the object W to be weighed. That is, at the same time as the uppermost part of the weighing object W stored in the weighing hopper 8 finishes being discharged from the lower end (discharge door 8b) of the weighing hopper 8, the discharge door 8b is closed.
Weighing object W height L = 1 / 2gt²Further, the opening / closing time t is obtained.
[0043]
For example, if the weighing value of the object W stored in the weighing hopper 8 is 30 (g) and the specific volume is 20 (ml / g), the volume is 600 (ml). The capacity of the weighing hopper 8 is 600 (ml) and the bottom area is 150 (cm²), The height L of the workpiece W is 4 (cm). As a result, the opening / closing time t is calculated to be 90 (ms).
When the type (specific volume) of the object to be weighed W is different and the height L is 8 (cm), the opening / closing time t is 130 (ms).
The opening / closing time t is a period from when the discharge door 8b is opened until it is closed.
[0044]
As described above, the opening and closing time of the weighing hopper 8 is set longer as the type (specific volume) of the object to be weighed W differs and the height is higher.
As a result, it is possible to perform control so that the opening / closing time of the weighing hopper 8 is optimized in accordance with the type (specific volume) of the workpiece W. That is, the discharge door 8b of the weighing hopper 8 is opened to start discharging the object W, and the discharge door 8b is closed almost simultaneously with the uppermost portion of the object W stored in the weighing hopper 8 being discharged. Is done.
[0045]
For the sake of convenience, the above calculation is to obtain the height L of the workpiece W on the assumption that the weighing hopper 8 has a rectangular parallelepiped shape. In the weighing hopper 8, when the portion corresponding to the bottom area is inclined, the height L of the object to be weighed W is referred to with reference to a table in which the weight and height are previously associated with the type (specific volume) of the item to be weighed. Ask for. Further, the height L of the object to be weighed W can be obtained based on the weight of the object to be weighed based on the shape of the weighing hopper 8 and referring to the table of the bulk specific volume.
[0046]
In the above description, the configuration for controlling the opening / closing time of the discharge door 8b for the weighing hopper 8 has been described. However, the opening / closing time of the discharge door 9b is also applied to the memory hopper 9 that stores the object W after weighing. It can be controlled to be optimal.
In this case, the control means 20 sets the opening / closing time of the discharge door 9b of the memory hopper 9 by using the calculation result of the weighing hopper 8 provided on the memory hopper 9 and discharging the object W to the memory hopper 9. Control. Here, if the volume (bottom area etc.) of the weighing hopper 8 and the memory hopper 9 is the same, the control means 20 uses the calculation result of the weighing hopper 8 as it is. When the volumes are different, the calculation result obtained by the weighing hopper 8 is corrected according to the volume of the memory hopper 9 and used.
[0047]
(Second Embodiment)
The second embodiment is configured to control the discharge timing for discharging the objects to be weighed from the combination weighing device 1 to the packaging device 17.
As shown in FIG. 3, the control means 20 is provided with a timing control means 25 for controlling the opening and closing of the discharge door of the discharge hopper 11, and obtains and controls the opening and closing cycle discharged to the packaging device 17. The opening / closing control means 24 obtains the opening / closing time of the discharge hopper 11 based on the specific volume of the object to be weighed, the volume (bottom area) of the discharge hopper 11 and the measurement value of the measurement means 8a as described above. Here, since the objects to be weighed discharged from the plurality of weighing hoppers 8 (memory hoppers 9) are gathered in the discharge hopper 11, the measured value is an added value of the measured values of the discharged weighing hoppers 11.
[0048]
The opening / closing control means 24 obtains the opening / closing time of the discharge hopper 11 based on the specific volume set in the specific volume setting means 22.
In the discharge hopper 11, the objects to be weighed W stored in the plurality of weighing hoppers 8 (memory hoppers 9) corresponding to the target mass after weighing by the weighing hoppers 8 are collected and collected by the collecting chute 10. The volume (bottom area) is larger than that of the weighing hopper 8.
By setting a value along the discharge hopper 11 for the term of the volume (bottom area), the height of the object to be weighed W is obtained in the same manner as described above, and then the opening / closing time t of the discharge door 11b of the discharge hopper 11 is set. Ask.
[0049]
Next, the opening / closing cycle discharged to the packaging device 17 is obtained and controlled.
FIG. 5 is a timing chart showing the opening / closing timing of the discharge hopper 11. As shown in FIG. 5 (a), the discharge door 11b of the discharge hopper 11 is opened at the time of discharge request T1 from the packaging device 17, and is closed after a predetermined opening / closing time t1 has elapsed.
Therefore, the timing control means 25 sets the timing immediately after the discharge door 11b is closed, that is, when the opening / closing time t1 has elapsed (time T2), as the timing at which the workpiece W is started to be charged into the discharge hopper 11.
[0050]
And the timing control means 25 calculates | requires injection | throwing-in time t2 of the discharge hopper 11. FIG. During this charging time t2, the leading end Ws of the object to be weighed W is discharged from the upper memory hopper 9 and slides down the collecting chute 10 until the rear end We of the object to be weighed W is accommodated in the discharge hopper 11 completely. Is the period.
For calculating the charging time t2, as shown in the schematic diagram of FIG. 4, the distance from the memory hopper 9 to the discharge hopper through the collective chute 10, the work length of the workpiece W on the collective chute 10 Wa (Wa = length from the front end Ws to the rear end We) and the inclination angle of the collective chute 10 are set as items for calculation. Further, since the workpiece length Wa changes in relation to the type (specific volume) of the object to be weighed W, the specific volume is used for the calculation. In addition, the friction coefficient for each type of the objects to be weighed W on the collective chute 10 is set.
[0051]
Next, the timing control means 25 obtains the opening / closing cycle t0 of the discharge hopper 11. As shown in FIG. 5A, the opening / closing cycle t0 is the sum of the opening / closing time t1 and the closing time t2.
Thereby, the discharge hopper 11 can discharge | emit the to-be-measured object W to the packaging apparatus 17 sequentially by the space | interval of the opening / closing period t0. The object to be weighed W is discharged to the packaging device 17 when the discharge door 11b of the discharge hopper 11 is next opened (time T3).
[0052]
Next, the timing control means 25 performs setting to synchronize the discharge timing of the objects to be weighed from the combination weighing device 1 with the packaging operation of the packaging device 17.
That is, after supplying the objects to be weighed, the packaging device 17 performs an accommodating operation on the tray and a packaging operation at a substantially constant cycle, and outputs a discharge request at a predetermined cycle tx shown in FIG.
Here, the combination weighing device 1 needs to be set so that the objects to be weighed are sequentially discharged at a cycle shorter than at least the cycle tx of the discharge request of the packaging device 17. Actually, the operation cycle is set on both sides according to the capabilities of the combination weighing device 1 side and the packaging device 17 side.
[0053]
Then, as shown in FIG. 5C, the timing control means 25 obtains the surplus time tr when the opening / closing cycle t0 of the discharge hopper 11 is shorter than the discharge request cycle tx of the packaging device 17. The surplus time tr is the period tx of the discharge request minus the input time t2. Then, the surplus time tr is assigned before and after the charging time t2 at a predetermined ratio.
In the example shown in FIG. 5C, the surplus times tr1 and tr2 are assigned before and after the charging time t2 (tr = tr1 + tr2, tr1 = tr2), respectively. With this assignment, a new opening / closing cycle t0 ′ (t0 ′ = Tx in the illustrated example) of the discharge hopper 11 is set, and the object W is in a stable state with a margin with respect to the operation cycle of the packaging device 17. Can be stored in the discharge hopper 11. In other words, it is possible to provide a margin for the period from the memory hopper 9 to the passage through the collective chute 10 and being accommodated in the discharge hopper 11, and the downhill state of the collective chute 10 portion depending on the type of the object to be weighed W. It becomes possible to cope with fluctuations.
[0054]
Next, the timing control means 25 sets the opening / closing timing of the memory hopper 9 based on the calculated charging time t2 of the discharge door 11b of the discharge hopper 11.
After assigning and setting the surplus time tr, a time T4 before the charging time t2 is a time when the leading end Ws of the workpiece W is started to be charged into the discharge hopper 11.
The timing control means 25, as shown in FIG. 5 (d), discharges the memory hopper 9 based on this charging time t2 (time from the memory hopper 9 to be accommodated in the discharge hopper 11 via the collective chute 10). Time T4 for opening the door 9b is obtained. By this time T4, a period t3 from when the discharge request is output at time T5 to when the discharge door 9b of the memory hopper 9 is opened can be obtained. That is, the operation timing of the memory hopper 9 with respect to the discharge request timing can be set.
[0055]
With the above setting, the workpiece W discharged from the discharge hopper 11 can be synchronized with the operation timing of the packaging device 17, and the opening / closing timing of the memory hopper 9 can be set at the same time.
[0056]
【The invention's effect】
  According to claim 1 of the present invention,The opening and closing timing of the discharge door provided on the discharge hopper of the combination weighing device is controlled by obtaining the input time until the collective chute slides down and is accommodated after discharging from the upper hopper. This is a configuration considering the volume. As a result, the opening / closing timing of the discharge hopper can be set in an optimum state corresponding to the type of the object to be weighed W, and it is possible to cope with this even if the type of the object to be weighed differs. Since the discharge timing can be obtained, the operating efficiency of the apparatus can be improved.
[0057]
  BookClaims of the invention2Accordingly, since the timing with the subsequent apparatus is synchronously controlled based on the above-described charging time, the objects to be weighed after being discharged from the discharge hopper can be stably supplied to the subsequent apparatus.
  Claim3According to the present invention, the discharge timing on the combination weighing device side and the discharge request timing of the subsequent device are taken, and when the surplus time occurs, the charging timing from the upper hopper to the discharge hopper is changed. It can be discharged to the subsequent device after the storage of the object to be weighed is stable, and the object to be weighed can be securely stored temporarily in the discharge hopper and then discharged to the subsequent device. Can improve the reliability.
  Claim4According to the configuration, the opening / closing timing of the upper hopper is obtained from the opening / closing timing of the discharge door of the discharge hopper, and the timing at which the article can be reliably stored in the discharge hopper can be set.
[0058]
  The specific volume of the object to be weighed is5It can be configured to calculate and set from mass and volume as described. And claims6As described, if the value calculated by the control means is stored in the storage means, the values required for the control by type of the object to be weighed can be set all at once, and the operation when changing the type of the object to be weighed Can be done easily and appropriately.
[Brief description of the drawings]
FIG. 1 is a plan view showing a combination weighing device of the present invention.
FIG. 2 is a side view of the apparatus.
FIG. 3 is a block diagram showing an electrical configuration of the apparatus.
FIG. 4 is a diagram showing a flow of an object to be weighed.
FIG. 5 is a view for explaining opening / closing time and timing of the discharge hopper.
FIG. 6 is a side view showing a conventional combination weighing device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Combination measuring device, 7 ... Stock hopper, 7b, 8b, 9b, 11b ... Discharge door, 8 ... Weighing hopper, 8a ... Weighing means, 9 ... Memory hopper, 10 ... Collecting chute, 11 ... Discharge hopper, 13 ... Input Means, 17 ... packaging device, 20 ... control means, 21 ... input means, 22 ... specific volume setting means, 24 ... opening / closing control means, 25 ... timing setting means, 29 ... storage means.

Claims (6)

In the combination weighing device that distributes the input objects to be weighed to a plurality of weighing hoppers and combines the weighing hopper weighing values to obtain an object to be weighed with a predetermined weight,
A collecting chute for collecting objects to be weighed contained in the selected weighing hoppers among objects to be weighed by the weighing hoppers;
A discharge hopper provided at the lower end of the collective chute;
Specific volume setting means for setting a specific volume based on the volume and weight of the object to be weighed;
Weighing means for detecting the mass of an object to be weighed accommodated in the weighing hopper;
Based on the set specific volume and the weighing value of the weighing means, after the object to be weighed is discharged from the upper hopper, the charging time until the collective chute slides down and is completely accommodated in the discharge hopper is obtained. Control means for controlling the opening and closing timing of the discharge door of the discharge hopper based on the charging time;
A combination weighing device comprising: The control means, the closing time calculated opening and closing cycle of the discharge door provided in the discharge hopper based, the combination weighing apparatus according to claim 1, wherein synchronously controlling the timing of the succeeding apparatus. When the surplus time occurs when the opening / closing timing of the discharge door of the discharge hopper is short with respect to the output cycle of the discharge request output by the subsequent apparatus, the control means changes the input timing from the upper hopper. Item 3. The combination weighing device according to Item 1 . Wherein, based on the opening and closing timing of the discharge door of the discharge hoppers, combination weighing apparatus according to claim 1, 3 to set the close timing of the exhaust door at the top of the hopper. The combination weighing device according to any one of claims 1 to 4 , wherein the specific volume setting means calculates and sets the specific volume based on the mass and volume of the input object to be weighed. The control means according to any one of claims 1 to 4, a calculated value relating to the control of the objects to be weighed stored in the storage means together with a specific volume by type of該被weighed, and configured to be reconfigured read as needed Combination weighing device.

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