JPS6225971B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an apparatus for filling powders, other foods, medicines, etc., and more particularly to a filling amount control apparatus for filling to an accurate net weight.

Conventional filling equipment cannot achieve sufficient filling accuracy, and the net weight of the filled product is measured by manual sampling to determine whether the lot is good or bad. As a high-precision filling device that does not require manual sampling inspection, the present applicant previously filed an application (Utility Application No. 163274 (1974)
No. 61-4822)) This device has a configuration that uses a rough filling machine and a correction filling machine as filling machines, and measures the amount of rough filling filled by the rough filling machine, and calculates the amount of the rough filling. The amount value is compared with a value slightly smaller than the target weight value preset by the setting device, and the correction filling machine is controlled in a feedforward manner based on the tendency. In the device of this prior application by the present applicant, the total weight after correction filling is also measured, and the results are used to distinguish between non-defective products and defective products, and the defective products are transported to the defective product removal section. It is something that makes you

However, when the filling device is in operation, the amount of the object to be weighed in the hopper changes, or the surrounding conditions such as temperature and humidity change, resulting in a change in the apparent specific gravity of the object to be weighed, making it difficult to operate the unit. The filling accuracy deteriorates due to changes in the weight of the objects to be weighed per hour, and the apparatus of the applicant's previous application as described above does not have a structure to automatically control the rough filling amount, and the filling accuracy after correction filling is reduced. It was inevitable that variations would occur in the total weight.

The present invention has a configuration in which the feed forward control amount of the correction filling machine performed by the above device is further controlled based on the tendency of the total weight measurement performed after the correction filling, thereby making it possible to perform filling with even higher accuracy. It is an object of the present invention to provide a filling amount control device that can extremely reduce the occurrence of lightweight products or excessively excessive products that are ultimately sorted out.

Next, an embodiment of the control device according to the present invention will be described with reference to the drawings.

FIG. 1 is a schematic explanatory diagram of a control device according to the present invention and a filling device controlled by the control device. This is a transport device that transports. In detail, 101
is an empty container, 102 is a roughly filled container, 103
201 is an input conveyor section, 202 is a first conveyance section, 203 is a second conveyance section, and 204 is an exit conveyor section. A tare weight measuring section 301 is provided between the entrance conveyor section 201 and the first conveying section 202, and a rough filling weight measuring section 302 is provided between the first conveying section 202 and the second conveying section 203. A total weight measurement section 303 is provided between the second conveyance section 202 and the exit conveyor section 204. Furthermore, the first
At the upper position of the transport section 202, there is a rough filling machine 401 that fills the empty container 101 with 90 to 95% of the product weight.
and a container position detector 501 are provided, and the roughly filled container 10 is located at the upper position of the second transport section 203.
Correction filling machine 402 that fills 2 with the missing weight
and a container position detector 502 are provided. The auger filling machine A shown in FIG. 2 is used as the rough filling machine 401 and the correction filling machine 402, and the auger filling machine A will be explained as follows.
The auger filling machine A has an upper hopper 1 for storing powder P, and a lower hopper 2 provided in communication with the upper hopper 1, and an auger 3 is provided at the discharge port 2a of the lower hopper 2. There is. Above auger 3
is connected to a reduction gear 8 via an auger shaft 3a, bevel gears 4, 5, a transmission shaft 6, and a transmission belt 7, and this reduction gear 8 is connected to a motor M via a transmission belt 9. Further, a rotary plate shutter 10 is attached to the reduction gear 8 and rotates in proportion to the rotation angle of the auger shaft 3a, and at a position close to the shutter 10, the rotation of the shutter 10 changes in proportion to the rotation of the auger shaft 3a. A pulse sensor 11 is attached to obtain the pulses. The output of the above-mentioned pulse sensor 11 corresponds to each filling machine control circuit 1.
2, 13, and each control circuit 12, 1
From 3 onwards, an ON/OFF operation signal is applied to the motor M.

Next, the control device C that controls each of the filling machine control circuits 12 and 13 includes the tare weight measuring section 301,
Rough filling weight measurement section 302, total weight measurement section 30
3 and a container position detector 502, and has a circuit configuration shown in the block diagram of FIG. In addition, in measuring the rough filling weight and measuring the total weight, the value obtained in measuring the tare weight is subtracted from each measured value, but in the explanation of this example, the tare weight has already been calculated. It is treated as a subtracted value, and the explanation regarding the tare weight is omitted. In the figure, 14 is a sampling circuit that samples the weight signal Xi [g] from the rough filling weight measuring section 302, and the sampling circuit 14 includes a sample number setting device 15 that sets the number of samples, and a sample number setter 15 that sets the number of breaks. It has a rest number setting device 16. Reference numeral 17 denotes an average value calculation circuit that calculates an average value from the m measurement signals Xm sampled by the sampling circuit 14, and this calculation circuit 17 has a display 18 that displays the average value m that is the calculation result. have. 19
is a comparison calculation circuit that compares and calculates the average value m obtained by the calculation circuit 17 and _the target set central value It has a reference weight setting device 40 and a setting device 21 for setting a positive tendency limit A ₂ [g].
The setting value from X ₀ is input. This comparison calculation circuit 19 calculates the center value Xs as follows: Xs=[X ₀ +A ₁ +A ₂ /2], and uses the obtained Xs to calculate the center value
The ratio of the above average value m to Xs [Xs/m] is calculated, and the average value m is [m<X ₀ +
A ₁ , m>X ₀ +A ₂ ], an ON signal is collectively applied to a rough filling amount calculation/storage circuit 22, which will be described later. The rough filling amount calculation/storage circuit 22 is connected to a rough filling pulse number setting device 23 that sets the number of pulses corresponding to the discharge amount per gram in the rough filling machine 401, and the calculation of the comparison calculation circuit 19 is performed. From the result [Xs/m], calculate the rough filling machine operation pulse number [P _n =P _{n- 1}
The configuration is such that P _n is stored instead of P n . 2
2a is a display on which the number of pulses P _n calculated by the rough filling amount calculation/memory circuit 22 is displayed;
The rough filling machine operation pulse number P _n is applied to the filling machine control circuit 12, and when this filling machine control circuit 12 receives the detection signal from the container position detector 501, the coarse filling machine operation pulse number P _n is added to the filling machine control circuit 12. The structure is such that the auger 3 of the rough filling machine 401 is rotated correspondingly.

On the other hand, 24 is a sampling circuit that samples the weight signal Yk [g] from the total weight measurement section 303, and the sampling circuit 24 includes a sample number setting device 25 that sets the sampling circuit, and a number of breaks that sets the number of breaks. It has a setting device 26. Reference numeral 27 denotes an average value calculation circuit that calculates an average value from n measurement signals Yn sampled by the sampling circuit 24, and this calculation circuit 27
has a display 28 that displays the average value n that is the result of the calculation. 29 is the average value n obtained by the arithmetic circuit 27 and the target set central value Ys
This comparison calculation circuit 29 is a comparison calculation circuit that compares and calculates the negative trend limit B ₁ [g]
Setter 30 and positive trend limit B ₂ to set
[g], and a setting value X ₀ from the reference weight setting device 40 is input thereto. This comparison calculation circuit 29 calculates the center value Ys as Ys=[X ₀ +B ₁ +B ₂ /2], and uses the Ys obtained here to calculate the ratio of the average value n to the center value Ys [Ys/ m], and when the average value n satisfies [n<X ₀ +B ₁ , n>Y ₀ +B ₂ ], an ON signal is applied to the total filling amount calculation/storage circuit 32, which will be described later. ing. The total filling amount calculation/storage circuit 32 is connected to a correction filling pulse number setting device 33 that sets the number of pulses corresponding to the discharge amount per gram in the correction filling machine 402, and the calculation of the comparison calculation circuit 29 is performed. A configuration in which the corrected filling machine operation pulse number [Q _o =Q _o-1 Ys/Yn] is calculated from the result [Ys/m], and Q _o is stored instead of Q _o-1 by the ON signal of the comparison calculation circuit 29. It is said that 34 is a display on which the number of pulses _Qo calculated by the total filling amount calculation/storage circuit 32 is displayed.

Further, the weight signal Xi [g] from the rough filling weight measuring section 302 is added to the memory 35, and the memory 35 receives the signal Xi [g] as follows.
Store it in the address specified by the weight write signal i,
The configuration is such that the detection signals j from the container position detector 502 are read out sequentially. 36 is a correction amount calculation circuit that calculates the weight signal Xj read from the memory 35 and the center value Ys obtained from the comparison calculation circuit 29 to calculate the correction amount [Ys−Xj]; , the above correction amount [Ys−Xj]
and the pulse number signal Q _o from the total filling amount calculation/storage circuit 32 to obtain a corrected filling machine operation signal Q that is further corrected based on the tendency of the total weight measurement.
This is a correction filling amount calculation/storage circuit that calculates _o・[Ys−Xj]. The operation signal Q _o [Ys-Xj] is applied to the filling machine control circuit 13, and this filling machine control circuit 13 is connected to the container position detector 50.
When receiving the detection signal from 2, the auger 3 of the correction filling machine 402 is rotated by the amount corresponding to the operation signal.

Next, the operation of the device configured as described above will be explained.

First, the containers 102 that have been roughly filled in the rough filling machine 401 are sequentially transferred to the rough filling weight measuring section 30.
Sent to 2. For example, three weight signals are collected in the sampling circuit, and the average value circuit 1
7, and sampling is performed in such a way that the next five signals are not sent.

Next, the average value m of the weight signals of the sampled containers 102 is calculated in the average value calculation circuit 17, and further, the average value m is calculated in the comparison calculation circuit 19.
and the target set center value Xs is calculated. The rough filling machine 401 is subjected to feedback control based on the ratio between this average value m and the set center value Xs, and a rough filling amount of 90 to 95% of the product weight is maintained.

Container 1 was then sent to correction filling machine 402.
02 is detected by a container detector 502 provided close to the correction filling machine 402, and the container 102
The rough filling weight Xj is read out from the memory 35. The difference between this rough filling weight Xj and the target setting center value Ys is calculated by the correction amount calculation circuit 36, and the correction filling machine 402 performs feed forward control based on the correction amount [Ys−Xj] that is the difference. However, the above-mentioned correction amount [Ys-Xj] is further controlled based on the measured total weight of the container 103 that has been filled previously. That is,
The previously filled container 103 is measured by the total weight measuring section 30
Sent to 3. This weight signal is processed by a sampling circuit, for example, three signals are sent to an average value circuit.
7, and sampling is performed in such a way that the next five signals are not sent. The average value n of the weight signals of the containers 103 sampled in this way
is calculated by the average value calculation circuit 27, and further, the ratio between the above-mentioned average value n and the target setting center value Ys is calculated by the comparison calculation circuit 29. This average value n
The correction amount [Ys-Xj] is controlled based on the ratio between the set center value Ys and the set center value Ys.

In addition, in the embodiment described above, the correction amount [Ys - Xj] is controlled using the ratio between the average value n obtained by measuring the total weight and the target setting center value Ys, but as shown in FIG. By adding a circuit indicated by a dotted line, it is possible to configure a configuration in which control is performed using a value based on the average value n after rough filling. That is, the corresponding rough filling weight is read from the memory 35, sampled, and the average value n of the rough filling weight is calculated by the average value calculation circuit 27. Furthermore, the comparison calculation circuit 29 calculates [Ys-Xn/Yn-Xn] instead of [Ys/n] obtained in the above embodiment, and based on this ratio, the corrected filling machine operation pulse number Q _o
= Q _o-1 [Ys-Xn/Yn-Xn] makes the correction amount Q _o
- It can be configured to calculate and control [Ys−Xj].

Note that the present invention can be modified in various ways without changing the gist thereof. For example, instead of setting the deviation from the reference weight, the trend limit may be set using the absolute value of the weight.

Further, when a pulse motor is used as the auger motor, the filling machine control output may be such that a pulse generator generates a predetermined number of pulses.

As explained above, according to the present invention, the rough filling amount is measured, and the rough filling machine is feedback-controlled based on the tendency thereof, and the correction filling machine is also feedback-controlled based on the amount of shortage of the fixed value of the rough filling amount. The filling amount control device of the filling device is configured to control the feedforward control amount of the correction filling machine based on the tendency of the total weight measurement performed after correction filling, so that extremely highly accurate filling operations can be performed. There is an effect that can be done. Further, according to the present invention, the trend of the total weight measurement after the correction filling is determined by sampling the measurement values for each container after the correction filling and taking the average value thereof.
Since this average value is compared with the set center value and output, the variation in the total weight value for each container is averaged out to a highly accurate value, and a highly accurate filling operation can be performed.

Therefore, there is very little variation in the product weight of each container that is sent sequentially, and there are almost no defective products, so there is no need to take the trouble of removing defective products from each container after correction filling. This has the excellent effect of streamlining the filling operation and subsequent operations, and further improving the safety of the product.

[Brief explanation of the drawing]

FIG. 1 is a schematic explanatory diagram of a control device according to the present invention and a filling device controlled by the control device;
The figure is a cross-sectional explanatory view showing the structure of the auger filling machine, and FIG. 3 is a block diagram showing an embodiment of the control device according to the present invention. 24... Sampling circuit, 27... Average value calculation circuit, 29... Comparison calculation circuit, 302... Rough filling weight measuring section, 303... Total weight measuring section, 401... Rough filling machine, 402... Correction filling machine.

Claims (1)

[Claims] 1 A large number of containers are sequentially conveyed in a predetermined direction by a conveyor means, and during the conveyance, a rough filling machine 4
Roughly fill each empty container with the contents in sequence according to 01,
A correction filling machine 402 is installed downstream of the rough filling position by the rough filling machine during the conveyance.
The contents are sequentially corrected filled into the containers after each rough filling, the rough filling weight is measured between after the rough filling and the corrected filling, and the rough filling machine 401 is feedback-controlled based on the tendency, and
In a filling amount control device of a filling device that performs feed-forward control of the correction filling machine 402 based on the amount of shortage with respect to the determined value of the rough filling amount, at least a total weight measuring section that sequentially measures the total weight of each container after correction filling. 303, a sampling circuit 24 that samples the measured value for each container obtained from the total weight measurement section, an average value calculation circuit 27 that calculates the average value of the values sampled by the sampling circuit, and the average value It is equipped with a comparison calculation circuit 29 that compares and calculates the average value obtained by the calculation circuit and a set center value serving as a target, and the correction filling machine 402 is provided based on the ratio calculated by the comparison calculation circuit 29. A filling amount control device for a filling device, characterized in that the device is configured to control a feedforward control amount of the filling device.