JPH0240965B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a weighing label issuing device that can preset the number of labels to be issued.

Conventionally, it is known that, for example, the number of labels to be issued can be preset each time a label is issued, but with this, the number of labels to be issued for the next one is preset every time the preset quantity of labels for the previous label has been issued. There was a drawback that the label issuing operation was troublesome.

This invention was devised in order to eliminate such drawbacks, and it presets the number of labels to be issued each time when issuing labels multiple times. To provide a weighing label issuing device capable of reading out a preset issue quantity corresponding to the issuance of a label and issuing labels based on the read issue quantity, facilitating a label issuing operation and improving operability. The purpose is to

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a display section 1 and an operation section 2. The display section 1 consists of an upper display section 3, a lower display section 4, and a lamp display section 5. The upper display section 3 includes a weight display 6, A unit price display 7, a price display 8 are provided, and the lower display section 4 includes a tare display 9, a quantity display 10,
A numerical value display 11 and a code display 12 are provided. The lamp display section 5 includes the respective indicators 6 to 6.
A lamp is provided corresponding to 12. In other words, the zero point indicator lamp 1 corresponds to the weight indicator 6.
3. A tare weight setting lamp 14 and a tare amount lamp 15 are provided, and a 10g lamp 1 corresponds to the unit price display 7.
A 6,100g lamp 17 and a 1Kg lamp 18 are provided, and a correction lamp 19 and an error/power outage lamp 20 are provided corresponding to the price display 8. Also,
A pack number lamp 21 corresponding to the number display 10,
Number of settings (1), (2) to (10) lamps 22a, 22b to 22
j. A total number of issues lamp 23 is provided, and a processing date lamp 24 and a time lamp 2 correspond to the numerical display 11.
5. An effective date lamp 26 and a department code lamp 27 are provided, and a product lamp 28 and a store lamp 29 are provided corresponding to the code display 12. The operation unit 2 has switches such as automatic issue, manual issue,
Business switching switch 3 that performs 3-stage switching of fixed printing
0. This business switching switch 30 is valid when the printing is fixed, and unit price/weight is fixed, weight/price is fixed,
Fixed changeover switch 3 that performs 3-stage changeover of fixed price
1. Unit price changeover switch 32 for switching unit price per 10g, per 100g, or per 1Kg, turn on addition.
Addition switch 33 for switching to OFF, printing switch 3 for switching from one-stage printing to two-stage printing
4. A tare weight cancellation force switch 35 is provided to switch the tare weight cancellation force ON/OFF. Also, the effective date
Product code, tare, time, processing date, unit price, weight,
An effective date switch 36, a product code switch 37, a tare switch 38, a time switch 39, a processing switch 40, a unit price switch 41, a weight switch 42, and a price switch for switching whether to print or erase each printing item such as price and department code. A switch 43 and a department code switch 44 are provided. The operation unit 2 also has keys such as "0", "1" to "9", which are used to input numerical data.
numeric keys 45, an erase key 4 used for input using these numeric keys, erasing and correcting the total number of issues, or stopping printing on journals and receipts, etc.
6. Wind key 47 used to take in weighed weight data as tare weight, wind key 48 used to call up tare weight and take in tare weight with numeric keys, manually feed label. The feed key 49 is used to complete the setting of fixed printing hourly unit price, weight, price, tare setting, number of packs, processing date, effective date, total number of issues, time, and store code. Processing to return to the original work, completion of settings when setting the 4th digit of the code, unit price, tare weight, and department code for each product code, calling the set value for each product code, and returning to the original after calling A * key 50 is provided as a classification key used for returning to work, issuing labels during manual issuing, and the like. In addition, a zero setting key 51 used to set the zero point of the scale, unit price, tare,
A setting key 52 is used to set each item such as department code, product code, weight, and price, a print every time key 53 is used when printing a single item, and a print key 53 is used to call up the values set for each product code. A set value call key 54 is used, a processing date key 55 is used to set and call the processing date, and a pack number 1, 2 to 10 key 56a is used as a quantity preset key to set and call the number of packs 1 to 10. , 56b-56
j, total number of labels issued key 57 used to call up the total number of labels issued, time key 58 used to set and call up the time, store code key 59 used to set and call up the store code of each store, valid. A valid date key 60 is provided for use in setting and recalling the date. There is also a subtotal check key 61 used to print and check the subtotal contents on labels, journals, and receipts, a total check key 62 used to print and check the total contents on labels, journals, and receipts, and a subtotal check key 62 used to print and check the total contents on labels, journals, and receipts. Label and journal the contents. Subtotal settlement key 63 used to print on the receipt and clear the subtotal, total settlement key 64 used to print the total on the label, journal, receipt and clear the total contents, memory A correction (+) key 65 is used to add and correct the number of packs, weight, and price to the memory. A correction (-) key 66 is used to subtract and correct the number of packs, weight, and price to the memory. A last-minute correction key 67 is provided which is used to subtract and correct the weight and value, and also to subtract one from the pack number.
Furthermore, a set value print key 68 is used to print the value set for each product code on journals and receipts, and a set value print key 68 is used to print all the contents of the classification total memory corresponding to each product code on journals and receipts. A classification inspection key 69, which is used to print all the contents of the classification total memory corresponding to each product code on the journal and receipt, and a classification settlement key 70, which is used to clear all the contents of the classification total memory. A store check key 71 is used to check the contents of the store's classified total memory, and a product classification key 72 is used to check the classification and pay for products whose fourth digits are the same. Variable key 7 used for sorting inspection and sorting settlement for the product code corresponding to the memory whose contents of the category total memory are other than zero.
3. Classification clear key 74 used to clear the contents of the classification total memory, points A to K used to set and call store codes for stores A to K (however, I is omitted) Each point key 75a-7
5j is provided. The setting key 52, the print every time key 53, the A store key 75a to the K store key 75j
is a self-illuminated key.

Although not shown in the figure, this operation section 2 also includes a weight preset switch for specifying whether the number of pack labels to be issued is to be preset by quantity or by weight, and a weight preset switch for specifying whether to preset the number of pack labels to be issued by number or weight, and a preset button for presetting item data in the preset memory area for each store or for all stores. A unit-price store-specific switch is provided in the form of a depth switch that specifies whether or not all items are to be performed all at once.

FIG. 2 shows a product name stamp that can be inserted into and removed from the label issuing mechanism. The product code recording section 81 records an insertion detection mark 82, which is used to detect the correct insertion of the product name mark into the label issuing mechanism, and is represented by a bright part 82a and a dark part 82b, and also corresponds to the product name. The set product code 83 is set to ``1'' and ``0'' to the hole part 83a and non-hole part 83.
It is expressed and recorded as b.

Figure 3 is a block diagram showing the overall circuit configuration.
84 is an arithmetic circuit, an instruction decoder,
CPU (central processing unit) with built-in memory control circuit, etc., 85 is an electronic scale as a weighing device, 86
87 is a ROM (read-only memory) in which a program is set so that the CPU 84 can control each part in a predetermined order for each input, and fixed data used in other processing is set. RAM (Random Access Memory) is a RAM (Random Access Memory) in which various types of memories are formed to store variable data such as information and data. Said CPU
84 and the scale 85, ROM 86, and RAM 87 are electrically connected by an address bus 88 and a data bus 89. Further, 90 is a clock circuit that counts the time, 91 is a product name stamp reader that reads the insertion detection mark 82 and product code 83 from the product name stamp, 92 is a product name stamp reader that reads the insertion detection mark 82 and product code 83 from the product name stamp, 92 is an input input from various switches 93, various keys 94, a display device 95, and various lamps. 96
97 is a printer controller that outputs data to the printer 98 and various signals for stamp operation, feed operation, and buzzer activation. The CPU 84, the product name mark reader 91, the keyboard/display controller 92, and the printer controller 93 are electrically coupled via an address bus 88 and a data bus 89. In addition to the switches 30 to 44, the various switches 93 include a depth switch including a weight preset switch and a unit price store switch.
5 to 74, the indicators 95 are the indicators 6 to 12 of the upper display 3 and the lower display 4, and the various lamps 96 are the lamps 13 to 29 of the lamp indicator 5. It shows. The printer 98 constitutes the main part of label issuing means for printing data on labels, journals, and receipts.

The RAM 87 has a configuration of 8 bits per word, and this RAM includes various flag memories, various registers,
Various classification total memories, subtotal memories, total memories, total total memories, etc. are formed, and in particular, various flag memories and various registers are formed as shown in FIG. In other words, the main flag memory is the 1-word metric F, IKAWF,
IKWPF, IKPF, number F, weight preset,
DISPF, DISP data 1F, DISP data 2F, Preset F, Preset count up F, Preset 1F, Preset 2F, Preset 3F, Preset 4F, Preset 5F, Preset 6F, Preset 7F, Preset 8F, Preset 9F, Preset 10F, Product name Inserting mark F, unit price by store F, product name stamp error F, setting F, F3F, F4F, F5F, F6F,
There are F7F, A store F, B store F, C store F, D store F, E store F, F store F, G store F, H store F, J store F, and K store F. The main registers are a 4-word wait count register and a wait count register.
Count register 3, 2-word X register, product code register, tare register, 1-word department code register, 3-word processing date register, 2-word pack number register, 4-word walk register , a 12-word setting register, a 14-word upper display register, a lower display register, an 8-word S register, a 16-word preset read register, and the like. The setting registers include a product code setting register, a unit price setting register, a weight setting register, a tare setting register, and a 3-word setting register.
It consists of a word-structured price setting register and a one-word structure of a department code setting register.
The upper display register consists of a weight display register consisting of 4 words, a unit price display register, a price display register consisting of 5 words, etc., and the lower display register consists of a tare display register consisting of 2 words, and a pack number display register consisting of 4 words. It consists of registers, department code/date display registers, product code display registers, etc. The S register consists of a 2-word WS register, an S register, and a 3-word register.
It consists of a word-structured PS register, etc.
The preset read register is the 4th digit preset read register of the product code consisting of a half word, and 1 bit for each half word reads IKP2F, IKWP2F,
It consists of a flag preset read register for storing the contents of IKAW2F and weighing 2F, a 2.5 word preset read register, a 1.5 word tare preset read register, a 1 word department code preset read register, and the like.
In addition, the issued quantity preset memory includes 2 words of preset 1 register, preset 2 register, preset 3 register, and preset 3 register.
4 registers, preset 5 registers, preset 6 registers, preset 7 registers, preset 8 registers, preset 9 registers,
10 preset registers are provided. Furthermore, each store A, B to K stores has a preset memory area designated by the lower 3 digits of the product code (001, 002,...), and each memory area contains the 4 digits of the product code consisting of a half word. Preset memory, IKP2F, IKWP2F, 1 bit for each half word
It consists of a flag preset register for presetting the contents of IKAW2F and weighing 2F, a 2.5 word preset memory, a 1.5 word tare preset memory, a 1 word department code preset memory, etc.

In FIG. 5, the CPU 84 is a product name mark reader 91,
This is a main flowchart showing the process of controlling each part according to inputs from various switches 93 and various keys 94, and the main controls will be explained below based on this flowchart.

When the start is started by turning on the power, the display 95 is checked, various lamps are checked, RAM is cleared, and then the depth switch is read. When reading the depth switch, when the weight preset switch is ON, the weight preset F is set to "1", and when it is OFF, it is set to "0". Also, when the unit price store switch is ON, the unit price store F is set to "1", and when it is OFF, it is set to "0". Next, read the main business switch in ○A. This main business switch is read by the business changeover switch 30 and the fixed changeover switch 3.
Let's do this for 1. In other words, business switching switch 3
When 0 is set for automatic issuance or manual issuance, ``1'' is set in metric F. Also, when the business switching switch 30 is set to fixed printing, the fixed switching switch 31 sets IKAWF to "1" if the unit price and weight are fixed, and sets IKWPF to "1" if the weight and price are fixed. If the price is fixed, set IKPF to “1”. When the reading of this main business switch is completed, key processing of ○ and ○ is then performed. After this key processing is completed, the product code is read from the product name stamp marked with ◯.
In this reading process, the product code 83 recorded on the product name stamp is first read by the product name stamp reader 91, and then the bits between the bright part 82a and the dark part 82b of the insertion detection mark 82 are detected. , check whether each bit is bright or dark. If both bits are bright and dark, it is determined that the product name stamp has been inserted correctly.
During product name stamp insertion, set F to "0", turn off the buzzer, and store the read product code in the X register. In addition, the insertion detection mark 82
If each bit is not bright and dark, then it is checked whether both bits are bright. If both bits are clear, it is determined that the product name mark has not been inserted at all, and in this case, F is set to "0" while the product name mark is being inserted, the buzzer is turned OFF, and the X register is set. Clear to zero. Also, if both bits are not bright, that is, both bits are dark, it is determined that the product name mark is being inserted, and F is set to "1" while the product name mark is being inserted, and the buzzer is turned on. energize and clear the X register to zero. This indicates that a buzzer sounds when the product name stamp is inserted into a predetermined position, and when the product name stamp is inserted correctly, the buzzer stops and the product code of the product name stamp is stored in the X register. After storing the product code in the X register or clearing the X register to zero, it is then checked whether the contents of the product code register and the contents of the X register are equal. If the contents of both registers are equal, DISPF
is set to "1", and the contents of the X register, that is, the product code read from the product name stamp, is stored in the product code register. This reading process for ○C finally checks whether or not auxiliary work is being performed, and if it is during auxiliary work, it moves to the process that includes the odor zero processing of ○, and if it is not auxiliary work, it moves to the clearing process for ○2. . Here, the auxiliary work refers to work other than label issuance, including the wind setting key 48, setting key 52, setting value call key 54, processing date key 55, pack number keys 1 to 10 keys 56a to 56j, and total number of issues key 57. , time key 58, store code key 59, effective date key 60,
Subtotal inspection key 61, total inspection key 62, subtotal settlement key 63, total settlement key 64, correction (+) key 6
5. Correction (-) key 66, setting value print key 68,
It refers to the work performed by operating the classification/inspection key 69, the classification/settlement key 70, the store inspection key 71, the product classification key 72, and the variable key 73. In the second clearing process, check whether DISPF=1 or not. If DISPF=1, the fourth digit of the WS, S, and PS S registers, the tare register, the department code register, and the product code register are cleared to zero. Next, it is checked whether the product code register is "0" or not. If the product code register is “0”, then weigh F
= 1 or not. Then, if the measurement F=1, only the S register is cleared to zero,
If the metric F is not 1, then it is checked whether IKAWF is 1, and if IKAWF is 1, the WS register and S register are cleared to zero. Also, if IKAWF is not 1, then it is checked whether IKWPF is 1 or not. If IKWPF=1, the WS register and PS register are cleared to zero, and if IKWPF=1, only the PS register is cleared to zero. In this ○2 clearing process, the fourth digits of the tare register, department code register, and product code register are finally cleared to zero. When the clearing process for ○2 is completed, the product name stamp error F in the readout process for ○e is cleared to zero and the buzzer is turned off, and the process moves to the calculation and display process for ○. Further, if DISPF=1 is not found in the clearing process for ○2, the process immediately shifts to the calculation and display process for ○. Further, if the product code register is not "0" in the clearing process for ◯◯, the process moves to the read process for ○◯. In the read process of ○H above, the address where the preset data to be recalled is stored is searched from the preset memory area according to the product code in the product code register and the set contents of each store F, and the preset data is read from the preset memory at that address. Read the set data and store it in the preset read register. Next, it is checked whether the metric F=1 or not, and if the metric F=1, it is then checked whether the metric 2F of the preset read register is set to "1". If the metric 2F is set to "1", the contents of the preset read register are stored in the S register. Also, the contents of the tare preset read register are stored in the tare register. Subsequently, the contents of the fourth digit preset read register of the product code are stored in the fourth digit of the product code register, and the contents of the department code preset read register are stored in the department code register. Then, the product name stamp error F is cleared to zero, the buzzer is turned off, and the process moves to ○ calculation and display processing. In addition, if "1" is not set in the weighing 2F in the above-mentioned check of the weighing 2F, the product name stamp error F is set to "1", the buzzer is turned on, and the process moves to the calculation and display process for ○.

Also, in the above measurement F check, measurement F=1
If not, then check whether IKAWF=1. If IKAWF=1, then it is checked whether IKAW2F of the preset read register is set to "1". If IKAW2F is set to "1", the contents of the preset read register are stored in the S register, the tare register is cleared to zero, and the contents of the preset read register are stored in the fourth digit of the product code register. At the same time, the contents of the department code preset read register are stored in the department code register. Then, the product name stamp error F is cleared to zero, the buzzer is turned off, and the process moves to ○ calculation and display processing. Also, if IKAW2F is not set to "1" in the above IKAW2F check, the product name stamp error F is set to "1", the buzzer is turned on, and the process moves to ○ for calculation and display processing. Also, in the above IKAWF check, if IKAWF = 1, then IKWPF = 1.
Check whether or not. If IKWPF = 1, then IKWP2F of the preset successive register
Checks whether “1” is set on or not. If IKWP2F is set to "1", the contents of the preset read register are stored in the WS register. Thereafter, the process is the same as that after the contents of the preset read register have been stored in the S register when IKAW2F was set to "1". If "1" is not set in IKWP2F, "1" is set in the product name stamp error F, the buzzer is turned on, and the process moves to the calculation and display process for ○.

Also, in the above IKWPF check, IKWPF
If not =1, then it is checked whether IKP2F of the preset read register is set to "1". If IKP2F is set to "1", the contents of the preset read register are stored in the PS register. Thereafter, the process is the same as that after the contents of the preset read register have been stored in the S register when IKAW2F was set to "1". If IKP2F is not set to "1", the product name stamp error F is set to "1", the buzzer is turned on, and the process moves to the calculation and display process for ○. From the above, in the reading process of ○e, a specific preset memory is specified by the product code read from the inserted product name stamp and the store specified by the selection operation of the store keys 75a to 75j. The contents of the fourth digit preset memory, flag preset memory, preset memory, tare preset memory, and department code preset memory of the product code in the preset memory are read out to the corresponding registers of the preset read register. Then, it is checked whether each flag in the preset read register matches the contents set in the business changeover switch 30 and the fixed changeover switch 31, which are the main business switches. That is, it is checked whether the input format information read into the preset read register matches the input format set by the main operation switch. If the two match, it is determined that the correct product name stamp has been inserted and the store designation has been made, and a predetermined reading process is performed.If they do not match, it is determined that there is an error in the product name stamp insertion or store designation. Then, the product name stamp error F is set to "1" and a buzzer sounds to notify the user. In this erroneous operation, the contents of the preset read register are not stored in the S register, tare weight, product code, and department code registers, and a product name stamp error F = 1 occurs, which is explained later in the label issuing process. The issuance of labels will be prohibited. For example, to give an example of an erroneous operation, when the business switching switch 30 is set to automatic issue and the weighing F=1, the preset memory specified by the store key and the product code of the product name stamp is read out. The contents of the flag preset memory are 2F =
0, IKAW2F=1, IKWP2F=0, IKP2F=0
If the input form information is fixed printing of unit price and weight, the two do not match, so measurement F = 1 or "Yes", measurement 2F = 1 is "NO", and product name stamp error F is set to "1". The buzzer will be turned ON.

In the calculation and display processing for ○ above, first
Check whether DISPF=1 or not, if it is “1”
After clearing DISPF to zero, continue weighing F=
Check whether it is 1 or not. If the metric F=1, then it is checked whether IKAWF=1 or not. And when the metric F=1 or the metric F≠1
and IKAWF = 1, multiply the contents of the S register by the contents of the WS register, and use the result as PS.
Store in register. Also, if the measurement F≠1, IKAWF
When ≠1, the above multiplication process is not performed. Subsequently, the contents of each S register are stored in the upper display registers, that is, the weight, unit price, and price display registers. Next, the contents of the tare, pack number, processing date, and product code registers are stored in the lower display registers, that is, the tare, pack number, department code/date, and product code display registers. Next, turn on both the upper display and the lower display, and turn on the pack number lamp 21, processing date lamp 24, and product code lamp 28, respectively.
Turn ON control to end the process at this point, and move on to the process including auto-zero processing at point ○. Also above
If DISPF is not equal to 1 in the DISPF check, the process bypasses this process and moves to the process of ○.

In the process including the auto-zero process mentioned above,
Move the contents of DISP data 1F to DISP data 2F,
and moves the contents of the wait count register to wait count register 3. continue
Check whether DISP data 2F=1. If DISP data 2F = 1, both DISP data 1F and DISP data 2F are cleared to zero, then auto-zero processing is performed to automatically set the zero point in a predetermined count width, and finally, whether or not assistance work is being performed is performed. Check. Also DISP data 2F≠
If it is 1, then it is checked whether the metric F=1. Then, if the measurement F=1, and if the auxiliary work is being performed in the above-mentioned auxiliary work in progress check, the process returns to the main work SW reading input point in ◯B. Also, if the auxiliary work is not in progress, the process shifts to calculation and display processing for ○. In addition, when checking the measurement F above, the measurement F
If ≠1, the process moves to the auxiliary work check for calculation and display processing of ○.

In the above-mentioned calculation and display process, it is first checked whether the metric F=1. And the metric F=
If it is 1, the weight is calculated from weight count register 3 by rounding, etc., and stored in the WS register, and then the contents of the S register and the WS are calculated.
Multiply the contents of the register and store the result in the PS register. Furthermore, the contents of each S register are stored in each register of the upper display register, and finally, a check is performed during auxiliary work. In the above-mentioned measurement F check, if measurement F≠1, the final auxiliary work check is immediately performed. Then, in this auxiliary work in progress check, if the auxiliary work is in progress, the process returns to the above, and if the auxiliary work is not in progress, it moves to the label issuing process of ○.

The above ○ label issuance process is during product name stamp insertion F=
0, product name stamp error Check whether F=0 and determine whether label can be issued.
When it is determined that it is possible to issue a label, printing operations such as driving the printer 98 and stamping operation are performed, followed by a feed operation to issue a label, and the process moves to the number of packs of circles. Further, when it is determined that label issuance is impossible due to product name stamp insertion F≠0 or product name stamp error F≠0, the process returns to the above.

To process the number of packs for ○nu, first select the weight preset F.
= 1 or not. If the weight preset F = 1, the contents of the pack number register are changed to WS
Add the contents of registers. Also, if the weight preset F=1, "1" is added to the contents of the pack number register. This means that when the weight preset switch is ON and weight preset F=1, the number of packs is added to the pack number register as a weight value, and when the weight preset switch is OFF and weight preset F≠1, the number of packs is added to the pack number register. Indicates that the number of packs is added to the register. Next, a check is made to see if preset F=1. If the preset F=1, then it is checked whether the weight preset F=1. Then, if the weight preset F=1, the contents of the preset 1 register (weight value) and the contents of the pack number register (weight value) are compared, and if the contents of the pack number register are larger than the contents of the preset 1 register, then Set preset count up F and preset 1F to "1". You can also preset
If the contents of the 1 register are smaller than the contents of the pack number register, the contents of the pack number register are stored in the pack number display register. Above weight preset F
If the weight preset F is not 1 in the check, it is checked whether the contents (number of packs) of the preset 1 register and the contents (number of packs) of the pack number register are equal. If the contents of both registers are equal, preset count up F and preset 1F are each set to "1". If the contents of both registers are not equal, the contents of the pack number register are stored in the pack number display register. The preset count up F and preset
When the process of setting "1" to 1F is completed, the number F is cleared to zero, "F" to prohibit display is written to the lower display register, and "0" is written only to the pack number display register again. It's crowded.
Then, turn off the pack number lamp, processing date lamp, and product code lamp, turn on the set number 1 lamp, and finally turn on the lower display and return to the above process. Also, when the contents of the pack register have been stored in the pack number display register, the lower display will be displayed.
Turn on and return to above.

The above-mentioned ◯◯ key processing is performed based on the flowchart shown in FIG. In other words, when the pack number 1 key 56a is operated, the preset is
Set “1” to 1F and clear the numeral F to zero.
Next, the contents of the preset 1 register are stored in the wake register, and the pack number lamp 21, processing date lamp 24, and product code lamp 28 are turned off, and the set number 1 lamp 22a is turned on. Then, write the suppress data "F" to each display register, store the contents of the wake register in the pack number display register, turn on the lower display, and then
It appears in the figure. This key processing is pack number 2 keys 5
The same process is performed for the pack number 10 keys 6b to 56j. However, "1" set for Preset 2F ~ Preset 10F, Preset 2 register ~
Storing the contents of the preset/10 registers in the wake register, and controlling the ON of the 2-set lamp 22b to 10-set lamp 22j are performed by operating one or more of Preset 1F to Preset 10F when the pack number key is operated. It is checked whether "1" is set to "1" or not, and if "1" is set, the content of the number set on the numeric key 45 is taken into the wake register. Then, set the digit F to "1", then write the suppression data "F" to each display register, store the contents of the wake register in the pack number display register, and turn on the lower display to display the fifth It appears in the figure. Also, when the erase key 46 is operated, a check is made to see if one or more of presets 1F to 10F is set to "1".
If "1" is set, the wake register is cleared to zero and the numeral F is set to "1". Then, suppress data "F" is written in each display register, and the contents of the wake register, ie, "0", are stored in the pack number display register, and the lower display is turned on, as shown in FIG. Also *key 50
When the above operation is performed, flags set to "1" are checked in the order of preset 1F to preset 10F. Processing is then performed based on the flag that is initially set to "1". First, if "1" is set in preset 1F, it is checked whether preset count up F=1. If it is "1", then it is checked whether the set number F=1. If the numeral F≠1, the contents of the preset 2 register are shifted to the preset 1 register, the contents of the preset 3 register are shifted to the preset 2 register, and the contents of the preset 10 register are shifted to the preset 1 register. Shift to 9 register. In other words, preset, register 2 to preset, preset the contents of register 10, register 1 to preset, and set 1 to register 9.
Shift by step. Then, clear the preset 10 register to zero, and clear the pack number register to zero. Further, if the preset count up F is "1" or "0" and the set number F=1, the contents of the walk register are stored in the preset 1 register and the pack number register is cleared to zero.
When the pack number register has been cleared to zero, it is next checked to see if the preset/1 register has been cleared to zero. If it has been cleared to zero, preset F is cleared to zero, and if it has not been cleared to zero, preset F is set to "1". .
After that, clear the preset count up F to zero, and clear the preset 1F to zero. Furthermore, turn off the set number 1 lamp, set DISPF to "1", and exit as shown in Figure 5. In addition, in the above, the preset count up F≠1 and the set number F≠1
In this case, the preset 1F is immediately cleared to zero, the set number 1 lamp is turned off, and DISPF is set to "1", resulting in the output shown in Figure 5.

Further, when preset 1F≠1 and preset 2F=1, the contents of the wake register are stored in the preset 2 register if the number F=1. Further, if the set number F≠1, the above processing is bypassed.
Next, preset 2F is cleared to zero, set number 2 lamps are turned off, and DISPF is set to “1”.
It appears in Figure 5, where is set. Similarly, when presets 1F and 2F≠1 and preset 3F=1, when presets 1F to 3F≠1 and preset 4F=1...presets 1F to 9F≠1 and preset 10F=1.
Similar processing is performed in each case. However, when Preset 3F to Preset 10F are "1" and the number F = 1, the contents of the wake register will be set to Preset, 3 register to Preset, and 10 register corresponding to Preset 3F to Preset 10F, respectively. Stored. Also, zero clear of presets 3F to 10F and number of settings 3
The OFF control for lamps to 10 lamps is also performed corresponding to presets 3F to 10F, respectively.

The weight data is taken in from the scale 85 by means of an interrupt, no matter what point in the flowchart of FIG. 5 the process is being carried out. As shown in Figure 7, when an interrupt occurs, the interrupt processing
2, the weight data is taken in as a count number and the count number is stored in the weight count register. Then, the DISP data F is set to "1" and the process returns to the flowchart of FIG.

Further, the buzzer OFF control in the flowchart of FIG. 5 is performed based on the flowchart of FIG. In other words, the buzzer is turned off only when the product name stamp is being inserted F≠1 and the product name stamp error F≠1.

With this configuration, for example, when the weight preset switch is OFF and the weight preset F=0, the pack number 1 key 56a can be operated to preset.
By setting "1" in 1F, entering the number using the numeric keys 45, and operating the * key 50, the number data can be stored in the preset 1 register. In the same way, by sequentially operating the pack number 2 key 56b to the pack number 10 key 56j in combination with the numeric key 45 and * key 50, various number data can be stored for the preset 2 register to the preset 10 register. can do.

In this state, for example, the business switching switch 30 is set to automatic issuance, the corresponding store key is operated, and the corresponding product name stamp is inserted. As a result, various item data preset in the corresponding item data preset memory are recalled and displayed on the display 95. In this state, when the pack containing the product corresponding to the product name stamp is weighed on the scale 85,
Weight data is taken in from the scale 85 and displayed on the display 95, and a price is calculated from the weight data and the unit price preset as item data and displayed on the display 95. When all the data to be printed on the label is prepared in this way, the printer 98 is activated and the printing of the label is started. Each time this label is issued, the contents of the pack number register are counted up by one, and the contents of the pack number register are compared with the contents of the preset 1 register. When the contents of both registers match, "1" is set to preset count up F and preset 1F, and digit F is cleared to zero. Also, the pack number display register is cleared to zero and the pack number display 10 displays zero. In this way, labels corresponding to the number of packs preset in the preset 1 register are issued for the packs currently being weighed by the scale 85.

Next, if you want to change the product, you can change the product name stamp and also change the product to be weighed on the scale 85 in accordance with the new product name stamp. If you want to change the store, you can operate the corresponding store key. After performing these changing operations, the * key 50 is operated.
However, preset 2 register ~ preset
The contents of the 10 registers are shifted to the preset 1 register to the preset 9 register, respectively, and a number of labels are issued again based on the contents of the preset 1 register. When this label issuance is completed, the user only needs to perform the change operation again and then operate the * key 50. In this way, it is possible to issue up to 10 types of labels.

Therefore, it is possible to issue 10 types of labels with different numbers of labels for each store, or to issue 1 type of label with different numbers of labels for each of the 10 stores, by simply operating the key 50 after the change operation. This can be done by simple key operations. Furthermore, even when issuing up to 10 labels with different numbers of labels, each number of labels is preset at the same time by a preset operation, and there is no preset operation between label issues, which makes key operations complicated. It is possible to prevent erroneous operations as much as possible.

In the above description, the number of labels to be issued is determined by presetting the number of labels, but in this embodiment, the number of labels to be issued can also be determined by presetting the total weight to be measured. This can be done by setting the weight preset switch to ON and setting the weight preset F=1. That is, by setting in this way, the quantity data stored in the preset 1 register to the preset 10 register will be treated as weight data. Therefore, in this case, when issuing a label, the weight data of the WS register is added to the pack number register each time a label is issued, and the contents of the pack number register are compared with the contents of the preset/1 register. When the contents of the pack number register become larger than the contents of the preset 1 register, label issuance is stopped. In this way, the number of labels issued is determined by the preset weight. Of course, in this case, as in the case of setting the number of keys, key operations can be simplified and erroneous operations can be prevented as much as possible.

As detailed above, according to the present invention, the number of labels to be issued each time is preset for multiple label issuances, and when issuing labels, each time the previous label issue is completed, the next label is to be issued. Since it is possible to read out the preset issue quantity and issue labels based on the read issue quantity, the label issuing operation can be easily performed and operability can be improved, and erroneous operations can be prevented as much as possible. equipment can be provided.

[Brief explanation of drawings]

The figures show an embodiment of the present invention, in which Fig. 1 shows the display section and operation section, Fig. 2 shows the product name mark, Fig. 3 is a block diagram, and Fig. 4 shows the main parts of the RAM. Figure 5 is a flowchart showing the basic processing process, Figure 6 is a flowchart showing the key processing process, Figure 7 is a flowchart showing the scale interrupt processing, and Figure 8 is a flowchart showing the buzzer OFF processing. be. 45...Number keys, 5...* keys, 56a-56j
...Pack number key, 84...CPU (central processing unit), 85...Weigher, 86...ROM (read-only memory),
87...RAM (random access memory), 9
8...Printer.

Claims (1)

[Scope of Claims] 1. A weighing device that outputs weight data in response to a weighing operation and a preset memory for item data attached to a product are provided, and the weight data from the weighing device and the items from the item data preset memory are provided. A weighing label issuing device that can issue labels by printing data on labels has a numeric key, multiple quantity preset keys for inputting the numbers entered with the numeric keys as issue quantity data, and each quantity preset key. a plurality of issuance quantity preset memories for presetting the issuance quantity data inputted to each of the issuance quantity preset memories, and a means for reading out the issuance quantity data of the next label to be issued from one of the issuance quantity preset memories. A weighing label issuing device featuring: 2. The weighing label issuing device according to claim 1, wherein the issue quantity data is issue number data. 3. The weighing label issuing device according to claim 1, wherein the issued quantity data is issued weight data.