JP6624724B2 - Weight scale - Google Patents

Description

  The present invention relates to a weigh scale.

  2. Description of the Related Art Conventionally, as a weighing scale such as a weighing scale or a weighing scale with a body composition meter, a so-called step-on type weighing scale capable of measuring weight without operating a power switch for improving convenience is known. As an example of a step-on weighing scale, in addition to a load sensor that measures weight, it has a mechanical switch mechanism that detects that a person is sitting under the measuring table, and detects that the switch is turned on It does not have a weighing scale that starts measuring weight with the load sensor or a mechanical switch mechanism, and detects that a person is on the measuring table based on signals taken out from the load sensor at predetermined time intervals. In addition, there is a weighing scale that starts measuring the weight (for example, disclosed in Patent Document 1).

JP 2009-156754 A

When a mechanical switch is attached to the foot of the weighing scale, the stroke when the switch is turned on causes the weighing scale to slightly tilt. Therefore, when the weighing scale detects the step-on by a mechanical switch mechanism, there is a problem that the weighing scale cannot perform highly accurate measurement.
In addition, a load sensor constituted by a strain gauge needs to apply a voltage equal to or higher than a certain value in order to obtain an output level sufficient to obtain the accuracy required for accurate weight measurement. The load sensor constituted by the strain gauge is a component having the highest power consumption in constituting the weighing scale. For this reason, when the weighing scale applies a voltage equal to or more than a certain value to the load sensor at certain intervals and detects step-on based on a signal from the load sensor, it is difficult to significantly reduce power consumption.
An object of the present invention is to reduce the power consumption of a weighing scale while maintaining the load measurement accuracy.

According to the first aspect of the present invention, the weighing scale is connected to a power supply to form a bridge circuit, and a detection unit that outputs load data indicating a load applied to the measuring table; a weighing scale Ru and a current control unit for switching and controlling a connection state, the current-control unit, the current flowing from the power source to the bridge circuit, less than the current value sufficient to obtain the desired accuracy of the weighing scale Determining whether or not it is time to start updating the zero point at regular intervals in a standby state in which the connection state between the power supply and the bridge circuit is controlled to switch to the first current value. At the time when the zero point update process is started, the current flowing from the power supply to the bridge circuit becomes a second current value that is equal to or greater than a current value sufficient to obtain the desired accuracy of the weighing scale. Controlling the connection between the power supply and the bridge circuit to obtain the load data when nothing is mounted on the measurement table, and updating the data as zero point data based on the load data. Controlling the connection state between the power supply and the bridge circuit so that a current flowing from the power supply to the bridge circuit becomes the first current value at a timing when the zero point update process is started, Acquiring the load data when nothing is on the table, updating the load detection reference data based on the load data, and in the standby state, the load data and the load detection reference data. Comparing with a threshold value based on the load to determine whether a load is detected; and, when the load is detected, flowing from the power supply to the bridge circuit. The load state is obtained by switching control of the connection state between the power supply and the bridge circuit so that the current becomes the second current value, and the load is determined based on the difference between the load data and the zero point data. Perform the required steps .

According to a second aspect of the present invention, in the weighing scale according to the first aspect, the A / D conversion for generating load data by converting an output signal of the detection unit into a digital signal with a predetermined quantization width. The bridge circuit outputs an output signal of a voltage corresponding to a load applied to the measuring table .

According to a third aspect of the present invention, in the weighing machine according to the first or second aspect, in the step of determining whether or not the load is detected, the current control unit determines whether or not the load data is the load data. If the value is equal to or greater than the value obtained by adding the load count to the reference data, it is determined that the load is detected .

According to a fourth aspect of the present invention, in the weighing machine according to any one of the first to third aspects, the current control unit may be configured to connect to the bridge circuit when the detection unit detects a change in load. power supply for supplying a current, the bridge first from the power supply is a power source connected to the circuit, a power supply for supplying electric power greater than said first power supply, the bridge circuit current flowing through said second The power source is switched to a second power source which is a power source having a current value .

According to a fifth aspect of the present invention, in the weighing device according to any one of the first to third aspects, the current control unit may be configured to connect to the bridge circuit when the detection unit detects a change in load. The resistance between the power supply supplying the current and the bridge circuit is reduced so that the current flowing through the bridge circuit has the second current value .

According to a sixth aspect of the present invention, in the weighing scale according to the fifth aspect, the current control unit is configured to connect the power supply and the bridge circuit when the detection unit detects a change in load. the path connecting switches the path not having resistance from the path having the resistance.

According to a seventh aspect of the present invention, in the weighing machine according to any one of the first to third aspects, the current control unit may be configured to connect the bridge circuit to the bridge circuit when the detection unit detects a change in load. A constant current power supply that supplies a current, from a first constant current power supply that is a constant current power supply connected to the bridge circuit , a constant current power supply that supplies a current larger than the first constant current power supply, The current flowing through the bridge circuit is switched to a second constant current power supply having the second current value .

  According to at least one of the above aspects, the weighing scale can switch a current value flowing through the load sensor that detects a change in the load. For this reason, the weighing scale can reduce the current flowing through the load sensor when no load is applied while maintaining the load measurement accuracy, and thus can significantly reduce power consumption.

It is a block diagram of a 1st embodiment. 6 is a flowchart illustrating an operation of the weighing scale according to at least one embodiment. It is a block diagram of a 2nd embodiment. It is a block diagram of a 3rd embodiment.

<< 1st Embodiment >>
Hereinafter, the first embodiment will be described in detail with reference to the drawings.
FIG. 1 is a block diagram illustrating a hardware configuration of the weighing scale according to the first embodiment.
The weighing scale 1 includes a load detection unit 10, an operational amplifier 20 for amplifying a signal, an A / D converter 30 for converting an amplified analog signal into a digital signal, a CPU 40, a power supply VDDA and a power supply VDDB of a constant voltage power supply. And a switch 50 for switching the power supply of the detection unit 10. The current control unit includes the switch 50 and the CPU 40 that controls the switch 50. An example of a desired accuracy of the weighing scale 1 is an accuracy finer than a value obtained by dividing the minimum display in the weighing scale 1 by the maximum weighing. Specifically, when the minimum display of the weighing scale 1 is 100 g and the maximum weighing is 100 kg, an accuracy of at least 1/1000 is required. In this case, as the desired accuracy of the weighing scale 1, an accuracy smaller than 1/1000, for example, an accuracy of 1/10000 can be adopted in order to maintain stable accuracy. Note that the accuracy desired in other embodiments may be equal to the accuracy obtained by dividing the minimum display by the maximum weighing.

  The detection unit 10 is a load sensor including a strain body that is a metal member and a plurality of strain gauges g1 to g4 attached to the strain body. The strain gauge g1, the strain gauge g2, the strain gauge g3, and the strain gauge g4 constitute a bridge circuit 11. The bridge circuit 11 includes an input terminal in1, an input terminal in2, an output terminal out1, and an output terminal out2. The input terminal in1 is a terminal provided between the strain gages g1 and g4. The input terminal in2 is a terminal provided between the strain gages g2 and g3. The output terminal out1 is a terminal provided between the strain gauge g1 and the strain gauge g2. The output terminal out2 is a terminal provided between the strain gauge g3 and the strain gauge g4. The input terminal in1 is connected to the switch 50. The input terminal in2 is connected to a ground which is a reference potential on the circuit. The output terminal out1 is connected to a non-inverting input terminal of the operational amplifier 20. The output terminal out2 is connected to the inverting input terminal of the operational amplifier 20.

  The strain gauge g1 and the strain gauge g3 are stuck so as to be compressed when the strain element is deformed by applying a load. Therefore, when a load is applied to the weighing scale 1, the resistance values of the strain gauges g1 and g3 decrease. The strain gauge g2 and the strain gauge g4 are attached so that when a load is applied, the strain body expands when deformed. Therefore, as the load applied to the weighing scale 1 increases, the resistance values of the strain gauges g2 and g4 increase. When a constant voltage is applied to the input terminal in1 of the bridge circuit 11, there is a positive correlation between the voltage of the output terminal out1 between the strain gages g1 and g2 and the load. Further, there is a negative correlation between the voltage and the load of the output terminal out2 between the strain gauge g3 and the strain gauge g4.

  The output terminal out1 is input to the non-inverting input terminal of the operational amplifier 20, and the output terminal out2 is input to the inverting input terminal of the operational amplifier 20. The operational amplifier 20 is a differential amplifier, amplifies a minute output of the bridge circuit 11, and outputs the amplified output to the A / D converter 30. The A / D converter 30 is a converter that converts a signal output from the operational amplifier 20 from analog to digital. When the maximum weight of the weighing scale 1 is 100 kg and the minimum display is 100 g, a resolution of 1/10000 (10 g / 100 kg) which is finer than 1/1000 is required as a desired accuracy. This is because in order to maintain the stable accuracy of the minimum display of 100 g, the operation is performed at a resolution finer than that of the minimum display, and variations and fluctuation factors are monitored in detail. Therefore, as the A / D converter 30, for example, a high-precision A / D converter such as an integral double integration system, a pulse feedback integration system, or a ΔΣ system is used.

  The CPU 40 is an arithmetic device such as a microcomputer that controls each unit of the weighing scale 1 by executing a program. The storage unit 70 is provided inside or outside the CPU 40, and is a unit that stores a program executed by the CPU 40 and various data. Further, the CPU 40 includes an output unit 80 that outputs a measured value of the load of the target object. The output unit is connected to a display device such as a liquid crystal device, an utterance device, or an output device such as a printer. The CPU 40 receives the digital signal converted by the A / D converter 30 and performs processing such as scale scale conversion.

  The switch 50 is connected to the input terminal in1 and switches a power supply connected to the detection unit 10 between the power supply VDDA and the power supply VDDB. The power supply VDDB is a voltage lower than the power supply VDDA. The switch 50 is switched by the CPU 40.

  The power supply VDDA supplies power to the CPU 40, peripheral circuits, and the detection unit 10, and supplies a current of a current value or more sufficient to obtain a desired accuracy of the weighing scale 1, for example, a resolution of 1/10000, to the detection unit 10. . The current value supplied to the detection unit 10 is proportional to the output voltage output by the detection unit 10 to which a load is applied. That is, the output voltage output from the detection unit 10 satisfies the input voltage for obtaining the predetermined resolution of the A / D converter 30 by the power supply VDDA, and satisfies the desired accuracy of the weighing scale 1. The power supply VDDB outputs a voltage that is lower than the power supply VDDA and that outputs a voltage larger than the quantization width of the A / D converter 30 from the detection unit 10 when a person gets on the weighing scale 1. I do. Preferably, the power supply VDDB is configured to output the voltage corresponding to the quantization width of the A / D converter 30 from the detection unit 10 when the lightest weight (for example, 30 kg) assumed on the weighing scale 1 is applied. Output voltage. In other words, the output voltage output from the detection unit 10 by the power supply VDDB is lower than the input voltage for obtaining the resolution of the A / D converter 30, the resolution of the A / D converter 30 is insufficient, and The desired accuracy of the total 1 cannot be satisfied. On the other hand, the output voltage output from the detection unit 10 when a person gets on the weighing scale 1 by the power supply VDDB is larger than the quantization width of the A / D converter 30. It can be determined whether or not a person has got on the vehicle. Here, an example in which the output voltage of the power supply VDDA is set to 3 V and the output voltage of the power supply VDDB is set to 0.15 V will be described. When the resistance of the strain gauge of the bridge circuit 11 is 350Ω, when the power supply VDDA is supplied to the detection unit 10, the current flowing to the detection unit 10 becomes approximately 8.6 mA (1 / 10,000 accuracy). On the other hand, when the power supply VDDB is supplied to the detection unit 10, the current flowing to the detection unit 10 is about 0.43 mA (1/500 accuracy). As described above, the CPU 40 switches the power supply to the detection unit 10 from the power supply VDDA to the power supply VDDB, thereby lowering the accuracy (resolution) of the detection unit 10 and reducing the current flowing to the detection unit 10. . In this embodiment, the power supply VDDB outputs a voltage lower than the power supply VDDA. However, even if the power supply VDDB outputs a voltage equal to or higher than the power supply VDDA, the A / D converter 30 determines whether or not a person is on the vehicle. Outputs a distinguishable signal. On the other hand, when the power supply VDDB outputs a voltage higher than the power supply VDDA, reduction in power consumption cannot be expected.

Here, the operation state of the weigh scale 1 will be described. The weighing scale 1 has three types of operation states: a standby state, a zero point update state, and a measurement state. When determining that the operation state of the weighing scale 1 is the standby state, the CPU 40 reduces the current flowing to the detection unit 10 and determines whether or not there is a load in a state where the resolution of the detection unit 10 is reduced. Next, when determining that the operation state of the weighing scale 1 is the zero point update state, the CPU 40 increases the current flowing to the detection unit 10 for a certain period. Then, the CPU 40 obtains zero-point data (hereinafter referred to as zero-point data hs ₀ ) and updates the zero-point data hs ₀ with the resolution of the detection unit 10 increased. Then, after updating the zero point data hs ₀ , the CPU 40 obtains load detection reference data (hereinafter referred to as reference data Ls ₀ ) while reducing the current flowing to the detection unit 10 and reducing the resolution. to update the data Ls _0. Next, when determining that the operating state of the weighing scale 1 is the measuring state, the CPU 40 increases the current flowing to the detecting unit 10, increases the resolution of the detecting unit 10, and measures the weight. After measuring the weight, the CPU 40 changes the operation state of the weigh scale 1 from the measurement state to the standby state.

The zero point data hs ₀ is load data (hereinafter referred to as load data hs) obtained by increasing the resolution of the detection unit 10 by the CPU 40 and is not loaded on the measuring table of the weighing scale 1. Is the load data hs acquired. The load data hs when a person is placed on the measuring table includes a change in zero point data hs ₀ caused by an externally applied impact or a zero point data hs ₀ caused by the influence of the temperature of the weighing scale 1 or the like. Changes are included. Therefore CPU40 includes a load data hs of when a person resting on the measuring table, by obtaining the difference between the latest zero-point data hs _0, it is possible to accurately measure the load.

The reference data Ls _{0 for} load detection is load data (hereinafter, referred to as load data Ls) acquired by the CPU 40 by lowering the resolution of the detection unit 10, and is loaded on the measuring table of the weigh scale 1. This is the load data Ls acquired when it is not. The CPU 40 uses the load detection reference data Ls ₀ to determine whether any load is applied to the measuring table of the weigh scale 1. Further, CPU 40, for each update of the zero point data hs _0, to acquire and update the reference data Ls ₀ load detection.

CPU40 is (for example, once in several seconds) for each certain interval, to start the update process of the zero-point data hs _0. The execution time of the update process of the zero point data by the CPU 40 is several tens of milliseconds.

  The operation of the CPU 40 will be described. FIG. 2 is a flowchart illustrating the operation of the CPU 40 according to at least one embodiment. The CPU 40 shifts to the standby state, operates the switch 50, switches the power supply of the detection unit 10 from the power supply VDDA to the power supply VDDB, and reduces the current flowing to the detection unit 10 (Step S1). The weighing scale 1 operates in a state where power consumption is low due to the state of step S1. That is, the power supply VDDB is a power supply connected to the detection unit 10 before a change in load is detected.

The CPU 40 determines whether or not the current time is the time to start the zero point update process (step S2). If the current time is the time to start the zero point update processing in step S2 (step S2: Yes), the CPU 40 shifts from the standby state to the zero point update state in which the zero point update processing is executed (steps S3 to S3). Step S6). When the zero point update process starts, the CPU 40 operates the switch 50 to switch the power supply of the detection unit 10 from the power supply VDDB to the power supply VDDA. Thereby, the current flowing to the detection unit 10 increases (step S3), and the resolution of the detection unit 10 increases. Next, CPU 40 acquires the zero point data hs _0, this zero point data hs _0, updates the zero point data hs ₀ stored in the storage unit 70 (step S4). Next, the CPU 40 operates the switch 50 to switch the power supply of the detection unit 10 from the power supply VDDA to the power supply VDDB. Thereby, the current flowing to the detection unit 10 decreases (Step S5), and the resolution of the detection unit 10 decreases. Subsequently, CPU 40 obtains the reference data Ls ₀ of the load detection, this reference data Ls _0, and updates the reference data Ls ₀ which is stored in the recording unit 70 (step S6). Note that the reference data Ls _0, was obtained when not anything placed on the measuring table of the weight meter 1, the resolution of the detector 10 is a load data Ls of a low state. If the current time is not the timing to start the zero point update processing in step S2 (step S2: No), or if the CPU 40 completes the zero point update processing in steps S3 to S6 and shifts to the standby state The process proceeds to the next step S7.

The CPU 40 determines whether or not a load has been detected (step S7). Specifically, the CPU determines whether a load is detected according to the following procedure. First, the CPU 40 acquires the load data Ls in a state where the resolution of the detection unit 10 is low. Next, the CPU 40 compares the load data Ls with a threshold and determines whether the load data Ls is equal to or greater than the threshold. Threshold value is a value obtained by adding any load count in the reference data Ls ₀ the resolution is obtained in a low state of the detection portion 10. For example, when it is desired to detect a load of 5 kg or more, the CPU 40 calculates a value obtained by adding a load count for 5 kg to the reference data Ls ₀ and sets the calculated value as a threshold. Further, in another embodiment, CPU 40 includes a load data L _s and the reference data Ls ₀ to be output to indicate different values may be determined that there is detection of the load.
When the load data Ls is equal to or greater than the threshold (Step S7: Yes), the CPU 40 shifts from the standby state to the measurement state, operates the switch 50, and switches the power supply of the detection unit 10 from the power supply VDDB to the power supply VDDA. Thereby, the current flowing to the detection unit 10 increases (step S8), and the resolution of the detection unit 10 increases. Then, the CPU 40 proceeds to the next step S9. If the load data is less than the threshold (step S7: No), the CPU 40 returns to step S2 to determine whether it is time to start the zero point update process.

  The CPU 40 acquires the load data hs indicating the load applied to the measuring table, and performs a load (weight) measurement process based on the load data hs (step S9). The CPU 40 proceeds to the next step S10.

The CPU 40 determines whether or not the load has been determined by the measurement process (step S10). As a method of determining whether or not the weight has been determined, for example, a state in which the difference between the load data hs acquired this time and the previous load data hs stored in the storage unit 70 is equal to or smaller than a predetermined value is repeated a predetermined number of times. In this case, it can be determined that the load has been determined. If the CPU 40 determines that the load is determined in step S10 (step S10: Yes), the CPU 40 converts the average value of the load data hs into a multiple of a minimum unit (eg, 0.05 kg) and outputs the data from the output unit 80. I do. Then, the CPU 40 shifts from the measurement state to the standby state, operates the switch 50, switches the power supply of the detection unit 10 from the power supply VDDA to the power supply VDDB, and returns to step S1. Thereby, the current flowing to the detection unit 10 decreases, and the resolution of the detection unit 10 decreases.
If the CPU 40 determines that the load is not determined in step S10 (step S10: No), the CPU 40 continues the load measurement processing in step S9.

As described above, the weighing scale 1 of the first embodiment switches the power supply of the detection unit 10 from the power supply VDDA to the power supply VDDB, thereby reducing the current flowing to the detection unit 10 and reducing the resolution of the detection unit 10. To perform the treatment in the standby state. For this reason, the weighing scale 1 can reduce the power consumption. Since the detecting section 10 has the largest power consumption among the components constituting the weighing scale 1, it is not possible to reduce the current flowing to the detecting section 10. High contribution to low power consumption. The weighing scale 1 does not require a mechanical switch for detecting the load because the detecting unit 10 detects the load, and therefore the tilt due to the stroke for turning on the mechanical switch does not occur. Highly accurate measurement is possible. In addition, the weighing scale 1 of the first embodiment increases the current flowing to the detection unit 10 by switching the power supply of the detection unit 10 from the power supply VDDB to the power supply VDDA when the detection unit 10 detects a change in load. Let it. Thereby, the resolution of the detection unit 10 is increased, and the weighing scale 1 can accurately measure the load.
Further, in this embodiment, the detection unit 10 as a load sensor using a strain gauge has been described, but the present invention can be applied to other load sensors.

<< 2nd Embodiment >>
Next, a second embodiment will be described. The weighing scale 1 according to the first embodiment switches the power supply VDDA and the power supply VDDB to switch the current flowing to the detection unit 10. On the other hand, the weighing machine 1 according to the second embodiment switches the resistance to switch the current value flowing to the detection unit 10. FIG. 3 is a block diagram showing a hardware configuration of the weighing scale 1 according to the second embodiment. (Note that in the following embodiments, elements having the same functions and functions as those of the first embodiment are the same as above.) The reference numerals are used and the description is omitted as appropriate.
The weighing scale 1 connects a load detecting unit 10, an operational amplifier 20 for amplifying a signal, an A / D converter 30 for converting an amplified analog signal into a digital signal, a CPU 40, a power supply VDDA, and the detecting unit 10. And a switch 51 for switching a power supply path between a path not passing through the resistor 60 and a path passing through the resistor 60.

  The switch 51 connects a path connecting the power supply VDDA connected to the input terminal in1 of the bridge circuit 11 of the detection unit 10 to the detection unit 10 between a path not passing through the resistor 60 and a path passing through the resistance 60. This is a switch for switching. The resistance 60 has a resistance value equal to or higher than the resistance value of the strain gauge. Here, “equivalent” is not necessarily limited to the equivalent, but may have values before and after the same. The switch 51 is switched by the CPU 40. The current control unit includes the switch 51 and the CPU 40 that controls the switch 50.

  Assuming that the resistance value of the resistor 60 is the same as the resistance value of the strain gauge, for example, 350Ω, when the CPU 40 selects the switch 51 from the power supply VDDA and passes through the resistor 60, the power supply VDDA / (gauge resistance + resistance 60) The current Bi2 determined by the above flows through the detection unit 10. In addition, when the CPU 40 selects the switch 51 from the power supply VDDA and does not pass through the resistor 60, the current Bi3 flows to the detection unit 10. The current Bi3 is a current sufficient to obtain the required accuracy of the weighing scale 1. The current Bi3 is twice as large as the current Bi2, and the resolution of the detection unit 10 for the current Bi3 is twice the resolution of the current Bi2. Here, the case where the output voltage of the power supply VDDA is 3 V and the resistance 60 is 6650Ω will be described. The power supply VDDA supplies a current equal to or more than a current value sufficient to obtain the required accuracy of the weighing scale 1 to the detection unit 10. At this time, the current flowing to the detection unit 10 is 3 V / 350Ω = about 8.6 mA (1 / 10,000 accuracy). On the other hand, when the CPU 40 selects the path from the power supply VDDA via the resistor 60 to the switch 51, the current flowing to the detection unit 10 is 3V / (350Ω + 6650Ω) = about 0.43 mA (1/500 accuracy). Therefore, the CPU 40 switches the switch 51 of FIG. 3 to a path passing through the resistor 60, thereby lowering the accuracy (resolution) of the detection unit 10 and reducing the current flowing to the detection unit 10.

  The operation of the CPU 40 will be described. FIG. 2 is a flowchart illustrating the operation of the CPU 40 according to the second embodiment. The CPU 40 shifts to the standby state, operates the switch 51, switches the power supply of the detection unit 10 from the power supply VDDA to the path passing through the resistor 60, and reduces the current flowing to the detection unit 10 (Step S1). The weighing scale 1 operates in a state where power consumption is low due to the state of step S1.

The CPU 40 determines whether or not the current time is the time to start the zero point update process (step S2). If the current time is the time to start the zero point update processing in step S2 (step S2: Yes), the CPU 40 shifts from the standby state to the zero point update state in which the zero point update processing is executed (steps S3 to S3). Step S6). When the zero point update process is started, the CPU 40 operates the switch 51 to switch the power supply of the detection unit 10 from the path from the power supply VDDA via the resistor 60 to a path not passing through the resistor 60 and to the detection unit 10. The flowing current is increased (step S3). CPU40 acquires the zero point data hs _0, this zero point data hs _0, updates the zero point data hs ₀ which is stored in the storage unit 70 (step S4). Next, the CPU 40 operates the switch 51 to switch the power supply of the detection unit 10 from the path from the power supply VDDA via the resistor 60 to a path not via the resistor 60, thereby reducing the current flowing to the detection unit 10 ( Step S5). The resolution of the detection unit 10 is reduced. Subsequently, CPU 40 updates the reference data Ls ₀ of the load detected (step S6). If the current time is not the timing to start the zero point update process in step 2 (step S2: No), or if the CPU 40 completes the zero point update process in steps S3 to S6 and shifts to the standby state The process proceeds to the next step S7.

  Next, the CPU 40 determines whether or not a load is detected (step S7). When the load is detected (Step S7: Yes), the CPU 40 shifts from the standby state to the measurement state, operates the switch 51, and switches the power supply of the detection unit 10 from the power supply VDDA through the resistor 60 through the resistor 60. By switching to a route that does not pass through 60, the current flowing to the detection unit 10 is increased (step S8), and the resolution of the detection unit 10 is increased. Then, the CPU 40 proceeds to the next step S9. If the load data is less than the threshold value (step S7: No), the process returns to step S2 to determine whether it is time to start the zero point update process.

  The CPU 40 acquires the load data hs indicating the load applied to the measuring table, and performs a load measurement process (step S9). The CPU 40 proceeds to the next step S10.

  The CPU 40 determines whether or not the load is determined in the measurement processing (Step S10). If the CPU 40 determines that the load is determined in step S10 (step S10: Yes), the average value of the load data hs is converted into a multiple of a minimum unit (eg, 0.05 kg) and the data is output from the output unit 80. I do. Then, the CPU 40 shifts from the measurement state to the standby state, operates the switch 51, and switches the power supply of the detection unit 10 from the path not passing through the resistor 60 from the power supply VDDA to the path passing through the resistor 60, and proceeds to step S1. Return. Thereby, the current flowing to the detection unit 10 decreases, and the resolution of the detection unit 10 decreases. If the CPU 40 determines that the load is not determined in step S10 (step S10: No), the CPU 40 continues the load measurement processing in step S9.

As described above, the weighing scale 1 according to the second embodiment switches the path connecting the detection unit 10 and the power supply VDDA from the path not passing through the resistor 60 to the path passing through the resistance 60, and By reducing the current flowing to the circuit 10, the same effect as in the first embodiment can be obtained. Therefore, the weighing scale 1 can reduce the power consumption in the standby state. Further, in the first embodiment, two types of power supplies, the power supply VDDA and the power supply VDDB, are used. However, in the second embodiment, the power supply VDDB is reduced and replaced with the resistor 60. Thus, the weight scale 1 of the second embodiment can reduce the number of components and the cost around the power supply VDDB as compared with the first embodiment.
In addition, when the detection unit 10 detects a change in load, the weighing scale 1 according to the second embodiment changes the path connecting the detection unit 10 and the power supply VDDA from the path passing through the resistance 60 to the resistance 60. By switching to a route that does not pass, the current flowing to the detection unit 10 is increased. Thereby, the resolution of the detection unit 10 is increased, and the weighing scale 1 can accurately measure the load.

  Note that the number of resistors 60 in the weighing scale 1 of the second embodiment is not limited to one. For example, if the power supply to the detection unit 10 is set to three levels of the power supply VDDA, the resistance 60, and the resistance larger than the resistance 60, the CPU 40 sets the current flowing to the detection unit 10 to three types and sets the resolution of the detection unit 10 to 3 levels. Can be staged. Further, the combination of the resistor 60 and the switch 51 may be replaced with a variable resistor to correspond.

<< 3rd Embodiment >>
Next, a third embodiment will be described. The weighing scale 1 according to the first embodiment switches the power supply VDDA and the power supply VDDB to switch the current flowing to the detection unit 10, and the weighing scale 1 according to the second embodiment switches the resistance to change the detection unit 10 Switch the current value flowing to the On the other hand, the weighing machine 1 according to the third embodiment switches the current source IA and the current source IB to switch the current value flowing to the detection unit 10. The current source IA and the current source IB are constant current sources through which a constant current flows. FIG. 4 is a block diagram illustrating a hardware configuration of the weighing scale 1 according to the third embodiment. The same reference numerals are given and the description is appropriately omitted for each). The weighing scale 1 includes a load detecting unit 10, an operational amplifier 20 for amplifying a signal, an A / D converter 30 for converting an amplified analog signal into a digital signal, a CPU 40, and a current for supplying a current to the detecting unit 10. It includes a source IA and a current source IB, and a switch 52 for switching between the current source IA and the current source IB.
The current control unit includes the switch 50 and the CPU 40 that controls the switch 50.

  The switch 52 switches a current source connected to the input terminal in1 of the bridge circuit 11 of the detection unit 10 between the current source IA and the current source IB. This switch 52 is operated by the CPU 40. The current source IA is a current source that supplies the detection unit 10 with a current or more sufficient to obtain the desired accuracy of the weighing scale 1, for example, 1/10000 accuracy. The current source IB is a current source that supplies a current corresponding to an accuracy lower than the desired accuracy of the weighing scale 1, for example, 1/500 accuracy to the detection unit 10. For example, if the current source IA is a constant current source of 8.6 mA and the current source IB is a constant current source of 0.43 mA, the CPU 40 switches the switch 52 from the current source IA to the current source IB to perform detection. The current flowing to the section 10 can be reduced from about 8.6 mA (1/10000 precision) to about 0.43 mA (1/500 precision), and the precision (resolution) of the detection section 10 can be lowered.

  The operation of the CPU 40 will be described. FIG. 2 is a flowchart illustrating the operation of the CPU 40 according to the third embodiment. The CPU 40 shifts to the standby state, operates the switch 52, switches the current source supplied to the detection unit 10 from the current source IA to the current source IB, and reduces the current flowing to the detection unit 10 (Step S1). The weighing scale 1 operates in a state where power consumption is low due to the state of step S1.

The CPU 40 determines whether or not the current time is the time to start the zero point update process (step S2). If the current time is the time to start the zero point update processing in step S2 (step S2: Yes), the CPU 40 shifts from the standby state to the zero point update state in which the zero point update processing is executed (steps S3 to S3). Step S6). When the zero point updating process is started, the CPU 40 operates the switch 52 to switch the current source to be supplied to the detection unit 10 from the current source IB to the current source IA. Thereby, the current flowing to the detection unit 10 increases (Step S3), and the resolution of the detection unit 10 increases. CPU40 acquires the zero point data hs _0, this zero point data hs _0, updates the zero point data hs ₀ stored in the storage unit 70 (step S4). Next, the CPU 40 operates the switch 52 to switch the current source supplied to the detection unit 10 from the current source IA to the current source IB. Thereby, the current flowing to the detection unit 10 decreases (Step S5), and the resolution of the detection unit 10 decreases. Subsequently, the CPU 40 updates the reference data Ls for load detection (step S6). If the current time is not the timing to start the zero point update process in step 2 (step S2: No), or if the CPU 40 completes the zero point update process in steps S3 to S6 and shifts to the standby state The process proceeds to the next step S7.

  The CPU 40 determines whether or not a load has been detected (step S7). When the load is detected (Step S7: Yes), the CPU 40 shifts from the standby state to the measurement state, operates the switch 52, and switches the current source supplied to the detection unit 10 from the current source IB to the current source IA. As a result, the current flowing to the detection unit 10 increases (step S8), and the resolution of the detection unit 10 increases. Then, the CPU 40 proceeds to the next step S9. If the load data is less than the threshold (step S7: No), the CPU 40 returns to step S2 to determine whether it is time to start the zero point update process.

  The CPU 40 acquires the load data hs indicating the load applied to the measuring table, and performs a load measurement process (step S9). The CPU 40 proceeds to the next step S10.

  The CPU 40 determines whether or not the load is determined in the measurement processing (Step S10). If the CPU 40 determines that the load is determined in step S10 (step S10: Yes), the average value of the load data hs is converted into a multiple of a minimum unit (eg, 0.05 kg) and the data is output from the output unit 80. I do. Then, the CPU 40 shifts from the measurement state to the standby state, operates the switch 52, switches the current source supplied to the detection unit 10 from the current source IA to the current source IB, and returns to step S1. Thereby, the current flowing to the detection unit 10 decreases, and the resolution of the detection unit 10 decreases. If the CPU 40 determines that the load is not determined in step S10 (step S10: No), the CPU 40 continues the load measurement processing in step S9.

As described above, the weighing machine 1 of the third embodiment is equivalent to the first embodiment and the second embodiment by switching the current source supplied to the detection unit 10 from the current source IA to the current source IB. The effect of can be obtained. Further, the weighing machine 1 according to the first embodiment and the second embodiment can improve the output voltage of the power supply VDDA, for example, by increasing the output voltage of the battery. For example, if the output voltage of the battery is 3 V and the output voltage of the power supply VDDA is 4.2 V, by replacing the battery with a battery having a 6 V output, the current flowing to the detection unit 10 becomes about 8.6 mA to about 8.6 mA. 12.0 mA. As described above, in order to increase the current flowing to the detection unit 10 and further increase the resolution, it is necessary to increase the output voltage of the power supply VDDA. On the other hand, in the third embodiment, the current value of the constant current source supplied to the detection unit 10 can be increased without changing the output voltage of the power supply VDDA. This is because the current value in the constant current source can be set independently of the voltage value of the power supply. Therefore, the weighing scale 1 according to the third embodiment increases the current flowing to the detecting section 10 even if the supply voltage of the circuits other than the detecting section 10 is reduced and the power consumption of the weighing scale 1 is further reduced, thereby increasing the resolution. It is possible to operate at a higher height. In addition, the weighing scale 1 of the present embodiment needs to use two types of current sources, a current source IA and a current source IB, but a resistor that uses one type of current source and sets a constant current value. Can also be switched.
The weighing scale 1 according to the third embodiment switches the current source supplied to the detection unit 10 from the current source IB to the current source IA when the detection unit 10 detects a change in the load. Increase the current flowing to the Thereby, the resolution of the detection unit 10 is increased, and the weighing scale 1 can accurately measure the load.

As described above, one embodiment has been described in detail with reference to the drawings. However, the specific configuration is not limited to the above, and various design changes and the like can be made.
For example, when the current flowing to the detection unit 10 is reduced and the resolution of the detection unit 10 is reduced, in another embodiment, the CPU 40 can set the amplification factor (gain) of the operational amplifier 20 high to increase the load detection sensitivity. It may be. Further, in the above-described embodiment, the detection unit 10 as the load sensor in the bridge circuit 11 using the strain gauge has been described, but is not limited thereto. For example, in another embodiment, a pressure sensor using a piezo element as a load sensor or a sensor using a semiconductor gauge or the like may be applied. Further, in the weighing scale 1 of another embodiment, in the standby state in which the current flowing through the detection unit 10 is reduced, the current is passed through the detection unit 10 only for a predetermined period to perform the intermittent operation, thereby further reducing the power consumption. It is also possible.
Further, the number of power supplies may be increased to a value other than VDDA and VDDB, and, for example, the state may be shifted stepwise to, for example, a standby state 2 in which power consumption is reduced from the standby state 1 in accordance with a period during which load detection is not performed. Good.

  The operation of the CPU 40 is defined by a program. The operation of each processing unit described above is stored in the storage unit 70 in the form of a program. The CPU 40 executes the above processing according to the program of the storage unit 70.

  Note that in at least one embodiment, the storage unit 70 is an example of a non-transitory tangible medium. Other examples of the non-transitory tangible medium include a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, and a semiconductor memory connected via an interface. When this program is distributed to a computer via a communication line, the CPU 40 of the distributed computer may load the program into the storage unit 70 and execute the above processing.

  Further, the program may be for realizing a part of the functions described above. Further, the program may be a program that realizes the above-described functions in combination with another program already stored in the auxiliary storage device, that is, a so-called difference file (difference program).

  DESCRIPTION OF SYMBOLS 1 ... Weight scale 10 ... Detection part 11 ... Bridge circuit 20 ... Operation amplifier 30 ... A / D converter CPU 40 ... 50 50, 51, 52 ... Switch 60 ... Resistance 70 ... Storage part 80 ... Output part

Claims (7)

A detection unit that is connected to a power supply to form a bridge circuit, and outputs load data indicating a load applied to the measurement table;
The connection between the power supply and the bridge circuit a weighing scale Ru and a current control unit for switching control,
The current controller,
A standby state in which a connection state between the power supply and the bridge circuit is controlled so that a current flowing from the power supply to the bridge circuit has a first current value smaller than a current value sufficient to obtain desired accuracy of the weighing scale. Determining whether or not it is time to start the zero point update process at regular intervals; and
The power supply and the bridge are controlled such that a current flowing from the power supply to the bridge circuit has a second current value equal to or greater than a current value sufficient to obtain a desired accuracy of the weighing scale at a timing when the zero point update process is started. Controlling the connection state with the circuit, acquiring the load data when nothing is mounted on the measurement table, and updating the data as zero point data based on the load data;
At the time when the zero point update process is started, the connection state between the power supply and the bridge circuit is switched and controlled so that the current flowing from the power supply to the bridge circuit becomes the first current value. Acquiring the load data when nothing is on it, and updating the load detection reference data based on the load data,
In the standby state, a step of comparing the load data and a threshold based on the reference data of the load detection to determine whether there is a load detection,
When the load is detected, the load data is obtained by switching and controlling the connection state between the power supply and the bridge circuit so that the current flowing from the power supply to the bridge circuit becomes the second current value. Obtaining a load based on a difference between the load data and the zero point data ;
Weight scale to run . An A / D converter that generates load data by converting an output signal of the detection unit into a digital signal with a predetermined quantization width;
The weighing scale according to claim 1, wherein the bridge circuit outputs an output signal of a voltage corresponding to a load applied to the measuring table. In the step of determining whether or not the load is detected, the current control unit determines that the load is detected if the load data is equal to or greater than a value obtained by adding a load count to the reference data. The weight scale according to claim 1 or 2. The current control unit, when the detection unit detects a change in load, changes a power supply that supplies a current to the bridge circuit from a first power supply that is a power supply connected to the bridge circuit to the first power supply. 4. The power supply for supplying a power larger than the power supply of claim 2, wherein the power supply is switched to a second power supply that is a power supply in which the current flowing in the bridge circuit has the second current value. 5. Weight scale. The current control unit, when the detection unit detects a change in load, the resistance between the power supply for supplying current to the bridge circuit and the bridge circuit, the current flowing through the bridge circuit the second current The weighing scale according to any one of claims 1 to 3, wherein the weighing scale is reduced to a value. The current control unit, when the detection unit detects a change in load, switches a path connecting the power supply and the bridge circuit from a path having the resistance to a path without the resistance. 5. The weighing scale according to 5. The current control unit includes a constant current power supply that supplies a current to the bridge circuit when the detection unit detects a change in load, a first constant current that is a constant current power supply connected to the bridge circuit. 2. A constant current power supply for supplying a current larger than the first constant current power supply from a power supply, wherein the current flowing through the bridge circuit is switched to a second constant current power supply having the second current value. Item 4. The weight scale according to any one of items 3.

Images