Thermoelectric system

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a thermoelectric system to supply power (electric energy) generated by a thermoelectric power generator which generates electricity by utilizing an outside temperature difference to a load so as to operate the load. The present invention especially relates to a thermoelectric system which provides a function to adequately control power supply from a thermoelectric power generator to a load, compensating for an influence of the Peltier effect peculiar to the thermoelectric power generator.

2. Description of the Related Art

There exists a thermoelectric system which generates electric power from heat energy caused by an outside temperature difference using a thermocouple and drives electronic equipment such as an electronic timepiece and the like utilizing electric energy obtained from the power generation.

An electronic timepiece driven by generated power from a thermoelectric power generator shown in

FIG. 6

can be cited as a conventional example, which applies such a thermoelectric system to a small portable electronic device.

The electronic timepiece has a configuration in which a load means

20

is connected to the thermoelectric power generator

10

and power generated by the thermoelectric power generator

10

can be used with the load means

20

.

The load means

20

is configured with a voltage-up converter

23

, a timekeeping means

21

and an accumulator

22

. The voltage-up converter

23

is connected to the thermoelectric power generator

10

and raises the voltage to twice that of the voltage generated by the thermoelectric power generator

10

.

The timekeeping means

21

having a time-clock function and the accumulator

22

which is a second battery are connected in parallel to an output side of the voltage-up converter

23

, and the accumulator

22

is charged by a voltage-up output of the voltage-up converter

23

to supply the charged power to the timekeeping means

21

.

Furthermore, the electronic timepiece is provided with a generated voltage detector

35

using an amplifier circuit to detect the generated voltage of the thermoelectric power generator

10

, and a controller

36

to control operation of the voltage-up converter

23

in accordance with the detected voltage.

The thermoelectric power generator

10

is configured to connect plural thermocouples in series. In the case that the electronic timepiece in this example is a wrist watch, the thermoelectric power generator

10

is disposed so that a warm junction side is contacted with a case back of the wrist watch and a cold junction side is contacted with the case which is insulated against heat from the case back. Heat energy created by a temperature difference between the case back which closely contacts an arm of the person who carries the wrist watch and the case exposed to the outside air, is converted to electric energy.

In an electronic time piece utilizing such a conventional thermoelectric system, generated voltage by the thermoelectric power generator

10

is raised by means of the voltage-up converter

23

after being charged to the accumulator

22

and then used to operate hand-driving of the timekeeping means

21

and the like with the charged electric energy.

At this time, when the generated voltage of the thermoelectric power generator

10

detected by the generated voltage detector

35

exceeds a predetermined value, the controller

36

considers that the generated power of the thermoelectric power generator

10

is applicable and outputs a signal to operate the voltage-up converter

23

. Through this process, the voltage-up converter

23

starts voltage-up operation to raise the generated voltage of the thermoelectric power generator

10

to charge the accumulator

22

. On the other hand, when the generated voltage of the thermoelectric power generator

10

detected by the generated voltage detector

35

is less than a predetermined value, the controller

36

stops the voltage-up operation of the voltage-up converter

23

to stop power supply to the load means

20

from the thermoelectric power generator

10

. At the same time, the controller

36

prevents electric energy charged in the accumulator

22

from discharging to the thermoelectric power generator

10

side.

In the conventional thermoelectric system, when the thermoelectric power generator

10

used for a power generating device is given a higher range of temperatures on the warm junction side and a lower range of temperatures on the cold junction side, the thermoelectric power generator

10

generates electricity through the Seebeck effect and outputs generated voltage (incidentally, the generated voltage caused by Seebeck effect is called thermal electromotive force). Especially, when the thermoelectric power generator

10

has no load, generated voltage proportional to the temperature difference existing between its own warm and cold junctions can be obtained from the thermoelectric power generator

10

.

However, when a load is connected to take out power from the thermoelectric power generator

10

, current flows from the thermoelectric power generator

10

to the load. The current causes the Peltier effect which is a reaction of the Seebeck effect and a phenomenon which reduces the temperature difference given to the thermoelectric power generator

10

. That is, when current flows from the thermoelectric power generator

10

to the load, an exothermic reaction occurs on the cold junction side and an endothermic reaction takes place on the warm junction side. Through this Peltier effect, the temperature difference existing in the thermoelectric power generator is reduced, such that the generated voltage which is a thermal electromotive force is also reduced.

However, in the conventional thermoelectric system, temporary reduction of the thermal electromotive force caused by the Peltier effect is not considered, and the temporary reduction of the thermal electromotive force is merely considered to be the result of a temperature change in the outside circumstances.

Therefore, if the thermoelectric system is configured to switch between operation and suspension of the voltage-up converter in accordance with the magnitude of the generated voltage of the thermal power generating device as above, there exists a disadvantage that the voltage-up converter repeatedly performs the operation and the suspension when the value of the generated voltage is close to the detection threshold value.

That is, when a thermoelectric system is configured to switch between supply and suspension of power to a connected load in accordance with the value of generated power from a thermoelectric power generator, it becomes impossible to precisely measure the thermal electromotive force while the load is in operation. As a result, there may be cases where generated power from the thermoelectric power generator can not be used effectively.

SUMMARY OF THE INVENTION

It is an object of the present invention to solve the above-described disadvantages in a thermoelectric system, to facilitate effective utilization of generated power energy from the thermoelectric power generator while compensating for the influence of the Peltier effect on the generated voltage of the thermoelectric power generator, even when the Peltier effect occurs as a result of power supply from the thermoelectric power generator to a load means.

In order to achieve the above-described object, the thermoelectric system according to the present invention comprises: a thermoelectric power generator provided therein with a plurality of thermocouples electrically in series, a load means for utilizing generated power from the thermoelectric power generator, and a controller for controlling power supply and suspension of the power supply to the load means in accordance with the generated voltage, wherein the controller is provided with a compensating means, when power is continuously supplied to the load means from the thermoelectric power generator for more than a predetermined period of time, which measures compensated the generated voltage.

Furthermore, the thermoelectric system is preferably provided with a controller for controlling operation of the load means.

Additionally, the above-described compensating means is preferably a means for compensating for the amount of reduction of the generated voltage of the thermoelectric power generator caused by the Peltier effect resulting from current which flows when power is continuously supplied from the thermoelectric power generator to the load means for a predetermined period of time.

The above-described controller is preferably provided with a means to intermittently measure the generated voltage of the above-described thermoelectric power generator at a predetermined period of time and to block a power supply route from the thermoelectric power generator to the above-described load means or to put the power supply route in a high impedance state during the measurement.

In such cases, the controller can control so as to supply power to the load means from the thermoelectric power generator if the measured result of the generated voltage during the predetermined period of time exceeds a set value, and to suspend the power supply to the load means if the measured result is below the set value.

Furthermore the thermoelectric system can be configured in a manner that the power for the above-described compensating means regards the power as being continuously supplied from the thermoelectric power generator to the load means for more than a predetermined period of time, under the condition that the measured results described above exceed the set value consecutively by the number of times previously set. The compensating means also measures the generated voltage with compensation from next time of the measurement.

The configured thermoelectric system allows the measured thermal electromotive force to be compensated when influenced by the reduction of generated voltage due to the Peltier effect, which occurs when the continuously supplied electric power to the load means, by thermoelectric power generator is not negligible, so as to control supply and suspension of power to the load, assuming voltage as corresponding to the generated voltage originally expected. Accordingly, a thermoelectric system which can effectively utilize the generated power of the thermoelectric power generator even when the Peltier effect is created, and makes the most of the power which can be generated by the thermoelectric power generator, can be realized without being affected by the Peltier effect.

The above and other objects, features and advantages of the invention will be apparent from the following detailed description which is to be read in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a block circuit diagram showing a system configuration of an electronic timepiece which is an embodiment of the thermoelectric system according to the present invention;

FIG. 2

is a circuit diagram showing a detailed circuit configuration of the controller in

FIG. 1

;

FIG. 3

is a circuit diagram showing a detailed circuit configuration of the voltage-up converter in

FIG. 1

;

FIG. 4

is a sectional view showing an outline of the inner structure when the electronic timepiece in

FIG. 1

is a wrist watch;

FIG. 5

is a waveform diagram of voltages and signals of each part to explain the operation of the electronic timepiece shown in

FIG. 1

to

FIG. 3

; and

FIG. 6

is a block circuit diagram showing a configuration example of the conventional thermoelectric system.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the thermoelectric system according to the present invention will be explained in detail with reference to drawings hereinafter.

FIG. 1

is a block circuit diagram showing a system configuration of an electronic timepiece which is an embodiment of the thermoelectric system according to the present invention.

FIG. 2

is a circuit diagram showing a detail circuit configuration of a controller in the electric timepiece, and

FIG. 3

is a circuit diagram showing a detail circuit configuration of the voltage-up converter.

FIG. 4

is a sectional view showing an outline of the inner structure when the electronic timepiece is a wrist watch, and

FIG. 5

is a waveform diagram of voltages and signals in

FIG. 1

to

FIG. 3

to explain the operation of the electronic timepiece.

Explanation of the System Configuration:

FIG. 1

First, a system configuration of the electronic timepiece which is an embodiment of the thermoelectric system according to the present invention will be explained with reference to FIG.

1

. The thermoelectric system of the present embodiment is an electronic timepiece which uses generated power from a thermoelectric power generator as a power source, the same as in the above-described conventional example explained with FIG.

6

. Incidentally, the inner configuration of the electronic timepiece will be explained later.

The electronic timepiece shown in

FIG. 1

is configured in a manner that a load means

20

is connected to a thermoelectric power generator

10

and power generated by the thermoelectric power generator

10

is supplied to the load means

20

for utilization. The electronic timepiece is further provided with a controller

30

which measures the generated voltage of the thermoelectric power generator

10

and controls power supply and suspension of the power supply to the load means

20

in accordance with the generated voltage.

The thermoelectric power generator

10

in which many thermocouples are electrically connected in series (not shown), is assumed to obtain about 1.5V of thermal electromotive force at a temperature difference of 1° C. The thermoelectric power generator

10

outputs electromotive force obtained by the thermal power generation as a generated voltage V

1

.

The load means

20

comprises a timekeeping means

21

having a time-clock function, an accumulator

22

and a voltage-up converter

23

.

The timekeeping means

21

comprises a time-keep circuit (not shown) which divides a quartz oscillation frequency at least into a frequency of two seconds a cycle in the same way as an ordinary electronic timepiece and deforms the divided signal to a waveform necessary to drive a stepping motor, and a stepping motor which is driven by the waveform of time-keep circuit, and a time displaying system which transmits the rotation of the stepping motor while reducing the rotation with a train wheel, to rotatively drive time displaying hands.

The timekeeping means

21

generates a measuring clock S

2

and a voltage-up clock S

3

by means of the above-described time-keep circuit, and inputs the measuring clock S

2

and the voltage-up clock S

3

together into the controller

30

.

The measuring clock S

2

is a signal having a waveform in which the time to be a low level is 8 milliseconds having a cycle time of 2 seconds, and has trailing edge transitions soon after receiving leading edge transitions of the voltage-up clock S

3

. The voltage-up clock S

3

is a rectangular waveform having a frequency of 4 KHz. Since the formation of waveforms of the measuring clock S

2

and the voltage-up clock S

3

is possible by a simple waveform synthesizing, a detailed explanation of the synthesizer circuit will be omitted.

In the present embodiment, the time period when measuring clock S

2

stays in the low level is simultaneously the time period when the voltage-up converter

23

keeps on suspending the voltage-up operation. The reason why the time period for the voltage-up converter

23

to suspend the voltage-up operation is set, is as follows.

That is, since the voltage which occurs at terminals of the thermoelectric power generator

10

is lower than the voltage capable of actual power generation, due to the influence of current caused by voltage-up operation of the voltage-up converter

23

, the suspension time for the voltage-up operation is set so as to suspend the voltage-up converter

23

during and just before measurement of the generated voltage V

1

by a comparator

40

which will be explained later, so that the comparator

40

does not measure generated voltage V

1

by mistake. The voltage-up suspension time is suitably determined by the time constant due to an inner impedance of the thermoelectric power generator

10

and a capacity load of the voltage-up converter

23

.

The accumulator

22

is a second battery using lithium ions, and for an easy explanation, it is assumed that terminal voltage is always taken to be a constant value of 1.8V, without depending on the amount of charge and discharge.

The voltage-up converter

23

is assumed, for simplicity, to be a voltage-up circuit which raises the input voltage twice by switching the connection state of two sets of capacitors. In the voltage-up converter

23

, the thermoelectric power generator

10

is connected to an input side, and the accumulator

22

and the timekeeping means

21

are connected in parallel to an output side. The voltage-up converter

23

inputs voltage-up control signals S

5

and S

6

which are outputted from the controller

30

, and raises the generated voltage V

1

inputted from the thermoelectric power generator

10

to output to the accumulator

22

and the timekeeping means

21

. Incidentally, the circuit and its operation will be later explained in detail.

The negative pole of the thermoelectric power generator

10

, the negative pole of the voltage-up converter

23

, and the negative pole of the accumulator

22

are all grounded. In this embodiment, the voltage direction usually obtained when this electronic timepiece is worn is taken as the forward direction, the side to get warm at that time is called a warm junction, and the side to get cold is called a cold junction. Further, a terminal where a higher potential is created is taken as “a positive pole (+)”, and a terminal where a lower potential is created is taken as “a negative pole (−)”.

The controller

30

measures the generated voltage V

1

of the thermoelectric power generator

10

, controls the operation of the voltage-up converter

23

by means of the voltage-up control signals S

5

and S

6

in accordance with values of the generated voltage V

1

and controls power supply and suspension of the power supply from the thermoelectric power generator

10

to the load means

20

. A detail configuration and operation of the controller

30

will be explained later in detail.

It should be noted that all circuit groups such as a time-keep circuit of the above-described timekeeping means

21

, portions excepting a capacitor of the voltage-up converter

23

, and the controller

30

can be configured on the same integrated circuit similar to a typical electronic timepiece.

Explanation of the Controller:

FIG. 2

Next, a configuration and an operation of the controller in the electronic timepiece shown in

FIG. 1

will be explained in detail with reference to FIG.

2

.

The controller

30

comprises a comparator

40

with an operational amplifier as a voltage measuring means, a first flip-flop circuit

41

and a second flip-flop circuit

42

, a first inverter

45

and a second inverter

46

, a first AND gate

48

and a second AND gate

49

and a regulator circuit

50

.

The comparator

40

outputs a high level signal when input voltage to the noninverting input terminal (+) exceeds input voltage to an inverting input terminal (−), and outputs a low level signal when the input voltage to the noninverting input terminal is equal to or less than the input voltage to the inverting input terminal.

The positive pole of the thermoelectric power generator

10

is connected to the noninverting input terminal of the comparator

40

to input the generated voltage V

1

, and the output terminal of the regulator circuit

50

is connected to the inverting input terminal, and the outputted voltage is inputted as comparison voltage V

2

. The output terminal is connected to a data-input terminal of the first flip-flop circuit

41

, the generated voltage V

1

is compared with the comparison voltage V

2

, a high level or low level signal S

1

in response to the comparison result (measurement result) is outputted as described above, which is inputted to the data-input terminal of the first, flip-flop circuit

41

.

The first flip-flop circuit

41

is a data-type flip-flop circuit in which output is reset when the power supply is turned on, and the second flip-flop circuit

42

is a data-type flip-flop circuit with an inverting reset input. The output terminal of the first flip-flop circuit

41

is connected to a data-input terminal of the second flip-flop circuit

42

, and the first flip-flop circuit

41

and the second flip-flop circuit

42

are connected in series.

The measuring clock S

2

outputted from timekeeping means

21

is inputted to clock input terminals of the first flip-flop circuit

41

and the second flip-flop circuit

42

respectively. Then, respective flip-flop circuits

41

and

42

perform signal holding and signal outputting of the data-input terminal on receiving the leading edge transition of the waveform of the measuring clock S

2

. Furthermore, an output terminal of the first flip-flop

41

is connected to a reset input terminal of the second flip-flop circuit

42

.

The first inverter

45

inputs an output signal of the second flip-flop circuit

42

, which is outputted after being inverted. The second inverter

46

inputs the voltage-up clock S

3

outputted from the timekeeping means

21

, which is outputted after being inverted.

The measuring clock S

2

and the voltage-up clock S

3

from the timekeeping means

21

, an output signal of the first flip-flop circuit

41

are inputted in the first AND gate

48

, and the first AND gate

48

outputs the AND signal of these three signals as a first voltage-up signal S

5

.

The measuring clock S

2

from the timekeeping means

21

, and an output signal of the first flip-flop circuit

41

, and an output signal of the second inverter

46

(an inversion signal of the voltage-up clock S

3

) are inputted in the second AND gate

49

, and the second AND gate

49

outputs the AND signal of these three signals as a second voltage-up signal S

6

.

The regulator circuit

50

is a circuit for generating a comparison voltage, and is configured to select either one of two voltage levels to output the comparison voltage V

2

from the output terminal. That is, when a high level signal is inputted from the first inverter

45

to the input terminal, a comparison voltage V

2

having 0.9V is outputted, and when a low level signal is inputted, a comparison voltage V

2

having 0.81V is outputted.

It should be noted that the comparison voltage V

2

of the regulator circuit

50

is usually set to 0.9V. This voltage value is set in consideration that when the generated voltage V

1

of the thermoelectric power generator

10

becomes larger than 0.9V, a desired charging current can be obtained by outputting twice of the generated voltage V

1

to the accumulator

22

which has a terminal voltage of 1.8V. The value of 0.81V is a voltage value of the comparison voltage V

2

outputted when the influence of the Peltier effect is compensated, this will be explained later in detail.

Explanation of the Voltage-up Converter:

FIG. 3

Next, a configuration and an operation of the voltage-up converter in the electronic timepiece shown in

FIG. 1

will be explained with reference to FIG.

3

.

The voltage-up converter

23

shown in

FIG. 3

comprises a first voltage-up switch

91

, a second voltage-up switch

92

, a third voltage-up switch

93

, a fourth voltage-up switch

94

, a first voltage-up capacitor

101

and a second voltage-up capacitor

102

.

The first voltage up switch

91

is an n-channel type electric field effect transistor (FET) and the second voltage-up switch

92

, the third voltage-up switch

93

, and the fourth voltage-up switch

94

are all p-channel type FETs.

The first voltage-up switch

91

connects a negative pole of the first voltage-up capacitor

101

to a drain terminal and grounds a source terminal, and is controlled on or off by the voltage-up control signal S

5

from the controller

30

inputted to the gate terminal.

The third voltage-up switch

93

connects a positive pole of the first voltage-up capacitor

101

to the source terminal and connects a positive pole of the thermoelectric power generator

10

to the drain terminal to input the generated voltage V

1

. And similarly to the first voltage-up switch

91

, the third voltage-up switch

93

is controlled on or off by the voltage-up control signal S

5

from the controller

30

inputted to the gate terminal.

The second voltage-up switch

92

connects the positive pole of the thermoelectric power generator

10

to the source terminal and connects the negative pole of the first voltage-up capacitor

101

to the drain terminal, and controlled on or off by the voltage-up control signal S

6

from the controller

30

inputted to the gate terminal.

The fourth voltage-up switch

94

connects the source terminal to the positive pole of the accumulator

22

, and connects the positive pole of the first voltage-up capacitor

101

to the drain terminal. And similarly to the second voltage-up switch

92

, the fourth voltage-up switch

94

is controlled on or off by the voltage-up control signal S

6

from the controller

30

inputted to the gate terminal.

The first voltage-up capacitor

101

and the second voltage-up capacitor

102

are components attached outside of the integrated circuit described above, in which the capacity is 0.22 μF for both. The second voltage-up capacitor

102

is connected to the thermoelectric power generator

10

in parallel for stabilizing the terminal voltage of the thermoelectric power generator

10

.

A voltage-up output V

3

(see

FIG. 1

) is outputted from the source terminal of the fourth voltage-up switch

94

, which is charged to the accumulator

22

.

Since the voltage-up converter

23

is configured as above, by switching the on-off states of respective voltage-up switches

91

,

92

,

93

, and

94

through the voltage-up control signals S

5

and S

6

from the controller

30

, the voltage-up converter

23

operates as follows.

First, when the first voltage-up switch

91

and the third voltage-up switch

93

are both in an on-state, the thermoelectric power generator

10

and the first voltage-up capacitor

101

are connected in parallel, the first voltage-up capacitor

101

is charged by the generated voltage of the thermoelectric power generator

10

, so that the voltage on the positive pole of the first voltage-up capacitor

101

becomes nearly the same as the generated voltage.

Incidentally, the second voltage-up capacitor

102

is always connected to the thermoelectric power generator

10

in parallel and the voltage on the positive pole is nearly the same as the generated voltage of the thermoelectric power generator

10

.

Then, when the first voltage-up switch

91

and the third voltage-up switch

93

are made in an off-state, and at the same time, the second voltage-up switch

92

and the fourth voltage-up switch

94

are in an on-state, the parallel circuit of the thermoelectric power generator

10

and the second voltage-up capacitor

102

, is connected to the first voltage-up capacitor

101

in series. Accordingly, in a non-load state where load is not connected, voltage obtained by adding terminal voltage of the first voltage-up capacitor

101

to the generated voltage of the thermoelectric power generator

10

, that is, the voltage twice of the generated voltage, can be obtained on the drain terminal of the fourth voltage-up switch

94

as a voltage-up output.

Explanation of a Configuration of the Electronic Timepiece:

FIG. 4

An example of the inner configuration of the above-described timepiece is shown in

FIG. 4

when it is a wrist watch. In this electronic timepiece, a metal case

61

fitting a glass

60

therein on the upper surface portion, and a metal case back

62

are integrally engaged through a heat insulator

63

to form a closed space in the inside thereof. A thermoelectric power generator

10

which is composed of many thermocouples formed in a ring-shape is disposed around the closed space, and a movement

65

is provided, which rotationally drives a time-display hand group

66

consisting of an hour hand, minute hand and second hand in the inside.

In the thermoelectric power generator

10

, the warm junction side is adhered to the inner surface of the back case

62

which is heated by a bodily temperature when the wrist watch is worn on an arm, and the cold junction side is adhered to the inner surface of the case

61

which is cooled by air.

The load means

20

and the controller

30

shown in

FIG. 1

are housed in the movement

65

, and each hand of the hand group

66

is rotated through the train wheels respectively by a stepping motor rotationally driven by a drive waveform signal from the time-keep circuit of the timekeeping means

21

in the load means

20

.

The time-keep circuit, circuits excepting the first and second voltage-up capacitors

101

, and

102

, of the voltage-up converter

23

, and the control circuit

30

are formed into the same integrated circuit (IC) as described above and are provided within the movement

65

.

Explanation of the Operation of the Thermoelectric System:

FIG. 1

to FIG.

3

and FIG.

5

.

Next, the operation of an embodiment of the above-described electronic timepiece, that is a thermoelectric system according to the present invention, will be explained with reference to

FIG. 1

to FIG.

3

and FIG.

5

.

In the following explanation, assuming that electric energy accumulated in the accumulator

22

is sufficient to drive the timekeeping means

21

, the terminal voltage of the accumulator

22

always maintains 1.8V regardless of whether it is charging or discharging. When the accumulator

22

is in this state, the timekeeping means

21

can be operated and performs usual time-keep operation and hand-drive operation. And the controller

30

is also in an on-state.

At this time, the first flip-flop circuit

41

shown in

FIG. 2

in the control circuit

30

, is in a state such that the time keeping data is reset by turning the power on, that is, outputs a low level signal. Then, the first AND gate

48

and the second AND gate

49

always output low level signals as voltage-up signals S

5

and S

6

to input a low level signal outputted from the first flip-flop circuit

41

.

Consequently, the voltage-up converter

23

shown in

FIG. 3

is in a state that all voltage-up switches

91

to

94

are off to stop the operation.

In the second flip-flop circuit

42

of the controller

30

, the time keeping data and the output signal are reset to input a low level output signal of the first flip-flop circuit

41

. Accordingly, since the output signal becomes a low level and the output signal of the first inverter

45

inputted into the regulator circuit

50

becomes a high level, the regulator circuit

50

outputs voltage of 0.9V as the comparison voltage V

2

.

Now, it is assumed that an electronic timepiece of this thermoelectric system is under a circumstance that not much of a temperature difference occurs between both terminals of the thermoelectric power generator

10

, and the generated voltage V

1

became about 0.85V, below 0.9V.

Then, the comparator

40

, shown in

FIG. 2

of the controller

30

, compares the generated voltage V

1

of about 0.85V with the comparison voltage V

2

of 0.9V, and judges it to be V

1

<V

2

and makes the output signal S

1

(measured output) in a low level (refer to FIG.

5

).

On the other hand, in the measuring clock S

2

inputted into the first flip-flop circuit

41

, as shown in

FIG. 5

, the waveform makes the trailing edge transitions from a high level to a low level at a 2 second period and makes the leading edge transition after 8 milliseconds. That is, it alternatively repeats to be in a high level state during a period of 2 seconds minus 8 milliseconds, and in a low level state during a period of 8 milliseconds.

The first flip-flop circuit

41

captures the measured output S

1

when the measuring clock S

2

is at the leading edge transitions. And when the measured output S

1

is in a low level, the output is maintained in the low level by capturing the measured output S

1

in the low level. Accordingly, the low level signal continues to input into both the first AND gate

48

and the second AND gate

49

similarly to the time of initialization. Therefore, the voltage-up control signals S

5

and S

6

stay in the low level, and as a result, the voltage-up converter

23

stays in a suspension state of voltage-up.

Soon, a temperature difference of about 0.67° C. is created at both ends of the thermoelectric power generator

10

and the generated voltage V

1

is assumed to reach 1.0V, in other words, greater than 0.9V. Then, the comparator

40

, shown in

FIG. 2

, of the controller

30

compares the generated voltage V

1

of 1.0V with the comparison voltage V

2

of 0.9V and judges it to be V

1

>V

2

, so that the output signal (measured output) S

1

is made to be in a high level (refer to FIG.

5

).

When the waveform of the measuring clock S

2

takes the trailing edge transitions from the high level to the low level at a period of two seconds and takes the leading edge transitions after 8 milliseconds by taking the measured output S

1

to be in the high level, the first flip-flop circuit

41

captures the high level measured output S

1

to make the output in the high level. Through this, the second flip-flop circuit

42

is canceled and the reset state is in a waiting state for capturing data.

When the output of the first flip-flop circuit

41

is in the high level, the first AND gate

48

outputs a waveform corresponding to the AND signal of the voltage-up clock S

3

and the measuring clock S

2

as the voltage-up control signal S

5

. Similarly, the second AND gate

49

outputs a waveform corresponding to the AND signal of an inversion signal of the voltage-up clock S

3

and the measuring clock S

2

as a voltage-up control signal S

6

.

At this time, both the voltage-up control signals S

5

and S

6

alternatively repeat the high level and the low level at the same periodicity as that of the voltage-up clock S

3

having a frequency of 4 KHz as shown in FIG.

5

. At the same time, when the voltage-up control signal S

5

is in the high level, the voltage-up control signal S

6

is in the low level, and when the voltage-up control signal S

5

is in the low level, the voltage-up control signal S

6

is in the high level. That is, the voltage-up control signals S

5

and S

6

become signals which mutually inverse their phases.

Both the voltage-up control signals S

5

and S

6

are signals having waveforms in which the voltage-up converter

23

is designed to perform voltage-up operation. As explained as the configuration and operation of the above-described voltage-up converter

23

, when the voltage-up control signals S

5

and S

6

having this waveform are inputted into the voltage-up converter

23

, the voltage-up converter

23

performs a voltage-up operation which allows to output voltage of twice the value of the generated voltage V

1

while the measuring clock S

2

is in the high level.

That is, if the generated voltage larger than 0.9V is generated after the thermoelectric power generator

10

starts power generation, the voltage-up converter

23

starts voltage-up operation to charge the accumulator

22

. Through this step, power supply from the thermoelectric power generator

10

to the load means

20

is started to perform.

If the circumstances are maintained in which the temperature difference of 0.67° C. is possible to be created, the waveform of the measuring clock S

2

takes the trailing edge transition again during that time. Then, since the voltage-up control signals S

5

and S

6

which are outputs of the first AND gate

48

and the second AND gate

49

become to be in the low level during 8 milliseconds in which the measuring clock S

2

is in the low level, the voltage-up operation of the voltage-up converter

23

temporarily suspends.

When the measuring clock S

2

takes the leading edge transition after 8 milliseconds, the first flip-flop circuit

41

captures the measuring clock S

1

which is still in the high level and outputs the high level signal. The second flip-flop circuit

42

captures the high level output signal retained by the first flip-flop circuit

41

until just before the measuring clock S

2

makes the leading edge transition. At this time, the second flip-flop circuit

42

is reset to output the output signal changing from low level to high level.

When the output signal of the second flip-flop circuit

42

becomes in the high level, the first inverter

45

inverts it and inputs the low level signal into a regulator circuit

50

. The regulator circuit

50

outputs the comparator voltage V

2

changing from 0.9V to 0.81V.

At this time, since the output of the first flip-flop circuit

41

is in the high level, when the measuring clock S

2

makes the leading edge transition, the voltage-up control signals S

5

and S

6

are again outputted, as shown in

FIG. 5

, and the voltage-up converter

23

continues the voltage-up operation.

Furthermore, if the circumstances are maintained in which the temperature difference of 0.67° C. is possible to be created similarly in the thermoelectric power generator

10

, the waveform of the measuring clock S

2

again makes the leading edge transition, similarly to the above, and makes the trailing edge transition two seconds later. The voltage-up converter

23

then temporarily suspends.

At this time, the thermoelectric power generator

10

is to supply power to the load means

20

continuously during the aforementioned period of about 4 seconds (around two cycles of the measuring clock S

2

) to keep on feeding charging current to the accumulator

22

through the voltage-up converter

23

or feeding current to the timekeeping means

21

. Accordingly, the thermoelectric power generator

10

receives influence of the Peltier effect caused by the current, and the temperature difference created between both ends is substantially decreased and the generated voltage V

1

gradually declines as shown by a broken line in FIG.

5

.

Therefore, while the measuring clock S

2

gets the low level, the thermoelectric power generator

10

becomes a no-load state separated from the voltage-up converter

23

, and although current does not pass to the load means

20

, the temperature difference can not be retrieved so soon. As a result, voltage of, for instance, 0.9V that is lower than a thermal electromotive force of 1.0V which should be created by the temperature difference of 0.67° C. appears as a generated voltage V

1

.

When the generated voltage of 0.9V appears just after power generation starts, a state to suspend the voltage-up operation of the voltage-up converter

23

is to be continued. But at this time, the comparison voltage V

2

outputted by the regulator circuit

50

has been changed to 0.81V in the controller

30

during the previous measuring of generated voltage, estimating the amount of voltage lowered by the influence of the Peltier effect as described above.

That is, when the thermoelectric power generator

10

supplies power for more than a predetermined period of time continuously, in this instance, when the measured result of the generated voltage by means of the comparator

40

exceeds the comparison voltage consecutively two times, the controller

30

regards the influence of the Peltier effect as being not able to ignore, then reduces the value of the comparison voltage V

2

outputted by the regulator circuit

50

and measures the generated voltage V

1

by the comparator

40

compensating for the lowered value of the generated voltage V

1

due to the influence of the Peltier effect. The function described above corresponds to the “compensating means” in the present invention.

Therefore, even when the generated voltage V

1

of the thermoelectric power generator

10

in this time of measuring is 0.9V, the output signal (measured output) S

1

is outputted continuously in the high level, because the comparator

40

in

FIG. 2

measures the power generating voltage V

1

of 0.9V comparing with the comparison voltage of 0.81V. Accordingly, when the measuring clock S

2

takes the leading edge transition, the output signal of the first flip-flop circuit

41

becomes again in the high level.

Accordingly, while the measuring clock S

2

is in the high level, the voltage-up control signals S

5

and S

6

are outputted continuously as waveform signals which allow the voltage-up converter

23

to perform voltage-up operation as shown in FIG.

5

.

Thus, in this embodiment, when the voltage-up converter

23

keeps on performing the voltage-up operation continuously for more than a predetermined period of time (about 4 seconds), the power generating voltage V

1

lowers to 0.9V by the influence of the Peltier effect. Yet, regarding that the actual thermoelectric power generator

10

has capacity to generate voltage corresponding to 1.0V, the controller

30

controls so as to continue power supply from the thermoelectric power generator

10

to the load means

20

without suspending the voltage-up operation of the voltage-up converter

23

.

Next, suppose that while the voltage-up converter

23

thus continues the voltage-up operation, circumstances are changed to a state in which a temperature difference of only 0.6° C. is created on both ends of the thermoelectric power generator

10

. This temperature difference corresponds a temperature difference in which the generated voltage V

1

is 0.9V, if the thermoelectric power generator

10

has no load.

At this time, similar as above, when a waveform of the measuring clock S

2

again takes the trailing edge transition, the voltage-up converter

23

temporarily suspends the voltage-up operation. But since the influence of the Peltier effect remains during the period of time that the waveform of the measuring clock S

2

keeps in the low level, the actual generated voltage V

1

inputted to the comparator

40

of the controller

30

is about 0.81V which is lower than 0.9V described above.

Consequently, since the comparator

40

compares the generated voltage V

1

of 0.81V with the comparison voltage V

2

of 0.81V, and outputs the output signal (measured output) S

1

in the low level, judging it to be V

1

≦V

2

, the output of the first flip-flop circuit

41

shifts from the high level to the low level at the leading edge transition of the measuring clock S

2

.

When the output of the first flip-flop circuit

41

is in the low level, the controller

30

becomes a state initialized similar to the beginning of the power supply. That is, the voltage-up control signals S

5

and S

6

are fixed in, the low level as shown in the right end portion in FIG.

5

. And the keeping data in the second flip-flop circuit

42

is also reset, and the regulator circuit

50

outputs voltage of 0.9V as the comparison voltage V

2

.

At this time, by fixing the voltage-up control signals S

5

and S

6

outputted from the controller

30

in the same way as the beginning of the power supply, the voltage-up converter

23

, remains in a state of suspension of the voltage-up operation.

Accordingly, when generated power of the thermoelectric power generator

10

cannot substantially be supplied to the load means

20

depending on whether the electronic timepiece is put, the controller

30

suspends the operation of the voltage-up converter

23

to stop the power supply from the thermoelectric power generator

10

, so that electric energy charged in the accumulator

22

does not flow backward to the thermoelectric power generator

10

. At this time, electric energy charged in the accumulator

22

is supplied to the timekeeping means to allow the operation to continue.

It is clear by the above explanation, when the generated voltage V

1

of the thermoelectric power generator

10

raises voltage and reaches a voltage value of a predetermined level capable to utilize thereof, the electronic timepiece which is a thermoelectric system of the present embodiment feeds the generated voltage of the thermoelectric power generator

10

to the load means

20

, and raises voltage by the voltage-up converter

23

to charge the accumulator

22

. After that, when the power supply is continued for more than a predetermined period of time (in the above example, it is 4 seconds which is 2 cycles of the measuring clock S

2

), the generated voltage V

1

of the thermoelectric power generator

10

is measured with compensation, and the voltage-up operation of the voltage-up converter

23

is continued even when the generated voltage V

1

is lower than the above-described predetermined level. And when the generated voltage V

1

of the thermoelectric power generator

10

is lower than another level which is set to be lower than the above-described predetermined level, it operates in such a manner that the voltage-up operation of the voltage-up converter

23

is suspended so as to suspend the power supply to the load means

20

.

Though no reference is made in the previous explanation of the operation, when the generated power from the thermoelectric power generator

10

is not taken out continuously, that is, when the generated voltage V

1

of the thermoelectric power generator

10

is lowered due to a change of circumstances, and the comparator

40

of the controller

30

makes the measuring output S

1

to be in the low level, just after the measurement that the generated voltage V

1

of the thermoelectric power generator

10

is in the level capable of voltage-up charging, output of the first flip-flop circuit

41

takes the low level in the following measurement, thereby the controller

30

becomes an initial state similar to power on, and a compensating operation is not performed.

It should be noted that when the generated voltage V

1

of the thermoelectric power generator

10

is compensated, continuous power supply for more than 4 seconds from the thermoelectric power generator

10

to the load means

20

is regarded as the condition for it. It is preferable to determine the time for the condition of performing the compensation by suitably changing it in accordance with heat-conductive structure of the warm or cold junction portion where the thermoelectric power generator

10

in the electric timepiece is provided, heat capacity or a heat-conductive structure in relation to the outside.

Furthermore, in this embodiment, compensation at the times of measuring the generated voltage is carried out by just changing the comparison voltage (threshold value) in the comparator

40

, the Peltier effect often changes the magnitude of the effect according to the amount of current passing from the thermoelectric power generator

10

. In such cases, more flexible thermoelectric system to perform compensation considering the magnitude of the Peltier effect can be realized by providing another means to measure the amount of electric current passing from the thermoelectric power generator

10

, and by setting in advance voltage for which the controller

30

compensates in response to the measured amount of current.

Additionally, in this embodiment, the load means

20

is cited to explain a load means, in which a charging circuit of a second battery (accumulator

22

) using the voltage-up converter

23

is a main load, but the load means is not limited to this but any electronic device which is a load using the generated power of the thermoelectric power generator

10

to perform the operation will be applicable.

It is conceivable, for instance, to be a load means which uses a voltage-up converter capable of changing the magnification of the voltage-up operation, though not used in the above-mentioned embodiment. In such a case, precise measurement of the generated voltage V

1

is required to select a suitable magnification of the voltage-up operation according to the change of the generated voltage V

1

, but the present invention is applicable to such a case without any problem.

In addition, various examples of application can be conceivable such as a case when a voltage value of the generated voltage V

1

is displayed with liquid crystals. In such cases, it can also be performed by adding a compensation according to the present invention to an output signal performed by an analog-digital conversion using an analog-digital converter (A/D conversion) circuit to obtain a binary generated voltage value of the thermoelectric power generator. However, in this case, the analog-digital converter circuit corresponds to a means for measuring power generations, the controller is required only to process the analog-digital conversion output by adding compensation, and the operation of the analog-digital converter circuit need not change.

As explained above, according to the thermoelectric system of the present invention, supply of power and suspension of the power supply to the load means can be optimally controlled in response to the generated voltage of the thermoelectric power generator by measuring with compensation for the lowering of generated voltage due to the Peltier effect created by such a manner that the thermoelectric power generator continues to pass a load current, and the load means can utilize generated power of the thermoelectric power generator most effectively.

Number	Name	Date	Kind
5705770	Ogasawara et al.	Jan 1998
5835457	Nakajima	Nov 1998

Number	Date	Country
06022572	Jan 1994	JP
06153549	May 1994	JP
10142358	Nov 1997	JP
09308125	Nov 1997	JP
10014255	Jan 1998	JP

Thermoelectric system

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

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US

International Classifications

Abstract

Description

Claims

Priority Claims (1)

US Referenced Citations (2)

Foreign Referenced Citations (5)