JPH0625718U - Electronic pressure measuring device - Google Patents

Abstract

(57) [Summary] [Purpose] To provide an electronic pressure measurement device that enables the user to grasp the travel time between points and the surrounding environmental conditions at the time of movement, in order from the start of diving, when moving between arbitrary points. To aim. [Composition] The read / write selector switch S ₁ is used to switch to the write mode, and the address counter 12 is incremented each time the set switch S ₂ is operated, and the pressure data and the pressure data at that time are stored in the storage area of the RAM 11 addressed by the address counter 12. The time information is sequentially stored. When the read / write changeover switch S ₁ is switched to the read mode, the address counter 12 is preset to the initial state, and the set switch S ₂ is set in the read mode.
Each time the operation of
The pressure data and time information stored in the plurality of storage areas are read out in the oldest order and are sequentially displayed on the display device 5.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an electronic pressure measuring device for measuring water depth, altitude, etc.

[0002]

[Prior art]

 Recently, it has been considered that a pressure sensor is provided in an electronic wrist watch to measure and display the water depth when diving, or to measure and display the altitude when climbing a mountain.

[0003]

[Problems to be solved by the device]

 Since the electronic wrist watch with a water depth meter as described above only displays the water depth, when it is used for so-called underwater navigation, for example, where multiple points are continuously moved by diving, the current state of movement is It was only possible to know the water depth at the location. However, in the case of sequentially moving between multiple points by diving like underwater navigation, I would like to know not only the water depth at each point but also how long it took to move between predetermined points. It is a thing. In such a case, a stopwatch other than the pressure gauge should generally be used to start at the starting point and take a lap or stop at the point where data is to be stored. It is troublesome. In addition, since the water depth and pressure change especially due to the ebb and flow of the tide, the travel time varies greatly depending on the travel time even on the same course. Conventional pressure gauges could not obtain such data. The present invention has been made in view of the above circumstances, and when moving a plurality of arbitrary points, an electronic type that can grasp the moving time between points and the surrounding environmental condition at the time of movement in order from the dive start An object is to provide a pressure measuring device.

[0004]

Means for Solving the Problems In order to achieve the above object, the present invention provides a time measuring means for counting a reference clock signal to obtain current time information, and a pressure detecting means for outputting pressure data according to the pressure. Pressure data generating means, display means for displaying the pressure data output from the pressure data generating means, storage means having a plurality of storage areas for storing the pressure data and the time information, and storage means of the storage means. An address counter for addressing a plurality of storage areas, a mode switch for switching between a write mode for writing the pressure data and the time information to the storage means and a read mode for reading from the storage means, and a first operation switch. Means and the address counter is incremented each time a switch operation is performed by the first operation switch means in the write mode. Storage control means for sequentially storing the pressure data output from the pressure data generation means and the time information obtained by the timekeeping means in a plurality of storage areas of the storage means, and switching to the reading mode by the mode switching switch. The address counter is incremented each time a switch operation is performed by the second operation switch means in the read mode, the means for presetting the address counter to the initial state when the address operation is performed, and the second operation switch means. And display control means for reading the pressure data and the time information stored in the respective storage areas of the storage means in order of oldness and sequentially switching and displaying them.

[0005]

[Action]

 In the write mode, the address counter is stepped up each time the first switch means is operated, the pressure data and time information at that time are sequentially stored in the memory area addressed by the address counter, and the mode is switched to the read mode. When this is done, the address counter is preset to the initial state, and the address counter is incremented each time the second switch means is operated, and the pressure data and time information stored in the plurality of storage areas of the storage means are read out in the old order. To switch and display sequentially.

[0006]

【Example】

 An embodiment in which the electronic pressure measuring device of the present invention is incorporated in an electronic wristwatch will be described below with reference to the drawings. First, the basic clock circuit outputs an oscillator 1 for generating a reference clock signal, a frequency dividing circuit 2 for dividing a reference clock signal generated by the oscillator 1 to obtain a signal of 1 Hz, and a frequency dividing circuit 2. It is composed of a clock counting circuit 3 for counting 1 Hz signals to obtain time information. The hour and minute time information obtained by the clock counting circuit 3 is passed through the display switching circuit 4 to the time display section of the display device 5. 5c is given and displayed.

Further, the pressure measuring device includes a sensor 6 for detecting the magnitude of pressure, and a detection signal from the sensor 6 is converted into a digital signal via an A / D (analog / digital) converter 7. The data is successively latched in the latch 8 as pressure data. The pressure data from the latch 8 is displayed on the pressure display section 5a as the current pressure data A ₁ via the display switching circuit 9 and the unit converter 10.

The pressure data from the latch 8 is written to a designated address of the address counter 12 in the pressure data area 11 a of the RAM (random access memory) 11 when a write signal from the AND gate 13 is applied. At this time, the time data from the total clock number circuit 3 is simultaneously written in the time data area 11b at the same address. The RAM 11 in which this writing is performed has a storage area from 1 to 5, and is capable of storing a maximum of 5 pressures at that time. The pressure data and time data read from the RAM 11 are stored as pressure data A ₂ and storage time data T ₂ via the display switching circuit 9, the unit converter 10 and the display switching circuit 4, and the pressure display section 5a and It is displayed on the time display section 5c. 1 in S ₁ is a read-write changeover switch for switching a mode for writing pressure data in RAM 11, and a mode for reading from RAM 11 the pressure data written, TFF from the one-shot circuit 14 by turning on the reading and writing change-over switch S ₁ One pulse is given to the (trigger flip-flop) 15, its Q output and bar Q output can be inverted, and when the Q output of the TFF 15 is "1" (binary level hi gh state), the read mode is set, When the bar Q output is "1", the writing mode is set. Further, the Q output of the TFF 15 is given to one input terminal of the AND gate 16, and when the Q output is "1", the switch S ₁ is operated to output one pulse from the one-shot circuit 14. The output is applied as a clear signal to the RAM 11 via the AND gate 16 and also applied to the address counter 12 of the RAM 11 as a clear signal. The bar Q output is applied to one input terminal of the AND gate 13.

[0009] S ₂ causes the storage up to five pressure value at that time by the on operation in the write mode, the read mode is a set switch for displaying the pressure value the stored sequence, the set switch S ₂ When turned on, one pulse is given from the one shot circuit 17 to the address counter 12, the specified address of the RAM 11 is incremented, and one pulse is also given to the one shot circuit 18, and the one pulse output of the one shot circuit 18 is written. In the mode, the write signal is given to the RAM 11 via the AND gate 13.

S ₃ is a maximum / minimum value measurement switch for measuring the maximum value and the minimum value of the pressure within a fixed time from the first turning on to the next turning on, and by turning on this switch S ₃ . One pulse is given from the one-shot circuit 19 to the TFF 20, and its Q output can be inverted to "1" and "0" (low state of binary logic level), and when this Q output becomes "1", The "1" output is given to the minimum value comparator 21 and the maximum value comparator 22 as an operation command signal.

S ₄ is a time setting switch for setting the time when the pressure measurement is performed at the current time or a desired time, and when the switch S ₄ is turned on, one pulse is sent from the one-shot circuit 23 to the setting circuit 24. The setting circuit 24 gives a correction signal to the time counting circuit 3 and the measurement time area 25b of the measurement register 25 to set the measurement time.

S ₅ indicates the display contents of the display device 5 at the current time and the current pressure (a mode), the time when the set switch S ₂ is operated and the pressure at that time (b mode), the measurement time and the current time. pressure (c mode), a display changeover switch for switching the respective maximum pressure and time at that time (d mode) and minimum pressure time when the and its (e mode), the one-shot circuit 26 by turning on the switch S ₅ From this, a circulation pulse is applied to the circulation counter 27, and the display switching signals a to e are sequentially output to the display switching circuits 9 and 4 to perform data selection and display switching. Of the switching signals a to e, the switching signals a and c are also given to the setting circuit 24, and switching control of the output of the correction signal is performed when setting the time.

S ₆ is a unit for switching and displaying the pressure value displayed on the pressure display unit 5 a and the unit display unit 5 b of the display device 5 in water depth (m), water pressure (kg / cm ² ) and altitude (m). This is a switching switch. When the switch S ₆ is turned on, one pulse is given from the one-shot circuit 28 to the ternary circulation type counter 29, and unit switching signals 0 to 2 are sequentially output to the unit converter 10 to output pressure data. Is converted into corresponding numerical data of water depth, water pressure, and altitude and displayed on the pressure display section 15a, and the same unit switching signal is also output on the unit display section 5b of the display unit 5 to display m, kg / cm ² The corresponding unit display of is displayed.

The measurement time data T ₃ preset in the measurement time area 25b of the measurement register 25 is given to the coincidence circuit 30 together with the current time data from the total clock number circuit 3, and the current time coincides with the measurement time. Then, a coincidence signal is output from the coincidence circuit 30 and given to the AND gate 31 as an opening signal, and the pressure data from the latch 8 is preset in the pressure area 25a of the measurement register 25 via the opened AND gate 31. . The pressure data A ₃ and the time data T ₃ from the timer register 25 are also displayed on the pressure display section 5a and the time display section 5c via the display switching circuits 9 and 4 and the like.

Maximum pressure data A ₄ from the maximum pressure area 32 a of the maximum value register 32 is stored in the maximum value comparator 22 that is driven by turning on the maximum / minimum value measurement switch S ₃ and the current value from the latch 8 is output. It is given together with the pressure data A ₁ , and when the current pressure data A ₁ becomes larger than the maximum pressure data A ₄ , a rewriting signal is output from the maximum value comparator 22 and given to the AND gates 33 and 34 as an opening signal. Through the opened AND gates 33 and 34, the pressure data from the latch 8 and the time data from the clock counting circuit 3 are preset in the maximum pressure area 32a and the maximum time area 32b of the maximum value register 32, respectively. It The maximum pressure data A ₄ and the maximum time data T ₄ from the maximum value register 32 are also displayed on the display device 19 via the display switching circuits 9 and ₄ and the like.

The minimum pressure data A ₅ from the minimum pressure area 35 a of the minimum value register 35 is supplied to the minimum value comparator 21 which is driven by turning on the maximum / minimum value measurement switch S ₃ and the current value from the latch 8 is output. It is given together with the pressure data A ₁ , and when the current pressure data A ₁ becomes larger than the minimum pressure data A ₅ , a rewriting signal is output from the minimum value comparator 21 and given to the AND gates 36 and 37 as an opening signal. The pressure data from the latch 8 and the time data from the clock counting circuit 3 are preset in the minimum pressure area 35a and the minimum time area 35b of the minimum value register 35 through the opened AND gates 36 and 37, respectively. It The minimum pressure data A ₅ and the minimum time data T ₅ from the minimum value register 35 are also displayed on the display device 5 via the display switching circuits 9 and 4 and the like.

Next, the operation of this embodiment will be described. Now, it is assumed that the electronic pressure measuring device of this embodiment is used as a depth gauge for diving. First, by turning on the unit changeover switch S ₆ to output unit switching signal "0" from the counter 29, the display unit display section 5b is "m" is displayed, by turning the display switching switch S _5, the counter The display switching signal a is output from 27 to the display switching circuits 9 and 4. Then, the current pressure data A ₁ latched in the latch 8 from the sensor 6 through the A / D converter 7 is converted into water depth data by the unit converter 10 via the display switching circuit 9 and displayed on the pressure display section 5a. Is displayed. At the same time, the current time data T ₁ from the total clock circuit 3 is also displayed on the time display section 5c via the display switching circuit 4. Thus, as shown in FIG. 2A, the current time and the pressure indicated by the water depth are displayed on the display device 5 every moment.

In the case of diving and measuring and storing the water depth at a predetermined point, first, the read / write selector switch S ₁ is turned on to output one pulse from the one-shot circuit 14 to the address counter 12 and then the address counter. At the same time, 12 is cleared to "0", the Q output of the TFF 15 becomes "1" and the one pulse is also output to the RAM 11 through the opened AND gate 16 to clear the contents of the RAM 11. At the same time, one pulse from the one-shot circuit 14 is also given to the TFF 15, the bar Q output of the TFF 15 is inverted to "1" and given to one input terminal of the AND gate 13.

In this state, if the set switch S ₂ is turned on at a point where the water depth is 7.5 m, for example, one pulse is applied from the one-shot circuit 17 to the address counter 12, and the content is incremented by one. Further, a write signal is given to the RAM 11 through the AND gate 13 through the one-shot circuits 17 and 18, and the pressure data corresponding to the water depth of 7.5 m from the latch 8 at this time and the afternoon from the clock counting circuit 3. The time data of 3:10 is written in the areas 11a and 11b of the address "1". When the set switch S ₂ is further operated, the address counter 12 is stepped up, the write signal is given to the RAM 11, the data is sequentially written after the next address of the RAM 11, and up to 5 data are written. Can be remembered.

In order to read and display the data set in the RAM 11, the read / write switching switch S ₁ is turned on again to give one pulse to the TFF 15 from the one-shot circuit 14 to invert the bar Q output to “0”, The AND gate 16 is closed and switched to the read state so that the write signal is not given to the RAM 11. Then, the display changeover switch S ₅ is turned on, and the display changeover signal b is output from the counter 27 to the display changeover circuits 9 and 4. When the set switch S ₂ is turned on, the display pressure is switched between the stored pressure data A ₂ indicating the pressure corresponding to the water depth of 7.5 m read out from the first address of the RAM 11 and the storage time data T ₂ indicating 3:10 pm. It is displayed on the display device 5 through the circuits 9 and 4 as shown in FIG. If the set switch S ₂ is further turned on, the address counter 12 is incremented, so that the stored pressure data A ₂ and the storage time data T _{2 at} each address are switched and displayed one after another.

In this way, the pressure data once stored and the time data at that time can be recalled and displayed at any time, and there is no need to bother to remember them or make a memo in a notebook.

To automatically memorize the pressure data at a preset time, the display changeover switch S ₅ is turned on in advance and the display changeover signal c is given to the display changeover circuits 9 and 4 from the counter 27 to display the display device. 5, the contents of the measurement time area 25b of the measurement register 25 are displayed, the time setting switch S ₄ is turned on, and a correction signal is given from the setting circuit 24 to the measurement time area 25b to preset the desired time, for example, 3:00 pm. Keep it. Then, the preset pm 3:00 measurement time data T ₃ is provided on one致回path 30, because they present time data also provided for a total coincidence circuit 3 in the coincidence circuit 30, the current When the time coincides with 3:00 pm, a coincidence signal is given to the AND gate 31 to be opened, and if the pressure data from the latch 8 at that time, for example, a pressure corresponding to a water depth of 8 m, the data is written in the pressure area 25a. In this way, the pressure data at the measurement time can also be stored.

In order to read and display the pressure data A ₃ , the display changeover switch S ₅ is turned on and the display changeover signal c is given from the counter 27 to the display changeover circuits 9 and 4. As a result, the pressure data A ₃ and the time data T ₃ from the measurement register 25 are selectively output to the display device 5, and the timer time 3:00 pm and the pressure 8.0 m at that time are displayed as shown in (c) of FIG. Will be displayed.

Furthermore, in order to automatically memorize the maximum pressure data and the minimum pressure data within a fixed time, the maximum / minimum value measurement switch S ₃ is first turned on at the beginning of the time when the measurement is to be performed. The Q output of the TFF 20 is set to "1" through and the minimum value comparator 21 and the maximum value comparator 22 are driven to operate. Then the maximum value comparator 2 2 begins to now compare the pressure data A ₁ from the pressure data A ₄ and latch 8 from the maximum pressure area 32a of the maximum value register 32, the direction of current pressure data A ₁ size In this case, a write signal is given to the AND gates 33 and 34 to open it, and the current pressure data A ₁ and the current time data T ₁ at that time are written in the maximum value register 32. Thus, if the current pressure data A ₁ is still larger than the maximum pressure data A ₄ previously written in the maximum value register 32, the large pressure data is rewritten as new maximum pressure data A ₄ .

At the same time, similarly, between the minimum value comparator 21 and the minimum value register 35, if the current pressure data A ₁ is still smaller than the minimum pressure data A ₅ written in the previous minimum value register 35, it is smaller. Rewrite the pressure data as new minimum pressure data A ₅ . Then, when the maximum / minimum value measuring switch S ₃ is turned on again, the Q output of the TFF 20 becomes “0”, so that the comparison operations of the maximum value comparator 22 and the minimum value comparator 21 are stopped.

In order to read and display the maximum pressure data A ₄ and the minimum pressure data A ₅ , the display changeover switch S ₅ is turned on, and the display changeover signals d and e are given from the counter 27 to the display changeover circuits 9 and 4. When the signal d is given, the maximum pressure data A ₄ and the maximum time data T ₄ from the maximum value register 32 are selectively output to the display device 5, whereby the maximum pressure A ₄ and the maximum pressure data T ₄ are output as shown in FIG. The water depth value of 15m and the time when this maximum pressure was recorded are displayed at 2:38 pm. When the signal e is given, similarly, as shown in (e) of FIG. 2, 0 m showing the minimum pressure and the time 2:00 pm at that time are displayed.

In this case, the pressure display based on the water depth (m) can be changed to the water pressure (kg / cm ² ) display by operating the unit changeover switch S ₆ , and the altitude (m) can be displayed while climbing or flying. You can also switch to the display.

In the above embodiment, the pressure data to be stored are the one when the set switch S _{2 is} turned on, the one at the measurement time, and the maximum pressure and the minimum pressure within a fixed time. The average pressure may be memorized by sampling the pressure data from the memory at every fixed cycle and storing it, and then dividing it by the number of samplings. Good. Further, the pressure to be measured may be not only water pressure and atmospheric pressure but also wind pressure, water flow pressure and the like.

[0029]

[Effect of device]

 In the present invention, for example, the depths and arrival times of a plurality of points can be easily stored in a dive, and the display can be switched in order from oldest to newest. Not only can it be grasped, but since the data is always displayed in the order of oldness, it is possible to grasp it in order exactly from the beginning of the dive. In addition, it is possible to easily compare and compare the water depth and the travel time, and it is possible to know information about how long the water takes to travel between the predetermined points and how long it takes. In addition, after storing multiple pressure data, if you do not know which pressure data is which pressure data at which point, for example, if you remember what time you were at which point, you can use the time information. It is possible to know at which point the pressure data to be applied is pressure data.

[Brief description of drawings]

FIG. 1 is an overall circuit diagram of an electronic pressure measuring device of the present invention.

FIG. 2 is a diagram showing a transition of display when a display changeover switch S ₅ is operated.

[Explanation of symbols]

3 Count Clock Circuit 5 Display Device 5a Pressure Display Section 5b Unit Display Section 6 Sensor 11 RAM 21 Minimum Value Comparator 22 Maximum Value Comparator 25 Measurement Register 30 Matching Circuit 32 Maximum Value Register 35 Minimum Value Register S ₁ Read / Write Switch S ₂ Set switch S ₃ Maximum / minimum value measurement switch S ₄ Time set switch S ₅ Display changeover switch S ₆ Unit changeover switch

Claims (1)

[Scope of utility model registration request] 1. A time measuring means for counting a reference clock signal to obtain current time information, a pressure data generating means for detecting pressure and outputting pressure data corresponding to the pressure, and a pressure data generating means for outputting the pressure data. Display means for displaying pressure data, storage means having a plurality of storage areas for storing the pressure data and the time information, an address counter for addressing the plurality of storage areas of the storage means, the pressure data and the time A mode switching switch for switching between a writing mode for writing information in the storage means and a reading mode for reading information from the storage means; a first operation switch means; and a switch operation by the first operation switch means in the write mode. Each time it is done, the address counter is incremented so that the pressure data generating means is stored in a plurality of storage areas of the storage means. Storage control means for sequentially storing the output pressure data and time information obtained by the time measuring means; means for presetting the address counter to an initial state when the read mode is switched by the mode changeover switch; Second operation switch means, and pressure data stored in respective storage areas of the storage means by incrementing the address counter each time the switch operation is performed by the second operation switch means in the read mode. An electronic pressure measuring device comprising: display control means for reading out time information in the order of oldness and sequentially switching and displaying.