JPH1120787A - Information processing device for diver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To lead out and inform of required information for protecting a diver from oxygen sickness by providing a permissible depth value lead out means leading out a divable depth value in the respiration air of a set mixing ratio and a display means displaying the permissible depth value led out by the permissible depth value lead out means. SOLUTION: A permissible depth value lead out means 93 leads out a divable permissible depth value 907 in the respiration air of a set mixing ratio based on the setting result by a mixing ratio setting means 94. The permissible depth value lead out means 93 can be realized as the function of a control part. In leading out the permissible depth value 907 from the oxygen mixing ratio of the respiration air, since oxygen sickness occurs when respiration oxygen partial pressure 906 exceeds a permissible oxygen partial pressure value, the permissible depth value lead out means 93 computes a diving depth position where the respiration oxygen partial pressure exceeds the permissible oxygen partial pressure value from the elected oxygen mixing ratio via the mixing ratio setting means 94 by an operating formula. The obtained permissible depth value 907 can be displayed on the liquid crystal display panel of a display part 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information processing apparatus for divers, also called a dive computer. More specifically, the present invention relates to a technique for deriving and notifying information for protecting a diver from oxygen sickness caused by oxygen in respiratory air in such an information processing apparatus.

[0002]

2. Description of the Related Art For a method of calculating decompression conditions after diving performed in a diver's information processing apparatus called a dive computer, see "DIVE COMPUTERS A CONSUMER'S GUIDE TO HISTORY," written by KEN LOYST et al.
THEORY & PERFORMANCE ') Watersport Publishing Inc.
(1991). For literature on the theory, see AA Buhlmann's "Decompression-Deco
mpression Sickness ", Springer, Berlin (1984). Both of these documents suggest that an inert gas such as nitrogen in the respiratory gas dissolved into the body by diving may become a bubble in the body and cause decompression sickness. From the standpoint of more reliably preventing decompression sickness, AABu
hlmann's "Decompression-Decompression Sicknes
s ", Springer, Berlin (1984), pp.14.

Therefore, in the conventional divers information processing apparatus, the amount of inert gas in the body is grasped from the above theory, and after the dive is completed, when the body reaches the land, the amount of the inert gas in the body returns to the equilibrium value on land. Is displayed (inert gas discharge time in the body). Therefore, divers who saw this display should take a rest on land only for an appropriate amount of time before resuming diving, so they should dive multiple times a day without suffering from decompression sickness. Can be.

[0004]

As described above, in the conventional information processing apparatus for divers, the amount of inert gas in the body is monitored from the viewpoint of protecting the diver from decompression sickness. The condition that arises is not limited to decompression sickness. That is, when the respiratory oxygen partial pressure in the respiratory gas is too high, the diver suffers from so-called oxygen sickness.
In particular, when a respiratory gas having a mixture ratio of oxygen larger than that of air is used for diving for a long period of time, oxygen sickness tends to occur more easily than decompression sickness.

In view of the above problems, an object of the present invention is to provide a divers information processing apparatus that can derive and notify information necessary for protecting a diver from oxygen sickness.

[0006]

In order to solve the above-mentioned problems, in the information processing apparatus for divers according to the present invention, the mixture ratio of oxygen and inert gas of breathing gas used for diving is set to a predetermined value from outside. Mixing-ratio setting means for performing the setting, mixing-ratio setting means for obtaining a depth-of-water value that can be diverted by breathing air having a set mixing ratio, Display means for displaying the allowable water depth value derived by the means.

According to the present invention, the oxygen mixing sickness is considered to occur when the respiratory oxygen partial pressure exceeds the allowable oxygen partial pressure. Based on the above, it is calculated at which depth position the respiratory oxygen partial pressure exceeds the allowable oxygen partial pressure value when diving into the water at this mixture ratio. That is, the permissible water depth deriving means obtains the permissible water pressure from the following equation: permissible water pressure = (permissible oxygen partial pressure value / mixing ratio of oxygen in respiratory gas) −atmospheric pressure indicate. Therefore, the diver does not suffer from oxygen sickness as long as he or she dives within the permissible dive time corresponding to the breathing air having the selected oxygen mixture ratio within the permissible water depth.

Further, in the information processing apparatus for divers according to the present invention, there is provided a water pressure measuring means for measuring a water pressure, and a device for externally setting a mixture ratio of oxygen and inert gas of respiratory gas used for diving to a predetermined value. Mixing ratio setting means, oxygen partial pressure deriving means for deriving the respiratory oxygen partial pressure at the current water depth position based on the setting result of the mixing ratio setting means and the measurement result of the water pressure measuring means, and the oxygen partial pressure Display means for displaying the respiratory oxygen partial pressure at the current water depth position derived by the derivation means.

[0009] Similarly, in the present invention, the oxygen partial pressure deriving means determines the oxygen partial sickness when the respiratory oxygen partial pressure exceeds the allowable oxygen partial pressure. Based on the measurement result of the water pressure measuring means, for example, the following formula is used to obtain the respiratory oxygen partial pressure from the respiratory oxygen partial pressure = (current water pressure + atmospheric pressure) x the mixing ratio of oxygen in the respiratory air and display it. Means display. Therefore, the diver selects the mixing ratio and diving position of oxygen in the respiratory gas so that the respiratory oxygen partial pressure is equal to or less than the allowable oxygen partial pressure value, and as long as diving within the corresponding allowable diving time,
No oxygen sickness.

In the present invention, the oxygen partial pressure determining means for determining whether or not the respiratory oxygen partial pressure at the current water depth position exceeds the allowable oxygen partial pressure value based on the derived result of the oxygen partial pressure deriving means, If the respiratory oxygen partial pressure at the current water depth position exceeds the allowable oxygen partial pressure value as a result of the determination by the oxygen partial pressure determining means, the notifying means notifies the user of the fact. It is preferable to warn the user to change the mixing ratio of oxygen in the respiratory gas and the diving position, because the person suffers from oxygen sickness as it is.

In the present invention, the oxygen partial pressure determination means is configured to determine whether or not the current respiratory oxygen partial pressure exceeds a warning value obtained by multiplying the allowable oxygen partial pressure value by a safety factor, If the respiratory oxygen partial pressure at the current water depth position exceeds the warning value in the determination result of the oxygen partial pressure determining means, the notifying means is configured to notify that effect, so that the diver can be more sick from oxygen sickness. It is preferable to secure it.

In the present invention, furthermore, a timer means for measuring the passage of time, a respiratory oxygen partial pressure to date derived from the measurement result of the timer means and the respiratory oxygen partial pressure derived by the oxygen partial pressure deriving means. Dive time deriving means for deriving a time from which dive can be continued based on the temporal change of the dive time, wherein the display means also displays the dive possible time derived by the dive time deriving means. It is preferred that With this configuration, the diver can be notified of information for preventing oxygen sickness after taking in not only the respiratory oxygen partial pressure but also the time factor.

In the present invention, the display means displays the setting result of the mixing ratio setting means, and displays the mixing ratio when the set mixing ratio of oxygen and inert gas is 21:79. Instead, it is preferable to directly display that the respiratory air is air and inform the diver in an easy-to-understand manner.

In the present invention, the mixing ratio setting means includes:
It is preferable that a predetermined mixing ratio is selected from a plurality of mixing ratios set in advance. In this way, the operation is simple from the viewpoint of the method of setting numerical values. Therefore, the mixing ratio setting means can easily switch the setting of the mixing ratio of the breathing gas during the dive. In such a configuration, it is preferable that the mixing ratio setting means is configured so that the plurality of selected mixing ratios can be externally changed to a predetermined value.

In the present invention, when diving is completed in a state where the mixture ratio of oxygen and the inert gas is set to a mixture ratio of oxygen larger than 21:79, the mixture ratio of oxygen in the respiratory air is changed to any one. It is preferable to have a mixture ratio compulsory setting means for automatically setting the mixture ratio to a value larger than the oxygen mixture ratio of the respiratory gas.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. When diving for a long time, it is common to use respiratory gas in which the mixture ratio of oxygen is larger than air and the mixture ratio of nitrogen (inert gas) is smaller than air. In the information processing device for divers,
It is characterized in that when a mixture ratio of oxygen and nitrogen of respiratory gas used during diving is set, useful information for protecting a diver from oxygen sickness is reported in accordance with the input. Therefore, in the following description, first, the basic configuration and operation of the information processing apparatus for divers will be described, and then the above-described features will be described. In addition, as a theoretical document regarding nitrox diving (diving when the mixture ratio of oxygen and nitrogen is changed), Dick Rut
Kowski's "Nitrox MANUAL" describes the effects of oxygen on the human body, oxygen sickness, etc., and also specifies the dive allowable time for the oxygen partial pressure of the respiratory gas.

[Basic Configuration] (Overall Configuration) FIGS. 1A and 1B are plan views showing a part of a device main body and an arm band of a diver's information processing device according to the present embodiment, respectively, and FIG. FIG. 3 is a side view when the apparatus main body is viewed from FIG. FIG. 2 is a block diagram thereof.

In FIG. 1, the diver's information processing apparatus 1 of the present embodiment is also called a so-called dive computer, and measures the amount of nitrogen accumulated in the body during diving (partial nitrogen pressure in the body). Based on the results, the display indicates the rest time to be taken on land after diving. In this information processing apparatus 1 for divers, arm bands 3 and 4 are connected to a 6 o'clock side and a 12 o'clock side of a wristwatch, respectively, with respect to a rectangular apparatus main body 2.
4, it can be worn on the wrist and used like a wristwatch. The apparatus main body 2 has an upper case 21 and a lower case 22 which are fixed in a completely watertight state by screws or the like, and a substrate (not shown) on which various electronic components and the like are mounted is housed inside. ing.

A display unit 10 using a liquid crystal display panel 11 is formed on the upper surface side of the apparatus main body 2, and switches A and B composed of two push buttons are formed on the wristwatch at 6 o'clock. I have. Therefore, the switch operation is easy even during diving. Here, the switches A and B are
As will be described later, the operation unit 5 is used to select and switch each mode performed by the information processing apparatus 1 for divers, and to set various conditions. On the 9 o'clock side of the wristwatch on the upper surface side of the apparatus main body 2, a water entry monitoring switch 30 using a moisture detection sensor for monitoring whether or not diving has started is configured. The water entry monitoring switch 30 includes two electrodes 31 and 32 exposed on the upper surface of the apparatus main body 2, and these electrodes 31 and 32 conduct with seawater or the like, and the resistance between the electrodes 31 and 32 decreases. It is determined that water has entered when the water has entered. However, this water entry monitoring switch 30 is only used to detect that water has entered and to shift to a diving mode described later.
It does not detect that one tying has started. That is, the arm on which the information processing apparatus 1 for divers is mounted may be merely immersed in seawater, and in such a case, it should not be treated as having started diving. Therefore, the information processing apparatus 1 for divers of the present embodiment
Then, it is considered that the diving is started when the water depth (water pressure) is equal to or more than a predetermined value by a pressure sensor (not shown) built in the apparatus main body 2, for example, in this embodiment, the water depth becomes deeper than 1.5 m. And, when the depth becomes shallower than this water depth value, it is considered that the diving has been completed.

As shown in FIG. 2, the information processing apparatus 1 for divers according to the present embodiment includes a liquid crystal display panel 11 for displaying various kinds of information to notify the user, and a liquid crystal driver 12 for driving the same. Display unit 10 (display means)
And a control unit 50 that performs processing in each mode and causes the liquid crystal display panel 11 to perform display according to each mode. For the control unit 50, a switch A,
B and an output from the water input monitoring switch 30 are input.

The diver's information processing apparatus 1 displays the normal time and measures the dive time.
, A clock output from the oscillation circuit 31 is input via the frequency dividing circuit 32, and the time counter 33 constitutes a time measuring means 68 in which time is measured in units of one second.

The diver's information processing apparatus 1 measures and displays the water depth, and measures the amount of nitrogen gas accumulated in the body from the water depth (water pressure) and the dive time. (Semiconductor pressure sensor), an amplification circuit 35 for an output signal of the pressure sensor 34, and an A / D conversion circuit 36 for converting an analog signal output from the amplification circuit 35 into a digital signal and outputting the digital signal to the control unit 50. The water depth measuring means 61 (water pressure measuring means) is constituted. Further, the information processing device 1 for divers is provided with a sound notification device 37 and a vibration generating device 38, which can notify a diver of a warning or the like as an alarm sound or vibration.

In the present embodiment, the control unit 50 includes a CPU 51 for controlling the entire apparatus, and a control circuit 52 for controlling the liquid crystal driver 12 and the time counter 33 under the control of the CPU 51. Each mode, which will be described later, is realized by each process performed by the CPU 51 based on the executed program. RAM5
4 is a memory for recording diving results as log data,
It is used as a working memory when performing various calculations.

(Description of Display Unit) Referring again to FIG. 1A, a plurality of display areas are formed on the display surface of the liquid crystal display panel 11, and the display performed in these display areas is basically as follows. is there. First, the first display area 111 located on the 12 o'clock side of the wristwatch is the largest of the display areas, and includes a diving mode, a surface mode (time mode), a planning mode, and a log, which will be described later. In the mode, the current water depth, the current month and day, the water depth rank, and the diving month and day (log number) are displayed. The second located at 3 o'clock from the first display area 111
In the display area 112, the dive time, the current time, the dive time, and the dive start time (dive time) are displayed in the diving mode, the surface mode (time mode), the planning mode, and the log mode. Third display area 1 located on the 6 o'clock side of first display area 111
13 displays a maximum water depth, a body nitrogen discharge time, a safety level, and a maximum water depth (average water depth) in the diving mode, the surface mode (time mode), the planning mode, and the log mode, respectively. Fourth display area 114 located on the 3 o'clock side of third display area 113
In the diving mode, the surface mode (time mode), the planning mode, and the log mode, the dive time, the water surface stop time, and the dive end time (maximum water temperature at the depth) are displayed. 6 from the third display area 113
In a fifth display area 115 located on the hour side, a power supply exhaustion warning 104 and a high rank 103 are displayed. In a sixth display area 116 located at the 6 o'clock side of the liquid crystal display panel 11, the amount of nitrogen in the body is graphically displayed. A seventh display area 117 located on the 3 o'clock side of the sixth display area 116 displays whether nitrogen (inert gas) tends to be absorbed or discharged when the decompression diving mode is entered in the diving mode. An area that indicates whether there is an object, an area that displays “SLOW” as one of the ascent speed violation warnings that the ascent speed is too fast, and “DECO” as a warning that decompression diving has been reached during diving are displayed. An area is configured.

Further, in the present embodiment, the third display area 11
An area adjacent to the third and fourth display areas 114 on the 6 o'clock side includes an eighth display area 118 and a ninth display area 119. In these display areas, as described later, Information for protecting the diver from oxygen sickness is also displayed based on which value the oxygen mixing ratio is set to.

(Configuration for protecting diver from decompression sickness)
FIG. 3 calculates the amount of nitrogen in the body (the amount of inert gas in the body) in the information processing apparatus 1 for divers of the present embodiment, and derives safety information such as the nitrogen discharge time in the body and the non-decompression diving time based on the result. It is a functional block diagram for.

As shown in FIG. 3, in the diver's information processing apparatus 1, nitrogen contained in respiratory air is absorbed into the body.
In addition, the body nitrogen deriving means 6 for simulating the state of being discharged and calculating the body nitrogen amount (body nitrogen partial pressure) 6
0 is configured. The calculation of the amount of nitrogen in the body described below is merely an example, and various methods can be used. Here, an example will be briefly described.

The body nitrogen amount deriving means 60 first uses a pressure sensor 34, an amplification circuit 35 and an A / D conversion circuit 36 shown in FIG. 61, the CPU 51 shown in FIG.
OM 53, respiratory nitrogen partial pressure calculating means 62 realized as functions of RAM 54, respiratory nitrogen partial pressure storing means 63 using RAM 54 shown in FIG. 2, CPU 5 shown in FIG.
1. Internal nitrogen partial pressure calculating means 64 realized as a function of ROM 53, RAM 54, internal nitrogen partial pressure storing means 65 using RAM 54 shown in FIG. 2, and time measuring means using time counter 33 shown in FIG. 68, C shown in FIG.
Comparison means 6 implemented as functions of PU 51, ROM 53, and RAM 54 and comparing data stored in respiratory nitrogen partial pressure storage means 63 and internal nitrogen partial pressure storage means 65
6, CPU 51, ROM 53, RAM 54 shown in FIG.
The half-saturation time selecting means 67 realized as the function of (1) is constituted.

Among these components, the respiratory nitrogen partial pressure calculating means 62, the internal nitrogen partial pressure calculating means 64, and the comparing means 6
6. The half-saturation time selecting means 67 is the CPU 51, R
Although it can be realized as software by the OM 53 and the RAM 54, it can also be realized by only a logic circuit which is hardware, or a combination of a logic circuit and a processing circuit including a CPU and software.

In this configuration example, the water depth measuring means 61 measures and outputs a water depth P (t) corresponding to time t.

The respiratory nitrogen partial pressure calculating means 62 calculates and outputs the respiratory nitrogen partial pressure PIN ₂ (t) based on the water depth P (t) output from the water depth measuring means 61. The breathing air is air, the oxygen mixture ratio is 21%, and the nitrogen mixture ratio is 7
If it is 9%, the respiratory nitrogen partial pressure PIN ₂ (t) can be calculated by the following equation PIN ₂ (t) = 0.79 × P [bar] from the water depth P (t) during diving.

The respiratory nitrogen partial pressure storage means 63 stores the P calculated by the respiratory nitrogen partial pressure calculating means 62 as
The value of IN ₂ (t) is stored.

The internal nitrogen partial pressure calculating means 64 calculates the internal nitrogen partial pressure PGT (t) for each compartment having a different nitrogen absorption / extraction rate. Taking one compartment example, tissue nitrogen partial pressure PGT absorbing / discharged from dive time t = t ₀ to t _E ((t _E) is, t ₀ o'clock tissue nitrogen partial pressure PGT and (t ₀₎ It is calculated from the dive time t _E and the half-saturation time T _H.

[0034] In the half-saturation time T _H referred herein, as shown in FIG. 4, tissue nitrogen partial pressure PGT (t _E) is under the water depth from t ₀ o'clock tissue nitrogen partial pressure PGT (t ₀₎ In the process of reaching the respiratory nitrogen partial pressure PIIG, the internal nitrogen partial pressure PGT (t
₀ ) and the intermediate pressure between the respiratory nitrogen partial pressure PIIG (half time).

The result is shown in FIG.
It is stored in the body nitrogen partial pressure storage means 65 as PGT (t _E ). The calculation formula for that is as follows.

[0036]

(Equation 1)

Here, k is a constant obtained experimentally.

Next, the respiratory gas nitrogen content is
PIN as a result of the pressure storage means 63 _Two(T) and body nitrogen
PGT (t) as a result of the voltage dividing means 5 is compared, and the result is compared.
As a result, the nitrogen partial pressure gauge in the body
Half saturation time T used in the calculating means 64_HIs variable.

For example, the respiratory gas partial pressure P at t = t ₀
Assuming that IN ₂ (t ₀ ) and the internal nitrogen partial pressure PGT (t ₀ ) are stored in the respiratory nitrogen partial pressure storage means 63 and the internal nitrogen partial pressure storage means 65, respectively, the comparison means 66 determines the PIN ₂ (T ₀ ) and PGT ((t ₀ ) are compared.

The internal nitrogen partial pressure calculating means 64 is controlled by the half-saturation time selecting means 67 as follows.
= T _E , the body partial pressure PGT (t _E ) is calculated.

[0041]

(Equation 2)

[0042]

(Equation 3)

In the above two equations, k is calculated as a constant, T _H2 <T _H1 .

Note that PGT (t ₀ ) = PIN ₂ (t ₀ )
In this case, it is preferable to calculate as half-saturation time _TH = ( _TH2 + _TH1 ) / 2. In addition, these times (t ₀ and t
The measurement of _E ) is managed by the timing means 68 of FIG.

Here, PGT (t ₀ )> PIN
_{When 2} (t ₀ ), nitrogen is excreted from the body, and when PGT (t ₀ ) <PIN ₂ (t ₀ ), nitrogen is absorbed into the body. Changing the half-saturation time at these times means that when nitrogen is discharged, the half-saturation time is long and it takes time to discharge, and conversely, when nitrogen is absorbed, the half-saturation time is It is short and the time required for absorption is short compared to the time required for discharge.

In this way, the simulation of the amount of nitrogen in the body can be performed more strictly. Therefore, if the allowable value of the partial pressure of nitrogen in the body is set, a certain water depth (water pressure)
Time to reach this tolerance (dive time 30
2) and the time required for the internal nitrogen partial pressure to drop to the equilibrium value on the water surface (internal nitrogen excretion time 201) can be accurately obtained. In this manner, the diver's information processing apparatus 1 of the present embodiment includes the dive possible time deriving means 92 and the in-vivo nitrogen discharging time deriving means 91 for deriving the decompressible diving time 302 and the in vivo nitrogen discharge time 201 as diver safety information. It is configured. Here, dive possible time deriving means 92 and body nitrogen excretion time deriving means 9
1 is a CPU 51 and a ROM 5 shown in FIG.
3. It is realized as a function of the RAM 54.

When calculating the respiratory nitrogen partial pressure PIN ₂ (t) based on the water depth P (t) output from the water depth measuring means 61, the respiratory nitrogen partial pressure calculating means 62 will be described later. When using a respiratory gas in which the mixture ratio of oxygen and nitrogen is different from that of air, when the following oxygen mixture ratio is 32% and the nitrogen mixture ratio is 68%, PIN ₂ (t) = 0.68 × P [bar] When the oxygen mixture ratio is 36% and the nitrogen mixture ratio is 64%, the respiratory gas nitrogen partial pressure PIN ₂ (t) is calculated from PIN ₂ (t) = 0.64 × P [bar].

(Explanation of each mode) The information processing apparatus 1 for divers configured as described above has the following modes (time mode ST1, surface mode ST2, planning mode ST3, setting mode ST) described below with reference to FIG.
4. It can be used in diving mode ST5 and log mode ST6). Note that the characteristic operation and display of the diving mode ST5 in the present embodiment will be described later, and FIG.
The display in the eighth display area 118 and the ninth display area 119 is omitted.

(Time Mode ST1) Time Mode ST1
Is a function for carrying on land when no switch operation is performed and nitrogen in the body is in an equilibrium state. The liquid crystal display panel 11 has a current date 100, a current time 101, and an altitude rank 102 (see FIG. 1). ./No mark is displayed when the altitude rank is rank 0.). The altitude rank 102 automatically measures the altitude of the current location and displays the altitude at three ranks. The display of the current time 101 is indicated by the blinking of the colon and the current time 1
01 is notified. For example, in the state shown in FIG. 5, it is displayed that it is 10:06 on December 5 at present.

In the time mode ST1, when the switch A is pressed, the mode shifts directly to the planning mode ST3, and when the switch B is pressed, the mode shifts directly to the log mode ST6. When the switch B is pressed for 5 seconds while the switch A is pressed after the switch A is pressed, the mode shifts to the setting mode ST4.

The time mode ST1, the surface mode ST2 described below, and the planning mode ST
3. In any of the setting mode ST4 and the log mode ST6, when it is detected that water has entered through the water entry monitoring switch 30 shown in FIGS. If it can be confirmed that the above condition is satisfied, the process automatically shifts to the diving mode ST5. At this time, if there is an abnormality in the sensor or the like, the fact is notified by an alarm sound or the like from the sound notification device 37 shown in FIG.

(Surface Mode ST2) The diving information processing apparatus 1 automatically shifts to the surface mode ST2 when the conducting water entry monitoring switch 30 becomes insulated after the end of the dive. The surface mode ST2 is a function for carrying on the land until 48 hours have passed since the last dive. In the surface mode ST2, in addition to the data (current month and day 100, current time 101, altitude rank) displayed in the time mode ST1, an indication of a change in the amount of nitrogen in the body after the end of the dive is displayed. That is, the time until the excess nitrogen dissolved in the body is exhausted and the state of equilibrium is reached is displayed as the body nitrogen exhausting time 201. This body nitrogen excretion time 201
Counts down the time to equilibrium.
After the internal nitrogen excretion time 201 becomes 0 hour and 00 minutes, there is no display. Further, the elapsed time after diving is displayed as the water surface pause time 202, and the water surface pause time 202
In the diving mode ST5, when the water depth becomes shallower than 1.5 m in the diving mode ST5, the timing is started as the end of the diving, and after no more than 48 hours, no display is made. Accordingly, in the diver's information processing apparatus 1, the surface mode ST2 is maintained on land until the elapse of 48 hours after the end of the diving, and thereafter, the time mode S
T1. In addition, in the state shown in FIG. 5, it is displayed that it is 11:58 on December 5 and that 1 hour and 13 minutes have passed since the end of the dive. In addition, it is displayed that the amount of nitrogen dissolved in the body by the diving performed so far corresponds to four in the body nitrogen graph 203,
The time from this state until the body is exhausted with excess nitrogen to reach an equilibrium state (body nitrogen removal time 201) is displayed as, for example, 10 hours and 55 minutes.

In the surface mode ST2, pressing the switch A shifts directly to the planning mode ST3, and pressing the switch B shifts directly to the log mode ST6. When the switch B is pressed for 5 seconds while the switch A is pressed after the switch A is pressed, the setting mode S
Move to T4.

(Setting mode ST4) Setting mode ST4
Is a function for setting ON / OFF of a warning alarm and setting of a safety level in addition to the setting of the date 100 and the current time 101. In this setting mode ST4,
The current month and day 100, year 106, current time 101, safety level (not shown), alarm ON / OFF (not shown), and altitude rank are displayed. Of these items, the safety level is usually And a level for performing a decompression calculation on the premise of moving to a place at an altitude rank one rank higher after diving. The ON / OFF of the alarm is a setting for setting whether or not to sound various warning alarms from the alarm device 37. If the alarm is set to OFF, the alarm does not sound.

In this setting mode ST4, every time the switch A is pressed, the setting items are switched in the order of hour, second, minute, year, month, day, safety level, alarm ON / OFF, and the display of the corresponding portion blinks. I do. At this time, when the switch B is pressed, the numerical value or character of the setting item changes, and when the switch B is continuously pressed, the numerical value or character changes quickly. Alarm ON / O
When the switch A is pressed while the FF is blinking, the mode returns to the surface mode ST2 or the time mode ST1. If neither of the switches A and B is pressed for one to two minutes, the surface mode ST2 or the time mode ST
Return to 1 automatically.

(Planning Mode ST3) The planning mode ST3 is a mode for inputting the maximum water depth and dive time guide for the next dive. In this mode, a water depth rank 301, a dive available time 302, a safety level, an altitude rank, a water surface pause time 202, and a body nitrogen graph 203 are displayed. The display of the ranks of the water depth ranks 301 is sequentially changed from a low rank to a high rank, and the dive time 302 at each water depth rank 301 is displayed. For example, water depth rank 301
Is 9m, 12m, 15m, 18m, 21m, 24m,
27m, 30m, 33m, 36m, 39m, 42m, 4
Switching is performed every 5 seconds in the order of 5 m and 48 m. At this time, if the operation mode has shifted from the time mode ST1 to the planning mode ST3, the initial diving is performed without excessive nitrogen accumulation in the body due to past diving.
03 is 0 and dive time is 3 when the water depth is 15m
02 is displayed as 66 minutes. Therefore, more than 12m in water depth,
It can be seen that non-decompression diving is possible up to less than 66 minutes at 15 m or less. On the other hand, if the mode has shifted from the surface mode ST2 to the planning mode ST3, since the repetitive diving plan has excessive nitrogen accumulation in the body due to past diving, the in-vivo nitrogen graph 203 is 4
If the maximum water depth is 15 m, the dive time 302 is displayed as 49 minutes. Therefore, water depth 12
It can be seen that non-decompression diving is possible up to 49 m and less than 49 m at a distance of 15 m or less. Here, dive time 3
02 has a different value if the nitrogen partial pressure of the respiratory gas changes.
However, in this embodiment, since the nitrogen mixture ratio (oxygen mixture ratio) of respiration may be externally changed for nitrox diving as described later, the nitrogen mixture ratio of the respiratory air which is set at all times can be dived. It is configured to be reflected in the derivation of the time 302.

In the planning mode ST3, if the switch A is pressed for 2 seconds or more before the water depth rank 301 is displayed as 48 m, the process directly shifts to the surface mode ST2. After the depth rank 301 is displayed as 48 m, the mode automatically shifts to the time mode ST1 or the surface mode ST2. Further, when there is no switch operation for a predetermined period, the mode automatically shifts to the surface mode ST2 or the time mode ST1, so that it is convenient because there is no need to perform the switch operation each time. On the other hand, when the switch B is pressed, the mode directly shifts to the log mode ST6.

(Diving Mode ST5) The diving mode ST5 is a mode during diving. In the non-decompression diving mode ST51, the current depth 501, diving time 502,
This function displays information necessary for diving, such as the maximum water depth 503, dive time 302, in-vivo nitrogen graph 203, and altitude rank.

For example, in the state shown in FIG. 5, 12 minutes have passed since the start of the diving, the water depth was 16.8 m, and the fourth display on the liquid crystal display panel 11 shown in FIG. In the area 114, it is displayed that the non-decompression diving can be continued for another 42 minutes at this water depth.
Further, it is displayed that the maximum water depth to date is 20.0 m, and furthermore, the liquid crystal display panel 11 shown in FIG.
In the sixth display area 116, it is displayed that the current amount of nitrogen in the body is at a level at which four marks of the body nitrogen graph 203 are lit.

In the diving mode ST5, since the rapid ascent causes decompression sickness, the current ascent speed is determined every 6 seconds, and the ascent speed is compared with the ascent value corresponding to the current water depth. If the ascent speed obtained this time is faster than the ascent value of the ascent speed, an alarm sound is issued from the sounding device 37 at a frequency of 4 kHz (ascent speed violation warning).
Is displayed in the seventh display area 117 of the liquid crystal display panel 11 shown in FIG. 1A so that the display of “SLOW” and the display of the current water depth are made at a frequency of 1 Hz so that the floating speed is reduced. Flashes alternately to warn of ascent speed violation. Further, the vibration generator 38 warns the diver by vibration that the flying speed is violated. When the ascent speed is reduced to a normal level, the ascent speed warning is stopped.

In the diving mode ST5, when the switch A is pressed, the current time 101 and the current water temperature 504 are displayed as the current time display mode ST52 only while the switch A is kept pressed. In the state shown in FIG. 5, it is displayed that the current time is 10:18 and the water temperature is 23 ° C. Thus, the diving mode ST5
When there is a switch operation to that effect, the current time 101 and the current water temperature are displayed only for a predetermined period,
Even if only the data necessary for diving is always displayed on the small display surface (non-decompression diving mode ST51), the current time 101 can be displayed as needed (current time display mode ST52). It is convenient. Moreover, even in the diving mode ST5, the switch operation is used for switching the display, so that information desired by the diver can be displayed at an appropriate timing.

If the water surface rises to a position shallower than 1.5 m during the diving mode ST5, it is treated as if the diving has been completed, and when the conducting water entry monitoring switch 30 becomes insulated. The mode automatically shifts to the surface mode ST2. During this time, the dive results (diving date, dive time, various data such as maximum depth) are taken as one dive operation from when the water depth becomes 1.5 m or less to when it becomes shallower than 1.5 m. It is stored and held in the RAM 54. In addition, during the current dive, the ascent speed warning
If there is more than one dive, this is also recorded as a diving result.

The diver's information processing apparatus 1 of the present embodiment
Although the configuration is based on non-decompression diving, if a decompression diving condition occurs, the diver is notified with an alarm sound to that effect, and the mode is switched to the following decompression diving display mode ST53. That is, in the decompression diving display mode ST53, the current water depth 501, the dive time 502, the body nitrogen graph 203, the altitude rank, the decompression stop depth 505, the decompression stop time 506, and the total ascent time 50
7 is displayed. In the state shown in FIG.
It is displayed that four minutes have passed and the water depth is 29.5 m. In addition, since the amount of nitrogen in the body exceeds the maximum allowable value and is dangerous, the water depth is 3m while keeping the safe ascent speed.
Is displayed, and an instruction to stop decompression for 1 minute is displayed. Further, an instruction is displayed that a safe ascent speed should take at least 5 minutes to reach the water surface. Further, the fact that the amount of nitrogen in the body is currently increasing is displayed by an upward arrow 508. Then, the diver floats after stopping the decompression based on the above display contents. During the decompression, the downward arrow 509 indicates that the amount of nitrogen in the body is on the decrease.

(Log mode ST6) When the switch B is pressed in the time mode ST1 or the surface mode ST2, the mode directly shifts to the log mode ST6. Log mode S
T6 is a function of storing and displaying various data when diving deeper than 1.5m in the diving mode ST5 for 3 minutes or more. Such diving data is sequentially stored as log data for each dive, and up to 10 log data are stored and retained, and when diving more, older data is deleted in order from the oldest, and the latest 10 dive data are always stored. Diving is stored.

In the log mode ST6, the log data is displayed on two screens switched every four seconds. First
In the screen ST61, the dive date 601 and the average water depth 50
9. The dive start time 603, the dive end time 604, the altitude rank, and the in-vivo nitrogen graph 203 when the dive ends are displayed. On the second screen ST62, a log number 605, which is a dive number on that day, a maximum water depth 608, a dive time 606, a water temperature 607 at the maximum water depth, an altitude rank,
A graph 203 of the in-vivo nitrogen when the diving is completed is displayed. For example, in the state shown in FIG. 5, when the altitude rank is 0, the second dive on December 5 is dive 1
After starting at 0:07, it ends at 10:45,
It is displayed that the dive was for 38 minutes. In the diving at this time, the average water depth was 14.6 m, the maximum water depth was 26.0 m, and the water temperature at the maximum water depth was 23 ° C. After the dive was completed, the nitrogen in the in-vivo nitrogen graph 203 dissolved into the body for four times. Is displayed. As described above, in the log mode ST6, various information is displayed while automatically switching between the two screens, so that a large amount of information can be displayed even if the display surface is small.

In the log mode ST6, if the above-mentioned speed violation warning is given twice or more during the dive displayed this time, the fact is notified, for example, by the liquid crystal display panel 11.
In the seventh display area 117, “SLOW” is displayed.

In the log mode ST6, each time the switch B is pressed, the data is switched from new data to old data, and after the oldest data is displayed, the mode shifts to the time mode ST1 or the surface mode ST2. If the switch B is kept pressed for 2 seconds or more during the operation, the mode shifts to the time mode ST1 or the surface mode ST2. Furthermore, even when neither of the switches A and B is pressed for 1 to 2 minutes, the mode automatically returns to the surface mode ST2 or the time mode ST1, so that it is convenient because there is no need to perform the switch operation each time. On the other hand, when the switch A is pressed, the process directly shifts to the planning mode ST3. As described above, in the present embodiment, direct transition can be made between any one of the planning mode ST3, the surface mode ST2, and the log mode ST6 by a single switch operation.

[Configuration for Protecting Divers from Oxic Sickness] The diver's information processing apparatus 1 of the present embodiment configured as described above has the following configuration for the purpose of protecting divers during diving from oxygen sickness. ing.

First, a diver operates a breathing air MX1 composed of compressed air having a mixing ratio of oxygen and nitrogen of 21:79 and a breathing air MX composed of compressed air having a mixing ratio of oxygen and nitrogen of 32:68.
2. Scuba diving is carried out while carrying a cylinder filled with breathing air MX3 made of compressed air having a mixing ratio of oxygen and nitrogen of 36:64, and a breathing air to be used during diving is selected.

Therefore, in the information processing apparatus 1 for divers according to the present embodiment, as shown in FIG. 3, the mixing for setting the selected information from the outside to the information processing apparatus 1 for divers from the outside. The ratio setting means 94 is configured to derive information (information for protecting the diver from oxygen sickness) corresponding to the currently used respiratory air based on the setting result, and notify the diver of the information. Has become.

At the start of the dive, the breathing air MX1 composed of air is used.
Is most commonly used, the mixing ratio setting means 9
4 is initially set to use the respiratory air MX1 made of air. However, the mixing ratio setting means 94 includes the CPU 51, the ROM 53, the RAM 54, the switch A,
B, the breathing air MX1 made of air is changed from a state in which initial settings are made in the ROM 53 to a diving mode ST as shown in FIG.
Each time the switch B is pressed in 5 (dive), the setting contents are cyclically switched between the breaths MX1, MX2, and MX3 each time, and which breath is finally selected is stored in the RAM 54. You. Therefore, after the setting of the respiratory air is changed, information corresponding to the newly set respiratory air is derived and displayed.

If such conditions are set before the start of diving, the setting mode S described with reference to FIG.
Perform at T4. That is, from the state initially set as the respiratory air MX1, the setting is changed to the respiratory air MX2 or the respiratory air M2.
If it is desired to change the setting to X3, the setting item is set to the breathing air in the setting mode ST4, and in this state, when the switch B is pressed, the breathing air MX2, MX3, and MX1 are sequentially switched each time. Also at this time, information corresponding to the respiratory air newly set in the RAM 54 is derived and displayed instead of the respiratory air MX1 initially set in the R0M53. Therefore, the planning mode S shown in FIG.
Also at T3, it is possible to display the dive time 302 reflecting the oxygen partial pressure of the respiratory gas set from outside.

As shown in FIG. 6, which respiratory gas is selected, the oxygen mixture ratio 90 is displayed on the left side of the eighth display area 118 of the liquid crystal display panel 11 on the display unit 10, as shown in FIG.
5 is displayed. In the state shown in FIG. 6, it is assumed that the respiratory air MX3 has been set and the oxygen mixture ratio is displayed as 36%. However, when the respiratory air MX1 is selected, instead of the oxygen mixture ratio 905, if there is a margin in the number of displayed digits,
"AIR" or the like may be displayed so that the diver can easily recognize that the air has been selected.

Referring again to FIG. 3, in the diver's information processing apparatus 1 according to this embodiment, the current water depth value (water pressure value) measured by the water depth measuring means 61 and the respiratory air MX1, MX2, MX3 An oxygen partial pressure deriving means 95 for deriving a respiratory oxygen partial pressure 906 at the current water depth position based on which breath is selected and set is configured. The respiratory oxygen partial pressure 906 at the current water depth derived by the oxygen partial pressure deriving means 95 is displayed on the display unit 10 in the right side of the eighth display area 118 of the liquid crystal display panel 11 on the display unit 10, as shown in FIG. You. That is, in view of the fact that oxygen sickness occurs when the respiratory oxygen partial pressure 906 exceeds the allowable oxygen partial pressure value, in the present embodiment, the oxygen partial pressure deriving means 95 determines the setting result of the mixing ratio setting means 94 and Based on the measurement result (water pressure value) of the water depth measuring means 61, the following formula is used to obtain the respiratory oxygen partial pressure 906 from the (current water pressure + atmospheric pressure) × mixing ratio of oxygen in the respiratory air. Are displayed on the liquid crystal display panel 11. In the state shown in FIG. 6, the respiratory air MX3 is selected and its oxygen mixture ratio becomes 36.
%, Since the water depth is 16 m at present, the corresponding water pressure value is 1.6 bar, and the atmospheric pressure is assumed to be 1.0 bar, and the respiratory oxygen partial pressure 906 obtained from these values is 0.1 bar. It is displayed as 9 bar. Here, the allowable value of the respiratory oxygen partial pressure 906 is generally set to 1.6 bar from the viewpoint of preventing oxygen sickness. Therefore, the diver has a respiratory oxygen partial pressure 906 of an acceptable value (1.6 bar).
By selecting the oxygen mixing ratio and diving position in the breathing air as follows, and performing proper diving, you can protect yourself from oxygen sickness. The oxygen partial pressure deriving means 95
Are the CPU 51, ROM 53, RAM 54 shown in FIG.
Function.

In the diver's information processing apparatus 1 according to the present embodiment, the current respiratory oxygen partial pressure 906 is set to the allowable oxygen partial pressure value (1.
6 bar), the oxygen partial pressure judging means 96 for judging whether or not the pressure exceeds 6 bar) is constituted.
If the pressure exceeds the allowable oxygen partial pressure value, the diver is notified of the fact as an alarm sound or vibration from the sounding device 37 or the vibration generating device 38, and the respiratory oxygen partial pressure 906 is displayed on the liquid crystal display panel 11. Blinks the display. In this way, a notification unit that notifies a diver that the respiratory oxygen partial pressure 906 exceeds the allowable oxygen partial pressure is realized. The oxygen partial pressure determining means 96 also uses the CP shown in FIG.
It can be realized as a function of U51, ROM53, and RAM54.

In the diver's information apparatus 1 of the present embodiment, the permissible water depth deriving means 93 which derives the permissible water depth 907 that can be dive by the breathing gas of the set mixing ratio based on the setting result of the mixing ratio setting means 94. Is also configured. The allowable water depth deriving means 93 is also provided by the CPU 51 shown in FIG.
It can be realized as a function of the ROM 53 and the RAM 54.

In the present embodiment, in deriving the allowable water depth value 907 from the oxygen mixture ratio of the respiratory gas, it is considered that oxygen sickness occurs when the respiratory gas oxygen partial pressure 906 exceeds the allowable oxygen partial pressure value. , The permissible water depth value deriving means 93,
Any of the respiratory gases MX1, M via the mixture ratio setting means 94
Based on whether X2 or MX3 has been selected, it is calculated from the oxygen mixing ratio of the selected respiratory gas to which water depth position the respiratory oxygen partial pressure exceeds the allowable oxygen partial pressure value. For example, the permissible water depth value deriving means 93 calculates the following equation: permissible water depth value = (permissible oxygen partial pressure value / mixing ratio of oxygen in respiratory gas) −atmospheric pressure water depth conversion value = 1.6bar, the permissible water depth value 907 is obtained, and the value is displayed in the ninth display area 119 of the liquid crystal display panel 11 on the display unit 10. For example, in the state shown in FIG.
Is selected, the oxygen mixture ratio is 36%, and the respiratory oxygen partial pressure allowable value is 1.6 bar. Therefore, it is indicated that there is no oxygen sickness even if diving to a depth of 34m (permissible water depth value 907). Have been.

Further, in the diver's information device 1 of the present embodiment, as described above, the diving possible time deriving means 92 determines how long the dive can be performed at a certain water depth after the current nitrogen content in the body. (A possible diving time 302), and a temporal change in the respiratory oxygen partial pressure up to the present time derived from the measurement result of the timer means 68 and the respiratory oxygen partial pressure 906 derived by the oxygen partial pressure deriving means 95. Is derived from this, a time during which diving can be continued (a dive time 302). Here, the two dive possible times 302 obtained from different viewpoints may be displayed on the liquid crystal display panel 11, but in the present embodiment, the shorter of the two dive possible times 302 is used for the purpose of further enhancing safety. Is displayed. In the present embodiment, when the diving possible time 302 is obtained based on the respiratory oxygen partial pressure 906, the above-described Dick Rutk
The values shown in Table 1 are used with reference to "Nitrox MANUAL" by owski.

[0079]

[Table 1]

The index T of the dive time shown in Table 1
_P means the maximum time during which you can dive without oxygen sickness. For example, if the respiratory oxygen partial pressure 906 is 1.6 bar from the beginning to the end, you can dive for 45 minutes, and the respiratory oxygen partial pressure 906 from the beginning. If the bar is 1.5 bar to the end, the user can dive for 120 minutes, and if the respiratory oxygen partial pressure 906 is 0.5 bar from the beginning to the end, the dive is infinite. Therefore, in this time of diving, so far breathing air oxygen partial pressure 1.6bar, 1.5bar, dive time in ··· t _p each t _1.6 minutes, t _1.5 minutes, -
.., (T _1.6 / T _1.6 + t _1.5 / T _1.5 +...) = Σ (t
_The value determined by _p / T _p ) is regarded as the degree of progression to oxygen sickness, and when the value becomes 1, it is treated as oxygen sickness. Therefore, the oxygen partial pressure deriving means 95 determines how many minutes can be dive at the current respiratory gas and water depth position, that is, the current respiratory oxygen partial pressure P _ox (oxygen mixture ratio × water pressure value). Using the index T _Pox of the dive time of the dive time, the following formula: dive time = T _PoX × [1- (t _1.6 / T _1.6 + t _1.5 / T _1.5 +...)] = T _PoX × [1-Σ ( t _p / T _p )], the dive time 302 is derived, and the value is displayed on the display unit 10
Is displayed in the fourth display area 114 of the liquid crystal display panel 11. This value is the fourth display area 1 of the liquid crystal display panel 11.
At 14, the countdown is performed with the passage of time. The dive time 302 may be displayed as a graph. For example, in the state shown in FIG. 6, if the oxygen mixture ratio is 36% and the water depth is 16 m, that is, if the respiratory oxygen partial pressure 906 is kept at 0.9 bar, the remaining 42%.
It is displayed that even if you dive for a minute (diving possible time 302), you will not suffer from oxygen sickness. Therefore, the diver can dive based on the oxygen mixing ratio 905 of the selected respiratory gas and the dive history in the current dive.
If you observe the above, it can be said that you will not suffer from oxygen sickness.

When the diving is completed in this way,
If the process ends in a state where the respiratory air MX1 is selected as air, the respiratory air MX1 remains in the selected state. Therefore, when diving is performed again using the breathing air MX1, it is not necessary to change the setting again.

On the other hand, in order to ensure safety when diving is resumed when the breathing air MX2 or MX3 having a large oxygen mixture ratio is finished in the selected state,
The information processing apparatus 1 for divers automatically sets the mixing ratio of oxygen and the mixing ratio of nitrogen in the respiratory gas to 99% and 79%, respectively, which are larger than the mixing pressure of any respiratory gas. The ratio forcing setting means 97 is configured. If the mixture ratio of oxygen in the respiratory gas is set to a large value in this way, the information that is erroneously issued when the user forgets to set the correct condition when diving again is that the respiratory oxygen partial pressure 906 is Even if it is less than the allowable value, it is only emitted if it is too large, and there is no problem from the viewpoint of ensuring the safety of the diver.
If you notice a mistake during the dive,
When the switch B is pressed, the state of the respiratory air MX1 is switched to the selected state, so that the correct conditions can be set again during the dive.

As described above, the information processing apparatus 1 for divers according to the present embodiment allows the diver to breathe air MX1,
When switching between MX2 and MX3, the mixing ratio setting means 9
4. Whether the dive mode can be used to dive without causing oxygen sickness during the dive mode ST5 by simply changing the setting in dive mode 4, or to which depth position the dive mode can be used to dive after changing the respiratory mode Is notified to the diver, so that the diver can be protected from oxygen sickness.

[Other Embodiments] In the above embodiment, when the respiratory oxygen partial pressure at the current water depth position exceeds the allowable oxygen partial pressure value, a notification to that effect is given, but the safety is further improved. For this purpose, as shown in FIG. 3, the present respiratory oxygen partial pressure is a warning value obtained by multiplying the allowable oxygen partial pressure value by a safety factor, for example, 0.9 is multiplied by the allowable oxygen partial pressure value. The oxygen partial pressure determination means 96 is configured to determine whether or not the oxygen partial pressure exceeds the warning value in the determination result of the oxygen partial pressure determination means 96 at the current water depth position. In such a case, the sound emitting device 37 or the vibration generating device 38 may be configured to issue a warning to that effect.

In the above embodiment, when the mixture ratio of oxygen and nitrogen is set to a predetermined value from the outside, the respiratory air M
21:79, 32: 6 for X1, 2, 3 respectively
The configuration is such that predetermined values are selected from those set as 8, 36:64, but these selected values themselves are
For example, for each of the respiratory air MX1, 2, and 3,
0:70, 40:60, 50:50 and mixing ratio setting means 9
4 may be configured so that the value can be externally changed to an arbitrary value.

[0086]

As described above, the information processing apparatus for divers according to the present invention derives a water depth value (permissible water depth value) that can be dive by breathing air having a mixture ratio set to a predetermined value from the outside. It is characterized by displaying it. Therefore, the diver does not suffer from the diver's oxygen sickness as long as the diver sees the display and dives below the allowable water depth. In addition, when the respiratory oxygen partial pressure is derived from the respiratory gas of the mixture ratio set to a predetermined value from the outside and the current water depth value and displayed,
Divers should keep the respiratory oxygen partial pressure below the allowable value.
As long as you select the mixing ratio and diving position of oxygen in the respiratory air, you will not suffer from oxygen sickness. Therefore, according to the information processing apparatus for divers of the present invention, the diver can be protected from oxygen sickness.

[Brief description of the drawings]

FIG. 1A is a plan view showing a device main body and a part of an arm band of a diver's information processing device to which the present invention is applied, and FIG. 1B is a view of the device main body viewed from 6:00 on a wristwatch. It is a side view at the time.

FIG. 2 is a block diagram of the entire information processing apparatus for divers to which the present invention is applied.

FIG. 3 is a functional block diagram showing a configuration for deriving and reporting various types of safety information configured in the information processing apparatus for divers to which the present invention is applied.

FIG. 4 is an explanatory diagram showing the meaning of a half-saturation time used in deriving a body nitrogen amount and a body nitrogen excretion time in the information processing apparatus for divers to which the present invention is applied.

FIG. 5 is a flowchart showing functions of a diver's information processing apparatus to which the present invention is applied.

FIG. 6 is an explanatory diagram showing information displayed to protect a diver from oxygen sickness in a diver's information processing apparatus to which the present invention is applied.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Divers information processing apparatus 5 ... Operation part 10 ... Display part (display means) 11 ... Liquid crystal display panel 34 ... Pressure sensor 37 ... Sound emitting device 38 ... Vibration Generator 50 Control part 51 CPU 53 ROM 54 RAM 60 Nitrogen content deriving means 61 Water depth measuring means (water pressure measuring means) 62 Breathing air Nitrogen partial pressure calculation means 63 ・ ・ ・ Respiratory gas nitrogen partial pressure storage means 64 ・ ・ ・ Intracorporeal nitrogen partial pressure calculation means 65 ・ ・ ・ Internal nitrogen partial pressure storage means 67 ・ ・ ・ Saturation time selection means 68 ・ ・ ・ Timekeeping Means 91 ··· Nitrogen discharge time deriving means 92 · · · Diving possible time deriving means 93 · · · Permissible water depth value deriving means 94 · · · Mixing ratio setting means 95 · · · Oxygen partial pressure deriving means 96 · · · Oxygen partial pressure determination means 97 ・ ・ ・ Forced setting of mixing ratio Means A, B ··· switch ST1 ··· time mode ST2 ··· surface mode ST3 ··· planning mode ST4 ··· setting mode ST5 ··· diving mode ST6 ··· log mode

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Satoshi Chiba 3-3-5 Yamato, Suwa City, Nagano Prefecture Inside Seiko Epson Corporation

Claims (11)

[Claims] 1. A mixing ratio setting means for externally setting a mixing ratio of oxygen and inert gas of respiratory gas used for diving to a predetermined value, and based on a result set by the mixing ratio setting means.
Divers having a permissible water depth value deriving means for deriving a water depth value that can be dive with breathing air having a set mixing ratio, and a display means for displaying the permissible water depth value derived by the permissible water depth value deriving means. Information processing device. 2. A water pressure measuring means for measuring water pressure, a mixing ratio setting means for externally setting a mixing ratio of oxygen and inert gas of respiratory gas used for diving to a predetermined value, and the mixing ratio setting means Oxygen partial pressure deriving means for deriving the respiratory oxygen partial pressure at the current water depth position based on the setting result at the above and the measurement result of the water pressure measuring means, and the respiratory oxygen at the current water depth position derived by the oxygen partial pressure deriving means An information processing apparatus for divers, comprising: display means for displaying a partial pressure. 3. An oxygen partial pressure determining means according to claim 2, wherein said oxygen partial pressure determining means determines whether or not a current respiratory oxygen partial pressure exceeds an allowable oxygen partial pressure value based on a derivation result of said oxygen partial pressure deriving means. When the result of the oxygen partial pressure determination means is determined that the respiratory oxygen partial pressure at the current water depth position exceeds the allowable oxygen partial pressure value, there is provided notification means for notifying that fact. Information processing device for divers. 4. The apparatus according to claim 2, wherein the current respiratory oxygen partial pressure exceeds a warning value obtained by multiplying a permissible oxygen partial pressure value by a safety factor based on a result of the derivation by the oxygen partial pressure deriving means. Oxygen partial pressure determining means for determining whether the respiratory oxygen partial pressure at the current water depth position exceeds the warning value as a result of the determination by the oxygen partial pressure determining means. An information processing device for divers, comprising: 5. The method according to claim 2, wherein
Further, based on the setting result in the mixing ratio setting means,
It has an allowable depth value deriving unit that derives a water depth value that can be dive with breathing air having a set mixing ratio, and the display unit is configured to also display an allowable depth value derived by the allowable depth value deriving unit. An information processing device for divers. 6. The method according to claim 2, wherein
Furthermore, based on a time-measuring means for measuring the passage of time, and a time-dependent change in the respiratory oxygen partial pressure up to the present time derived from the measurement result of the time-measuring means and the respiratory oxygen partial pressure derived by the oxygen partial pressure deriving means. And dive time deriving means for deriving a time during which the dive can be continued, wherein the display means is configured to also display the dive time derived by the dive time deriving means. Divers information processing device. 7. The method according to claim 1, wherein
The display means displays the setting result of the mixing ratio setting means, and displays that the breathing air is air when the set mixing ratio of oxygen and inert gas is 21:79. Divers information processing device. 8. The method according to claim 1, wherein
The information processing apparatus for divers, wherein the mixture ratio setting means is configured to select a predetermined mixture ratio from a plurality of preset mixture ratios. 9. The information for divers according to claim 8, wherein said mixture ratio setting means is configured to be able to arbitrarily change said selected plurality of mixture ratios from outside. Processing equipment. 10. The diver's information processing apparatus according to claim 8, wherein the mixing ratio setting means is configured to be able to switch the setting of the mixing ratio of the respiratory gas during diving. 11. The respiratory air according to claim 1, wherein the dive is terminated when the mixture ratio of oxygen and the inert gas is set to be higher than 21:79. An information processing apparatus for divers, comprising: a mixture ratio compulsory setting means for automatically setting a mixture ratio of oxygen to a value larger than a mixture ratio of oxygen of any respiratory gas.