NL9002127A - TIME DETERMINATION DEVICE. - Google Patents

Description

Title: Timing device.

The present invention relates to an apparatus for determining the time in any geographical location in the world relative to the time of any chosen location. The device may be combined with a 24 hour clock mechanism for automatic operation.

Many devices and calculators for determining time in different time zones of the world have been used in the past. However, all of these known organs required some form of calculation, or expert treatment, on the part of the user or a high degree of knowledge and familiarity with the subject or world geography.

U.S. Patent No. 594,410 describes such a device comprising two overlapping cards which rotate together by means of the operation of a 24 hour clock mechanism, one map covering the Southern Hemisphere and the other covering the Northern Hemisphere. However, the use of such overlapping maps creates a high degree of visual confusion and makes it difficult to identify the position of selected cities, or even countries, on such a combination of maps. In addition, the above-mentioned patent does not provide visual coding means by which land areas falling within different time zones can be easily distinguished. Furthermore, the publication does not lend itself easily to marking city names and country names on the maps themselves due to the fact that there are two overlapping maps and therefore several areas have too many associated names to mark on the limited area provided.

The present invention provides an apparatus for determining the time of day at any place in the world, and the apparatus does not have the above-mentioned drawbacks of the prior art. The device can be operated manually or can be automated in the form of a clock. Essentially, the device includes a frame, a rotatable map positioned over it, a first time zone attached to the frame defined by an annular band which is concentrically outwardly concentric with the map and evenly divided into 24 segments, and a second time zone defined by a circumferential ring around the circumference of the card which is evenly divided into 24 segments. The map is a South Pole projection of the world and can be rotated manually or by a clock mechanism about the central point corresponding to the South Pole. Preferably, an hour hand is also provided for the manual embodiment. For both manual and automated embodiments, the hour hand rotates clockwise along with the chart. Each of the segments of the first time zone on the frame corresponds to a specific hour of a consecutive 24 hour time period. The respective hour is printed in the center of the sector. Preferably, when a 12-digit scale is used, the abbreviations a.m. and p.m. are recommended to distinguish day hours from night hours. Each of the segments of the second time zone on the periphery of the map are visually separated. Preferably they are color coded. These segments are centered on the long lines, 15 ° apart (corresponding to an hour).

The geographic time zones consist of countries of longitude with the same local hour. For practical reasons, they are typically separated from neighboring countries by conventions (eg territorial, state or economic). Land areas of the map are also visually encoded to correspond to a neighboring sector of the second time zone. Thus, every second time zone has an associated geographic time region. The map must be rotated to align the sector of the second time zone with the sector of the first time zone to set the (known) local time of the selected geographical area. Thus, by associating sectors of the first and second time zones, the time of all geographical areas can be determined by the visual coding. In a preferred embodiment of the invention, operation of the device is automated by means of a 24 hour clock mechanism, with the hour hand of the clock mechanism moving with the map (i.e., the map rotates together with the hour hand).

To reset / set the zone, (ie when re / installing the device in a selected geographic area), the hour hand must be positioned in the center of the sector of the second time zone which is color coded as the selected geographic area) ie the area of re / location). A stop mechanism allows the hour hand to be rotated counterclockwise for re / positioning. The map will not rotate counterclockwise with the hour hand.

To set the time, the hour, minute, and second hands should be positioned as desired as with any known clock, according to the local time. The map will rotate clockwise with the hour hand.

Another preferred embodiment relates to a manually operated device. In this case, only an hour hand is provided. To reset / set the zone, the hour hand is rotated counterclockwise as described above. Then the map is rotated together with the hour hand clockwise to the position indicative of the local time.

For both embodiments described above, after resetting the zone and time, the local time of any geographical area can be continuously rejected against the annular band of the first time zone using the visual coding.

Furthermore, the capability is also provided for the creation of a computer database containing the South Pole projection of the world map in the form of a dial, the first and second time zones (using adequate visual coding), hour, minute, and second hands. The clock image can be retrieved from the computer memory and displayed under the supervision of a program, which is also capable of resetting the zone and time as described above.

The manual version can be used as an example in schools for didactic purposes (i.e. to explain to students changes in dates and hours around the world). The automatic embodiment can be used by aviation and maritime companies, in armed forces and in office buildings.

Preferably, the device, manually operable or in the form of a clock, includes additional visual encoders associated with land areas of the map located in half-hour time zones.

The invention will be further elucidated hereinafter by description of preferred embodiments with reference to the drawing, in which:

Fig. 1 illustrates a world time clock device according to the present invention;

Fig. 2 is a perspective view illustrating the stop mechanism for resetting / adjusting the clock hour map (of the zone); and

Fig. 3 is a lateral view illustrating the stop mechanism for resetting the pointer hour chart.

In all the figures, each part is indicated by the same reference numeral. The embodiment of the invention shown in Figures 1 to 3 has been chosen by way of illustration only, and it will be apparent to the reader that other embodiments may be selected if desired, for example, an embodiment that is manually operable.

Reference is now made to Fig. 1, which shows a world time clock device 10 having a frame 15, a rotatable card 50 positioned over it and a first time zone in the form of an annular band 85. The annular band 85 is evenly divided into 24 first time zone sectors. 20, 45, is fixed to the frame 15 and positioned partially beyond the outer boundary of the card 50. A second time zone in the form of a circumferential ring 40, defined on and around the circumference of the map 50, is divided into 24 second time zone sectors 30, 35 at even intervals.

The map 50 is a South Pole projection of the world and, in a preferred embodiment, rotates clockwise about the center point 150 corresponding to the South Pole. A conventional 24 hour clock mechanism 25 is arranged below the card 50 and within the frame 15. The clock mechanism includes an hour hand 60, a minute hand 70 and a second hand 80. The hour hand 60 is fixed on an hour axis 55 along with the rotatable card 50 so that they are rotated together by the conventional (e.g. battery operated) 24 hour clock mechanism 25. Full circle rotation of the hour hand 60, and thereby the chart 50, occurs once every 24 hour period. It should be noted that a map with an Arctic projection is not suitable since the device may not use a conventional clock mechanism operating in a clockwise direction; counterclockwise rotation would be required. A further drawback associated with an Arctic projection map would be the high land concentration around the center of the map.

The 24 first time zone sectors 20 are marked to identify every hour of a 24 hour time period from 12 am to 11 pm. For clarity and improved readability, these hour markers may also include the "NOON" mark in association with the as 12 pm marked first time zone sector and the marking "MIDNIGHT" in association with the first time zone sector marked as 12 am. The hour hand 60 traverses a first time zone sector 20 in an hour. The minute hand 70 rotates once an hour (the same as with conventional 12-hour clocks) and therefore traverses every first time zone sector 20 in two and a half minutes. Similar to the operation of the minute hand 70, the second hand 80 traverses each first time zone sector in two and a half seconds. Accordingly, the time of day as indicated by the clock hands 60, 70, 80 shown in Fig. 1 for all land areas corresponding to the second time zone sector 30 is approximately 4:26:58.5 pm. This is, for example, time in Vancouver, Seattle and Los Angeles.

All land areas of the world are shown on map 50 in a single plane relative to the South Pole. The time zones corresponding to geographic time regions of the map 50 are visually distinguished by color coding. For example, referring to FIG. 1, the color coding chosen for the geographic time region 180, which includes the Canadian province of Manitoba, the US state of Minnesota and down to Louisiana, Mexico, and Central America (shown in FIG. 1 by a dark hue) and, as can be seen from the map 50, this region intersects the longitudinal lines 175 and 185. The second time zone sector 35 is also color-coded with the color red so that all the geographic time regions 180, which are color-coded with the color red, correspond to the red color coded second time zone sector 35. The center of the second time zone sector 35 denotes approximately 6:26:58.5 pm, being positioned between the first time zone sector 45 denoting 6 pm in Figure 1 and a first time sector denoting 7 pm. For any given geographical area, time can be read in a similar fashion. In each quadrant of the map 50, the color chosen for the visual coding of land areas within a geographic time region is not duplicated, to avoid confusion in identifying land areas. The colors can be duplicated in the opposite quadrants without the risk of confusion. Thus, in the embodiment of Fig. 1, it was chosen to also use the color red for a second time zone and its associated land areas diametrically opposed to the second time zone 35 and time regions 180. The time for that geographic time region is approximately 6:26:58. 5 am.

Installing the device 10 for use in the specific geographic area in which the user is located requires two types of settings.

The first step is to set the zone. For this purpose, the hour hand must be rotated counterclockwise while the map is held still, to a position where the hour hand is in the middle of a second time zone of interest (ie the same color as the geographic area of the new location ). The hour hand must be aligned with that respective longitudinal line. This is accomplished by using a stop mechanism as illustrated in Figures 2 and 3. An hour axis 55 has such a length that the disc with the card 50 and the hour hand 60 is received over it. Disk 65 is mounted on the back of the card. Its diameter is smaller than the diameter of the card. The system consists of the card 50 and the disc 65 is mounted to slide over the hour axis. The disc 65 has a flexible lip 75. The disc is rotated with the card 50 and with the hour hand 60 through the hour axis 55 of the clock mechanism 25 in a clockwise direction. At the base of the frame, along the periphery of a central bottom recess 200, a circular row of ratchet teeth 95 is arranged. When the chart moves with the hour axis 55 in a clockwise direction, the lip 75 slides over the ratchet teeth of the circular row of ratchet teeth 95. When it is desired to reset / adjust the zone, the hour hand 60 should be careful rotated counterclockwise to the new desired position in the center of the respective second time zone sector aligned with the central longitudinal line of the new zone. The lip 75 would counteract the rotation of the card 50 because it will be locked between two ratchet teeth.

The second step consists of setting the time and this takes place after the first step is completed. For this purpose, the use of a classic 24 hour clock mechanism will allow the hour hand and minute hand to be rotated clockwise and positioned to show the correct time. The hour hand 60, the minute hand 70 and the second hand 80 will be positioned to indicate the hour, minutes and seconds of that area on the first time zone (bearing in mind that each first time zone position only corresponds to two and half a minute or two and a half seconds).

Referring to Fig. 1, device 10 is set up for use in the preselected geographic land area that Los Angeles in U.S.A. and the hour hand 60 moves to the first time zone position marked "5 p.m.". The device identifies the time in Los Angeles, USA, as being 4:26:58.5 pm The same time applies to all other land areas with the same color coding as the second time zone sector 30, for example, Seattle, USA, or Vancouver, Canada. To determine the time in any other selected geographic land area at this particular time, identify the color associated with that land area, the second time zone sector closest to that area corresponding to that color, and read the time the annular band of the first time zone corresponding to that second time zone sector. For example, referring to Fig. 1, it can be seen that when the time in Alberta, Canada as indicated by the second time zone sector 100 equals 5:26:58.5 p.m., the time in Los Angeles, U.S.A. is one hour earlier, i.e. 4:26:58.5 pm. At the same time, the time in all other country areas of the map can be determined according to the previous procedure.

To account for land areas located in half-hourly time zones, a different or additional visual coder is used to identify such areas. In the embodiment of Fig. 1, vertical lines are used to indicate an area for which the time is half an hour earlier than the neighboring land areas with the same color code. Therefore, India is color coded to be the same color as Pakistan and is also coded by vertical lines to indicate that the time in India is half an hour earlier than that in Pakistan. It can be assumed that embodiments where the base color of half-time zones have been chosen such that their time will be read by adding half an hour to the time of the neighboring land areas of the same color are also conceivable.

The International Date Line 90 marks the date applicable to the geographic areas of the map 50. To illustrate this with reference to Fig. 1, one of Alaska's second time zone sectors is shown to be the first time zone 3:26:58 .5 pm and that the Eastern State of Australia's second time zone sector in the first time zone indicates 10:26:58 am. If the date is January 1 in Ottawa, Canada, the date in Alaska is also January 1, but January 2 in New Zealand. As the applicable a.m. hour on New Zealand falls on the opposite side of the International Date Line from Alaska, the time of this geographic area refers to the day following that of Ottawa, Canada.

Furthermore, circular concentric recesses may be present on the front face of the frame 15; for example a bottom, a middle and an upper space. As shown in Figs. 2 and 3, in the bottom space 200, the circular row of ratchet teeth 95 is fixed along the circumference, as described above for the stop mechanism. The center space 210 includes the circular card 50 so that it can rotate freely (i.e. without touching the walls of this space). The headspace 220 is created to fix the first time zone in the form of the annular band 85. The annular band 85 will preferably partially cover the second time circumferential ring on the card 50 to create a guide for the card in the frame 15 For the automated embodiments of the device, the clock mechanism is arranged below the plane of the frame 15. The hour, minute and seconds axes intersect the front face of the frame to grab the hour hand and the map, the minute hand and the second hand, respectively. As a rear face and front face of the frame, a cover may be provided to protect the clock mechanism.

Although the foregoing specific description is directed to the embodiment shown in Figure 1, the invention is not limited to the described embodiment. Many variations of the specific aspects described above can be made while still falling within the scope of the invention. For example, as stated above, the clock mechanism does not have to be present if, for example, a manually operated pocket device according to the invention is desired instead. In the case of a handheld device, the user may prefer to rotate the frame in a counterclockwise direction relative to the map to set the time zone sectors for a preselected land area, instead of the card, these two modes of operation being equivalent.

Furthermore, the conventional presence of a particular geographical area in a time zone may vary, for political or economic reasons, without changing the scope of the present invention.

Claims (11)

An apparatus for determining the time at any location in the world relative to a selected geographic area, the apparatus comprising: a frame; a circular world map positioned over the frame that is rotatable relative to the frame, the world map, representing a modified South Pole projection of the world, rotating about the central point of said map corresponding to the South Pole, and divided into 24 geographic time areas corresponding to local time, the geographic time areas being color-coded such that the colors of adjacent areas differ; a first time zone defined by an annular band located on the frame concentric with said map, said first time zone evenly divided into hourly marked segments for a calibrated 24 hour clock scale; and a second time zone defined by a circumferential ring located on and around the circumference of the rotatable circular map, said second time zone evenly divided into 24 segments distinguished by a different adjacent color, each second time zone segment being associated with a nearby geographic time area of the same color; wherein by aligning a second time zone segment associated with said selected geographical area with a first time zone segment corresponding to the known local time of the selected geographical area, the local time of said random location in the world can be identified by reading the hour indication on the first time zone adjacent to the second time zone sector associated with said random location in the world. The device according to claim 1, characterized by a 24 hour clock mechanism comprising hour, minute and second hands for reading the time indicated on the first time zone, the hour hand being attached to the map so that the map is rotated through and with the hour hand. Device as claimed in claim 1 or 2, characterized in that the map comprises coding means for geographical areas which are located in half-hour time zones, which coding means comprise additional hatching lines, the time of said half-hour time zones being different by half an hour. first time zone identified time. Device according to claim 1, characterized by a central hour hand; and a stop mechanism, the stop mechanism comprising: a retaining member disposed and rotated on the back face of the circular world map, said retaining member positioned to cooperate with a circular row of ratchet teeth; and said circular row of ratchet teeth mounted on the clock frame for co-operation with the retainer; wherein when the hour hand is manually rotated counterclockwise to reset / adjust the device, the movement of the circular world map is stopped by the retainer held between two ratchet teeth of the circular row of ratchet teeth, and when the hour hand rotated manually clockwise, the circular world map rotates with the hour hand, the retainer sliding over said row of ratchet teeth. The device of claim 2, characterized by a stop mechanism, wherein the stop mechanism comprises: a retainer mounted on the back face of the circular world map and rotated through it, said retainer positioned to cooperate with a circular row of ratchet teeth; and said circular row of ratchet teeth mounted on the clock frame for co-operation with the retainer; wherein when the hour hand is manually rotated counterclockwise to reset / adjust the device, the movement of the circular world map is stopped by the retainer held between two ratchet teeth of the circular row of ratchet teeth, and when the hour hand rotated manually clockwise, the circular world map rotates with the hour hand, the retainer sliding over said row of ratchet teeth. The device according to claim 4 or 5, characterized in that the retaining member comprises a disc concentrically fixed on the rear face of the circular world map, said disc being centrally intersected by an hour axis of a 24 hour mechanism and having a flexible lip is positioned on an exposed plane, so that when the hour hand is rotated counterclockwise to reset / reset the device, the circular world map movement is stopped by the flexible lip located between two ratchet teeth of the circular row of ratchet teeth. is gripped, and when the hour hand is rotated clockwise by the clock mechanism, the circular world map rotates with the hour hand axis, said holding member sliding over the row of ratchet teeth. The stop mechanism suitable for use with the device of claim 1, comprising: a retaining member disposed on the back face of the circular world map and rotated thereby, said retaining member positioned to cooperate with a circular row of ratchet teeth; and said circular row of ratchet teeth mounted on the clock frame for co-operation with the retainer; wherein when a central hour hand attached to the circular world map is rotated counterclockwise to reset / reset the device, the movement of the circular world map is stopped by the retainer interposed between two of the ratchet teeth of the circular row of ratchet teeth is held, and when said hour hand is rotated manually clockwise, the circular world map rotates with the hour hand, the holding member sliding over said row of ratchet teeth. The stop mechanism suitable for use with the device of claim 2, comprising: a retainer mounted on the back face of the circular world map and rotated therethrough, said retainer positioned to cooperate with a circular row of ratchet teeth; and said circular row of ratchet teeth mounted on the clock frame for co-operation with the retainer; wherein when the hour hand is manually rotated counterclockwise to reset / adjust the device, the movement of the circular world map is stopped by the retainer held between two ratchet teeth of the circular row of ratchet teeth, and when the hour hand rotated manually clockwise, the circular world map rotates with the hour hand, the retainer sliding over said row of ratchet teeth. The stop mechanism according to claim 7 or 8, characterized in that the retaining member comprises a disk concentrically fixed on the rear face of the circular world map, which disk is centrally intersected by an hour axis of a 24 hour mechanism and has a flexible lip is positioned on an exposed plane, so that when the hour hand is rotated counterclockwise to reset / reset the device, the circular world map movement is stopped by the flexible lip located between two ratchet teeth of the circular row of ratchet teeth. is gripped, and when the hour hand is rotated clockwise by the clock mechanism, the circular world map rotates with the hour hand axis, said holding member sliding over the row of ratchet teeth. 10. Device as claimed in claim 4, characterized in that the frame is provided with central concentric spaces for accommodating in a spatial relationship the circular row of ratchet teeth in a bottom space, the circular world map in a center space, and the annular band of the first time zone in an upper space; wherein the annular band of the first time zone is arranged in the headspace to partially cover the circumferential ring of the second time zone to create a guide for the circular world map in the frame. The device according to claim 5, characterized in that the frame comprises central concentric spaces for receiving the circular row of ratchet teeth in a bottom space, the circular world map in a center space, and the annular band of the first time zone in an upper space. ; wherein the annular band of the first time zone is arranged in the headspace to partially cover the circumferential ring of the second time zone to create a guide for the circular world map in the frame; and wherein the clock mechanism is attached to the frame so that its concentrically arranged hour, minute, and second axes extend along the center of the frame for engagement with the hour hand with the circular world map, the minute hand, and the second hand, respectively.