JP2010169699A - Device for displaying amount of acquired solar radiation energy - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device for displaying amount of acquired solar radiation energy which can verify a room having a possibility of becoming too hot during summer season, before sunset or a room warmed by the sun in winter season, and to provide a method for displaying the amount of solar radiation energy acquired. <P>SOLUTION: The amount of solar radiation energy acquired from apertures 26 of a building is measured in units of apertures 26 for each period by an acquired solar radiation energy amount measuring section 28. Summer days and winter days which are defined from at least any one from among the temperature, solar radiation quantity, and period are extracted by a summer day extraction part 14 and a winter day extraction part 19. Respective amount of acquired solar radiation energy of summer day and winter day measured by an acquired solar radiation energy amount measuring part 28 is accumulated by an acquired solar radiation energy amount accumulation calculating section 11, and the amounts of solar radiation energy acquired are displayed, together on a drawing of building of a display unit 17 as the amounts of solar radiation energy acquired during the summer season and the winter season. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an acquired solar energy amount display device and an acquired solar energy amount display method for displaying an acquired solar energy amount from an opening represented by a glass window capable of transmitting solar radiation in a building, particularly a residential room. is there.

  Calculate the position of the sun with respect to the opening based on the building location (latitude, lightness), direction of the opening, season, and time, and from the calculation result and information on the sunlight obstacles outside the opening A technique has been proposed in which the position and area of sunshine irradiated to the opening is calculated, the illuminance distribution irradiated through the opening is calculated from the calculation results, and the amount of heat input to the opening surface is calculated. (For example, refer to Patent Document 1).

JP 2000-008476 A

  However, in the above-described conventional example, there is no display that clearly shows the summer heat state and the winter cold state of a room having an opening such as a glass window that can transmit sunlight. For example, there has been a demand for a technology that can easily verify a room that may become too hot on the west (sunlight before sunset) or a room where sunlight from the sun enters the room in winter.

  The present invention solves the above-mentioned problems, and the object of the present invention is to look at the summer heat and the winter cold in a closed room having an opening such as a glass window that can transmit sunlight. The solar radiation energy that can be clearly displayed and that can be easily verified for rooms that may become too hot in the summer, for example, the west (sunlight before sunset) or in the winter It is intended to provide a quantity display device and a method for displaying an acquired amount of solar radiation energy.

  In other words, when the customer tries to build a building, the structure of the opening (glass window) to avoid the excessive heat of each room as much as possible and to get as much sunlight as possible from the winter sun, that is, It was difficult to predict how the window size, type, shading screen, glazing, etc. should be used. In this way, the acquired solar radiation energy amount display device and the acquired solar radiation can make the customer understand what happens to the changes in the state of heat and cold in each room of the building when various combinations of aperture structures and surrounding conditions are converted. It is intended to provide an energy amount display method.

A first configuration of an acquired solar energy amount display device according to the present invention for achieving the above object is an acquired solar energy amount display device that displays an acquired solar energy amount from an opening that can transmit solar radiation, The acquired solar radiation energy amount acquisition means for acquiring the solar radiation energy amount acquired from the opening for each opening unit and for each unit time, and a summer day defined by at least one of temperature, solar radiation amount, and period A summer sun extracting means for extracting, a winter sun extracting means for extracting a winter day defined by at least one of temperature, amount of solar radiation, and period, the summer sun acquired by the acquired solar radiation energy amount acquiring means, and The acquired solar radiation energy amount integrating means for integrating the acquired solar radiation energy amount for each winter day and the acquired solar radiation energy amount integrating means, respectively. The day and the cumulative acquisition solar energy amount of frost days, and having a display means for displaying the Everyone as an acquisition solar energy in the summer and winter.

Moreover, the 2nd structure of the acquired solar radiation energy amount display apparatus which concerns on this invention is the said 1st structure. WHEREIN: The each integrated acquired solar radiation energy amount of the summer day and the said winter day integrated | accumulated by the said acquired solar radiation energy amount integration means Obtained by dividing the total daylight hours of the summer day and the winter day by the total obtained solar radiation energy amount per hour, and the display means obtains per hour The accumulated acquired solar radiation energy amounts per hour calculated on the summer day and winter day respectively calculated by the solar energy amount calculating means are displayed together as the respective acquired solar radiation energy quantities in the summer and winter seasons. The total number of sunshine hours is the number of hours that the sun is out of the horizon over the summer and winter days, that is, the number of hours when the solar altitude is greater than zero.

Moreover, the 3rd structure of the acquired solar radiation energy amount display apparatus which concerns on this invention is the said 1st structure WHEREIN: The several opening part contained in this area | region for every predetermined area | region in the building in which the said opening part was provided The acquired solar radiation energy amount calculating means for adding the respective acquired solar radiation energy amounts for each summer day and winter day acquired from the above, the display means is the summer day and winter day added by the acquired solar radiation energy amount calculating means Each acquired solar radiation energy amount is displayed together as an acquired solar radiation energy amount in summer and winter.

Further, a fourth configuration of the acquired solar radiation energy amount display device according to the present invention is configured to display each acquired solar radiation energy amount in the summer and winter days added by the acquired solar radiation energy amount calculation unit of the third configuration. The accumulated solar radiation energy amount per hour divided by the total number of sunshine hours for each of the summer and winter days is calculated by the solar radiation energy amount calculating unit per hour having the configuration of 2 , and the display unit The amount of solar radiation energy is displayed together as the amount of solar radiation energy acquired in summer and winter.

Moreover, the 5th structure of the acquired solar radiation energy amount display apparatus which concerns on this invention is a building drawing of a computer display screen in the said 1st- 4th structure in which the said display means shows the solar radiation energy amount acquired in the said summer and winter. It is characterized by being displayed together on the top.

Further, in the sixth configuration of the acquired solar radiation energy amount display device according to the present invention, in the first to fifth configurations, the energy acquisition means is a surrounding building that blocks the acquired solar radiation from the opening, or the opening. The acquired solar radiation energy received by the opening is adjusted based on the solar radiation shielding means provided in the section .

Further, in a seventh configuration of the acquired solar radiation energy amount display device according to the present invention, in the sixth configuration, the solar radiation shielding means changes the shielding state of the opening between the summer day and the winter day. It is characterized by being .

Moreover, the first configuration of the acquired solar energy amount display method according to the present invention is an acquired solar energy amount display method for displaying an acquired solar energy amount from an opening that can transmit solar radiation, and includes a temperature, a solar radiation amount, A summer day and a winter day defined by at least one of the periods are extracted, and the amount of solar radiation energy acquired from the opening on the summer and winter days is integrated for each opening unit and for each unit time, The accumulated amount of solar radiation energy accumulated in the summer day and winter day, which are accumulated respectively, is displayed together as the amount of solar radiation energy obtained in summer and winter.

Further, in the second configuration of the acquired solar radiation energy amount display method according to the present invention, in the first configuration, the accumulated solar radiation energy amount of each of the summer day and the winter day is calculated for each of the summer day and the winter day. Calculate the cumulative amount of solar radiation energy acquired per hour divided by the total number of sunshine hours, and calculate the amount of solar radiation energy acquired per hour for each summer day and winter day. As a whole.

Moreover, the 3rd structure of the acquired solar radiation energy amount display method which concerns on this invention is the said 1st structure WHEREIN: The several opening part contained in this area | region for every predetermined area | region in the building in which the said opening part was provided Add the acquired solar radiation energy amounts for each summer day and winter day acquired from the above, and display the added solar radiation energy amounts for the summer and winter days together as the acquired solar radiation energy amounts for the summer and winter seasons. It is characterized by.

Moreover, the 4th structure of the acquired solar radiation energy amount display method which concerns on this invention is the said 1st structure WHEREIN: The several opening part contained in this area | region for every predetermined area | region in the building in which the said opening part was provided The amount of solar energy acquired for each summer day and winter day acquired from the above is added, and the amount of solar energy acquired for each summer day and winter day is divided by the total number of sunshine hours for each summer day and winter day. In addition, the cumulative amount of solar radiation energy acquired per hour is displayed together as the amount of solar radiation energy acquired in summer and winter.

Further, a fifth configuration of the acquired solar radiation energy amount display method according to the present invention is characterized in that, in the first to fourth configurations, the acquired solar radiation energy amounts in the summer and winter seasons are displayed together on a building drawing. And

In addition, in the sixth configuration of the acquired solar radiation energy amount display method according to the present invention, in the first to fifth configurations, the acquired solar radiation energy amount from the opening portion is integrated as the cumulative solar radiation energy amount from the opening portion is integrated. The acquired solar radiation energy received by the opening is adjusted based on the surrounding buildings that block the sun or the solar radiation shielding means provided in the opening .

Further, in a seventh configuration of the acquired solar radiation energy amount display method according to the present invention, in the sixth configuration, the solar radiation shielding means changes the shielding state of the opening between the summer day and the winter day. It is characterized by being .

  According to the first configuration of the acquired solar radiation energy amount display device according to the present invention, for example, an extended AMeDAS that processes weather data of AMeDAS (Automated Meteorological Data Acquisition System), which is an automatic weather observation system installed at about 1300 locations nationwide. By using the weather data, a result obtained by calculating the amount of solar radiation energy acquired from the opening that can transmit solar radiation for each unit of the opening and for each unit time is acquired by the acquired solar energy amount acquisition means.

  On the other hand, a summer day is extracted by the summer day extraction means, and a winter day is extracted by the winter day extraction means. Then, the acquired solar radiation energy amount integrating means can integrate the summer solar acquired solar energy amount extracted by the summer day extracting means, and can also integrate the winter solar acquired solar energy amount extracted by the winter day extracting means.

  The summer day referred to here is the total number of days in which the room becomes too hot in the summer, and the winter day is the number of days in the period including a day that seems to be cold in the winter.

  Then, the accumulated solar radiation energy amounts accumulated in the summer and winter days respectively obtained by the obtained solar radiation energy amount integrating means can be displayed together as the summer solar radiation and winter acquired solar radiation energy quantities.

  As a result, it is possible to clearly display the summer heat state and the winter cold state of an area (such as a room) having an opening such as a glass window through which solar radiation can be transmitted. It is easy to verify areas (rooms) that are likely to be too hot on the west and areas (rooms) where sunlight enters during the winter season.

Also, the summer day extraction means, and whether the horizontal global solar radiation for one day by the weather data is a predetermined value or more, or the average temperature for one day by the meteorological data a day is not less than a predetermined value and summer day By the winter day extraction means, a predetermined period in winter can be set as a winter day.

  Then, the acquired solar radiation energy amount integrating means can integrate the summer solar acquired solar energy amount extracted by the summer day extracting means, and can also integrate the winter solar acquired solar energy amount extracted by the winter day extracting means.

  The accumulated solar radiation energy amounts accumulated in the summer and winter days respectively obtained by the obtained solar radiation energy accumulation means can be displayed together as the summer solar radiation and winter acquired solar radiation energy quantities.

  As a result, it is possible to clearly display the summer heat state and the winter cold state of an area (such as a room) having an opening such as a glass window through which solar radiation can be transmitted. It is easy to verify areas (rooms) that are likely to be too hot on the west and areas (rooms) where sunlight enters during the winter season.

Further, according to the second configuration of the acquired solar radiation energy amount display device according to the present invention, the cumulative solar radiation acquisition for each summer day and winter day integrated by the acquired solar radiation energy amount integration means by the acquisition solar radiation energy amount calculation means per hour. It is possible to calculate the accumulated solar radiation energy amount per hour obtained by dividing the energy amount by the total number of sunshine hours for each summer day and winter day.

  Then, the accumulated solar radiation energy amount per hour for each summer day and winter day calculated by the solar radiation energy amount calculating means per hour is displayed together as the solar radiation energy amount acquired in summer and winter by the display means. I can do it. Thereby, it is possible to display the accumulated solar radiation energy amounts per hour for summer and winter days, which are easy to handle numerical values, as the solar radiation energy amounts acquired in summer and winter.

Further, according to the third configuration of the acquired solar radiation energy amount display device according to the present invention, each summer acquired from the plurality of openings included in the predetermined region (room) in the building by the acquired solar energy amount calculation means. The acquired solar radiation energy amounts for the sun and winter days can be added, and the acquired solar radiation energy amounts for the summer and winter days can be displayed together as the acquired solar radiation energy amounts for the summer and winter seasons. As a result, it is possible to clearly display the summer heat of a region (such as a room) having a plurality of openings and the cold weather in winter, for example, it becomes too hot on the western day in summer. It is easy to verify possible areas (rooms) and areas (rooms) where sunlight enters during the winter season.

Moreover, according to the 4th structure of the acquired solar radiation energy amount display apparatus which concerns on this invention, each solar radiation energy amount of the summer day and winter day which were added by the acquired solar radiation energy amount calculation means is obtained per hour. To calculate the amount of accumulated solar radiation energy per hour divided by the total number of sunshine hours for each summer day and winter day, and use the display means to obtain the amount of solar radiation energy acquired in summer and winter. It can be displayed together as a quantity.

Moreover, according to the 5th structure of the acquired solar radiation energy amount display apparatus which concerns on this invention, the solar radiation energy amount acquired in summer and winter can be displayed on the building drawing of a computer display screen all by the display means. This makes it possible to easily verify changes in the amount of solar radiation energy acquired in summer and winter by displaying the amount of solar radiation energy acquired in summer and winter in correspondence with the structure of the openings on various building drawings. I can do it.

  Moreover, according to the first configuration of the acquired solar radiation energy amount display method according to the present invention, for example, using the extended AMeDAS weather data or the like, a summer day and a winter day are extracted, and each acquired solar solar energy amount for the summer day and the winter day is extracted. Glass window that can transmit solar radiation by displaying the accumulated amount of solar radiation energy accumulated in the summer and winter days in the vicinity of the opening as the amount of solar radiation energy acquired in summer and winter. It is possible to clearly display the summer heat in the area (room, etc.) with the opening and the cold weather in winter, for example, it may be too hot on the western day in summer It is easy to verify the area (room) and the area (room) where sunlight enters in the winter season.

Also, for example, using the extended AMeDAS meteorological data, horizontal global solar radiation of one day by meteorological data is equal to or larger than a predetermined value, or summer day the average daily temperature for one day by the meteorological data is equal to or greater than a predetermined value And the winter period is defined as the winter period. Then, the acquired solar radiation energy amount from the opening on the summer and winter days is integrated for each opening unit and for each unit time, and each integrated acquired solar energy amount for the summer day and winter day is calculated for each summer and winter. By clearly displaying the amount of solar radiation energy acquired during the winter, it is possible to clearly show the summer heat and the winter cold in the areas (rooms, etc.) that have openings such as glass windows that can transmit solar radiation. For example, it is possible to easily verify an area (room) that may become too hot on a western day in summer or an area (room) in which sunlight is inserted in winter.

Further, according to the second configuration of the acquired solar radiation energy amount display method according to the present invention, one hour obtained by dividing the accumulated solar radiation energy amount for each summer day and winter day by the total number of sunshine hours for each summer day and winter day. It is easy to handle by calculating the accumulated solar radiation energy amount per hour and displaying the calculated cumulative solar radiation energy amount for each summer day and winter day as the solar radiation energy amount for summer and winter. It is possible to display the accumulated amount of solar radiation energy obtained in the summer and winter days, which are numerical values, as the amount of solar radiation energy acquired in the summer and winter.

Further, according to the third configuration of the acquired solar radiation energy amount display method according to the present invention, the acquired solar radiation energy amount acquired from each of the plurality of openings included in the predetermined area in the building is obtained for each summer day and winter day. The summer heat of the area (rooms, etc.) with multiple openings is displayed by adding and displaying the acquired solar radiation energy amounts for summer and winter together as the solar radiation energy amounts for summer and winter. And the cold weather in winter can be displayed in a clear contrast, for example in areas (rooms) that may become too hot on the west in the summer or areas (rooms) where the sun goes into the winter Verification is easy.

Further, according to the fourth configuration of the acquired solar radiation energy amount display method according to the present invention, the acquired solar solar energy amount added for each of the plurality of openings is calculated as the total amount of each of the summer day and winter day. The integrated acquired solar radiation energy amount per hour divided by the number of sunshine hours can be calculated, respectively, and each integrated acquired solar radiation energy amount can be displayed together as the acquired solar solar energy amount in summer and winter.

Further, according to the fifth configuration of the acquired solar radiation energy amount display method according to the present invention, the solar radiation energy amount acquired in summer and winter can be displayed on the building drawings all together, and the openings on various building drawings can be displayed. Correspondingly, by displaying the acquired solar radiation energy amount in summer and winter together, it is possible to easily verify changes in the acquired solar energy amount in summer and winter.

It is a block diagram which shows the structure of the control system of the acquired solar radiation energy amount display apparatus which concerns on this invention. It is a figure which shows an example of the weather data of extended AMeDAS in a graph. It is a figure which shows an example of the weather data of extended AMeDAS in a graph. It is a flowchart which shows a mode that verification of the summer and winter of a building is performed by the acquired solar radiation energy amount display apparatus which concerns on this invention. It is a figure which shows a mode that the azimuth | direction where the building was installed is set with the acquired solar radiation energy amount display apparatus which concerns on this invention. It is a figure which shows an example of the image displayed with the acquired solar radiation energy amount display apparatus which concerns on this invention. It is a figure which shows an example of the image displayed with the acquired solar radiation energy amount display apparatus which concerns on this invention. It is a figure which shows an example of the image displayed with the acquired solar radiation energy amount display apparatus which concerns on this invention. It is a figure which shows an example of the image displayed with the acquired solar radiation energy amount display apparatus which concerns on this invention. It is a figure which shows an example of the image displayed with the acquired solar radiation energy amount display apparatus which concerns on this invention. It is a figure which shows an example of the image displayed with the acquired solar radiation energy amount display apparatus which concerns on this invention.

  An embodiment of an acquired solar radiation energy amount display device and an acquired solar radiation energy amount display method according to the present invention will be specifically described with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a control system of an acquired solar radiation energy amount display device according to the present invention, FIGS. 2 and 3 are diagrams showing an example of graphs of extended AMeDAS weather data, and FIG. 4 is a diagram according to the present invention. FIG. 5 is a flowchart showing how to verify the summer and winter of a building with the acquired solar radiation energy amount display device, and FIG. 5 is a diagram showing how to set the direction in which the building is installed with the acquired solar radiation energy amount display device according to the present invention. 6 to 11 are diagrams showing examples of images displayed by the acquired solar radiation energy amount display device according to the present invention.

  In FIG. 1, reference numeral 1 denotes an acquired solar energy amount display device that displays an acquired solar energy amount from the opening 26 in a state where it is shut off so that there is no ventilation at an opening 26 such as a glass window that can transmit solar radiation. Weather data such as solar radiation and outside temperature in the area where buildings such as buildings are built is expanded Amedas that is an unmanned automatic meteorological observation device (Amended Meteorological Dataa Acquisition System) Weather data can be used.

  Expanded AMeDAS meteorological data was created by the Architectural Institute of Japan. It is the enhanced weather data. The contents include 15-year data from 1981 to 1995 with hourly values of air temperature, absolute humidity, horizontal solar radiation, atmospheric radiation, wind direction, wind speed, precipitation, and sunshine hours at 842 locations throughout Japan. Includes standard year data. Standard year data is hypothetical one-year meteorological data obtained by selecting and joining the average year (month) for each month from the 15-year meteorological data. Is. In this embodiment, the temperature in the standard year and the horizontal solar radiation amount are used.

Expanded AMeDAS meteorological data are: hourly temperature in units of 0.1 ° C, average daily temperature in units of 0.1 ° C, horizontal solar radiation over an hour in units of 0.01 MJ / m ² h, 0 .1MJ / m ² d The integrated value for 1 day is included. FIG. 2 shows an annual average temperature in Tokyo as an example of extended AMeDAS weather data, and FIG. 3 shows an average temperature in July-September of Tokyo and an integrated daily solar radiation amount as an example of extended AMeDAS weather data. These expanded AMeDAS meteorological data are stored in an extended AMeDAS weather information database (hereinafter referred to as “EXTENDED AMEDAS MEATHER INFORMATION DB”) 2 provided in the acquired solar radiation energy amount display device 1.

  The calculation device provided in the acquired solar radiation energy amount display device 1 is provided with a solar position calculation unit 3. The sun position calculation unit 3 calculates the position of the target building on the earth (latitude, longitude, address, etc.), the sun position corresponding to the season and time.

  When the position on the earth, season, and time are specified, the position of the sun corresponding to each specified condition is uniquely determined. The position of the sun is the solar altitude (h °; the angle between a line connecting the specific point on the ground and the sun and the horizontal line at the point) and the azimuth angle of the sun (A °; The west direction is positive and the east direction is negative), and can be calculated by the following equation (1).

[Equation 1]
sin (h) = sin (φ) · sin (δ) + cos (φ) · cos (δ) · cos (t)
sin (A) = cos (δ) · sin (t) · sec (h)
Where: h: solar altitude (°), φ: destination latitude (°), δ: solar declination (°), summer solstice δ = 2.45, spring / autumn δ = 0, winter solstice δ = -23.45, t; Hour angle (°), hour angle A at true sun with 15 ° for one hour; azimuth angle (°) of the sun.

  The solar position calculation unit 3 stores a program for solving the above equations and a trigonometric function table. From the input unit 4, as shown in FIG. 5, the latitude, longitude, season and time of the destination where the building to be verified is constructed are stored. When such information is input, the information is temporarily stored in the temporary storage device 5, and when the execution of the program is instructed, the position of the sun according to the conditions specified by the sun position calculation unit 3 is calculated. It is possible. The calculated result can be stored or temporarily stored in the temporary storage device 5.

  Then, the opening 26 surface orientation (α) that is the azimuth of the normal direction of the opening 26 surface of the building at a point having a specific latitude and longitude, and the opening 26 surface that is the inclination angle of the opening 26 surface By setting the inclination angle (θ), it is possible to calculate the opening 26 surface intersection angle (hw), which is an angle formed by the surface of the opening portion 26 and the sun, by the following equation (2).

[Equation 2]
sin (hw) = sin (h) · cos (θ) + cos (h) · sin (θ) · cos (A−α)

  And when the opening part 26 surface crossing angle hw exceeds 90 degrees, the solar radiation will not hit the object opening part 26 surface.

  Here, the surface of the opening 26 is divided as a virtual panel having, for example, a 20 cm square as a unit cell area. When a straight line is drawn between the virtual panel and the sun, it can be determined that the virtual panel is exposed to solar radiation unless an obstacle such as a neighbor or a fence enters the straight line. Then, the amount of solar radiation energy acquired from the opening 26 is calculated by summing the amount of solar radiation to the virtual panel that receives the solar radiation. The size of the virtual panel can be set as appropriate.

  Specifically, it is judged whether or not solar radiation is given from the vector product of the direction vector of direct solar radiation from the sun and the normal vector in the direction of the outside of the building on the 26th surface of the opening. It is possible to calculate what angle the solar radiation has with respect to the surface of the opening 26, and to take into consideration the effect of the projected area, the transmission characteristics of the glass, and the effect of the solar radiation shielding means. Since the size of the opening 26 is not uniform and there is a height difference, the simplicity and accuracy of solar radiation calculation can be realized by treating the surface of the opening 26 as a virtual panel divided into a plurality of parts.

  Here, the direct solar radiation amount is the sunlight directly irradiated from the sun, and the horizontal total solar radiation amount based on the extended AMeDAS weather data is represented by the sum of the direct solar radiation amount and the diffuse solar radiation amount. The diffuse solar radiation amount is an amount of solar radiation that is indirectly detected as a result of reflection of solar radiation to the surroundings and recognized diffusely without having a specific direction.

  In this embodiment, hourly extended AMeDAS weather data is used. For example, in order to inspect sunlight such as the western sun, direct calculation is only for direct solar radiation in the horizontal solar radiation amount. Yes.

  When separating horizontal solar radiation into direct and diffuse solar radiation, the direct-scattering separation method is known, which includes the Nagata model, Udagawa model, Erbs model, Watanabe model, Each model is known, such as the Perez model. In this embodiment, the Watanabe model is adopted and the horizontal solar radiation amount is separated into direct solar radiation amount and diffuse solar radiation amount as extended AMeDAS weather data, and the direct solar radiation amount is adopted to obtain the amount of solar radiation energy acquired from the opening 26. It is an example calculated. In order to increase the accuracy, the amount of solar radiation acquired from the opening 26 can be calculated by adding the amount of diffuse solar radiation to the amount of direct solar radiation.

  The floor plan creation unit 8 provided in the arithmetic unit 27 of the acquired solar radiation energy amount display device 1 creates floor plans of the buildings shown in FIGS. 5 to 11, and is a floor plan database (hereinafter “floor plan DB”). 9) can be appropriately selected and referred to, and a new floor plan that is updated by reference can also be stored in the floor plan DB 9. In addition, a function for selecting a room for displaying the acquired solar radiation energy amount by the acquired solar radiation energy amount display device 1 or a partial area of the one room from the created floor plan is also provided. In addition, the unit area and the number of the divided panels of the opening 26 surface can be set as appropriate.

  The peripheral building information creation unit 12 creates a peripheral information map related to solar radiation obstacles such as neighboring neighbors and standing trees of the building to be constructed, and is a peripheral building information database (hereinafter referred to as “peripheral building information DB”). It can also be created with reference to 13. FIG. 11 is an example of creating a neighbor 18.

  Enter the latitude and longitude of the building to be constructed using the azimuth setting screen 10 shown in FIG. 5 and the angle in the normal direction toward the outside of the opening 26 when true north is 0 °. On the outside of the opening 26 created by the surrounding building information creation unit 12 on a straight line connecting the position of the sun calculated by the position calculation unit 3 and the position of each virtual panel divided into a plurality of openings 26. Ask whether there is solar radiation acquired in each virtual panel of the opening 26 based on the condition whether there is a solar radiation obstacle such as a wall, a neighbor 18 or a standing tree that exists, and the acquired solar radiation is The total amount of solar radiation obtained from the opening 26 can be calculated by summing the amount of solar radiation of a certain virtual panel.

  Then, the acquired solar energy amount from each opening 26 is acquired by the acquired solar energy amount acquisition unit 28 serving as an acquired solar energy amount acquisition unit for each unit of the opening 26 and for each unit time.

  Here, one day of horizontal global solar radiation by the weather data acquired by the acquired solar radiation energy acquisition unit 28 by the summer sun extraction unit 14 serving as a summer sun extraction means and stored in the extended AMeDAS weather information DB 2 is stored. The day whose amount is equal to or greater than a predetermined value or the average temperature for one day based on weather data is equal to or greater than a predetermined value is extracted as a summer day, and the number of days for summer day is calculated. This is to verify whether there is excessive solar radiation acquisition in the summer. In the present embodiment, an example in which a day on which the horizontal solar radiation amount for one day is equal to or greater than a predetermined value and the average temperature for one day is equal to or greater than a predetermined value will be described as a summer day will be described. The day when either the total solar radiation amount is equal to or greater than a predetermined value or the average temperature for one day is equal to or greater than the predetermined value may be a summer day. The extended AMeDAS weather information includes statistical data of the average daily temperature in units of 0.1 ° C, and this data can be used.

For example, the determination reference value for the horizontal solar radiation amount for one day is 14 MJ / m ² d, the determination reference value for the average temperature for one day is 25 ° C., and the horizontal solar radiation amount for one day is 14 MJ / m. The day when the average temperature of m ² d or more and the average temperature for one day is 25 ° C or more is regarded as a summer day, or the horizontal solar radiation amount for one day is 14 MJ / m ² d or more or the average for one day A day in which the temperature is at least 25 ° C. can be a summer day. The summer day conditions can also be set to various other conditions. For example, the minimum daily temperature is 25 ° C. or higher, the minimum night temperature is 25 ° C. or higher, and the daily solar radiation amount is 7 MJ / day. It is also possible to extract a summer day by appropriately setting a predetermined numerical value in each of these conditions such as m ² d or more and further combining them appropriately.

  When verifying excessive solar radiation acquisition, it is effective to set a summer day because the overall average image is ambiguous if data on relatively mild days is included. In addition, when the number of summer days is small, even if the summer day inspected is relatively warm and shows a large value, the solar radiation mitigation treatment may not always be advantageous until the cost is increased. The target number of days of summer is calculated as a guideline for the determination. If the number of summer days is small, it is not necessary to treat solar radiation. That is, excessive correspondence can be prevented.

For example, in FIG. 3, 15 indicates a summer day when the average daily temperature is 25 ° C. or more and the horizontal solar radiation amount for one day is 14 MJ / m ² d or more. The reason why the horizontal solar radiation amount was set to 14 MJ / m ² d or more was confirmed in the steel-based ALC (lightweight aerated concrete) building by the relationship between the change in the amount of solar radiation and the room temperature responding to it. is there.

  Also, during a predetermined period of time by the weather data acquired by the acquired solar radiation energy amount acquisition unit 28 as the acquired solar radiation energy amount acquisition means by the winter day extraction unit 19 as winter day extraction means, and stored and stored in the extended AMeDAS weather information DB 2 Is extracted as a winter day, and the number of days covered by the winter day is calculated. In winter, for example, as shown in FIG. 2, the amount of acquired solar radiation energy for three months from December to February when the annual average temperature is lowered is integrated. The purpose is to calculate how much solar radiation is obtained in winter.

  The acquired solar energy amount integrating unit 11 serving as an acquired solar energy amount integrating unit is an acquired solar energy amount acquiring unit that acquires the acquired solar energy amount from the opening 26 for each unit of the opening 26 and every unit time. The acquired solar radiation energy amount acquired by the energy amount acquisition unit 28 and stored in the extended AMeDAS weather information DB 2 is accumulated on the summer day 15 and the winter day during the winter period.

  The solar radiation energy amount calculation unit 16 obtained per hour, which is the means for calculating the solar energy acquisition amount per hour, calculates the accumulated solar radiation energy amount for each summer day 15 and winter day accumulated by the solar radiation energy amount accumulation unit 11 in summer 15 and The amount of accumulated solar radiation energy per hour divided by the total number of hours of sunshine on each winter day is calculated. Note that the number of hours of sunshine is the number of hours the sun is out of the horizon, that is, the number of hours when the solar altitude is greater than zero.

  Then, as shown in FIGS. 5 to 11, the display unit 17 serving as a display means indicates the accumulated acquired solar energy amount per hour calculated by the hourly acquired solar energy amount calculation unit 16 in the summer and winter seasons. The acquired solar radiation energy amount is displayed in the vicinity of each opening 26 on the building drawing.

  In addition, the acquired solar radiation energy amount calculation unit 20 serving as an acquired solar radiation energy amount calculation means each summer acquired from a plurality of openings 26 included in the area for each predetermined area in the building where the opening 26 is provided. Add each amount of solar radiation energy acquired for each day and winter day, and use the sum of each day's acquired solar energy amount for summer and winter as the amount of solar radiation energy acquired in summer and winter. It is displayed in the same area.

Next, with reference to FIG. 4, a description will be given of how the acquired solar radiation energy amount display device 1 verifies a building in summer and winter. First, in step S _1, and inputs a peripheral building information by the peripheral building information creation unit 12. At this time, the surrounding building information stored in the surrounding building information DB 13 can also be referred to. The floor plan creation unit 8 inputs a floor plan with reference to the floor plan sample stored in the floor plan DB 9. At this time, the verification area can be selected by designating a room to be verified or a partial area in the studio.

  Also, building position information is input using the orientation setting screen 10 shown in FIG. As building position information, the latitude and longitude of the building are input, or the address of the building is input. The solar position calculation unit 3 obtains the solar altitude and the solar azimuth from the building position information (latitude, longitude) and the date and time, and sets the direction angle and altitude of direct solar radiation.

In step S _2, that specifies the meteorological data reference point. Click the hop-up menu (not shown) and select the AMeDAS observation point, which is the weather condition closest to the location of the building.

In step S _3, it extracts the data of the inspection target period from the weather data. At this time, the summer average 15 where the daily average temperature is 25 ° C or higher and the horizontal solar radiation amount per day is 14 MJ / m ² d or higher is extracted, and the annual average temperature decreases from December Three months in February are extracted as winter days.

In step S _4, it calculates the acquired solar energy to the final time from the initial time of the test period summer day and winter days, at step S _5, a summer for each full opening 26 when it becomes final time The amount of solar radiation energy acquired during the winter season is displayed together (step S ₆ ). In step S _5, to a final time for all the respective openings 26 in summer and winter obtaining solar energy amount by integrating respectively (step S _7), and repeats the steps S ₄ to S _5.

  In the following FIGS. 6 to 11, the acquired solar radiation energy amount indicates the amount of energy supplied to a region such as a room after passing through the opening portion 26, and the opening portion even when no special light shielding means is used. The amount of acquired solar radiation energy supplied through the normal opening 26 in the space closed by 26 is calculated. Even when various types of light shielding means are used, the space being inspected is not open and exists in the opening 26 in some form to partially shield solar radiation.

  FIG. 6 shows an opening 26 made of low-radiation pair glass without providing any special light shielding means in the opening 26, and the amount of solar radiation energy acquired from the opening 26 in summer and winter is indicated by a bar graph. In addition, when each of the openings 26 has a plurality of openings 26 in one area (for example, one room), the acquired solar radiation energy amount in the summer and winter of each opening 26 is In addition, the acquired solar radiation energy amounts in the summer and winter days added to each are displayed together in each region (room) as the acquired solar radiation energy amounts in the summer and winter seasons. Note that the acquired solar radiation energy amounts in the summer and winter seasons shown in FIG. 6 are the accumulated solar radiation energy amounts accumulated by the acquired solar energy amount integrating unit 11 in the summer and winter days, respectively. The total amount of solar radiation energy acquired per hour divided by the total number of sunshine hours.

  One bar graph representing the amount of solar radiation energy acquired in summer and winter is created for each specific opening 26 and connected by a lead line. In addition, the initial position of the graph is displayed on the line connecting the center of gravity of the entire building and the center of each opening 26 at a position that is moderately separated from the building, and can be moved by dragging on the screen, if necessary It can be erased.

  Compared to the surface of the opening 26 that is simply open and has nothing in the opening 26, only the opening 26 made of low radiation pair glass has a solar radiation shielding rate of 35%. That is, the solar radiation is transmitted by 65%.

FIG. 7 shows the obtained amount of solar radiation energy in the summer and winter when the fixed solar shading member 21 is attached to the opening 26 made of the low radiation pair glass of the room 6 as an example of the light shielding means, as in FIG. It is displayed in the opening 26 by a bar graph. Solar radiation at the opening 26 of the low-E pair glass transmits 65%, in order to further solar radiation in stationary solar radiation shielding member (2) 1 is transmitted through 65%, total 42.3% (65% × 65% = 42.3 %) Of solar radiation. That is, the solar radiation shielding rate is 58%.

  FIG. 8 shows, as an example of the light shielding means, the obtained solar radiation energy amounts in the summer and winter when the heat shield glass 22 is attached to the opening 26 of the room 6 as a bar graph in the opening 26 as in FIG. It is. The heat shielding glass 22 increases the heat shielding effect of the glass, and the solar radiation shielding rate of the opening 26 alone is 60% as compared with the simply opened opening 26 surface having nothing in the opening 26. That is, the solar radiation is transmitted by 40%.

  FIG. 9 shows the obtained amount of solar radiation energy in the summer and winter when the movable solar radiation shielding member 23 is attached to the opening 26 made of the low radiation pair glass of the room 6 as an example of the light shielding means. It is displayed in the opening 26 by a bar graph. Solar radiation is 65% transmitted through the opening 26 of the low radiation pair glass, and further 30% of the solar radiation is transmitted through the movable solar shading member 23, so that 20% (65% × 30% = 20%) of the total solar radiation is transmitted. To do. That is, the solar radiation shielding rate is 80%. However, the movable solar shading member 23 is effective only in the summer, and the heat shielding effect affects only the summer.

  The solar shading function information such as the fixed solar shading member 21, the heat shielding glass 22, and the movable solar shading member 23 is stored and stored in the solar shading function information database (hereinafter referred to as “sunlight shielding function information DB”) 25. Each solar radiation shielding rate is used when the acquired solar radiation energy amount integrating unit 11 integrates the acquired solar solar energy amount on summer and winter days.

  FIG. 10 is a bar graph showing the amount of solar radiation energy acquired in summer and winter when the attachment rod 24 is attached to the upper part of the opening 26 made of low radiation pair glass in the room 6 as an example of the light shielding means. This is displayed in the opening 26. The solar radiation is transmitted by 65% through the opening 26 of the low radiation pair glass, and the presence of the attachment rod 24 shields the solar radiation depending on the direct solar radiation direction. The solar shading rate in the case of the spider 24 cannot be simply expressed, and is integrated taking into account the influence of the shielding around the opening 26 and the position of the sun every moment.

  FIG. 11 is a bar graph showing the amount of solar radiation energy acquired in summer and winter when there is a neighbor 18 in the adjacent land in front of the opening 26 made of low radiation pair glass. It is displayed. The solar radiation acquired from the opening 26 is partially shielded by the neighbor 18 and the neighbor 18 plays the role of a trap.

  The spider 24 and the neighbor 18 calculate the position of the target building on the earth (latitude, longitude, address, etc.), the sun position corresponding to the season and time by the sun position calculation unit 3, and move from moment to moment. On the straight line connecting the position of the sun and the position of each of the virtual panels divided into a plurality of openings 26, the neighboring house 18 and the attachment existing outside the opening 26 created by the surrounding building information creation unit 12 Based on the condition of whether or not there is 24, whether or not there is solar radiation acquired in each virtual panel of the opening 26, and by summing the amount of solar radiation to the virtual panel with acquired solar radiation, the opening Calculate the amount of solar radiation energy obtained from 26.

  For example, when the movable solar shading member 23 and the heat shielding glass 22 are combined, the solar radiation transmittance is 12%. That is, the solar radiation shielding rate is 88%. In this way, various light shielding means can be appropriately combined depending on the purpose of summer and winter.

  Also, it can be easily estimated what happens when the size of the opening 26 is changed. Furthermore, it is easy to understand how the solar shading effect changes when the building orientation in each figure changes.

  Here, the effects of separately calculating and displaying the acquired solar radiation energy amounts in summer and winter are as follows. That is, as is apparent from FIGS. 6 to 11, the amount of acquired solar radiation varies depending on the use of various light shielding means and the influence of surrounding buildings. The degree of this change varies depending on the light shielding means.

  For example, when the movable solar radiation shielding member 23 is used, the amount of solar radiation acquired in summer is reduced, but the amount of solar radiation acquired in winter does not change. On the other hand, the fixed solar shading member 21 and the heat shielding glass 22 reduce the amount of solar radiation energy acquired in summer and winter to approximately the same extent. However, the movable solar shading member 23 is difficult to see the outside situation through the opening 26, and conversely, it is difficult to see the inside from the outside, whereas when using the heat shielding glass 22 There is no particular obstacle to seeing the outside.

  It can also be seen that if the attachment rod 24 can be adjusted as appropriate, the amount of solar radiation acquired in summer can be shielded more than the amount of solar energy acquired in winter. Moreover, it turns out that the influence of an adjacent building will influence the reduction of the acquired solar radiation energy amount in winter more than the reduction of the acquired solar radiation energy amount in the summer.

  Since each shading means has the characteristics described above, if the shading means is applied to the dark clouds just because the amount of acquired solar radiation energy is large, the amount of solar radiation acquired in the winter will decrease, and rather it will be necessary to incorporate more solar radiation in winter. The amount of energy cannot be used effectively. For this reason, it is possible to simultaneously display the evaluation of the acquired solar radiation energy amount in summer and winter in order to take advantage of the characteristics of various light shielding means to control the acquired solar radiation amount while utilizing the characteristics of each light shielding means. Indispensable.

  Further, the effect of the adjacent building such as the spider 24 and the neighbor 18 varies depending on the arrangement and size thereof and the type of opening in which direction the building itself has. In general, the spider 24 is known to be effective in shielding the south-facing solar radiation in the summer. For example, if the opening 26 faces 30 ° from the south, It is not easy to judge whether it has a shielding effect. Therefore, simple studies can be performed only after the above-described acquired solar radiation energy amount display device 1 is constructed.

  In addition, this invention can be used for the space which requires the solar radiation acquisition energy evaluation of a room unit, such as a housing | casing house, a dormitory, a school, a nursing home, a nursery school, a hotel or an inn, such as a house.

  As an application example of the present invention, an acquired solar energy amount display device and an acquired solar energy amount display method for displaying an acquired solar energy amount from an opening that can transmit solar radiation can be applied to a building other than a building.

DESCRIPTION OF SYMBOLS 1 ... Acquisition solar energy amount display apparatus 2 ... Extended AMeDAS weather information DB
DESCRIPTION OF SYMBOLS 3 ... Solar position calculating part 4 ... Input part 5 ... Temporary storage device 6,7 ... Room 8 ... Floor plan creation part 9 ... Floor plan DB
10… Direction setting screen
11 ... Acquired solar radiation energy integration part
12… Neighboring building information creation department
13 ... Surrounding building information DB
14 ... Summer day extraction section
15 ... Summer
16… Acquired solar radiation energy calculation unit per hour
17… Display section
18 ... Next door
19… Winter day extractor
20… Acquired solar radiation energy calculation part
21 ... Fixed solar shading member
22 ... Thermal barrier glass
23… Movable solar shading member
24 ...
25 ... Solar radiation shielding function information DB
26… Opening
27: Arithmetic unit
28 ... Acquired solar energy acquisition part

Claims (14)

An acquired solar energy amount display device that displays an acquired solar energy amount from an opening that can transmit solar radiation,
An acquisition solar energy amount acquisition means for acquiring an acquisition solar energy amount from the opening for each opening unit and for each unit time;
Summer day extracting means for extracting a summer day defined by at least one of temperature, amount of solar radiation, and period ;
A winter day extraction means for extracting a winter day defined by at least one of temperature, amount of solar radiation, and period ;
Acquired solar radiation energy amount integrating means for respectively integrating the acquired solar radiation energy amount acquired by the acquired solar radiation energy amount acquiring means;
Display means for displaying the accumulated amount of solar radiation energy accumulated in the summer day and winter day respectively accumulated by the amount of solar radiation energy accumulated in the acquisition as the amount of solar radiation energy acquired in summer and winter.
The acquired solar radiation energy amount display apparatus characterized by having. Integrated acquired solar radiation energy amount per hour obtained by dividing the cumulative acquired solar radiation energy amount for each summer day and the winter day by the total solar radiation hours accumulated by the acquired solar radiation energy amount integration means by the total number of sunshine hours for each summer day and winter day A solar energy acquisition amount calculation means for calculating per hour,
The display means displays the accumulated acquired solar radiation energy amount per hour for each summer day and winter day calculated by the acquired solar radiation energy amount calculation means per hour as the acquired solar radiation energy amount for each summer and winter. The acquired solar radiation energy amount display device according to claim 1 . An acquired solar radiation energy amount calculating means for adding each acquired solar energy amount for each summer day and winter day acquired from a plurality of openings included in the predetermined area in the building provided with the opening. Have
The display means, each acquisition solar energy in the summer day and winter days which are added by the acquisition solar energy calculating means, to claim 1, wherein the displaying the Everyone as an acquisition solar energy in summer and winter The obtained solar radiation energy amount display device. The acquired solar radiation energy amount for each summer day and winter day added by the acquired solar radiation energy amount calculating means according to claim 3 , and the summer sun and winter day acquired by the acquired solar radiation energy amount per hour according to claim 2 . Calculate the accumulated solar radiation energy amount per hour divided by the total number of sunshine hours, and the display means displays each cumulative solar radiation energy amount as the solar radiation energy amount acquired in summer and winter. An acquired solar radiation energy amount display device. The acquired solar radiation energy amount display according to any one of claims 1 to 4 , wherein the display means displays the acquired solar radiation energy amount in the summer and winter together on a building drawing of a computer display screen. apparatus. The said energy acquisition means adjusts the acquisition solar radiation energy which the said opening receives based on the surrounding building which shields the acquisition solar radiation from the said opening, or the solar radiation shielding means provided in the said opening. The acquired solar radiation energy amount display apparatus of any one of -5 . The acquired solar radiation energy amount display device according to claim 6, wherein the solar radiation shielding means changes the shielding state of the opening between the summer day and the winter day . An acquired solar radiation energy amount display method for displaying an acquired solar radiation energy amount from an opening that can transmit solar radiation,
A summer day and a winter day defined by at least one of temperature, amount of solar radiation, and period are extracted, and the amount of solar radiation energy acquired from the opening on the summer day and winter day is determined for each opening unit and for each unit time. Respectively,
A method for displaying an acquired solar radiation energy amount, wherein the accumulated solar radiation energy amount for each summer day and winter day is displayed together as an acquired solar radiation energy amount in summer and winter. Calculate the accumulated acquired solar energy amount per hour by dividing the accumulated solar radiation energy amount of each of the summer day and the winter day by the total number of sunshine hours of each of the summer day and the winter day;
Each integrated acquisition solar energy amount per each hour of each calculated summer day and winter days, obtaining the solar radiation according to 請 Motomeko 8 you and displaying the Everyone as an acquisition solar energy in summer and winter Energy amount display method. For each predetermined area in the building where the opening is provided, add each amount of solar radiation energy acquired each summer day and winter day acquired from a plurality of openings included in the area,
The summed summer day and each acquisition solar energy in winter day, get solar energy display method according to 請 Motomeko 8 you and displaying the Everyone as an acquisition solar energy in the summer and winter. For each predetermined area in the building in which the opening is provided, add each acquired solar radiation energy amount acquired from a plurality of openings included in the area, and the added summer sun And the accumulated solar radiation energy amount per hour obtained by dividing each solar radiation energy amount acquired in winter and winter days by the total number of sunshine hours for each summer day and winter day. obtaining solar energy display method according to 請 Motomeko 8 you characterized. The acquired solar radiation energy amount display method according to any one of claims 8 to 11, wherein the acquired solar radiation energy amounts in summer and winter are displayed together on a building drawing. For integrating the amount of solar radiation energy acquired from the opening,
The acquired solar radiation energy which the said opening receives is adjusted based on the surrounding building which shields the acquired solar radiation from the said opening part, or the solar radiation shielding means provided in the said opening part, The any one of Claims 8-12 characterized by the above-mentioned. The acquisition solar energy amount display method according to the item . The acquired solar radiation energy amount display method according to claim 13, wherein the solar radiation shielding means changes the shielding state of the opening between the summer day and the winter day .