JPH06160127A - Indoor effective temperature measuring device - Google Patents

Abstract

PURPOSE:To accurately express the indoor effective temperature environment by connecting a removable recording device, air temperature and air flow detecting elements, and a detector with conductors, and fixing the detector to an expandable stanchion at the preset position. CONSTITUTION:A detector 3 is constituted of air temperature and air flow elements 9, 11 capable of detecting the air temperature and air flow, and it is fitted at the measurement position of a stanchion 5 and connected to a recording device with wiring. When the recording device is activated, the recording of measured values is started, and the measured data are stored on a memory card. The position of a detecting element fitting base 13 is adjusted to fix the element 11 to the stanchion 5 so that the air current direction of the measurement position is made the same as the plane perpendicular to an air current detecting element support shaft 12. The element 11 is fitted at the position not affected by the stanchion 5 and the fitting base 13, and the position is adjusted by the length of the support shaft 12.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention measures the temperature and air flow among environmental elements to evaluate the indoor environment, and combines them to approximate the thermal sensation of the human body. The present invention relates to a method of expressing a sensible temperature, a measuring device, and an analytical display of measurement results. [Prior Art] Various methods have been used to represent the indoor environment as a value close to the thermal sensation felt by the human body. The methods are roughly classified into two types: one is a method of measuring several elements of the environment and expressing them in combination, and the other is a detector having one element for detecting various elements.
It is a method of physically incorporating and expressing as one value. The former is usually cumbersome and time-consuming, so it is common to measure 1 to 2 points indoors, and the latter detector incorporates elements that detect various elements as a single unit. It is a measuring device expressed as a value and is very expensive. In addition, the present inventor utilizes an apparatus that has already been filed as "improvement of indoor environment multi-point measuring apparatus" (Patent application No. Hei 2-322308), measures each element of the environment, and combines them. The method of expressing as a value close to the thermal sensation felt by the human body has a problem that it is not a measurement that accurately represents the sensible environment because time lag occurs. The present invention has been made in view of this deficiency. [Problems to be Solved by the Invention] It is not enough to measure one or two representative points to evaluate the indoor environment, and it is necessary to measure many points in order to evaluate correctly. This multipoint measurement method has already been filed as "improvement of indoor environment multipoint measuring device" (Patent Application No. Hei 2-322308). However, in the "multipoint measuring device" of the previous application, the number of measuring elements is one, and the detector expressing as a value close to the thermal sensation felt by the human body (the elements that detect various elements are It is not practical as a detector of this "multipoint measuring device" because it is a very expensive one (incorporated and expressed as one value). Therefore, we have already applied for a method of expressing the indoor sensation by measuring several elements of the environment at the same time among the methods of expressing it as a value close to the thermal sensation that the human body feels. By applying "improvement of measuring device", three-dimensional multi-point measurement is performed to more accurately represent the indoor sensation environment. [Means for Solving the Problems] In order to achieve the above-mentioned object, the indoor sensation measuring apparatus according to the present invention is a detection device attached to a column of "improvement of indoor environment multipoint measuring apparatus" already applied. The elements are the elements of a plurality of elements, and the wiring between the elements of each element and the recording device is performed individually for each element of the element. This is the time that can be handled as the same in terms of environmental measurement, and is not the same electrically, but is measured and recorded according to a predetermined order for each element.
The time is within a few seconds. ), The time and the measured value are recorded for each predetermined time according to the predetermined order of the elements of each element. As a result, using the "improvement of multi-point measuring device for indoor environment" as it is, each element is measured,
It is possible to solve the drawback of time lag that occurs in the method of combining them and expressing them as values close to the thermal sensation felt by the human body. That is, in the indoor sensation measuring apparatus according to the present invention, elements of various elements are attached to the attachment points of the detectors that are attached in the vertical direction, and the wiring between the detection point and the recording apparatus is of various elements. It is ejected from the element and fixed to a column fixed to the recording device. Electric power for the various elements is supplied from a battery built in the recording device. Therefore, the recording device and the detector are integrally configured, and in this measuring device, the vertical measurement can be performed independently without disturbing any other space. This is the same as the “improvement of multi-point environmental measuring device”. Temperature, humidity, airflow, and radiation are factors that affect the experience in the indoor environment. Here, we will pick up the air temperature and air flow that have the greatest effect on the experience. This is known as the Linke formula,
It shows the relationship between the air temperature and the air flow that affects the experience. Sensible temperature = t-4√v + 12J t: Air temperature (° C.) v: Air flow (m / s) J: Radiation (cal / min.m ² ) Here, the term of radiation is ignored from the condition of being indoors. As can be seen from this formula, the wind of "1 m / S" corresponds to "4 ° C" in temperature, and it is a common experience with a fan to feel cold air when hit by the air flow. Regarding the distribution on the plane, the purpose can be achieved by installing this independent measuring device at a necessary place on the plane. A small computer (microcomputer that records and processes measurement data) is used as the recording device.
A built-in clock is used to record the time and the measured value at every predetermined time. Recording of this data is recorded on a memory card, and long-term measurement is also possible by replacing this memory card. At the same time, the memory card can be collected and analyzed, which is extremely convenient. Of course, the collected memory card is read from a separately prepared card reader into the same personal computer, and the specified analysis processing is performed, and it is displayed on the computer screen and at the same time printed out by a printer as necessary. . How to analyze and express depends on a pre-made program. The data recorded by the recording device include time and measurement height, temperature and airflow at the measurement location (position), and the like. The indoor sensation measuring apparatus according to the present invention is composed of a means for recording the measured values at multiple points in the place, height, time, and vertical direction, means for reading the recorded measured values, and expressing them in a table or graph. . [Operation] Since the indoor sensation measuring apparatus according to the present invention is configured as described above, it can measure the state of the indoor environment in which it actually operates without disturbing various operations. Moreover, not only on the plane but also in the vertical direction can be easily recorded. In addition, there is no need to bother humans during measurement. Since the recorded data is recorded in a memory card that is freely installed in the recording device, it can be measured and recorded for a long period of time by exchanging it.
Then collect the memory card that recorded the data, read the data into the computer using a card reader,
It can be analyzed by a program prepared in advance so that it can be easily understood and displayed on the screen, and can be printed as a table or drawn as a graph. As a result, it has become possible to measure and analyze indoor air temperature and air flow, and to experience sensible temperature more accurately, easily, and cheaply than ever before. [Embodiment] In the following, the constituent parts to the extent of being publicly known and the parts belonging to the contents of "improvement of multipoint measuring apparatus for indoor environment" already applied are omitted or simplified as much as possible, A specific embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an overall view of the measuring apparatus of the present invention, and 1 is the measuring apparatus. Reference numeral 2 is a recording device, and 3 is a detector equipped with temperature and air flow detection elements. 4 is detector 3
Wiring 5 connecting the recording device 2 with the recording device 2 is a column extending in the vertical direction, and is a detector 3 to which a temperature and air flow detection element is attached.
It is used for fixing the wires and fixing the wiring 4. The column 5 has a structure that can be attached to and detached from the recording device, and is firmly fixed to the recording device 2 when used. In addition, the strut 5 itself has a structure that can be expanded and contracted so that it can be set to a predetermined length and is convenient for transportation during movement.
The length of the recording device 2 can be set. 6 is a memory card that is detachably installed in the storage device, 7 is a display section for operating instructions and data, 8 is a switch for turning the device on and off, a switch for various operations, and a switch for data input And the switch section. The inside of the storage device 2 is a microcomputer for performing recording processing of various elements. Although details are omitted, a central processing unit (generally called a CPU), an AD conversion unit, and an internal memory are included. , A memory card control unit, a display interface, a parallel input control unit, a serial input / output control unit and a battery power supply unit.
Explaining an actual method of measuring the temperature and air flow in the room, a detector 3 composed of an element capable of detecting the air temperature and air flow is attached to the measurement position of the column 5 and connected to the recording device 2 through wiring. The recording apparatus 2 is started by the power switch of the switch unit 8 of the recording apparatus 2, and the recording apparatus 2 starts recording the measured value by inputting a necessary command through the switch according to the instruction of the display unit 7. The measured data is 6
It is recorded and stored in the memory card of. FIG. 2 shows a detailed view of the detector 3 composed of elements capable of detecting air temperature and air flow. 9 is an air temperature detecting element, 10 is a shaft supporting the air temperature detecting element, 11 is an air flow detecting element,
Reference numeral 12 is a shaft for supporting the air flow detection element, and 13 is each detection element mounting base. A fixing screw 14 is used for fixing the detection element mounting base 13 to a predetermined position of the support column 5. At this time, it is necessary to pay attention to the position (direction) of the airflow detection element 11. Air temperature detection element 9
The position (direction) of the air flow detection element 11 is relative to the support column 5 so that the direction of the air flow at the measurement position and the plane perpendicular to the shaft 12 supporting the air flow detection element are the same. The position of the detection element mounting base 13 is adjusted and fixed to the column 5 with the fixing screw 14. The air flow in a room usually flows in a substantially constant direction. This is done by checking for smoke when installing the airflow element. Further, what is important in air flow measurement is that the air flow detection element 11 needs to be mounted at a position that is not affected by the support column 5 and the detection element mounting base 13. For that purpose, the length is adjusted by the length of the shaft 12 supporting the air flow detecting element, but the distance D is set to a position separated by about 5 mm or more from the outer surface of the column 5. FIG. 3 shows a sectional view of a room in which the indoor environment is measured. 15 is the room, 16 is the floor of the room,
17 is the ceiling of the room, 18 is the outer wall, 19 is the window, and 20 is the situation where a person is working at the desk. The measuring device 1 is installed near the window so as not to disturb the work of a person, and the detector 3 is fixed to the column 5 so as to measure the environment at each height in the vertical direction. The wiring 4 is not shown. FIG. 4 is a plan view of the chamber and shows an example in which the measuring devices 1 are installed so as to be distributed on a plane. 21 is a pillar, 22 is a partition wall, and 23 is a desk. The chair is omitted. The measuring device 1 is installed at the end of the desk 23 so as not to interfere with the work of a person, or the outer wall 1
It is installed near 8 or between desks 23. This makes it possible to measure the vertical distribution as well as the plane distribution of the environment of the room in actual operation. FIG. 5 shows a personal computer 2 for processing the memory card 6 collected from the measuring device 1.
It is 4. Of course, as a computer, there is no problem if it is a high-end model other than a personal computer. The personal computer 24 is provided with a program in which various processing methods required for environmental analysis are defined in advance. As a matter of course, one of the programs is the relational expression of the sensible temperature: sensible temperature = t-4√v + 12J t: temperature (° C.) v: air flow (m / s) J: radiation (cal / min.m ^2). ) (Here, the term of radiation is ignored from the condition of being indoors.). Reference numeral 25 is a display of the personal computer 24, and 26 is a card reader for reading data from a memory card. Two
Reference numeral 7 is a printer for printing the analysis result on the personal computer 24, and 28 is a sheet for printing the analysis result. As a result, the indoor environment of his measurement room is analyzed and evaluated. FIG. 6 shows an example of analysis of the sensible temperature obtained from the measured temperature and air flow. This figure shows the distribution of sensible temperature on a plane at a certain height of the room at a certain time.
It is possible to express that the sensible temperature varies depending on the location. This is much better than the temperature alone. The indoor sensible temperature distribution as shown in FIG. 6 cannot be said to be a good indoor environment. [Effects of the Invention] As is clear from the above description, according to the present invention, in addition to the expression of a single element such as the temperature and the air flow, it is possible to express an expression that is more realistic. Moreover, the fact that not only the planar distribution but also the vertical distribution can be easily measured over a long period of time without interfering with work is extremely convenient and highly useful.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows an embodiment of the present invention. FIG. 1 is a diagram of a measuring device, FIG. 2 is a detailed diagram of a detector, and FIG. FIG. 4 is a plan view of the chamber in which the measuring devices 1 are installed so as to be distributed on the plane. FIG. 5 is a personal computer for processing the memory card 6 collected from the measuring device 1. Illustration of a series of devices, No. 6
The figure is an example in which the indoor sensible temperature is analyzed from the air temperature / air flow measurement results, and is a diagram showing the sensible temperature distribution on a plane at a certain height of the room. 1: Measuring device 2: Recording device 3: Detector 4: Wiring 5: Support rod 6: Memory card 7: Display unit 8: Switch unit 9: Air temperature detection element 11: Air flow detection element 13: Detection element mounting base 14: For fixation Screw 15: Room 16: Floor 17: Ceiling 18: Exterior wall 19: Window 20: People and desk 21: Pillar 22: Partition wall 23: Desk 24: Personal computer 25: Display 26: Card reader 27: Printer 28: Printing paper

Claims (1)

(1) In the measuring device 1, a recording device 2 having a removable memory card 6 and a detector 3 having an air temperature detecting element 9 and an air flow detecting element 11 are connected by a wire 4 and are also expandable and contractible. The indoor sensation measuring device characterized in that the support column 5 is fixed to the recording device 2 at the time of use, and the detector 3 is fixed to the support column 5 with a fixing screw 14 at a predetermined position. (2) The measuring device 1 according to claim 1 is provided in a chamber 1
5, the memory card 6 in which the measured data of the room temperature and air flow is recorded is collected, the data is read by the card reader 26, and the personal computer 24
An indoor sensation measuring device for performing a predetermined analysis process by the printer 27 and performing a print expression on the printing paper 28 by the printer 27.