JPH0759619A - Furniture structure for office automation equipment - Google Patents

Abstract

(57) [Abstract] [Objective] To provide a furniture structure for OA equipment that improves the thermal environment of the work space where the OA equipment is used by efficiently discharging the hot air radiated from the OA equipment with a simple structure. To do. [Structure] The CRT 10 is placed on the top plate 11a of the work desk 11, and the CPU 12 is arranged under the desk. Notch on the back edge of work desk 11
A louver 14 is formed in the cutout portion 14, and a partition 15 is provided along the inner edge of the working desk 11. An exhaust fan 16 is arranged below the cutout 13 to discharge the air under the desk to the upper side of the desk. Install a partition plate 17 under the desk to
The part where PU12 is arranged and the other part are divided. The air outlet 18 of the underfloor air conditioner is arranged facing the desk, and conditioned air is blown under the desk to ventilate the air around the CPU 12. The hot air under the desk flows through the notch 13 to the upper side of the desk, is guided by the louver 14, and rises above the work space along the partition 15.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to so-called office automation equipment such as computers (hereinafter referred to as "OA").
Equipment ". ) Related to the structure of furniture for office automation equipment having a heat treatment function for exhausting heat in order to maintain a comfortable working environment.

[0002]

2. Description of the Related Art In recent years, high-performance OA equipment such as EWS has been reduced in size and reduced in price. Therefore, these equipments have been widely used by arranging them on or under a desk for a general workstation. Came. However, high performance OA such as EWS
The device generates more heat than conventional general-purpose OA devices such as personal computers and word processors.

Further, partitions have come to be used more and more in order to divide the work spaces from each other in order to improve the work environment. Since the work space is surrounded by this partition, it is difficult for heat to diffuse, and the heat environment is deteriorated due to temperature rise of the work space, heat radiation, hot air from high-performance OA equipment, and the like. This is particularly noticeable when a high performance OA device is installed under the desk.

[0004] In order to improve such a warm environment of the working space, there is a furniture for OA equipment provided with heat dissipation as shown in FIG. 13 or 14. As shown in FIG. 13 as one of the furniture, a louver 4 is provided above the cable duct 3 at the back of the desk 1, and hot air under the desk 1 is raised and exhausted from here to heat the work environment. There is a desk 1 trying to improve. 8 is a central processing unit (hereinafter referred to as "CP
U ”. ), 9 indicates a display device (hereinafter referred to as "CRT").

Further, the exhaust heat compatible furniture shown in FIG. 14 is based on the partition 2 having the exhaust port 5 on the upper part and the ventilation louver 6 or the exhaust fan 7 on the lower part, and is arranged near the work desk. The hot air under the desk is sucked by the ventilation louver 6 or the exhaust fan 7 and exhausted from the upper exhaust port 5 to improve the thermal environment of the work space near the partition 2.

[0006]

However, in the case of the desk 1 shown in FIG. 13, the number of parts such as the cable duct 3 is increased and the appearance is deteriorated. Further, in the partition 2 shown in FIG. 14, in the case where the high temperature air under the desk is sucked in through the ventilation louver 6 in the lower part,
The ventilation resistance inside the partition 2 up to the discharge port 5 is large, or the air leakage of the partition 2 is large and a sufficient effect cannot be expected. Also, when high temperature air under the desk is sucked by the lower exhaust fan 7 and exhausted through the upper part of the partition 2 through the upper exhaust port 5, the same effect cannot be expected due to ventilation resistance and air leakage. Note that the capacity of the exhaust fan 7 must be increased to achieve a sufficient effect. However, when the exhaust fan 7 having a large capacity is used, noise increases and the space for incorporating the exhaust fan 7 in the partition 2 also increases.

Therefore, the present invention is to provide a furniture structure for office automation equipment which can effectively perform waste heat treatment of OA equipment without affecting the surrounding thermal environment with a minimum of additional equipment. Has an aim.

[0008]

As a technical means for achieving the above object, a furniture structure for office automation equipment according to the present invention is provided along a back side edge of a desk on which the office automation equipment is placed. The main feature is to have a partition that leans against the table top, and a notch is formed at the back side edge of the top plate of the desk, and a louver is provided in the notch, so that the hot air under the desk can be efficiently transferred from the desk. In order to exhaust air, a blower for blowing air from below the desk to above the desk is provided below the notch.

Furthermore, in order to promote ventilation under the desk and provide a more comfortable working space, the outlet of the underfloor air conditioner that blows out conditioned air for air conditioning from the underfloor to the room is exposed under the desk. The above-mentioned under-floor air conditioner is provided with a partition plate that divides the under-desk into a part where the central processing unit is installed and another part. It is also characterized in that the air outlet is placed under the desk facing the portion where the central processing unit is placed, and conditioned air is blown out from the air outlet under the desk.

[0010]

The hot air under the desk rises by natural convection and flows from the notch of the top plate to the upper side of the desk. At this time, the direction of the flow is adjusted by the louver and the louver rises along the partition. Therefore, it is possible to prevent hot air from flowing to the front side of the desk, and to prevent an increase in the ambient temperature of the worker as much as possible.

Further, when a blower is provided below the cutout portion, hot air under the desk can be forcibly discharged to the upper side of the desk. Moreover, since this hot air is pressurized by the blower, it is carried upward when passing through the louver,
It is possible to further prevent the ambient temperature of the worker from rising. Furthermore, the ventilation under the desk is promoted by introducing the conditioned air of the underfloor air conditioner under the desk.

Further, by providing the partition plate under the desk, the exhaust heat from the central processing unit is blocked by the partition plate and does not flow out to the operator side. Therefore, warm air is
It can be processed efficiently on the PU side.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The furniture structure for office automation equipment according to the present invention will be specifically described below with reference to the illustrated embodiments.

FIG. 1 is a perspective view of the furniture for OA equipment, which is mainly composed of a work desk 11 having a top plate 11a on which a CRT 10 as a display device is placed. This work desk
11 has left and right leg portions 11b, and the top plate 11a is attached to the upper ends of the leg portions 11b, and is located between the left and right leg portions 11b at a position biased to one leg portion 11b side. A CPU 12, which is a central processing unit, is installed. Also, the top plate
A notch 13 having an appropriate shape is formed at the end on the back side of 11a, and a louver 14 is provided in the notch 13 along the width direction of the work desk 11. Then, a partition 15 is set up on the back side of the work desk 11, and the front surface of this partition 15 abuts on the back side end of the work desk 11 so that the partition 15
The open side of the notch 13 is closed by 15. Also,
As shown in FIG. 2, partitions are also provided on the left and right of the work desk 11.
15 is set up.

Further, as shown in FIG. 3, an exhaust fan 16 is disposed below the cutout portion 13 so that the air under the desk is blown to the upper side of the desk through the cutout portion 13. I am doing it.

Further, as shown by an imaginary line in FIG. 1, a partition plate 17 is arranged under the work desk 11 as needed, and the CPU 17
The part where 12 is installed is separated from the other part. Further, if necessary, as shown in FIG. 3, the conditioned air is blown out under the desk by directing the blow-out port 18 of the underfloor air conditioner (not shown) toward the bottom of the desk. In this case, the conditioned air blown out from the air outlet 18 is blown to the CPU 12.

The operation of the embodiment of the furniture structure for office automation equipment according to the present invention constructed as above will be described below.

When the CPU 12 operates, it generates heat and is radiated to the lower part of the work desk 11. Since this warm air rises by natural convection, it flows through the notch 13 formed on the back side of the top plate 11a to the upper side of the top plate 11a, that is, the desk top side, and the hot air under the desk is discharged. Will be. When passing through the notch 13, the louver 14 is provided in the notch 13, so that hot air is guided by the louver 14 and does not flow to the front of the work desk 11 along the partition 15. Will rise. Therefore, a person working on the work desk 11 is not blown with warm air, and the work space can be kept comfortable.

An exhaust fan 16 is provided below the cutout portion 13.
In the case where is provided, the hot air trapped under the desk is forcibly sent to the upper side of the work desk 11 by the exhaust fan 16. Further, since the hot air is pressurized by the exhaust fan 16, it is guided by the louver 14 and rises further upward than in the case of natural convection, so that the working space can be kept more comfortable. Moreover, when the warm air rises, the warm air including the radiated heat radiated from the CRT 10 is sucked by the attractive effect and raised together, which makes the working space more comfortable.

If a partition plate 17 for partitioning the CPU 12 and other portions is provided under the desk, the CPU 12
It is possible to prevent the hot air released from the hot air from flowing out to the other portion. Since the worker sits down and works on the other parts, it is possible to prevent the worker from being blown with hot air. Then, the hot air diffused from the CPU 12 is blown to the upper side of the work desk 11 by the exhaust fan 16 and discharged. According to the structure in which the partition plate 17 is arranged, the heat radiation from the CPU 12 is CP at the partition plate 17 as a boundary.
Since it can be processed on the U12 side, the comfort of the work space can be improved. If the CRT 10 is arranged above the position where the CPU 12 is arranged, the radiated heat radiated from the CRT 10 rises together with the hot air radiated from the CPU 12, so that the hot air is prevented from flowing to the worker side. To be done.

Further, the outlet 18 of the underfloor air conditioner for introducing the conditioned air to the underfloor and blowing the conditioned air into the room from an appropriate position on the floor panel is arranged below the work desk 11 as shown in FIG. In the case where the conditioned air is blown to the CPU 12 from the air outlet 18, the conditioned air is always blown to the CPU 12. Therefore, ventilation of the hot air released from the CPU 12 is promoted, and the hot air is exhausted to the upper side of the desk by the exhaust fan 16, so that the temperature rise in the work space can be further suppressed.

Next, various experiments were conducted on this embodiment, and the results will be described with reference to FIGS. 4 to 12.

In this experiment, as shown in FIG.
Place the CRT10 on the top plate 11a of the
The furniture for OA equipment in which U12 was provided and the notch 13 was formed only at one place behind the CRT 10 was used. The working desk 11 has a width of 1600 mm, a depth of 800 mm, and a height of 700 mm, and the experimental data is, as shown in FIG. 4, within the vertical plane P at the substantially central portion of the working desk 11, and in the side view shown in FIG. It was acquired by measuring the temperature at 74 points indicated by Q. Also, the heat load of the CRT 10 on the desk is 120 W, and the CPU
Experiments were carried out for the 12 heat generation loads of 150 W and 480 W. 6 to 12 are sectional temperature distribution diagrams based on the acquired data.

<Experiment 1> From the data obtained for the furniture for OA equipment having a structure in which the CPU 12 having a heat load of 150 W is used, the top plate 11a is not formed with the notch 13 and no heat exhausting treatment is applied. The obtained cross-sectional temperature distribution is shown in FIG.

<Experiment 2> From the data obtained for the furniture for OA equipment having a structure in which the CPU 12 having a heat generation load of 480 W is used, the notch 13 is not formed in the top plate 11a, and no heat exhaustion treatment is performed. The obtained cross-sectional temperature distribution is shown in FIG.

<Experiment 3> A CPU 12 having a heat load of 150 W is used, and a top plate 11a has a notch portion having a width of 400 mm and a depth of 70 mm.
The cross-sectional temperature distribution obtained from the data obtained for the furniture for OA equipment having the structure in which 13 is formed on the back side of the CRT 10 is shown in FIG.

<Experiment 4> A CPU 12 having a heat load of 480 W is used, and a top plate 11a has a notch portion having a width of 650 mm and a depth of 150 mm.
13 is formed on the back side of the CRT, and the air volume is below the cutout 13.
Based on the data obtained for furniture for OA equipment having a structure in which a 4.2 m ³ / min forced suction fan is installed as the exhaust fan 16 and the exhaust fan 16 is operated to exhaust the hot air under the desk to the upper side of the desk. The obtained cross-sectional temperature distribution is shown in FIG.

<Experiment 5> A CPU 12 having a heat generation load of 480 W is used, and a top plate 11a has a notch portion having a width of 650 mm and a depth of 150 mm.
13 is formed on the back side of the CRT, and the louver is formed in this notch 13.
14 is provided, and the air volume is 4.2 m ³ below the cutout 13.
Install a forced suction fan of / min as the exhaust fan 16,
FIG. 10 shows a cross-sectional temperature distribution obtained from the data obtained for the furniture for OA equipment having a structure in which the exhaust fan 16 is operated to exhaust the hot air under the table to the upper side of the table.

<Experiment 6> A CPU 12 having a heat load of 480 W is used, and a top plate 11a has a notch portion having a width of 650 mm and a depth of 150 mm.
13 is formed on the back side of the CRT, and the louver is formed in this notch 13.
14 is provided and the air volume is 1.8 m ³ below the cutout 13.
Install a forced suction fan of / min as the exhaust fan 16,
Further, the cross section obtained from the data acquired for the furniture for OA equipment having a structure in which the conditioned air of the underfloor air conditioner is blown to the CPU 12 and the exhaust fan 16 is operated to exhaust the hot air under the desk to the upper side of the desk. The temperature distribution is shown in FIG.

<Experiment 7> A CPU 12 having a heat load of 480 W is used, and a top plate 11a has a notch portion having a width of 650 mm and a depth of 150 mm.
13 is formed on the back side of the CRT, and the louver is formed in this notch 13.
14 is provided, a forced suction fan with an air volume of 1.8 m ³ / min is installed as an exhaust fan 16 below the cutout 13, and conditioned air of an underfloor air conditioner is blown to the CPU 12, and a partition plate 17 is placed under the desk. The structure is such that the exhaust fan 16 is operated to exhaust hot air under the desk to the upper side of the desk.
FIG. 12 shows the cross-sectional temperature distribution obtained from the data acquired for the furniture for the A device.

FIG. 6 obtained from Experiment 1 and Experiment 2 above.
Further, in the temperature distribution shown in FIG. 7, the temperature of the work space near the work desk 11 is higher than room temperature, which impairs comfort.

Further, comparing the temperature distribution shown in FIG. 8 obtained from the experiment 3 with FIG. 6, natural convection occurs and the hot air under the desk rises and flows through the notch 13 to the upper side of the desk, where the hot air Is prevented from flowing to the worker side, and the thermal environment is improved.

When the temperature distribution shown in FIG. 9 obtained from the experiment 4 is compared with FIG. 7, the hot air under the desk is blown up to the upper side of the work space by the exhaust fan 16, and the hot air flows to the worker side. It is prevented from happening, and the thermal environment is improved.

Comparing the temperature distribution shown in FIG. 10 obtained from the experiment 5 with that of FIG. 9, warm air under the desk is guided by the louver 14 and rises by mounting the louver 14, and the CRT 10 The heat dissipated on the desk, which is dissipated from the room, is attracted and blown up above the work space. Therefore, the hot air flowing to the worker side is reduced, and the improvement of the hot environment of the work space is promoted.

Comparing the temperature distribution shown in FIG. 11 obtained from the experiment 6 with that in FIG. 10, since the conditioned air of the underfloor air conditioner is being supplied, the air volume in the experiment 5 shown in FIG. 10 is 4.2 m ³ / min.
In this experiment 6, the exhaust fan 16 of
With the air volume of 1.8 m ³ / min, almost the same effect as in Experiment 5 was obtained, and the temperature environment of the working space was improved.

Comparing the temperature distribution shown in FIG. 12 obtained from the experiment 7 with that in FIG. 11, the partition plate 17 is provided, so that hot air flows from the CPU 12 to the worker's feet or heat to the feet. Radiation is blocked, the thermal environment of the work space is further improved, and comfort is further improved.

[0037]

As described above, the O according to the present invention
According to the furniture structure for the A device, a notch is provided at the back side edge of the work desk in which the OA device is arranged, and the hot air under the table is raised upward from the notch by natural convection. , It is possible to prevent this warm air from getting under the desk. Therefore, the work space by the OA device can be made comfortable. Further, since the louver is provided in the cutout portion, the hot air rising from the underside of the desk to the upper side of the desk is guided by the louver so as to flow vertically along the partition. It does not interfere with the thermal environment of the person sitting.

Further, by providing a blower in the cutout portion, the hot air under the desk can be forcibly and efficiently raised to the upside of the desk and discharged. Moreover, since it is lifted while being pressurized by the blower, it can be lifted to a position higher than the top plate of the work desk, and the thermal environment of the work space can be kept good. Further, when the hot air rises, the radiated heat radiated from the desk CRT or the like is sucked by the attraction effect and rises together with the hot air, so that the working space can be made more comfortable.

Further, by introducing the conditioned air into the underside of the work desk with the air outlet of the underfloor air conditioner facing the underside of the desk, ventilation under the desk is promoted and a blower provided below the cutout portion. Even if the output is small, the hot air under the desk can be sufficiently discharged, and the working environment can be further improved.

In addition, by partitioning the underside of the desk into a portion where the CPU is arranged and another portion with a partition plate, hot air can be prevented from flowing out into the working space, and the comfort of the working environment can be improved. It can be further improved. Moreover, CPU
Since it is only necessary to provide a notch or a blower on the side where the heat exchanger is arranged to perform heat exhaustion treatment, an OA with a simple structure and a good working space is provided.
Equipment furniture can be provided.

[Brief description of drawings]

FIG. 1 is a schematic perspective view of furniture for office automation equipment having a structure according to the present invention.

FIG. 2 is a schematic plan view of furniture for office automation equipment provided with the structure according to the present invention.

FIG. 3 is a schematic vertical cross-sectional view of a central portion of furniture for office automation equipment provided with the structure according to the present invention.

FIG. 4 is a plan view showing measurement points in measuring the temperature distribution of furniture for office automation equipment having a structure according to the present invention.

FIG. 5 is a side view showing measurement points when measuring the temperature distribution of furniture for office automation equipment having a structure according to the present invention.

FIG. 6 is a temperature distribution diagram of data obtained as a result of Experiment 1.

7 is a temperature distribution chart of data obtained as a result of Experiment 2. FIG.

FIG. 8 is a temperature distribution chart of data obtained as a result of Experiment 3.

9 is a temperature distribution chart of data obtained as a result of Experiment 4. FIG.

10 is a temperature distribution chart of data obtained as a result of Experiment 5. FIG.

11 is a temperature distribution chart of data obtained as a result of Experiment 6. FIG.

FIG. 12 is a temperature distribution chart of data obtained as a result of Experiment 7.

FIG. 13 is a view for explaining a conventional furniture structure for office automation equipment, and is a schematic perspective view corresponding to FIG. 1.

FIG. 14 is a schematic perspective view of a partition that is one type of conventional furniture for office automation equipment.

[Explanation of symbols]

 10 CRT 11 Work desk 11a Top plate 12 CPU 13 Notch 14 Louver 15 Partition 16 Exhaust fan (blower) 17 Partition plate 18 Air outlet

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kenichi Sakai 5-7-8 Shiba, Minato-ku, Tokyo Hibiya General Equipment Co., Ltd. (72) Inventor Yuho Kato 1-6, Awaji-cho, Chuo-ku, Osaka-shi, Osaka No. 11 Itouki Co., Ltd. (72) Inventor Kazuki Ogiki 1-4-12 Imafukuhigashi, Joto-ku, Osaka-shi, Osaka (72) Inventor Keizo Yokoyama 37, 5-shiba Shiba, Minato-ku, Tokyo No. 8 Hibiya General Equipment Co., Ltd.

Claims (4)

[Claims] 1. A partition which leans against a back side edge of a work desk on which office automation equipment is mounted, and a notch is formed at a back side edge of a top plate of the work desk. A furniture structure for office automation equipment, which is characterized in that a louver is installed in the interior. 2. A partition that leans against a back side edge of a work desk on which office automation equipment is mounted, and a notch is formed at a back side edge of a top plate of the work desk. A furniture structure for office automation equipment, characterized in that a louver is provided on the lower part of the cutout portion, and a blower for blowing air from below the work desk to above the work desk is provided below the cutout portion. 3. A partition which leans against a back side edge of a work desk on which an office automation device is placed, and a notch is formed at a back side edge of a top plate of the work desk. In addition to the louver, the blower that blows air from the lower side of the work desk to the upper side of the work desk is installed under the cutout, and the outlet of the underfloor air conditioner that blows the conditioned air for air conditioning from the underfloor to the room is installed. A furniture structure for office automation equipment, which is arranged facing down and blows out conditioned air from the outlet under a desk. 4. A furniture for office automation equipment in which a display device is arranged on a work desk and a central processing unit is arranged under the work desk, and the back side of the work desk on which the office automation equipment is arranged. Having a partition leaning along the edge, a cutout is formed at the rear end edge of the top plate of the work desk, and a louver is arranged in the cutout, and a work desk is provided below the cutout. A blower is installed to blow air from the lower side to the upper side of the work desk, and a partition plate that divides the lower side into the part where the central processing unit is installed and the other part is provided, and conditioned air for air conditioning is blown into the room from below the floor. For office automation equipment, characterized in that the air outlet of the underfloor air conditioner is arranged so as to face the portion below the desk where the central processing unit is placed, and conditioned air is blown from the air outlet to the underside of the desk. Furniture structure.