JP6493997B2 - Air conditioner - Google Patents

Description

  The present invention relates to air conditioning in a task area (work area) for performing office work or other work.

  For example, various solutions have been proposed for improving the thermal environment for workers working indoors, such as office workers, but none of the solutions has satisfied all workers. For example, the method of air-conditioning the entire office room has the following problems.

  If a worker who has returned from going out increases the setting of the air-conditioning temperature of the entire office, the setting may become excessive, and wasteful energy is consumed.

  In addition, mixing loss occurs if different air conditioning settings are used in adjacent areas.

  There is a worker who is not always satisfied with the heat in the entire air conditioning, and the worker brings in a temperature control device with poor energy efficiency such as an electric heater to increase the energy consumption of the entire building.

  Therefore, personal air conditioning, for example, a floor blowing type air conditioning system (Patent Document 1) and a chair (Patent Document 2) having a temperature adjustment function can be used to individually adjust the thermal environment of each office worker. It has been proposed to improve the satisfaction level.

  Further, in Patent Document 3, as a method for supplying air to a specific space, fine particles contained in the air are removed by a filter means, and this clean air is flowed as a laminar flow into a predetermined space, so that a predetermined space is obtained. A clean booth that forms an air barrier for clean air has been proposed.

JP 2010-236820 A JP 2009-225923 A Japanese Patent Laid-Open No. 06-221639

  Using the floor blowing method (Patent Document 1) and the chair (Patent Document 2) having a temperature adjustment function, each office worker can individually set the thermal environment. There is a problem in that the power to be transported close to the person is large, and the latter uses electricity for each person, and the efficiency is low.

  The clean booth of Patent Document 3 is intended to provide an open and simple aseptic booth for leukemia patients and the like, and can be installed in the task area where office work and other work are performed to improve the thermal environment. It was not a thing. For example, in order to fill the entire predetermined space (task area) with a laminar flow, there is a problem that a large amount of conveyance power is required and the efficiency is poor.

  Therefore, an object of the present invention is to provide a technique for efficiently air-conditioning each worker's task area individually.

  In order to solve the above problems, the desk with an air conditioner according to the present invention is incorporated in a partition housing that partitions at least a part of a task area where an operator works, and corresponds to an upper portion of the task area in the casing. Is an opening formed in a slit shape that is long in the width direction of the task region, and is disposed below the blower outlet, and a blowout port that blows out the temperature-controlled air toward the task region side. The air conditioner includes a suction port that sucks air in the task area, and a restriction member that is provided at a lower portion of the air outlet and restricts the flow of air. The desk with the air conditioner may be arranged by combining the partition and the desk independent, and may constitute a unit as the desk with the air conditioner, or the partition and the desk may be integrated. There may be.

  As for the said desk with an air conditioner, the said blower outlet and the said suction inlet may be provided in the surface by the side of the task area | region of the said housing | casing.

  The desk with the air conditioner is provided with a restricting member at a lower portion of the air outlet, air passing through the upper portion of the air outlet is blown out without the restricting member, and air passing through the lower portion of the air outlet is the restricting member. You may restrict | limit the flow of the said air via.

  The desk with the air conditioner has a heat exchanger that heats the air by circulating heat between the heat source and the air sucked from the suction port and the heat medium. In preparation, the air temperature-controlled by the heat exchanger may be blown out from the outlet.

In the desk with the air conditioner, the temperature of the air blown out from the air outlet may be lower than the temperature around the task area.
In addition, said means can be used in combination with each other as much as possible.

  According to the present invention, it is possible to provide a technique for efficiently and efficiently air-conditioning each worker's task area.

It is a figure showing the schematic structure of the air-conditioning system in this embodiment. It is an external appearance perspective view of the partition which incorporated the task air conditioner. It is a figure which shows the internal structure of a task air conditioner. It is a disassembled perspective view of the task air conditioner principal part. FIG. 3 shows a suction chamber. It is a figure which shows the principal part of the task air conditioner which air-conditions the task area | region of a near side. It is a figure which shows the longitudinal cross-section of the task air conditioner principal part accommodated in the partition. It is a figure which shows the comparative example for demonstrating a blower outlet. It is a figure which shows the example of a blower outlet. These are figures which show the example which abbreviate | omitted the bulging part. It is explanatory drawing of the flow of the warm air which was blown off from the lower blower outlet at the time of heating. It is a figure which shows the state of the airflow at the time of changing an air volume. It is a figure which shows the specific example of the limiting member provided in a blower outlet.

  Hereinafter, an air conditioning system according to an embodiment of the present invention will be described with reference to the drawings. The configuration of the following embodiment is an exemplification, and the air conditioning system and the task air conditioner of the present invention are not limited to the configuration of the embodiment.

《Air conditioning system》
FIG. 1 is a diagram showing a schematic configuration of an air conditioning system in the present embodiment. The air conditioning system 100 of the present embodiment performs air conditioning of a target space (a conditioned room), and for example, adjusts the temperature, humidity, and cleanliness of indoor air. The present embodiment is an example in which the air conditioning system 100 is applied to an office. As shown in FIG. 1, an office room 102 and an air conditioner room 103 as a target space are provided in the office. The air conditioner 104 is installed. The air conditioner 104 includes a coil 141, a humidifier 142, and a blower 143 connected to a heat source (not shown) via a pipe 105. The ceiling 121 of the office room 102 has a double ceiling structure in which a space is provided between the office room 102 and the ceiling slab 129. The ceiling 121 of the office room 102 is provided with a plurality of outlets 144 and return ports 145. Yes. The air outlet 144 communicates with the air conditioner 104 through an air supply path 146 formed in the ceiling space. The return air port 145 communicates with the air conditioner 104 via a return air path 147 formed in the ceiling space. The air conditioner 104, the air outlet 144, the return air port 145, the air supply path 146, the return air path 147, and the like constitute the ambient air conditioner of this embodiment.

  A plurality of desks 9 are installed in the office room 102, and an area where the desks 9 are installed is a task area for performing office work and the like. The task air conditioner is adjacent to the task area by incorporating the task air conditioner in the partition 106 disposed between the desks 9 back to back. The task air conditioner and the ambient air conditioner constitute the air conditioning system 100 of the present embodiment.

《Task air conditioner》
2 is an external perspective view of the partition 106 incorporating the task air conditioner 1, FIG. 3 is a diagram showing an internal configuration of the task air conditioner 1, and FIG. 4 is an exploded perspective view of a main part of the task air conditioner.

  The task air conditioner 1 is erected on the floor 122 (FIG. 3) of the office room, and is housed in a casing of a partition 106 used as a partition between the desks 9 as shown in FIG. The partition 106 has a substantially plate-like outer shape standing vertically, and the desk 9 is arranged with its back on one plane side, and the desk 9 is similarly arranged with the back on the other plane side. The desk 9 has a top plate 91 mounted horizontally on a pair of left and right legs 92. In this embodiment, the partition 106 and the desk 9 are provided independently to constitute one unit as a desk with an air conditioner. However, the partition 106 and the desk 9 are provided integrally to provide a desk with an air conditioner. It may be configured. That is, the task air conditioner may be provided on a desk that is configured integrally with the partition.

  Each office worker sits in front of the desk 9 and performs office work and other work toward the partition 106. That is, the desk-side space of each partition 106 is a task area. In the following description, for each partition 106 (task air conditioner 1), the task area side to be air-conditioned is the front side, the opposite side is the depth side, and the width direction of the desk, that is, the width direction of the task area is the left-right direction. .

  On the task area side surface (exterior panel) 11 of the task air conditioner 1, the air outlet 30 of the task air conditioner 1, the suction port 10, the operation unit 8, and the lower air outlet 60 are provided. The air outlet 30 blows out air whose temperature is adjusted toward the task area side from a position corresponding to the upper part of the task area in the casing of the partition 106. Further, the air outlet 30 is formed in a slit shape that is long in the width direction of the task area, the upper portion of the air outlet 30 is an opening 301, and the restriction member that restricts the air passing through the lower portion of the air outlet to the lower portion of the air outlet 30 302 is provided. The restricting member 302 is a member having air permeability (a ventilation member), and the surface on which the ventilation member at the lower part of the air outlet 30 is provided can be formed of an air permeable material and an air permeable structure.

The suction port 10 is disposed below the blower outlet 30 and above the top plate 91 of the desk 9 and sucks air in the task area. In the present embodiment, the intake port 1 is taken into consideration for maintainability.
Although 0 is arranged above the top plate 91 of the desk 9, the suction port 10 may be provided below the top plate 91. Further, the suction port 10 may be provided above and below the top plate 91.

  The task air conditioner 1 of the present embodiment has two task air conditioners 1 on one screen 106 so as to air-condition the task areas located on both sides of the partition 106, that is, the front side and the back side in FIG. Is provided.

  FIG. 3 schematically shows a state in which the exterior panel 11 facing the task area is removed from the casing of the partition 106, and the blowout chamber 3, the coil 2, and the suction chamber are provided in the casing of the partition 106. 4. It has the control part 5 and the lower blower outlet 60. In this embodiment, since the two task air conditioners 1 are provided in the partition 106, the blow chamber 3, the coil 2, and the suction chamber are similarly provided on the surface opposite to the surface shown in FIG. 4 etc. are provided.

  FIG. 4 is a view showing the blowout chamber 3, FIG. 4 (a) is a front view, FIG. 4 (b) is a view showing an internal configuration from the front side, and FIG. 4 (c) is a rear view. Here, the front surface is a surface on the task area side when attached to the partition 106. The blow-out chamber 3 is a box-shaped member having a rectangular shape on the front left side and extending obliquely upward on the right side, as shown in FIG. 4 (a), and has a slit-like opening as an outlet 30 on the upper right side of the front. In addition, the back surface (FIG. 4C) has an opening 33 through which the temperature-controlled air is introduced. Further, as shown in FIG. 4B, guide vanes 32 are provided in the blowout chamber 3 so as to divide the width of the air supply path equally from the opening 33 side to the blowout port 30.

  FIG. 5 is a view showing the suction chamber 4, FIG. 5 (a) is a front view, and FIG. 5 (b) is a rear view. As shown in FIG. 5A, the suction chamber 4 is a trapezoidal box-like member in which the upper right corner of the rectangle is obliquely cut when viewed from the front. In front of the suction chamber 4, there are an opening 42 through which air sucked from the suction port 10 of the partition 106 is introduced and an opening 41 through which air in the suction chamber 4 is sucked out.

  In FIG. 6, the principal part of the task air conditioner 1 that air-conditions the task area on the near side is shown, and the coil 2 is attached in front of the opening 13c of the intermediate plate 13 provided in the center in the depth direction inside the partition 106, A fan 7 is attached to the openings 13 a and 13 b of the intermediate plate 13. The suction chamber 4 is attached to the inner surface of the intermediate plate 13 so that the openings 41 and 42 coincide with the openings 13 a to 13 c of the intermediate plate 13. The blowing chamber 3 is attached to the front surface of the middle plate 13 so that the fan 7 attached to the openings 13a and 13b of the middle plate 13 is fitted into the opening 33 (FIG. 4C) on the rear surface of the blowing chamber.

  Further, a lower outlet fan 6 and a lower outlet chamber 62 are provided on the inner side of the lower outlet 60, and the lower outlet chamber 62 is connected to the outlet chamber 3 through a duct 61. In the present embodiment, the lower air outlet 60 (FIG. 2) is provided at the lowermost center in the left-right direction, but is not limited thereto, and may be provided at other positions, for example, below the top plate 91 of the desk 9. If it is good. A plurality of lower outlets 60 may be provided. That is, a plurality of lower blowout mechanisms such as the lower blowout fan 6 and the lower blowout chamber 62 connected to the blowout chamber 3 through the duct 61 may be arranged. The lower blowing mechanisms 60, 61, and 6 are not necessarily provided and may be omitted. In particular, when the task air conditioner is used only during cooling, the lower blowing mechanisms 60, 61, 6 may not be provided.

FIG. 7 shows a longitudinal section of a main part of the task air conditioner 1 housed in the partition 106. A filter 12 is provided inside the suction port 10, the coil 2 is positioned on the back side of the filter 12, and a suction chamber 4 is provided on the back side surface of the intermediate plate 13. Further, the blowout chamber 3 is provided on the front side of the fan 7, and an air supply path 37 from the fan 7 to the blowout port 30 is formed. The air supply path 37 is formed vertically upward from the fan 7 toward the air outlet 30 in the vertical cross section shown in FIG. 7, and inside the air outlet 30, the bent portion 31 causes the air outlet side, that is, the task area. It is bent to the side. In the air supply path 37, bulging portions 38 and 39 are provided on the upstream side of the bent portion 31 in the air supply direction, and the width of the air supply path 37 in the depth direction is narrowed. Further, the bulging portion 38 provided on the front surface of the air supply path 37 has a surface (lower guide surface) 381 extending from the lower end 30a of the opening as the air outlet 30 to the opposite side to the air blowing direction. doing. In the present embodiment, the lower guide surface 381 is formed horizontally. As a result, the air sent upward from the fan 7 via the air supply path 37 is bent toward the task region side by the bent portion 31, and is applied to the tip portion (upper guide surface) 311 and the lower guide surface 381 of the inner surface of the bent portion 31. Guided and blown to the task area side.

  FIG. 8 is a comparative example for explaining the configuration of the outlet 30, and FIG. 9 is a diagram showing an example of the outlet 30. The air outlet 130 shown in FIG. 8A differs from the air outlet 30 in FIG. 7 in that the bulging portion 38 is omitted, and the other configurations are the same. In the configuration without the bulging portion 38 as shown in FIG. 8A, among the air SA that travels upward through the vertical air supply path 37, a part of the air SA <b> 1 that passes near the back surface of the exterior panel 11 is Since there is little influence of a member that changes the direction of the air SA such as the bent portion 31 and the inertia that has advanced upward in the air supply path 37 is dominant, the air is blown upward from the air outlet 30. Further, along with some of the air SA1 blown upward, the other airs SA2 and SA3 are also blown upward from the horizontal direction. When the bulging portion 38 is not provided, that is, the lower guide surface 381 formed by the bulging portion 38 is not provided, the air SA is blown upward from the horizontal direction and deviates from the task area. This is undesirable.

  Therefore, as shown in FIG. 8B, the nozzle 330 communicating with the air supply path 37 is provided so as to protrude from the exterior panel 11 on the task area side of the partition 106 to the task area side in the horizontal direction. Let the opening of the edge part of the side be the blower outlet 30. FIG. In this way, the nozzle 330 is provided, and the air SA that has advanced upward through the vertical air supply path 37 is bent at the bent portion 31 and then immediately blown out. Instead, the air SA is guided by the nozzle 330 in the horizontal direction and blown out. The direction is determined and the air is blown out from the air outlet 30. That is, the upper surface of the inner wall of the nozzle 330 is the upper guide surface 311, the lower surface of the inner wall is the lower guide surface 381, and the air SA is guided by the upper guide surface 311 and the lower guide surface 381 and blown horizontally toward the task area side. . If the nozzle 330 is configured to extend horizontally from the exterior panel 11 as shown in FIG. 8B, the flow of the entire air SA including the partial air SA1 passing near the back surface of the exterior panel 11 is horizontal. Since the air SA is blown out after changing to, the air SA can be blown out in the horizontal direction, and air can be appropriately supplied into the task area.

  However, when the nozzle 330 protrudes from the exterior panel 11 as shown in FIG. 8 (b), there is a problem that this protruding portion may become an obstacle and is aesthetically undesirable. Therefore, in the present embodiment, as shown in FIG. 7, the opening provided in the exterior panel 11 is used as the air outlet 30, and the upper guide surface 311 and the lower guide surface 381 that determine the direction of air blown from the air outlet 30 are used as the exterior panel 11. It was set as the structure arrange | positioned more inside. Specifically, a bent portion 31 is disposed at the upper end of the air supply path 37 inside the air outlet 30, and the surface on the air supply path side of the bent portion 31 is substantially arcuate in the vertical cross section shown in FIG. 7. The front end portion, that is, the portion on the outlet 30 side is formed horizontally to form the upper guide surface 311. Further, in the air supply path 37, a bulging part 38 is provided on the surface of the air supply path 37 on the task area side upstream of the bent part 31 in the air supply direction, and the upper end of the bulging part 38 is connected to the air outlet 30. A surface (lower guide surface) 381 is formed which is located at the height of the lower end 30a of the opening and extends from the lower end 30a to the side opposite to the air blowing direction. As a result, the partition 106 incorporating the task air conditioner 1 of the present embodiment has a flat and highly aesthetic appearance without providing a disturbing member protruding on the task area side surface (exterior panel) 11. In addition, air can be blown out from the air outlet 30 in the horizontal direction, and air can be appropriately supplied to the task area.

  In addition, although the bending part 31 of this embodiment showed the example made into substantially circular arc shape in the longitudinal cross-section shown in FIG. 7, not only this but the air SA which advanced upwards through the air supply path 37 is made into the task area | region side. Any shape can be used as long as it can be deflected to the right. FIG. 9 is a diagram illustrating another example of the bent portion. A bent portion 31a shown in FIG. 9A has a shape in which a metal flat plate is bent in multiple stages by press working. The bent portion 31 a has a horizontal surface 311 on the outlet 30 side, a vertical surface 312 on the upstream side in the air supply direction, and an inclined surface 313 that connects the horizontal surface 311 and the vertical surface 312. The bent portion 31a has a shape bent in two stages, but is not limited thereto, and may have a shape bent in three or more stages. Even if the bent portion 31a having a combination of flat surfaces is used instead of the bent portion 31 shown in FIG. 7, the air SA traveling upward through the air supply path 37 can be deflected to the task area side, and the air can be easily prevented. SA can be blown out. And when it is the shape which combined the plane like the bending part 31a, it can form by simple press work and there exists an advantage that manufacture becomes easy.

  9B is an L-shaped member, and has a horizontal surface 311 on the outlet 30 side and a vertical surface 312 on the upstream side in the air supply direction. The bent portion 31b may be formed by pressing a metal flat plate, or may be a general-purpose product such as an L-shaped casing. Even if the bent portion 31b having such a simplified shape is employed instead of the bent portion 31 of FIG. 7, the air SA traveling upward through the air supply path 37 can be deflected to the task area side, and the air SA can be prevented without any problem. Can be blown out. And if it is an L-shaped member like the bending part 31b, a general purpose product can be used and manufacture will become easier.

  Further, in the configuration shown in FIG. 7, the bulging portion 39 is provided at a position facing the bulging portion 38 of the air supply path 37, but the bulging portion 39 may be omitted. FIG. 10 is a diagram illustrating an example in which the bulging portion 39 is omitted.

  The task air conditioner 1 shown in FIG. 10 has a configuration in which the bulging portion 39 is omitted, the bent portion 31 is disposed on the back side, and the bulging portion 38 is extended on the back side, as compared with FIG. Further, a bulging portion 35 is provided on the back surface upstream of the bulging portion 38 of the air supply path 37 in the air supply direction. Note that the bulging portion 35 is not an essential component and can be omitted, but by providing the bulging portion 35 and the bulging portion 38 in the air supply path 37, internal sound such as driving sound of the fan 7 can be obtained. Is suppressed from being discharged from the air outlet 30, and quietness is improved. Therefore, it is desirable to provide the bulging portion 35.

  As described above, in the configuration of FIG. 10, the air supply path 37 is disposed on the back side as compared with FIG. 7, so that the horizontal length of the upper guide surface 311 and the lower guide surface 381 can be increased. The direction of the air blown out from the outlet 30 can be determined more reliably.

《Air conditioning control》
The air conditioner 104 shown in FIG. 1 adjusts the return air RA circulated through the return air path 147 and the outside air OA taken from the outside with the coil 141 to a predetermined temperature, and a humidifier as necessary. The air is humidified at 142, blown by the blower 143, and blown out from the air outlet 144 provided in the ceiling 121 of the office room 102 through the air supply path 146, thereby air-conditioning the office room 102.

  On the other hand, the task air conditioner 1 housed in the partition 106 is operated by each office worker, and individually air-conditions the task area of each office worker. In particular, in the present embodiment, two task air conditioners 1 are provided in the partition 106, and the task areas 10A and 10B (FIG. 1) on both sides partitioned by the partition 106 are air-conditioned.

Specifically, the air in the task area is sucked from the suction port 10 by the conveying force of the fan 7 in the task air conditioner 1 shown in FIG. The temperature-controlled air is blown from the suction chamber 4 to the blow-out chamber 3 by the fan 7, sent upward through the air supply path 37, bent to the task region side by the bent portion 31, and blown out. The air is blown from 30 to the task area side substantially horizontally or slightly upward. Here, when the task air conditioner 1 and the ambient air conditioner are in cooling operation, the temperature of the air blown out from the task air conditioner 1 is higher than the temperature of the surrounding area (ambient area) air-conditioned by the ambient air conditioner. The temperature is controlled to be low. For this reason, the blown out air descends gradually and becomes a mountainous airflow. For example, in the ambient air conditioner, the temperature of the supply air blown out from the outlet 144 is set to 13 ° C. to 20 ° C., and the temperature of the ambient region, particularly the temperature surrounding the task regions 10A and 10B is set to 26 ° C. to 28 ° C. Air conditioning. On the other hand, the task air conditioner 1 built in the partition 106 sets the temperature to be blown out from the outlet 30 to 20 ° C to 23 ° C. Thus, since the temperature of the air blown out from the task air conditioner 1 is lower than the ambient temperature of 26 ° C. to 28 ° C., which is 20 ° C. to 23 ° C., the blown out air gradually descends and becomes a mountainous airflow It becomes. The temperature in the task area varies depending on the air volume set by each office worker, but is air-conditioned to about 26 ° C., for example.

  Moreover, since the restriction member 302 is provided in the lower part of the blower outlet 30 of the task air conditioner 1, the degree of the descent and the spread of the air passing through the upper opening 301 of the blower outlet 30 and the air passing through the lower part of the blower outlet 30 are increased. The degree of is different. For example, the air that passes through the opening 301 at the upper part of the air outlet 30 and is not restricted by the restricting member 302 becomes a mountainous air current 1a that goes to a position away from the air outlet 30 at a high flow rate. That is, the air passing through the upper opening 301 of the air outlet 30 becomes an airflow covering the peripheral portion of the task area. In other words, the air passing through the upper opening 301 of the air outlet 30 becomes an air flow that wraps around the task area. On the other hand, the air passing through the lower part of the blower outlet 30 receives resistance when passing through the restricting member 302 and is slowed down and spreads while surrounding air is entrained, and spreads at a position closer to the blower outlet 30 than the upper airflow 1a. It becomes a descending airflow 1b. That is, the air passing through the restriction member 302 becomes an air current that spreads in the inner portion of the task area. Thus, the entire area of the task area is formed by forming an air flow 1a that air-conditions the distal part of the task area toward a position away from the air outlet 30 and an air current 1b that air-conditions the worker's hand and upper body near the air outlet 30. Comfortably air-conditioned over. In other words, the airflow that wraps around the task area due to the difference between the airflow formed by the air passing through the opening 301 at the upper part of the air outlet 30 and the airflow formed by the air passing through the restricting member 302 provided at the lower part of the air outlet 30. And an airflow spreading inside the task area, and the inside of the task area can be air-conditioned without being diffused unnecessarily. Further, in the present embodiment, the suction port 10 is provided in the exterior panel 11 on the task area side of the casing of the partition 106 similarly to the air outlet 30, and the task air conditioner 1 is blown out by sucking air on the task area side. The lowered air is returned to the task air conditioner 1. As a result, the air in the task area does not diffuse unnecessarily, and the task area can be efficiently air-conditioned individually. In addition, since the air in each task area does not diffuse unnecessarily, the influence on other areas is small and mixing loss can be suppressed.

  In the task air conditioner 1 of the present embodiment, the temperature of the supply air blown from the outlet 30 during cooling is 20 ° C. to 23 ° C. as described above, and the temperature of the heat medium supplied to the coil 2 via the pipe 21 is 13. A relatively high-temperature cold water is supplied at a temperature of from 17 ° C to 17 ° C. Thereby, the dew condensation in the coil 2 at the time of cooling can be suppressed, the apparatus structure can be simplified by reducing the drain piping, and the maintenance performance can be improved by eliminating the trouble of cleaning.

  Furthermore, the task air conditioner 1 according to the present embodiment supplies hot water as a heat medium supplied to the coil 2 via the pipe 21 so that the air sucked from the suction port 10 is heat-exchanged and heated by the coil 2. Heating can be performed by blowing from the outlet 30 or the lower outlet 60. For example, an air volume adjusting damper (not shown) is provided in the air supply path 37 to reduce or stop the air blown out from the blower outlet 30 so that warm air is blown mainly from the lower blower outlet 60 to the feet of the worker. On the other hand, the ambient air conditioner performs air conditioning so that the temperature of the ambient area surrounding the task areas 10A and 10B is lower than the temperature of the task areas 10A and 10B.

  FIG. 11 is an explanatory diagram of the flow of warm air blown from the lower outlet 60 during heating. The warm air 1c blown out from the lower outlet 60 rises gradually because it is higher than the ambient temperature. However, since the top plate 91 of the desk 9 is provided above the lower air outlet 60, a part of the warm air 1 a 1 is blocked by the top plate 91 and stays in the space below the top plate 91. Further, the warm air 1c2 that has reached the position farther from the lower air outlet 60 than the front end 91a of the top plate 91, that is, near the seating position of the office worker, rises beyond the top plate 91 and enters the space above the top plate 91. The reached warm air 1c3 is sucked from the suction port 10.

  As described above, the task air conditioner 1 of the present embodiment blows out the warm air 1c from the lower air outlet 60, sucks in the warm air 1c3 reaching the space above the top plate 91 of the desk 9 from the air inlet 10, and within the task area. By circulating, the air in the task area is not diffused wastefully even during heating, and the air in the task area can be efficiently and individually performed. In addition, since the air in each task area does not diffuse unnecessarily, the influence on other areas is small and mixing loss can be suppressed.

  Further, in the task air conditioner 1 of the present embodiment, each office worker can individually adjust the air conditioning setting. The operation unit 8 (FIG. 2) of the task air conditioner 1 is electrically connected to the control unit 5 (FIG. 3). The control unit 5 includes the flow rate adjusting valve 29, the lower outlet fan 6 (FIG. 6), and the fan. 7. It is electrically connected to a damper (not shown) on the air supply path. The operation unit 8 is a user interface for setting the task air conditioner 1 such as a switch, a selection button, and an adjustment volume. Thus, when the office worker operates the operation unit 8, the control unit 5 controls the flow rate adjustment valve 29, the lower outlet fan 6 (FIG. 6), the fan 7, a damper (not shown) on the air supply path, and the like. Adjust air conditioning capacity and air volume. The adjustment of the task air conditioner 1 is not limited to manual operation, but a thermal image sensor (not shown) is connected to the control unit 5 to take a thermal image of the office worker or task area, and the temperature of the office worker or task area May be recognized by the control unit 5 and the task air conditioner 1 may be adjusted based on this temperature.

  For example, the coil 2 has a heat medium circulated between the coil 21 and a heat source (not shown) via the pipe 21, and the flow rate adjusting valve 29 turns on / off the circulation of the heat medium and the flow rate of the heat medium. Be controlled.

  Moreover, the air volume of the air which blows off from the blower outlet 30 is adjusted by controlling the rotation speed of the fan 7. FIG. This makes it possible to make adjustments such as wanting to increase air conditioning when returning from the office to the office 102 or weakening air conditioning because there is little need for air conditioning.

  Similarly, the air volume of the air blown out from the lower air outlet 6 is adjusted by controlling the rotation speed of the lower air outlet fan 6. This increases the amount of air blown out from the lower outlet 6 when the foot or the seat surface is stuffy. Alternatively, it is possible to make an adjustment such that the blowing from the lower outlet 6 is stopped so that the feet do not cool.

FIG. 12 is a diagram showing the state of airflow when the air volume is changed to weak, medium, and strong. FIG. 12A shows a case where the air flow is set to a low value, for example, 25 m ³ / h. The air flow mainly flows from the chest of the worker toward the hand.

FIG. 12B shows a case where the air volume is set to the inside, for example, 34 m ³ / h, and the air flow mainly flows from the face of the office worker toward the chest.

FIG. 12 (c) shows a case where the air volume is set strong, for example, 61 m ³ / h.
Airflow flowed mainly from the head of the office worker to the shoulder area.

  As described above, when the air volume of the air blown from the air outlet 30 is changed, the position and strength of the air current hit change, so the office worker adjusts to a desired air volume according to the situation. As a result, the worker himself can select an appropriate state according to the situation, so that the satisfaction of each worker is improved.

  In addition, when the temperature distribution when this air volume was changed was measured, it was confirmed that the air cooled from the surroundings at any air volume descended with distance from the outlet 30 and was not diffused wastefully.

  The task air conditioner 1 of the present embodiment sets the sensible heat of one person and the sensible heat of illumination and OA equipment as a cooling load, and is set to 100 W to 150 W, for example. Alternatively, the cooling load may be set to 200 W by providing a margin for cases such as when the office worker returns from going out.

  By allowing each task air conditioner to handle the load of each task area in this way, the air conditioning in the ambient area by the ambient air conditioner is mainly ventilated, and by suppressing the degree of air conditioning within an allowable range, The energy saving property of the entire air conditioning system can be improved.

《Example of restriction member》
FIG. 13 is a diagram illustrating a specific example of the limiting member provided at the air outlet 30. In the example of FIG. 13A, a punching plate 302 is provided as a limiting member, the length in the left-right direction of the air outlet 30 is 500 mm, and the height H in the vertical direction is 33 mm. Among these, the height H1 of the upper opening 301 is 7 mm, and the height H2 of the punching plate 302 is 26 mm.

  In this case, the ratio of the opening area of the opening 301 and the restricting member 302 was set as the opening 301: the restricting member 302 = 1: 3-4.

  The punching plate 302 has a punching hole diameter of 5 mm and a pitch of 8 mm with a 60-degree zigzag pattern and an aperture ratio of 35.4%.

  As a result, the ratio of the air passing through the opening 301 and the restricting member 302 became the opening 301: the restricting member 302 = 1: 1, and the air blown from the outlet 30 to the task area could be appropriately distributed.

  Further, the punching hole diameter or pitch of the punching plate 302 may be changed between the upper and lower sides of the punching plate. For example, the upper opening ratio of the punching plate 302 may be increased and the lower opening ratio may be decreased. Further, two punching plates 302 may be provided in an overlapping manner, and the aperture ratio may be changed by adjusting the overlap between the punching holes of these punching plates 302 and the bone portion.

  Furthermore, the ratio of the opening area of the opening 301 and the limiting member 302 may be changed by making the punching plate 302 movable in the vertical direction.

Although FIG. 13A shows an example of a punched punched plate as the limiting member 302, the present invention is not limited to this, and a parallel punching plate provided with holes in parallel as shown in FIG. It may be used. Also, the shape of the hole may be other than a round hole such as a square hole, an oblong hole, a hexagonal hole, or a rhombus. The restricting member 302 is not limited to a punching plate, and may be any member that has air permeability (a ventilation member), and may be formed of an air permeable material or an air permeable structure. For example, the limiting member 302 may be any member that can change the flow of air supply, such as a mesh, a lattice, a louver, or a combination thereof. The limiting member 302 is not limited to a member having a clear opening as a vent hole such as a punching plate or a mesh, but may be a member that allows air to pass through a fine hole such as a nonwoven fabric or a sponge. good. The limiting member 302 can be made of any material such as metal or plastic depending on durability, maintainability, ease of formation, and the like. In addition, when using a net | network, a nonwoven fabric, etc. made from a synthetic resin, you may use the structure which fixes a net | network or a nonwoven fabric to a framework.

1 Task air conditioner 2 Coil 3 Blowing chamber 4 Suction chamber 5 Control unit 7 Fan 8 Operation unit 9 Desk 10 Suction port 12 Filter 13 Middle plate 21 Pipe 29 Flow control valve 30 Blowout port

Claims (4)

An air conditioner incorporated in a housing of a partition that partitions a task area where an operator works on a desk,
A first air conditioner that harmonizes the air supplied toward the first task area formed on one side of the partition by the partition;
A second air conditioner that harmonizes the air supplied toward the second task region formed on the side opposite to the one side of the partition by the partition;
The first air conditioner is arranged to be shifted to either one of the left and right sides in the housing when viewed from the first task area side,
The second air conditioner is arranged so as to be offset toward the opposite side of the left and right sides of the housing when viewed from the first task area side ,
The first air conditioner and the second air conditioner each include a coil that controls the temperature of air and a fan that blows air.
Air conditioner. An air conditioner incorporated in a housing of a partition that partitions a task area where an operator works on a desk,
A first air conditioner that harmonizes the air supplied toward the first task area formed on one side of the partition by the partition;
A second air conditioner that harmonizes the air supplied toward the second task region formed on the side opposite to the one side of the partition by the partition;
The first air conditioner is arranged to be shifted to either one of the left and right sides in the housing when viewed from the first task area side,
The second air conditioner has both left and right sides in the housing as viewed from the first task area side.
Are arranged on the opposite side to the one side,
The first air conditioner includes a first coil and a first fan that are arranged to be offset toward the one side in the casing, and left and right sides of the casing when viewed from the first task area side. A first blow-out chamber in which an opening serving as a blow-out port is located at the center of the direction,
The second air conditioner includes a second coil and a second fan that are disposed to be offset from the opposite side of the casing, and a left-right direction of the casing when viewed from the second task area side. center opening serving as the outlet is closed and a second blow chamber located in,
The first blowing chamber and the second blowing chamber are spaced apart from each other;
Air conditioner.   Further comprising an intermediate plate provided at the center in the depth direction inside the partition;
  The middle plate includes the first fan and the first blow-out chamber of the first air conditioner, and the second fan and the second blow-out chamber of the second air conditioner. Attached,
  The air conditioner according to claim 2.   A guide vane that is provided in a part of the air supply path of the first air conditioner and a part of the air supply path of the second air conditioner, and further divides the width of the air supply path;
  The air conditioner according to any one of claims 1 to 3.

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