JP2012093043A - Air type radiation panel device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a suitable radiation effect and a convection effect with a simple structure without any restriction on the position of an intake for receiving conditioned air.SOLUTION: A radiation panel device is provided with: a substantially box-shaped panel body 2 including a duct connection part 22 formed on the back 21 to be connected to a duct 100, and a radiation panel 23 which is a plane facing the duct connection part 22 and is provided with a radiation plane part 23a with a plurality of blowout holes 2a for discharging conditioned air to the outside and a blowout hole 23b for blowing the conditioned air to the outside; a porous body 3 which is arranged in the panel body 2 to face the radiation plane part 23a and is porous for suppressing a flow of the conditioned air to discharge the conditioned air equally from the blowout holes 2a; and a damper 4 which opens and closes the blowout hole 23b.

Description

  The present invention relates to a pneumatic radiant panel device having both radiation (radiation) and convection functions.

  In air conditioning, an air conditioning apparatus having both a radiation method using radiant heat and a convection method is known in the convection method that blows temperature-conditioned conditioned air because the airflow is greatly uncomfortable (for example, , See Patent Document 1). In this air conditioner, a damper mechanism is provided in the panel unit, and by switching the damper mechanism, the conditioned air is guided to the fan unit and the bottom of the panel for radiant air conditioning, or is guided to the outlet for convection air conditioning. Further, a vane mechanism is provided at the outlet, and the convection heat transfer effect is enhanced by allowing the conditioned air to flow along the outer surface of the panel bottom.

Japanese Patent Laid-Open No. 05-141718

  By the way, in the air conditioning apparatus as described above, conditioned air is guided to the fan part and the panel bottom part to perform radiant air conditioning. Therefore, it is necessary to flow conditioned air along the panel bottom part which is a radiation surface. That is, it is necessary to flow in the conditioned air from the end of the panel unit and flow the conditioned air along the bottom of the panel so that the temperature at the bottom of the panel is uniform, and the inlet of the conditioned air is limited. As a result, there arise problems that the installation conditions of the panel unit are limited and the construction becomes complicated. Moreover, even if conditioned air flows along the bottom of the panel, it is difficult to equalize the temperature over the entire surface of the bottom of the panel due to the flow of conditioned air, temperature changes, etc., and an even and proper radiation effect cannot be obtained. . Further, in order to enhance the convective heat transfer effect, it is necessary to provide a vane mechanism, and the structure becomes complicated.

  Accordingly, an object of the present invention is to provide a pneumatic radiant panel device having a simple structure and capable of obtaining an appropriate radiation effect and convection effect without restricting the position of the inlet of conditioned air. Yes.

  In order to achieve the above object, the invention according to claim 1 is a pneumatic radiant panel device in which conditioned air whose temperature is adjusted is sent from a duct and performs radiant air conditioning using radiant heat generated by the conditioned air. The duct connection part to which the duct is connected is provided on the back side, and a plurality of blowout holes for allowing the conditioned air to flow out are formed in the radiating panel which is a surface facing the duct connection part. A panel body provided with a radiating surface portion and a blow-out port for blowing out the conditioned air to the outside, and provided in the panel body so as to face the radiating surface portion, and is porous and suppresses the flow of the conditioned air. And a porous body for uniformly flowing out the conditioned air from the respective blowing holes, and an opening / closing means for opening and closing the blowing ports.

  According to this invention, in a state where the opening / closing means is closed, the conditioned air is not blown out from the outlet, and convection air conditioning from the outlet is not performed. On the other hand, radiant air conditioning is performed on the radiating surface portion of the radiating panel, and conditioned air is flowed out from each outlet hole of the radiating panel to perform convective air conditioning. At this time, the conditioned air is evenly discharged from the blowout holes by the porous body, and the temperature is uniform over the entire surface of the radiation surface portion. Further, in a state where the opening / closing means is opened, the porous body becomes a resistance to the flow of the conditioned air, and the conditioned air is blown out from the blowing port to the outside. That is, convection air conditioning from the outlet is mainly performed.

  According to a second aspect of the present invention, in the pneumatic radiating panel device according to the first aspect, a plurality of the outlets are provided, and the opening / closing means is provided for each of the outlets.

  According to a third aspect of the present invention, in the pneumatic radiant panel device according to the first or second aspect, the first temperature measuring means for measuring the temperature of the conditioned air in the panel body and the external temperature are measured. Based on the measurement results of the second temperature measuring means, the humidity measuring means for measuring the external humidity, the first temperature measuring means, the second temperature measuring means and the humidity measuring means, the opening and closing means is controlled to open and close. And a control means.

  According to the present invention, for example, the control means calculates the external dew point based on the measurement results of the second temperature measurement means and the humidity measurement means, and the measurement result of the first temperature measurement means (the temperature of the conditioned air). When is lower than the dew point, the opening / closing means is opened. Thereby, it switches to the convection air conditioning from a blower outlet, and prevents dew condensation of a radiation panel (radiation surface part).

  According to a fourth aspect of the present invention, in the pneumatic radiant panel device according to the first to third aspects, the conditioned air is connected to an external panel body on a side surface substantially perpendicular to the radiant panel of the panel body. It has a ventilating hole for sending to the external panel body.

  According to the first aspect of the present invention, it is possible to switch between air conditioning mainly based on radiant air conditioning and air conditioning mainly based on convection air conditioning by opening and closing the outlet by the opening / closing means. For example, in a normal time, the opening / closing means is closed and the radiant air conditioning is mainly used, and when a large air conditioning load is required such as when starting (starting up), the opening / closing means is opened and the convection air conditioning is mainly used. In addition, in the state where the opening / closing means is closed, the conditioned air is uniformly discharged from the respective blowout holes by the porous body and the temperature of the entire surface of the radiating surface is equalized. Effect and radiation effect are obtained.

  In addition, since the conditioned air is evenly discharged from the respective blowing holes by the porous body, the duct connection portion may be provided anywhere, the installation conditions and the design conditions are eased, and the workability is improved. In addition, it is not necessary to provide a vane mechanism or the like, and it is only necessary to provide a porous body. Therefore, the structure is simple, and manufacturing and maintenance are easy.

  According to the second aspect of the present invention, since a plurality of outlets and opening / closing means are provided, appropriate and flexible air conditioning according to the air conditioning target, the temperature of the conditioned air, and the like are possible. For example, the radiant panel is vertical, and the outlet and the opening / closing means are provided in the upper and lower portions. Then, by opening / closing the opening / closing means of the upper outlet during cooling, and opening / closing the opening / closing means of the lower outlet during heating, it is possible to appropriately perform the cooling air conditioning and the heating air conditioning by one apparatus.

  According to the third aspect of the present invention, the opening / closing means is controlled to open and close based on the temperature of the conditioned air, the external temperature, and the humidity. More appropriate air conditioning can be performed.

  According to the fourth aspect of the present invention, since conditioned air can be sent to the external panel body through the ventilation port, there is no need to provide a duct connection portion in the external panel body. For this reason, even when installing a large number of panel bodies, there is no need to provide a large number of duct connections (inflow ports) and ducts, and equipment costs can be reduced, while workability is improved and construction costs are reduced. In addition, the space can be saved.

It is sectional drawing which shows the pneumatic radiant panel apparatus which concerns on Embodiment 1 of this invention. It is sectional drawing which shows the pneumatic radiant panel apparatus which concerns on Embodiment 2 of this invention. It is sectional drawing which shows the pneumatic radiant panel apparatus which concerns on Embodiment 3 of this invention. It is a perspective view which shows the pneumatic radiant panel apparatus which concerns on Embodiment 4 of this invention.

  The present invention will be described below based on the illustrated embodiments.

(Embodiment 1)
FIG. 1 is a cross-sectional view showing a pneumatic radiant panel device 1 according to this embodiment. The pneumatic radiant panel device 1 is a device in which conditioned air whose temperature is adjusted is sent from a duct 100 and performs radiant air conditioning using radiant heat generated by the conditioned air, and mainly includes a panel body 2 and a porous body 3. And a damper (opening / closing means) 4.

  The panel body 2 is a rectangular box shape made of metal and having a small thickness, and the inside is a single space. That is, the internal space has no partition and is not partitioned. In addition, a cylindrical duct connection portion 22 to which the duct 100 is connected is provided at the center portion of the back plate 21, and the radiation panel 23 that is a surface facing the duct connection portion 22 has a plurality of blowout holes 2 a. And a blowout port 23b for blowing out conditioned air to the outside.

  The blowout hole 2a is a hole having a size that allows the conditioned air to flow outside, and is formed so that the radiation panel 23 has a predetermined aperture ratio. For example, the length of the panel body 2 is 2000 mm, the width (depth in the drawing) is 500 mm, the outer diameter of the duct 100 is around 100 mm, and the blow holes 2 a having a diameter of 10 mm are formed on the entire surface of the radiation surface portion 23 a with a pitch of 25 mm. ing. By forming such blowout holes 2a, the aperture ratio of the radiation surface portion 23a is about 10%, and a predetermined radiation effect is ensured. Further, an air flow of 0.1 to 0.3 m / second is blown out from each blowout hole 2a, and the opening area is set so that a predetermined amount of conditioned air can be blown out from the blowout opening 23b. . Furthermore, the area ratio between the radiation surface portion 23a and the outlet 23b is set so that predetermined radiation air conditioning and convection air conditioning are performed.

  In this embodiment, such a panel main body 2 can be divided into a radiation panel 23 and a chamber which is another part. However, the panel main body 2 may be divided into a back plate 21 and other parts.

  The porous body 3 is provided in the panel main body 2 so as to be in contact with the entire surface of the radiating surface portion 23a, and controls the flow of conditioned air in the panel main body 2 so that the conditioned air flows out from each blowout hole 2a evenly. It is. Specifically, it is composed of a porous sponge-like and thin plate-like filter, which acts as a resistance to the flow of conditioned air and suppresses the flow of conditioned air. The air does not reach the radiation surface portion 23a directly (immediately), spreads in the horizontal direction in the figure, and flows out almost uniformly from the entire surface of the radiation surface portion 23a.

  Further, the thickness of the porous body 3 is set to approximately half of the inner thickness of the panel body 2. That is, in this embodiment, the inner thickness of the panel body 2 is 100 mm, the radiating panel 23 side is the reference surface (arrangement surface), and the central portion of the porous body 3 facing the duct connecting portion 22 is 60 mm. Other parts are set to 40 mm.

  The damper 4 is configured to permit the conditioned air to be blown from the blowout port 23b, and is disposed between the end of the porous body 3 on the blowout port 23b side and the back plate 21 of the panel body 2, and It rotates about the face plate 21 side as a base point. The damper 4 is opened and closed manually or automatically. Further, a blade 41 for controlling the blowing direction of the conditioned air is provided at the blowout port 23b.

  Next, the operation of the pneumatic radiant panel device 1 having such a configuration will be described.

  When the duct 100 is connected to the duct connecting portion 22 of the panel body 2 and conditioned air such as cold air or warm air is sent from the duct 100, the conditioned air does not blow out from the outlet 23b in the normal operation state where the damper 4 is closed. Convection air conditioning from the outlet 23b is not performed. On the other hand, conditioned air passes through the panel body 2 and the porous body 3 and is transmitted to the radiation surface portion 23a, and radiation air conditioning is performed from the surface of the radiation surface portion 23a by radiation action. At the same time, conditioned air is discharged and discharged from each outlet hole 2a to perform fine convection air conditioning. At this time, as described above, the porous body 3 causes the conditioned air to flow out almost uniformly from the blowout holes 2a on the entire surface of the radiation surface portion 23a, and the temperature on the entire surface of the radiation surface portion 23a becomes uniform.

  Further, when a large air conditioning load is required such as at the time of startup (startup), the damper 4 is opened. As a result, conditioned air is blown out through the vane 41 from the blowout opening 23b. At this time, since the porous body 3 becomes resistance to the flow of conditioned air, the conditioned air flows through the outlet 23b side, and convection air conditioning from the outlet 23b is mainly performed.

  As described above, according to the pneumatic radiant panel device 1, the air conditioning mainly including the radiant air-conditioning and the fine convection air-conditioning and the air conditioning mainly based on the convection air-conditioning are switched by opening and closing the outlet 23 b by the damper 4. be able to. In addition, in a state where the damper 4 is closed, the conditioned air is almost uniformly discharged from the entire surface of the radiation surface portion 23a by the porous body 3. For this reason, the surface temperature of the radiation surface portion 23a is made uniform over the entire surface, so that an appropriate radiation effect can be obtained and a proper, uniform and comfortable convection effect can be obtained. Moreover, since the aperture ratio is set as described above, the radiation effect from the radiation surface portion 23a can be properly maintained. In addition, since the surface temperature of the radiation surface portion 23a is uniform over the entire surface, there is no temperature unevenness, radiation performance is improved, and the area of the radiation surface portion 23a can be reduced. As a result, the pneumatic radiation panel device 1 is manufactured. Costs and installation costs can be reduced.

  Furthermore, when the surface temperature of the radiating surface portion 23a is set to 20 ° C. with cold air, for example, since there is no temperature unevenness, it is possible to increase the blowing temperature by 1 to 2 ° C. compared to normal air cooling, and the evaporation temperature of the refrigerator As a result, the energy of the refrigerator can be saved. That is, when the conditioned air is flowed along the outer surface of the panel as in the prior art, temperature unevenness that partially increases the temperature occurs, so it is necessary to lower the blowing temperature, but according to this embodiment, Since there is no temperature unevenness, it is possible to increase the blowing temperature.

  In addition, since the conditioned air is uniformly discharged from the respective blowout holes 2a by the porous body 3, the duct connection portion 22 may be provided anywhere, the installation conditions and the design conditions are eased, and the workability is improved. Similarly, since uniform radiation air-conditioning and convection air-conditioning are performed by the porous body 3, the outlet 23b can be provided not only at the end of the radiation panel 23, but also at the design and installation properties. . In addition, since it is not necessary to provide a vane mechanism or the like and only the porous body 3 is provided, the structure is simple, and manufacturing and maintenance are facilitated. In addition, since the panel body 2 only needs to have a space for disposing the porous body 3, the inner thickness of the panel body 2 can be reduced, and the pneumatic radiating panel device 1 can be installed on the back of the ceiling or the wall. It becomes possible to arrange | position easily.

  In addition, by closing the damper 4 completely, opening it completely, or adjusting the opening, air conditioning operation mainly using radiant air conditioning, air conditioning operation mainly using convection air conditioning, or radiation air conditioning and convection air conditioning. The combined air conditioning operation enables optimum air conditioning according to the external environment and air conditioning load.

  Further, for example, when the temperature of the conditioned air is DB16 ° C., the humidity is RH 80%, the surface temperature of the radiation surface portion 23a is 18 ° C., the room temperature (external temperature) is DB 27 ° C., and the humidity is RH 80%, the conditioned air (air flow) When the mixing ratio between the air and the room air is about 2: 1, the temperature of the mixed air is DB20 ° C, the humidity is RH84%, the dew point is 18 ° C, and the radiation surface portion 23a is condensed. On the other hand, when the mixing ratio is about 1: 1, the temperature of the mixed air is DB 21.6 ° C., the humidity is RH 84%, the dew point is 19.7 ° C., and the radiation surface portion 23a is not condensed. Further, when there is no airflow from the radiation surface portion 23a, when the room temperature is DB27 ° C. and the humidity is RH 80%, the dew point is 18.6 ° C., and the radiation surface portion 23a is condensed. Thus, by performing radiation air conditioning and convection air conditioning on the radiation surface portion 23a, it is possible to prevent dew condensation and to widen the operating air condition compared to the case where convection air conditioning is not performed (no airflow is flowed). it can.

(Embodiment 2)
FIG. 2 is a cross-sectional view showing the pneumatic radiant panel device 10 according to this embodiment. The same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted. The same applies to the third and fourth embodiments.

  In this embodiment, two outlets 23b and 23c are provided, dampers 4 and 5 are provided for each outlet 23b and 23c, and the radiating panel 23 is arranged vertically. And the configuration is different. In other words, the radiating panel 23 is arranged so as to be positioned vertically along the wall of the room, the cooling outlet 23b is formed in the upper part of the radiating panel 23, and the heating outlet 23c is formed in the lower part. A cooling damper 4 for opening and closing the cooling outlet 23b and a heating damper 5 for opening and closing the heating outlet 23c are disposed in the panel body 2, and the cooling outlet 23b includes a cooling damper. Heating blades 51 are attached to the blades 41 and the heating outlet 23c.

  During cooling, the heating damper 5 is closed, and the cooling damper 4 opens and closes the cooling outlet 23b, so that the cool air becomes a downward air flow to cool the room, and during heating, the cooling damper 4 is closed. By opening and closing the heating outlet 23c with the heating damper 5, the warm air becomes an upward air flow to heat the room. In this way, the cooling air conditioning and the heating air conditioning can be appropriately performed with one apparatus. Further, by using the pneumatic radiating panel device 10 as an indoor wall, a partition, a partition, or a partition for a personal desk, it is possible to perform space-saving and energy-saving air conditioning. In addition, since only radiation air conditioning, only convection air conditioning, or combined use of radiation air conditioning and convection air conditioning can be performed, air conditioning according to individual differences can be performed appropriately. Furthermore, it is possible to provide a more comfortable air-conditioned space by calculating a comfort evaluation index (PMV value) and switching between the radiation air-conditioning and the convection air-conditioning based on the calculation result.

(Embodiment 3)
FIG. 3 is a cross-sectional view showing the pneumatic radiant panel device 20 according to this embodiment. In this embodiment, a first thermometer (first temperature measuring means) 61 for measuring the temperature of conditioned air in the panel body 2 is disposed in the panel body 2 to measure room temperature (external temperature). A second thermometer (second temperature measuring means) 62 and a hygrometer (humidity measuring means) 63 for measuring the humidity in the room are arranged on the front side of the radiation panel 23. A controller (control means) 64 that controls the opening and closing of the damper 4 based on the measurement results of the first thermometer 61, the second thermometer 62, and the hygrometer 63 is disposed in the panel body 2. .

  Specifically, the controller 64 calculates the dew point in the room based on the room temperature by the second thermometer 62 and the humidity by the hygrometer 63 during cooling, and the temperature of the conditioned air by the first thermometer is higher than the dew point. Determine whether it is low. And when lower than a dew point, the damper 4 is opened and it switches to the convection air conditioning from the blower outlet 23b, and the dew condensation of the radiation | emission surface part 23a is prevented.

  Here, the temperature of the conditioned air in the panel body 2 is considered to be approximately the same as the surface temperature of the radiation surface portion 23a, and the temperature of the conditioned air is measured by the first thermometer 61. You may measure directly. Further, the controller 64 controls the opening and closing of the damper 4 so as to prevent dew condensation. However, the control content is not limited to this, and the air conditioning target is controlled by opening and closing based on the temperature, room temperature, and humidity of the conditioned air. It is possible to perform more appropriate air conditioning according to the situation. Furthermore, this embodiment may be applied to the second embodiment, and the cooling damper 4 may be controlled to open and close as described above during the cooling in the second embodiment.

(Embodiment 4)
FIG. 4 is a perspective view showing a pneumatic radiating panel device 30 according to this embodiment. In this embodiment, the side surface 24 substantially perpendicular to the radiation panel 23 of the panel body 2 is provided with a ventilation port 24 a that is connected to the external panel body 110 and sends conditioned air to the external panel body 110.

  That is, the side surface 24 is positioned on the paper surface in FIG. 1, and a ventilation port 24 a is formed on the side surface 24. An external ventilation port 110 a is formed on the side surface of the external panel body 110, and a packing ventilation port (not shown) is also formed in the plate-like packing 111. The packing 111 is disposed between the panel device 30 and the external panel body 110 so that the ventilation port 24a, the external ventilation port 110a, and the packing ventilation port coincide with each other. In this state, the flanges of the panel device 30 and the external panel body 110 are connected with bolts and nuts. Thereby, the conditioned air in the panel device 30 is sent to the external panel body 110 through the ventilation port 24a, the packing ventilation port, and the external ventilation port 110a.

  As described above, conditioned air can be sent from the panel device 30 to the external panel body 110 via the ventilation opening 24 a, so that it is not necessary to provide a duct connection portion in the external panel body 110. For this reason, even when a large number of panel bodies 110 are installed, it is not necessary to provide a large number of duct connection portions (inflow ports) and ducts, which can reduce equipment costs, improve workability, and reduce construction costs. In addition, space can be saved.

  Although the embodiment of the present invention has been described above, the specific configuration is not limited to the above embodiment, and even if there is a design change or the like without departing from the gist of the present invention, Included in the invention. For example, in the above embodiment, the sponge-like porous body 3 is used. However, a fibrous porous body may be used, and the thickness and porosity of the porous body 3 may be set as the arrangement site. Accordingly, the conditioned air may be allowed to flow out more evenly from the entire surface of the radiation surface portion 23a. In the second embodiment, the two outlets 23b and 23c are provided, but more outlets may be provided according to the air-conditioning target, the temperature of the conditioned air, and the like. Furthermore, although the damper 4 is arrange | positioned in the panel main body 2, you may arrange | position directly in the blowing outlet 23b, and you may combine the function of the damper 4 in the blade | wing 41. FIG.

DESCRIPTION OF SYMBOLS 1, 10, 20, 30 Pneumatic radiation panel apparatus 2 Panel main body 2a Outlet hole 21 Back plate 22 Duct connection part 23 Radiation panel 23a Radiation surface part 23b Outlet port 24 Side surface 24a Ventilation port 3 Porous body 4 Damper (opening / closing means)
41 blade 61 first thermometer (first temperature measuring means)
62 Second thermometer (second temperature measuring means)
63 Hygrometer (humidity measurement means)
64 Controller (Control means)
100 Duct 110 External panel body 110a External ventilation port 111 Packing

Claims (4)

A temperature-adjusted conditioned air is sent from a duct, and is a pneumatic radiant panel device that performs radiant air conditioning using radiant heat from the conditioned air,
A duct connection portion to which the duct is connected is provided on the back side, and a plurality of blowout holes for allowing the conditioned air to flow out are formed in a radiant panel which is a surface facing the duct connection portion. A panel body provided with a radiation surface portion and a blow-out port for blowing out the conditioned air to the outside;
A porous body that is provided in the panel body so as to face the radiation surface portion, is porous and suppresses the flow of the conditioned air, and allows the conditioned air to flow out uniformly from the blowout holes;
Opening and closing means for opening and closing the outlet;
A pneumatic radiant panel device comprising:   2. The pneumatic radiant panel device according to claim 1, wherein a plurality of the outlets are provided, and the opening / closing means is provided for each of the outlets. First temperature measuring means for measuring the temperature of conditioned air in the panel body;
A second temperature measuring means for measuring an external temperature;
A humidity measuring means for measuring external humidity;
Control means for controlling opening and closing of the opening and closing means based on measurement results of the first temperature measuring means, the second temperature measuring means and the humidity measuring means;
The pneumatic radiating panel device according to claim 1, wherein the pneumatic radiating panel device is provided. 4. The air outlet according to claim 1, further comprising a vent hole connected to an external panel body and configured to send the conditioned air to the external panel body on a side surface substantially perpendicular to the radiation panel of the panel body. The pneumatic radiant panel device according to claim 1.

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