JP6683210B2 - Radiation panel and air conditioner - Google Patents

Description

  The present disclosure relates to a radiation panel and an air conditioner.

  Patent Document 1 discloses an air conditioner including a radiant indoor unit. The radiant indoor unit includes a pair of vertical frames that stand upright in the vertical direction, and a heating element that is arranged between the pair of vertical frames. The heating element includes a refrigerant pipe and a heat transfer member that transfers heat through the refrigerant pipe. During the heating operation of the air conditioner, the high-pressure refrigerant compressed by the compressor radiates heat in the refrigerant pipe of the radiant indoor unit. As a result, radiant heat is released from the heat transfer member of the radiant indoor unit to the indoor space.

JP, 2015-25627, A

  In the above radiation type indoor unit (radiation panel), it is possible to use a flat plate portion as a heat transfer member. However, when an in-room person such as a user or an operator touches the heat transfer member with bare hands during operation of the air conditioner, the in-room person may feel excessively hot or excessively cold.

  An object of the present disclosure is to prevent an occupant from feeling excessively hot or excessively cold due to the occupant touching the flat plate portion of the radiation panel.

A first aspect is a radiation panel including a panel body (60) exposed to an indoor space , wherein the panel body (60) includes a flat plate portion (63) and a flat plate portion (63). And a plurality of protrusions (72, 73) formed on at least one of the front side and the rear side (71a, 71b), and the interval between the plurality of protrusions (72, 73) is 100 mm or less, A cavity (69) on the side of the protrusion is formed inside the plurality of protrusions (72, 73), and a cavity (68) on the side of the plate is formed inside the flat plate (63). A heat transfer tube (53) having a circular cross section through which the heat medium flows is provided, and a circular insertion hole (64) through which the heat transfer tube (53) is inserted is formed inside the flat plate portion (63). The projection part (72, 73) is a radiation panel characterized by being provided at a position where the insertion hole (64) and the panel body (60) overlap in the thickness direction .

In the first aspect, the protrusions (72, 73) can prevent the entire area of the person's hand from coming into contact with the flat plate portion (63). Since the interval between the adjacent protrusions (72, 73) is 100 mm or less, it is difficult for the entire hand to enter between the protrusions (72, 73).

In the first aspect, the peripheral wall around the insertion hole (64) and the base of the protrusions (72, 73) overlap each other, so that the wall thickness of the peripheral wall can be easily secured.

A second aspect is the radiation panel according to the first aspect, wherein the interval between the plurality of protrusions (72, 73) is 15 mm or more.

In the second aspect, by setting the interval between the adjacent protrusions (72, 73) to be 15 mm or more, it is possible to prevent the entire hand from coming into contact with the tips of the protrusions (72, 73).

A third aspect is characterized in that, in the first or second aspect, the protrusion (72, 73) extends along the surface (71a, 71b) of the flat plate portion (63). It is a radiation panel.

In the third aspect, the protrusions (72, 73) are extended along the surfaces (71a, 71b), and the intervals between the adjacent protrusions (72, 73) are set to 100 mm or less, so that the entire hands are adjacent to each other. It is possible to reliably suppress the entry between the protrusions (72, 73).

A fourth aspect is the radiation panel according to the third aspect, wherein the protrusions (72, 73) extend in the vertical direction.

In the fourth aspect, the condensed water generated on the surface of the flat plate portion (63) can be guided downward along the protrusions (72, 73).

A fifth aspect is the radiation panel according to any one of the first to fourth aspects, wherein the protrusions (72, 73) are formed in a plate shape.

In a sixth aspect according to any one of the first to fifth aspects, the protrusions (72, 73) are formed on the front surface (71a) and the rear surface (71b) of the flat plate portion (63), respectively. It is a radiation panel characterized by that.

The sixth aspect can suppress an increase in the contact area of the hand on both the front surface (71a) and the rear surface (71b) of the flat plate portion (63).

In a seventh aspect, in the sixth aspect, the front surface (71a) side protrusions (72, 73) and the rear surface (71b) side protrusions (72, 73) form a panel body (60). The radiation panel is characterized by overlapping in the thickness direction.

In the seventh aspect, the protrusions (72, 73) and the flat plate portion (63) can form a cross-shaped cross section, and the aesthetic appearance of the panel body (60) can be improved.

An eighth aspect is the radiation panel according to the seventh aspect, wherein the thickness of the protrusion (72, 73) is larger than the diameter of the heat transfer tube (53).

In the eighth aspect, the width of the peripheral wall around the insertion hole (64) and the overlapping portion of the base of the protrusions (72, 73) can be increased.

A ninth aspect is characterized in that, in any one of the first to eighth aspects, a protrusion height of the protrusion (72, 73) is equal to or larger than a thickness of the flat plate portion (63). It is a radiation panel.

In the ninth aspect, the protrusion height of the protrusions (72, 73) is increased, so that it becomes difficult for the person in the room to reach the surface of the flat plate portion (63).

A tenth aspect is the sixth aspect, wherein, in the sixth aspect, the total number of protrusions (72) on the front surface (71a) of the flat plate portion (63) and the protrusions (73) on the rear surface (71b) of the flat plate portion (63). The radiation panel is characterized by being different from the total number of.

In the tenth aspect, the heat transfer areas of the front surface (71a) side and the rear surface (71b) side of the flat plate portion (63) can be different from each other.

Aspect of the eleventh is an air conditioning apparatus provided with any one of the radiation panel (40) of the first to 1 0 embodiment.

An eleventh aspect is a heat exchange element for a radiant panel, which is formed on a flat plate portion (71) and at least one of front and rear surfaces (71a, 71b) of the plate portion (71). A plurality of protrusions (72, 73) are provided, and the interval between the plurality of protrusions (72, 73) is 100 mm or less.

FIG. 1 is a piping system diagram showing a schematic configuration of an air conditioner according to an embodiment. FIG. 2 is a front view showing a schematic configuration of the radiation panel according to the embodiment. FIG. 3 is a cross-sectional view of the entire heat transfer member according to the embodiment. FIG. 4 is an enlarged perspective view of an end portion of the heat exchange element according to the embodiment. FIG. 5 is an enlarged horizontal cross-sectional view of a main part of the heat transfer member of the radiation panel according to the embodiment. FIG. 6 is a diagram corresponding to FIG. 5 according to the first modification. FIG. 7 is a diagram corresponding to FIG. 5 according to the second modification.

<< Embodiment >>
The air conditioner (10) of the present embodiment will be described with reference to the drawings.

<overall structure>
The air conditioner (10) switches between indoor cooling and heating. As shown in FIG. 1, the air conditioner (10) includes an outdoor unit (20), an indoor unit (30), and a radiation panel (40).

  The outdoor unit (20) is installed outdoors. The outdoor unit (20) constitutes a heat source unit. The outdoor unit (20) is provided with a compressor (21), an outdoor heat exchanger (22), an outdoor expansion valve (23), a four-way switching valve (24), and an outdoor fan (25).

  The indoor unit (30) is provided near the ceiling in the room. The indoor unit (30) constitutes a convection type indoor unit that cools or heats the air carried by the indoor fan (33). The number of indoor units (30) is one or more. Each indoor unit (30) is provided with an indoor heat exchanger (31), an indoor expansion valve (32), and an indoor fan (33).

  The radiation panel (40) is installed on the floor of the room. The radiant panel (40) constitutes a radiant indoor unit that cools or heats by moving radiant heat. The number of the radiation panels (40) is one, or two or more. The radiation panel (40) is provided with a panel body (60) and a radiation expansion valve (50). Details of the radiation panel (40) will be described later.

  A refrigerant circuit (11) is configured by connecting the outdoor unit (20), the indoor unit (30), and the radiation panel (40) with a connecting pipe. In the refrigerant circuit (11), a refrigeration cycle is performed by circulating the filled refrigerant. In the refrigerant circuit (11) of the present embodiment, the indoor unit (30) and the radiation panel (40) are connected in parallel.

<Overall structure of radiation panel>
The overall structure of the radiation panel (40) will be described with reference to FIG. The radiation panel (40) includes a pair of columns (41), a panel body (60), and a bottom plate (42).

  The columns (41) are provided one at each of the left and right ends of the radiation panel (40). Each of the columns (41) is erected on the floor surface and extends vertically.

  The panel body (60) is provided between the pair of columns (41). The front and rear surfaces of the panel body (60) are exposed to the indoor space. The panel body (60) exchanges heat between the refrigerant flowing inside and the room air. Details of the panel body (60) will be described later.

  The bottom plate (42) extends laterally between the pair of columns (41) so as to be connected to the lower ends of the pair of columns (41). The bottom plate (42) is fixed to the floor surface of the room through a fastening member (not shown) such as an anchor bolt. The upper ends of the pair of columns (41) are connected to a ceiling-side hanging bolt (not shown) via the fixing portion (43).

  In the radiation panel (40), the lower housing chamber (44) is formed below the panel body (60). The lower storage chamber (44) is provided with a drain pan (45) for collecting the condensed water generated from the panel body (60). The front and rear open surfaces of the lower storage chamber (44) are covered by the lower cover (46), respectively. Each lower cover (46) is detachably attached to, for example, the lower portions of the pair of columns (41).

  In the radiation panel (40), the upper housing chamber (47) is formed above the panel body (60). A gas pipe (51) and a liquid pipe (52) of a refrigerant pipe are housed in the upper housing chamber (47). A radiation expansion valve (50) (not shown in FIG. 2) is connected to the liquid pipe (52). The front and rear open surfaces of the upper storage chamber (47) are covered by the upper cover (48). Each upper cover (48) is detachably attached to, for example, the upper part of the pair of columns (41).

<Overall structure of panel body>
The structure of the panel body (60) will be described with reference to FIGS.

  The panel body (60) includes a lower end plate (61), an upper end plate (62), and a plurality (six in this example) of heat exchange elements (70). In the panel body (60) of the present embodiment, the heat transfer member (70A) is configured by connecting the plurality of heat exchange elements (70). A heat transfer tube (53) connected to the refrigerant circuit (11) is arranged inside the heat transfer member (70A).

  The lower end plate (61) is arranged at the lower end of the panel body (60). The lower end plate (61) extends leftward and rightward between the pair of columns (41) so as to be connected to the pair of columns (41). The upper end plate (62) is arranged at the upper end of the panel body (60). The upper end plate (62) extends leftward and rightward between the pair of columns (41) so as to be connected to the pair of columns (41).

  The plurality of heat exchange elements (70) are supported between the upper end plate (62) and the lower end plate (61). The plurality of heat exchange elements (70) are fixed to the upper end plate (62) and the lower end plate (61) via fastening members (for example, tapping screws).

  The heat exchange element (70) is made of an aluminum material. The heat exchange element (70) is manufactured by extrusion molding. That is, in the heat exchange element (70), the cross-sectional shape perpendicular to the extruding direction (vertical direction in FIG. 2) is substantially the same over both ends in the extruding direction.

  The heat exchange element (70) includes a vertically elongated flat plate portion (71), a plurality of protrusions (front protrusion (72)) provided on the front surface (71a) of the plate portion (71), A plurality of protrusions (rear side protrusions (73)) provided on the rear surface (71b) of the plate (71) and connecting portions (74) provided at both ends of the plate (71) in the width direction. I have it. In the panel body (60) of the present embodiment, a plurality of plate parts (71) are connected in the width direction to form one flat plate part (63). That is, the flat plate portion (63) of the panel body (60) is dividable into a plurality of plate portions (71).

<Structure of plate / flat plate>
A plurality of insertion holes (64) are formed in the plate portion (71) (flat plate portion (63)) so as to penetrate in the vertical direction. The insertion holes (64) are arranged at equal intervals in the width direction of the flat plate portion (63). The straight pipe portion (54) of the heat transfer pipe (53) is inserted into the insertion hole (64). A cylindrical peripheral wall (65) is formed around the insertion hole (64) so as to make surface contact with the outer peripheral surface of the straight pipe portion (54). Thereby, heat is conducted between the refrigerant flowing inside the heat transfer tube (53) and the heat transfer member (70A).

  In the present embodiment, the heat transfer tube (53) is not inserted through a part of the plurality of insertion holes (64) (see, for example, FIG. 5). That is, in the radiation panel (40), the total number of straight pipe portions (54) is smaller than the total number of insertion holes (64). As a result, the overall length of the heat transfer tube (53) can be shortened, and the pressure loss of the refrigerant flowing inside the radiation panel (40) can be reduced. The straight pipe portion (54) of the heat transfer pipe (53) may be inserted through all the insertion holes (64).

  The plate portion (71) (flat plate portion (63)) is formed with a plurality of fastening holes (66) into which fastening members (for example, tapping screws, not shown) can be fastened. Each fastening hole (66) is arranged between the adjacent peripheral walls (65). A fastening wall (67) having a substantially C-shaped cross section is formed around the fastening hole (66). That is, the fastening wall (67) has a shape in which a part of the annular wall is cut off. By cutting off the annular fastening wall (67) in this manner, the dimensional tolerance of the fastening hole (66) with respect to the fastening member can be relaxed.

  In the fastening wall (67) of the present embodiment, the corresponding cutout portion (67a) faces the width direction of the plate portion (71). In the heat exchange element (70), the cross-sectional shapes of the pair of fastening walls (67) are symmetric with respect to the widthwise intermediate portion of the plate portion (71) (see FIGS. 4 and 5). More specifically, in the pair of fastening walls (67), the corresponding cutout portions (67a) face outward in the width direction of the plate portion (71).

  The plate portion (71) (the flat plate portion (63)) is formed with a plurality of lightening portions (the plate portion side lightening portion (68)). The plate portion side thinned portion (68) penetrates the heat exchange element (70) so as to extend across both ends of the heat exchange element (70) in the longitudinal direction (vertical direction). The plate portion side lightening portion (68) is formed between the connecting portion (74) and the peripheral wall (65) and between the peripheral wall (65) and the fastening wall (67). As a result, the heat exchange element (70) can be made lighter, and the panel body (60) can be made lighter.

<protrusion>
A plurality of front projections (72) are formed on the front surface (71a) of the plate portion (71) (flat plate portion (63)). A plurality of rear projections (73) are formed on the flat surface (63) or the rear surface (71b) of the plate (71). That is, in the heat exchange element (70), a plurality of (two or more) protrusions (72, 73) are provided on both surfaces (71a, 71b) in the thickness direction thereof. In the radiation panel (40) of the present embodiment, the total number of front projections (72) is equal to the total number of rear projections (73).

  Each protrusion (72, 73) is formed in a substantially plate shape having a rectangular cross section. Each protrusion (72, 73) extends in the vertical direction. The front protrusion (72) is provided at a position where the heat transfer tube (53) or the insertion hole (64) and the flat plate portion (63) overlap in the thickness direction. The rear protrusion (73) is provided at a position overlapping the heat transfer tube (53) or the insertion hole (64) in the thickness direction of the flat plate (63). That is, in this embodiment, the front protrusion (72) and the rear protrusion (73) overlap each other in the thickness direction of the flat plate portion (63). With this configuration, the front protrusion (72), the rear protrusion (73), and the plate (71) are substantially cross-shaped as a whole.

  The front protrusion portion (72) and the rear protrusion portion (73) are respectively formed with lightening portions (projection-side lightening portions (69)). The protrusion side lightening portion (69) penetrates the heat exchange element (70) so as to extend across both ends of the heat exchange element (70) in the longitudinal direction (vertical direction). The cross-sectional shape of the protrusion side lightening portion (69) is formed into a substantially rectangular shape corresponding to each protrusion portion (72, 73). As a result, the heat exchange element (70) can be made lighter, and the panel body (60) can be made lighter.

<Connecting part>
As shown in FIGS. 4 and 5, a connecting portion (74) is provided at each end of the plate portion (71) in the width direction (left-right direction). The pair of connecting parts (74) includes a protruding piece (74a) protruding laterally outward from a side end of the plate (71) and a thickness of the plate (71) from the tip of the protruding piece (74a). And a claw portion (74b) that is bent inward in the vertical direction. The thickness of the protruding piece portion (74a) is smaller than the thickness of the plate portion (71). The projecting piece portion (74a) is substantially flush with either one of the front surface (71a) and the rear surface (71b) of the plate portion (71). By providing the connecting portion (74) in this way, an engaging groove (75) with which the claw portion (74b) engages is formed between the side end of the plate portion (71) and the claw portion (74b). It That is, the cross-sectional shape of the engaging groove (75) is substantially the same as the cross-sectional shape of the claw portion (74b). In the heat exchange element (70) of the present embodiment, the cross-sectional shape of the pair of connecting portions (74) is symmetrical with the widthwise intermediate portion of the plate portion (71) interposed therebetween.

  In the panel body (60), the plurality of heat exchange elements (70) are arranged in the width direction so that the directions of the heat exchange elements (70) are alternately opposite. In the panel body (60), the claw portion (74b) of one of the two adjacent heat exchange elements (70) has the engagement groove (75) of the other heat exchange element (70). ) Is engaged. As a result, the adjacent heat exchange elements (70) are connected to each other (see FIG. 3).

<groove>
A plurality of grooves (80) are formed on the surface of the heat exchange element (70). Specifically, the plurality of grooves (80) are formed on the front surface (71a) and the rear surface (71b) of the plate portion (71), the surface of the front side protrusion (72), and the surface of the rear side protrusion (73). Formed respectively. The groove (80) extends in the vertical direction. The cross-sectional shape of the bottom surface of the groove (80) of the present embodiment is formed in a substantially V shape. The cross-sectional shape of the groove (80) is substantially the same vertically.

  When condensed water is generated on the surface of the heat exchange element (70), this condensed water can be captured inside the groove (80). Further, since the groove (80) extends in the vertical direction, the condensed water that has been trapped can be guided downward through the groove (80).

-Driving operation-
The operation of the air conditioner (10) according to the embodiment will be described with reference to FIG. The air conditioner (10) switches between heating operation and cooling operation.

<Heating operation>
In the heating operation, the four-way switching valve (24) is in the state shown by the broken line in FIG. The refrigerant compressed by the compressor (21) is sent to the indoor unit (30) and the radiation panel (40).

  In the indoor unit (30), the refrigerant radiates (condenses) heat in the outdoor heat exchanger (22). The air heated by the refrigerant is supplied to the indoor space by the indoor fan (33).

  In the radiant panel (40), the refrigerant flows through the heat transfer tube (53) of the panel body (60). As a result, the heat of the refrigerant in the heat transfer tube (53) is transmitted through the heat transfer member (70A) and is released into the indoor space.

  The refrigerant that radiates heat in the indoor unit (30) and the radiation panel (40) is decompressed by the outdoor expansion valve (23) and then evaporated by the outdoor heat exchanger (22). The evaporated refrigerant is compressed again by the compressor (21).

<Cooling operation>
In the cooling operation, the four-way switching valve (24) is in the state shown by the solid line in FIG. The refrigerant compressed by the compressor (21) radiates (condenses) heat in the outdoor heat exchanger (22). The refrigerant radiating heat in the outdoor heat exchanger (22) is sent to the indoor unit (30) and the radiation panel (40).

  In the indoor unit (30), the refrigerant is decompressed by the indoor expansion valve (32) and then flows through the indoor heat exchanger (31). In the indoor unit (30), the refrigerant evaporates in the indoor heat exchanger (31). The air cooled by the refrigerant is supplied to the indoor space by the indoor fan (33).

  In the radiation panel (40), the refrigerant is decompressed by the radiation expansion valve (50) and then flows through the heat transfer tube (53). As a result, the air around the heat transfer member (70A) is cooled.

  The refrigerant evaporated in each of the indoor unit (30) and the radiation panel (40) is compressed again in the compressor (21).

<Dimensional relation of each element of radiation panel / heat exchange element>
The dimensional relationship of the elements of the panel body (60) (heat exchange element (70)) will be described with reference to FIG.

  In the panel body (60), the interval P1 between the adjacent front protrusions (72) is 100 mm or less. Further, the interval P1 between the adjacent front protrusions (72) is 15 mm or more. Similarly, the interval P2 between adjacent rear protrusions (73) is 100 mm or less. The interval P2 between the adjacent rear protrusions (73) is 15 mm or more. In this embodiment, the interval P1 and the interval P2 are equal. In this embodiment, the intervals P1 and P2 are set to about 36.6 mm.

  In the panel body (60), the protrusion height L1 of the front protrusion (72) is equal to or greater than the thickness D of the flat plate portion (63) (plate portion (71)). In the panel body (60), the protrusion height L2 of the rear protrusion (73) is not less than the thickness D of the flat plate portion (63) (plate portion (71)). In this embodiment, the protrusion height L1 and the protrusion height L2 are equal. In this embodiment, the protrusion height L1 and the protrusion height L2 are set to about 16.9 mm, and the thickness D is set to about 10.1 mm.

  The thickness D1 of the front protrusion (72) is larger than the diameter d of the heat transfer tube (53). The thickness D2 of the rear projection (73) is larger than the diameter d of the heat transfer tube (53). In the present embodiment, the thickness D1 and the thickness D2 are equal. In this embodiment, the thickness D1 and the thickness D2 are set to about 7.9 mm. The diameter d is set to be slightly smaller than the thickness D1 and the thickness D2.

-Effect of embodiment-
In this embodiment, the interval P1 between the plurality of front protrusions (72) is 100 mm or less. If the interval P1 is too large, the entire hand of the person in the room (user, maintenance company, etc.) may come into surface contact with the surface of the flat plate portion (63), and the person in the room may feel excessively hot. On the other hand, if the interval P1 is 100 mm or less, which is a general width dimension of the hand, it becomes difficult for the hand to enter between the adjacent front projections (72), and the whole hand is the front surface of the flat plate portion (63). Surface contact with the (71a) can be suppressed. Similarly, by setting the interval P2 of the plurality of rear side protrusions (73) to 100 mm or less, it becomes difficult for the hand to enter between the adjacent rear side protrusions (73), and the whole hand is the flat plate portion (63). It is possible to suppress surface contact with the front surface (71a) of the.

  By installing the radiation panel (40) having the flat plate portion (63) on the floor surface, the flat plate portion (63) functions as a partition in the room. Here, if the heat transfer member of the radiation panel has a structure like a louver, a plurality of gaps penetrating the front and back of the radiation panel will be formed. In this case, a user or the like may see the opposite side of the radiation panel through these gaps, which may impair the aesthetics of the room. On the other hand, in the present embodiment, since the flat panel portion (63) that completely partitions the front and back of the radiation panel (40) is provided, it is possible to prevent the aesthetics of the room from being impaired.

  The surface area of the heat transfer member (70A) can be increased by forming the protrusions (72, 73) on the front surface (71a) and the rear surface (71b) of the flat plate portion (63). As a result, the heating capacity and cooling capacity of the radiation panel (40) can be improved.

  In this embodiment, the interval P1 between the plurality of front protrusions (72) is 15 mm or more. If the interval P2 is too small, the area in which the person in the room touches the tip of the front projection (72) becomes large, and the person in the room may feel excessively hot. On the other hand, when the interval P1 is set to 15 mm or more, a part of the hand (for example, a finger) easily enters between the adjacent front protrusions (72), and the contact area of the tip of the front protrusion (72) becomes small. . Similarly, by setting the interval P2 between the plurality of rear protrusions (73) to 15 mm or more, it becomes easy for a part of the hand (for example, a finger) to enter between the adjacent rear protrusions (73).

  In the present embodiment, the front side protrusion (72) and the rear side protrusion (73) are formed by ridges extending along the surfaces (71a, 71b) of the flat plate portion (63). By setting the intervals P1 and P2 to 100 mm or less, it is possible to prevent the hand from entering between the adjacent front protrusions (72) and between the adjacent rear protrusions (73).

  In this embodiment, the front protrusion (72) and the rear protrusion (73) extend in the vertical direction. Therefore, even if dew condensation water is generated on the surface of the heat transfer member (70A), this dew condensation water can be easily guided downward.

  In this embodiment, the front protrusion (72) and the rear protrusion (73) are formed in a plate shape. As a result, it is possible to reliably prevent the hand touching the tips of the front protrusion (72) and the rear protrusion (73) from being damaged.

  In this embodiment, the protrusions (72, 73) are formed on both the front surface (71a) and the rear surface (71b) of the flat plate portion (63). For this reason, it is possible to prevent the contact area of the hand from increasing on both the front surface (71a) and the rear surface (71b) of the flat plate portion (63), and to expand the heat transfer area of the heat transfer member (70A).

  In this embodiment, the front protrusion (72) and the rear protrusion (73) overlap each other in the thickness direction of the panel body (60). As a result, the front projection (72), the rear projection (73), and the flat plate (63) can form a cross-shaped cross section, and the aesthetic appearance of the panel body (60) can be improved.

  In the present embodiment, an insertion hole (64) through which the heat transfer tube (53) is inserted is formed in the flat plate portion (63), and the front projection (72) and the rear projection (73) are inserted through the insertion hole (64 ) And the position which overlaps with the thickness direction. With this structure, the base portion of the protrusion (72, 73) and the peripheral wall (65) around the insertion hole (64) overlap each other, so that the wall thickness of the peripheral wall (65) can be easily ensured. In addition, heat transfer between the heat transfer tube (53) and the protrusions (72, 73) can be promoted.

  Particularly in the present embodiment, since the thicknesses D1 and D2 of the protrusions (72, 73) are made larger than the diameter d of the heat transfer tube (53), the protrusions (72, 73) and the peripheral wall (65) are It is possible to secure a sufficient width for the overlapping part of.

  In the present embodiment, the protrusion height L1 of the front protrusion (72) is greater than the thickness D of the flat plate portion (63). When the protrusion height L1 of the front protrusion (72) is relatively large as described above, it is possible to prevent the hand of the person in the room from reaching the front surface (71a) of the flat plate portion (63). Similarly, by making the protrusion height L2 of the rear side protrusion (73) larger than the thickness D of the flat plate portion (63), the hand of the person in the room can reach the rear surface (71b) of the flat plate portion (63). Can be suppressed.

  In the present embodiment, a structure in which a plurality of heat exchange elements (70) are arranged in the width direction of the heat transfer member (70A) and these heat exchange elements (70) are connected via a connecting portion (74) (divided structure ). If the heat transfer member (70A) has an integral structure, the amount of bending of the heat transfer member (70A) due to thermal strain increases. On the other hand, when the heat transfer member (70A) has such a divided structure, the amount of bending of the heat transfer member (70A) due to thermal distortion can be absorbed and alleviated. As a result, it is possible to prevent the heat transfer member (70A) from being largely bent as a whole. Further, by dividing the heat transfer member (70A) into a plurality of heat exchange elements (70), the heat transfer member (70A) can be easily transported.

  In the present embodiment, the heat exchange elements (70) are provided with the connecting portions (74), respectively, so that the arrangement and assembly work of the heat exchange elements (70) can be easily performed.

<Modification 1>
In the modified example 1 shown in FIG. 6, in the heat transfer member (70A) (heat exchange element (70)), the total number of front projections (72) and the total number of rear projections (73) are equal to each other. different. Specifically, in Modification 1, the total number of front protrusions (72) is greater than the total number of rear protrusions (73). With this configuration, in the heat transfer member (70A), the heat transfer area on the front surface (71a) side is larger than the heat transfer area on the rear surface (71b) side. Therefore, in the radiation panel (40) of the first modification, the heating capacity and the cooling capacity on the front surface (71a) side can be improved.

<Modification 2>
In the heat exchange element (70) of the second modification shown in FIG. 7, the protrusion directions of the claw portions (74b) of the left and right connecting portions (74) are opposite to each other. With this configuration, the adjacent heat exchange elements (70) can be connected without worrying about the orientation of the connecting portions (74) of the adjacent heat exchange elements (70).

<< Other Embodiments >>
In the above-mentioned embodiment and each modification, the following configurations may be adopted.

  All the intervals P1 between the front protrusions (72) may not be equal. Therefore, at least one of the intervals P1 may satisfy the above-mentioned relationship. This means that the intervals P2 between the rear protrusions (73), the thicknesses D1 of the front protrusions (72), the thicknesses D2 of the rear protrusions (73), and the heat transfer tubes (53). The same applies to each diameter d of).

  The protrusion (72) may be formed only on the front surface (71a) of the flat plate portion (63) (plate portion (71)). The protrusion (73) may be formed only on the rear surface (71b) of the flat plate (63) (plate (71)).

  The protrusions (72, 73) do not necessarily have to extend in a predetermined direction, and a plurality of protrusions such as a columnar shape, a prismatic shape, and a cone shape may be arranged in a dot shape. When the protrusions (72, 73) are structured to extend along the surfaces (71a, 71b), they may extend in the horizontal direction or obliquely.

  The protrusions (72, 73) do not have to be plate-shaped. That is, the cross-sectional shape of the protrusions (72, 73) perpendicular to the longitudinal direction does not have to be rectangular, and may be triangular or circular (elliptical).

  The heat transfer member (70A) has a divided structure including a plurality of heat exchange elements (70), but it may have an integrated structure.

  While the connecting portion (74) provided in the plurality of heat exchange elements (70) is omitted, a connecting member for connecting the heat exchange elements (70) may be separately provided.

  The indoor unit (30) of the air conditioner (10) and the radiation panel (40) may be connected in series. The indoor unit (30) of the air conditioner (10) may be omitted.

  Although the embodiments and modifications have been described above, it will be understood that various changes in form and details can be made without departing from the spirit and scope of the claims. Further, the above-described embodiments and modified examples may be appropriately combined or replaced as long as the functions of the object of the present disclosure are not impaired.

  As described above, the present disclosure is useful for a radiation panel and an air conditioner.

10 Air Conditioner 40 Radiation Panel 53 Heat Transfer Tube 60 Panel Main Body 63 Flat Plate Part 64 Insertion Hole 70 Heat Exchange Element 71 Plate Part 71a Front (Surface)
71b Rear surface (surface)
72 Front projection (projection)
73 Rear projection (projection)
74 Connection

Claims (11)

A radiation panel including a panel body (60) exposed to an indoor space ,
The panel body (60) is
A flat plate portion (63),
A plurality of protrusions (72, 73) formed on at least one surface (71a, 71b) on the front side and the rear side of the flat plate portion (63),
The interval between the plurality of protrusions (72, 73) is 100 mm or less,
Inside the plurality of protrusions (72, 73), a cavity (69) on the protrusion side is formed ,
Inside the flat plate portion (63), a hollow portion (68) on the flat plate portion side is formed,
The heat transfer tube (53) having a circular cross section through which the heat medium flows is provided
A circular insertion hole (64) through which the heat transfer tube (53) is inserted is formed inside the flat plate portion (63),
The radiation panel, wherein the protrusions (72, 73) are provided at positions where the insertion holes (64) and the panel body (60) overlap in the thickness direction . In claim 1 ,
The radiation panel characterized in that the interval between the plurality of protrusions (72, 73) is 15 mm or more. In claim 1 or 2 ,
The radiation panel characterized in that the protrusions (72, 73) extend along the surfaces (71a, 71b) of the flat plate portion (63). In claim 3 ,
The radiation panel characterized in that the projections (72, 73) extend in the vertical direction. In any one of Claim 1 thru | or 4 ,
The radiation panel characterized in that the projections (72, 73) are formed in a plate shape. In any one of Claim 1 thru | or 5 ,
The radiation panel, wherein the protrusions (72, 73) are formed on the front surface (71a) and the rear surface (71b) of the flat plate portion (63), respectively. In claim 6 ,
The protrusions (72, 73) on the front surface (71a) side and the protrusions (72, 73) on the rear surface (71b) side overlap in the thickness direction of the panel body (60). Radiation panel. In claim 7 ,
The thickness of the said protrusion part (72,73) is larger than the diameter of the said heat transfer tube (53), The radiation panel characterized by the above-mentioned. In any one of Claim 1 thru | or 8 ,
The projection height of the protrusions (72, 73) is equal to or larger than the thickness of the flat plate portion (63). In claim 6 ,
The radiation panel characterized in that the total number of protrusions (72) on the front surface (71a) of the flat plate portion (63) and the total number of protrusions (73) on the rear surface (71b) of the flat plate portion (63) are different. . Air conditioning apparatus with either one of the radiation panel (40) of claims 1 to 1 0.

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