JP2013083422A - Outdoor unit and refrigeration device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve heat exchanging efficiency in an outdoor unit including heat exchangers arranged in a hexagonal shape.SOLUTION: An outdoor unit (11) includes a first heat exchanger body (35) and a second heat exchanger body (36) which are formed along both side surfaces of a casing (12), and the first heat exchanger body (35) and second heat exchanger body (36) include a first air heat exchanger (37) and a second air heat exchanger (38) which are extended linearly in the outside direction of the casing (12) so that a central section forms an obtuse apex (39) positioned outside the casing (12) when viewed from the top. The outdoor unit includes a blower fan (17) positioned above the casing (12) and a first body recess (41) and a second body recess (42) which are formed below the first heat exchanger body (35) and second heat exchanger body (36) of the casing (12) and open on the sides of the casing (12).

Description

    The present invention relates to an outdoor unit and a refrigeration apparatus including the outdoor unit, and particularly relates to an external air intake structure.

    Conventionally, as shown in Patent Document 1, a large-scale heat pump chiller disposed on the roof of a building is known as a refrigeration apparatus. The outdoor unit of this heat pump chiller is formed in a substantially hexagonal shape in plan view, and has a casing having air suction ports on opposite sides, a plurality of flat plate heat exchangers disposed in the air suction ports, A blower fan disposed inside an air outlet formed on the upper surface of the casing.

JP 2010-216798 A

    By the way, in the heat pump chiller according to Patent Document 1 described above, for example, three outdoor units are installed side by side, and air is taken in from a gap between adjacent outdoor units.

    However, since the lower part of the casing is separated from the blower fan disposed above, the air hardly flows. For this reason, there existed a problem that the heat exchange performance of the downward direction of a casing fell.

    This invention is made | formed in view of such a point, and it aims at improving the heat exchange efficiency in the outdoor unit which has a heat exchanger arrange | positioned by substantially hexagonal shape by planar view.

    The first invention is a casing (12) and a heat exchanger body (35, 36) that is disposed on a side surface of the casing (12), extends along the side surface, and is exposed to the outside of the casing (12). The heat exchanger body (35, 36) is formed with a top portion (39) having a central portion located outside the casing (12) in a plan view, and the heat exchanger body (35, 36). ) Is an outdoor unit configured to allow air to flow into the casing (12) from the outside of the casing (12), and is disposed above the casing (12). A blower fan (17) that blows out, and a body recess formed below the heat exchanger body (35, 36) of the casing (12) and recessed inward from the side surface of the heat exchanger body (35, 36) (41, 42).

    In the said 1st invention, the heat exchanger main body (35, 36) is arrange | positioned at the side part of the casing (12). The heat exchanger body (35, 36) extends along the side surface of the casing (12) and is exposed to the outside of the casing (12). The heat exchanger body (35, 36) has a top portion (39) whose central portion is located outside the casing (12) in plan view. Air outside the casing (12) flows from the outside of the heat exchanger body (35, 36) through the heat exchanger body (35, 36) and into the casing (12). The air flowing into the casing (12) is heat-exchanged when passing through the heat exchanger body (35, 36).

    On the other hand, below the heat exchanger body (35, 36), a body recess (41, 42) is provided on the side surface of the casing (12). ing. External air flows through the space formed by the main body recesses (41, 42).

    The air flowing through the main body recess (41, 42) is guided to the outside of the heat exchanger body (35, 36) from below the heat exchanger body (35, 36). And it flows into the inside of a casing (12) from the outer side of a heat exchanger main body (35,36). The air flowing into the casing (12) is heat-exchanged when passing through the heat exchanger body (35, 36).

    In a second aspect based on the first aspect, the heat exchanger body (35, 36) is disposed on both side surfaces of the casing (12) and extends along both side surfaces of the casing (12). 1 heat exchanger main body (35) and 2nd heat exchanger main body (36), and the said 1st heat exchanger main body (35) and 2nd heat exchanger main body (36) are a casing ( A linear first heat exchanging portion (37) and a second heat exchanging portion (38) extending in the outer direction of the casing (12) so as to form an obtuse apex (39) located outside of 12). The main body recess (41, 42) is formed below the first heat exchanger body (35) and the second heat exchanger body (36) of the casing (12), and the first heat exchanger. The first main body recess (41) and the second main body recess (42 ).

    In the second aspect of the invention, the air outside the casing (12) flows from the outside of the first heat exchanger body (35) and the second heat exchanger body (36) to the respective first heat exchange sections (37) and It passes through the second heat exchange section (38) and flows into the casing (12). The air flowing into the casing (12) is heat-exchanged when passing through the first heat exchange part (37) and the second heat exchange part (38).

    On the other hand, on the lower side of the first heat exchanger body (35) and the second heat exchanger body (36), they are inside the side surfaces of the first heat exchanger body (35) and the second heat exchanger body (36). A first main body recess (41) and a second main body recess (42) are provided. Air outside the casing (12) flows through each of the first main body recess (41) and the second main body recess (42).

    The air flowing through the first main body recess (41) is guided to the outside of the first heat exchanger main body (35) from below the first heat exchanger main body (35). And it flows into the inside of a casing (12) through the 1st heat exchange part (37) and the 2nd heat exchange part (38) from the outside of the 1st heat exchanger main part (35). And the air which flows in into the inside of a casing (12) is heat-exchanged when passing a 1st heat exchange part (37) and a 2nd heat exchange part (38). The air flowing through the second main body recess (42) is guided to the outside of the second heat exchanger main body (36) from below the second heat exchanger main body (36). And it flows through the 1st heat exchange part (37) and the 2nd heat exchange part (38) from the outside of the 2nd heat exchanger body (36), and flows into the inside of a casing (12). And the air which flows in into the inside of a casing (12) is heat-exchanged when passing a 1st heat exchange part (37) and a 2nd heat exchange part (38).

    In a third aspect based on the second aspect, the first main body recess (41) and the second main body recess (42) are provided on the first heat exchange section (37) and the second heat exchange section (38). A first recess (43) and a second recess (44) which are respectively located below and are recessed inward from the side surfaces of the first heat exchange part (37) and the second heat exchange part (38), The air communication part (45) which connects the space which 1 recessed part (43) forms, and the space which the said 2nd recessed part (44) forms is provided.

    In the said 3rd invention, the 1st main body recessed part (41) below the 1st heat exchanger main body (35) is comprised by the 1st recessed part (43) and the 2nd recessed part (44). Moreover, the 2nd main body recessed part (42) below the 2nd heat exchanger main body (36) is comprised by the 1st recessed part (43) and the 2nd recessed part (44).

    The first recess (43) is connected to the outside of the casing (12), and the outside air flows. The air flowing through the first recess (43) is guided to the outside of the first heat exchange part (37) from below, and is exchanged when passing through the first heat exchange part (37) to be inside the casing (12). Flow into.

    The second recess (44) is connected to the outside of the casing (12), and the outside air flows. The air flowing through the second recess (44) is guided from below to the outside of the second heat exchanging part (38) and is exchanged when passing through the second heat exchanging part (38), so that the inside of the casing (12). Flow into.

    Here, the air communication part (45) communicates the space formed by the first recess (43) and the space formed by the second recess (44). For this reason, the air which flows through a 1st recessed part (43) and the air which flows through a 2nd recessed part (44) can go back and forth mutually space. That is, the air flowing through the first recess (43) flows into the second recess (44), while the air flowing through the second recess (44) flows into the first recess (43). Thereby, the amount of air flowing below the first heat exchanger body (35) and the second heat exchanger body (36) can be increased.

    According to a fourth aspect of the present invention, in the second or third aspect of the invention, the casing (12) is a machine in which components are arranged inside the first main body recess (41) and the second main body recess (42). Room (29) is provided.

    In the fourth aspect of the invention, the machine room (29) in which the constituent devices are arranged is formed inside the first main body recess (41) and the second main body recess (42) of the casing (12). By doing so, it is possible to perform maintenance on the components in the machine room (29) from the first main body recess (41) and the second main body recess (42).

    In a fifth aspect based on any one of the second to fourth aspects, the casing (12) extends along the first heat exchanger body (35) or the second heat exchanger body (36). Reinforcing member configured to extend and support each heat exchanging portion (37, 37, 38, 38) from below, and to allow drain water of each heat exchanging portion (37, 37, 38, 38) to flow (25).

    In the fifth aspect, the reinforcing member (25) is provided in the casing (12) along the first heat exchanger body (35) or the second heat exchanger body (36). The reinforcing member (25) is configured to support each heat exchange part (37, 37, 38, 38) from below and to allow drain water to flow. By doing so, the reinforcing member (25) becomes a member having both the reinforcing function of each heat exchanging part (37, 37, 38, 38) and the function of the drain pan.

    According to a sixth invention, in any one of the second to fifth inventions, the first heat exchange section (37) and the second heat exchange section (38) are connected to different refrigerant circuits and independently. And is configured to be operable.

    In the sixth invention, the first heat exchange section (37) and the second heat exchange section (38) are connected to different refrigerant circuits, respectively, and can operate independently. In this way, when only the first heat exchange part (37) operates, air can flow from the second recess (44) to the first recess (43). For this reason, the air flow rate which flows through the 1st heat exchange part (37) of operation object can be increased. Moreover, when only the 2nd heat exchange part (38) operate | moves, air can be flowed from a 1st recessed part (43) to a 2nd recessed part (44). For this reason, the air flow rate which flows through the 2nd heat exchange part (38) of operation object can be increased.

    7th invention is equipped with the outdoor unit (11) which concerns on any one invention of the said 1st-6th invention.

    The refrigeration apparatus according to the seventh aspect of the invention includes an outdoor unit (11).

    According to 1st invention, since the main-body recessed part (41, 42) was provided, in addition to the air which flows outside the heat exchanger main body (35, 36), it is on the outer side of a heat exchanger main body (35, 36) from the downward direction Can lead air. For this reason, the flow rate of the air passing through the heat exchanger body (35, 36) can be increased. Thereby, the heat exchange efficiency of the heat exchanger body (35, 36) can be improved. As a result, heat exchange efficiency can be improved in an outdoor unit having a heat exchanger arranged in a substantially hexagonal shape in plan view.

    According to the second invention, since the first main body concave portion (41) and the second main body concave portion (42) are provided, in addition to the air flowing outside the first and second heat exchanger main bodies (35, 36), The air can be guided to the outside of the first heat exchanger body (35) and the second heat exchanger body (36). For this reason, the flow volume of the air which passes a 1st heat exchange part (37) and a 2nd heat exchange part (38) can be increased. Thereby, the heat exchange efficiency of a 1st heat exchange part (37) and a 2nd heat exchange part (38) can be improved. As a result, heat exchange efficiency can be improved in an outdoor unit having a heat exchanger arranged in a substantially hexagonal shape in plan view.

    According to the third invention, since the air communication portion (45) is provided to communicate the space formed by the first recess (43) and the space formed by the second recess (44), the first recess ( While air flowing through 43) is supplied to the second recess (44), air flowing through the second recess (44) can be supplied to the first recess (43). Thereby, the flow volume of the air which flows from a 1st recessed part (43) to a 2nd recessed part (44) can be increased. That is, since the lower part of the first heat exchanger body (35) and the second heat exchanger body (36) is far from the blower fan (17), the air flow is deteriorated. However, in the present invention, the flow rate of the air flowing between the first recess (43) and the second recess (44) can be increased by the air communication portion (45), so that the first heat exchanger body (35) and The air flow rate below the second heat exchanger body (36) can be increased. Thereby, the heat exchange efficiency of a 1st heat exchange part (37) and a 2nd heat exchange part (38) can be improved. As a result, heat exchange efficiency can be improved in an outdoor unit having a heat exchanger arranged in a substantially hexagonal shape in plan view.

    According to the fourth invention, since the machine chamber (29) is provided inside the first main body recess (41) and the second main body recess (42), the first main body recess (41) and the second main body recess (42). From the above, it can be configured to maintain the components in the machine room (29).

    According to 5th invention, while providing the reinforcement member (25) comprised so that drain water may flow along a 1st heat exchanger main body (35) or a 2nd heat exchanger main body (36), from the downward direction Since the first heat exchange section (37) or the second heat exchange section (38) is supported, the first heat exchanger body (35) or the second heat exchanger body (36) can be mounted with one member. At the same time that it can be reinforced, drain water generated from the first heat exchange section (37) or the second heat exchange section (38) can be treated.

    According to the sixth aspect of the invention, the first heat exchanging part (37) and the second heat exchanging part (38) operate independently of each other, so that only the first heat exchanging part (37) operates. In this case, air supplied from the second recess (44) to the first recess (43) can be guided to the first heat exchange unit (37). For this reason, the flow volume of the air which flows through the 1st heat exchange part (37) which operate | moves can be increased. Further, when only the second heat exchange section (38) operates, the air supplied from the first recess (43) to the second recess (44) can be guided to the second heat exchange section (38). For this reason, the flow volume of the air which flows through the 2nd heat exchange part (38) which operate | moves can be increased.

FIG. 1 is a schematic perspective view illustrating a chiller device according to an embodiment. Drawing 2 is a perspective view which looked at an outdoor unit of a heat pump chiller concerning an embodiment from one side. Drawing 3 is a perspective view which looked at the outdoor unit of the heat pump chiller concerning an embodiment from the other side. FIG. 4 is a front view showing the outdoor unit of the heat pump chiller according to the embodiment. FIG. 5 is a rear view showing the outdoor unit of the heat pump chiller according to the embodiment. FIG. 6 is a left side view illustrating the outdoor unit of the heat pump chiller according to the embodiment. FIG. 7 is a right side view showing the outdoor unit of the heat pump chiller according to the embodiment. FIG. 8 is a top view showing the outdoor unit of the heat pump chiller according to the embodiment. FIG. 9 is a bottom view showing the outdoor unit of the heat pump chiller according to the embodiment. Drawing 10 is a longitudinal section showing the outdoor unit of the heat pump chiller concerning an embodiment. FIG. 11 is a perspective view showing the structure of the bottom member according to the embodiment. FIG. 12 is a perspective view showing the structure of the first bottom frame according to the embodiment. FIG. 13 is a perspective view showing the structure of the second bottom frame according to the embodiment. FIG. 14 is a perspective view of the air flow of the outdoor unit of the heat pump chiller according to the embodiment as viewed from one side surface. FIG. 15: is the perspective view which looked at the air flow of the outdoor unit of the heat pump chiller which concerns on embodiment from the other side surface side. FIG. 16 is a schematic perspective view showing an air flow of the chiller device according to the embodiment. FIG. 17 is a top view illustrating an air flow of the chiller device according to the embodiment. FIG. 18 is a schematic perspective view illustrating an air flow during one-line operation of the chiller device according to the embodiment. FIG. 19 is a graph showing the relationship between the height and the air volume in an outdoor unit according to a conventional example. FIG. 20 is a graph showing the relationship between the height and the air volume in the outdoor unit according to the embodiment. FIG. 21 is a perspective view showing a structure of a second bottom frame according to a modified example of the embodiment.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

    As shown in FIG. 1, the refrigeration apparatus of the present embodiment constitutes a chiller apparatus (10). The chiller device (10) includes an outdoor unit (11) of a heat pump chiller that is installed on a rooftop of a building or the like and cools or heats air-conditioning water supplied into the building. In the chiller device (10), for example, three outdoor units (11) are arranged in parallel in the width direction on the wall (1).

    As shown in FIGS. 2 to 9, each outdoor unit (11) includes a casing (12) having a refrigerant circuit (not shown).

    The casing (12) includes a fan casing (13) formed at the upper end, a bottom member (60) formed at the lower end, and a main body provided between the fan casing (13) and the bottom member (60). (20). 1 to 9 show a schematic bottom member (60), and a detailed structure will be described later.

    As shown in FIG. 10, the fan casing (13) accommodates the blower fan (17) in the interior thereof and is disposed at the upper end of the casing (12).

    The fan casing (13) is formed in a substantially thin box having a substantially rectangular shape in plan view, and is provided at the upper end of the casing (12). Although not shown, the fan casing (13) is open at a portion corresponding to the lower end main body (20). Further, four air outlets (14, 14, 14, 14) are formed side by side along the longitudinal direction on the upper end surface of the fan casing (13). A fan guard is attached to each air outlet (14) so as to cover the opening surface. The fan guard is a protective net for the blower fan (17). In addition, four blower fans (17) corresponding to each outlet (14) are provided inside the fan casing (13), and a bell mouth (16) is provided around each blower fan (17). ing.

    The fan casing (13) is formed such that both side surfaces (15a, 15b) extend outward to a position corresponding to the outermost part of the main body (20) described later. Specifically, one side surface (15a) of the fan casing (13) is an obtuse top (39) located outside the casing (12) at the center of the first heat exchanger body (35) in plan view. And is formed so as to extend linearly in the longitudinal direction of the casing (12). A portion of the fan casing (13) that projects to the outside of the first heat exchanger body (35) in plan view constitutes a first flange (13a).

    On the other hand, the other side surface (15b) of the fan casing (13) extends from the center of the second heat exchanger body (36) to the position of the obtuse apex (39) located outside the casing (12) in plan view. It is formed so as to protrude and extends linearly in the longitudinal direction of the casing (12). And the part which protruded outside the 2nd heat exchanger main body (36) in planar view among fan casings (13) comprises the 2nd collar part (13b).

    The air blown above the casing (12) from the blower outlet (14) by the first flange part (13a) and the second flange part (13b) flows below the fan casing (13) and is an air heat exchanger. It is possible to prevent a so-called short circuit that flows into (37, 37, 38, 38).

    The blower fan (17) is configured as an axial blower (for example, a propeller fan). The blower fan (17) is provided in four corresponding to the four outlets (14), and sucks air from the outside into the casing (12), and the air is sucked into the fan casing (13) and the outlet. It is configured to blow out through (14). The bell mouth (16) is formed in a substantially cylindrical shape and is provided in the fan casing (13) so as to surround the blower fan (17).

    The said bottom member (60) is a member which is arrange | positioned at the lower end part of a casing (12) as shown in FIG. 11, and mounts the compressor (50) mentioned later and a water heat exchanger (51). The bottom member (60) is configured by connecting a first bottom frame (61) and a second bottom frame (62). The first bottom frame (61) and the second bottom frame (62) are both formed by using a main body frame (63) which is a common member.

    As shown in FIG. 12, the first bottom frame (61) includes a main body frame (63), a dividing plate (65), two compressor mounting plates (68, 68), a wiring cover (67, 67) and three support brackets (66).

    The main body frame (63) is formed in a thin frame having a substantially rectangular shape in plan view. The main body frame (63) is provided with grooves (64, 64) arranged in two rows in the width direction. The groove portions (64, 64) are formed extending in the longitudinal direction of the main body frame (63).

    The compressor mounting plate (68) is formed in a substantially rectangular plate member. Each compressor mounting plate (68) is attached to the main body frame (63) so as to cover the corresponding groove (64). Three compressors (50), which will be described later, are mounted on one compressor mounting plate (68). The compressor mounting plate (68) closes the groove (64), so that the outside air passes through the bottom member (60) without passing through the first and second heat exchanger bodies (35, 36). It is prevented from being taken into the casing (12).

    The dividing plate (65) is formed in a substantially rectangular plate member, and is provided on the other end side of the main body frame (63) of the first bottom frame (61). The dividing plate (65) is disposed so as to extend outward from the approximate center in the width direction of the main body frame (63).

    The wiring cover (67) is a cover member for protecting the electrical wiring of the corresponding outdoor unit (11). The wiring cover (67) is attached along both side surfaces in the longitudinal direction of the main body frame (63).

    As shown in FIG. 13, the second bottom frame (62) includes a main body frame (63), a pump base (71), a dividing plate (65), a heat exchanger mounting plate (69), and a sealing plate ( 70) and three support brackets (66). The configuration of the main body frame (63) is the same as that of the main body frame (63) of the first bottom frame (61).

    The pump base (71) is a base for placing a pump member (not shown). The pump base (71) is provided on one end surface in the longitudinal direction of the main body frame (63) of the second bottom frame (62).

    The sealing plate (70) and the heat exchanger mounting plate (69) are formed in a substantially rectangular plate member. The sealing plate (70) and the heat exchange mounting plate (69) are each attached to the main body frame (63) so as to cover one groove portion (64). A water heat exchanger (51) to be described later is placed on the heat exchanger mounting plate (69). Since the sealing plate (70) and the heat exchanger mounting plate (69) block the groove (64), the outside air does not pass through the first and second heat exchanger bodies (35, 36), and the bottom member ( 60) is prevented from being taken into the casing (12).

    The said division board (65) is formed in the substantially rectangular board member, and is provided in the one end side of the main body frame (63) of a 2nd bottom frame (62). The dividing plate (65) is disposed so as to extend outward from the approximate center in the width direction of the main body frame (63).

    As shown in FIG. 11, the bottom member (60) is formed by connecting the first bottom frame (61) and the second bottom frame (62). When the first bottom frame (61) and the second bottom frame (62) are connected, the bottom surface of the casing (12) is formed without gaps by the dividing plates (65, 65) of the both bottom frames (61, 62). . Moreover, since the main body frame (63) of both bottom frames (61, 62) is a common member, the first bottom frame (61) and the second bottom frame (62) can be assembled separately. Further, it is possible to reduce the inventory of the main body frame (63) reserved for production.

    The main body (20) of the casing (12) is formed to have a substantially hexagonal shape in plan view from the upper direction. The hexagonal apex of the main body (20) of the casing (12) includes two long side struts (21) provided on the long side of the casing (12) and the short side of the casing (12). The four short side struts (22) provided on each of them extend up and down and stand upright. The main body (20) of the casing (12) has four openings (27, 28) on the side surface along the longitudinal direction of the casing (12) by the long side struts (21) and the short side struts (22). Forming. The openings (27, 28) are formed to extend from the bottom member (60) to the fan casing (13). Moreover, the partition plate (26) is formed so that the main-body part (20) of a casing (12) may straddle two long side support | pillars (21, 21). The partition plate (26) is a member for partitioning the interior of the main body (20) into two rooms, and extends vertically from the bottom member (60) to the fan casing (13). doing.

    The main body (20) of the casing (12) is provided with a reinforcing material (25). This reinforcing material (25) is formed in a rod body having a substantially concave cross section, and has a long side strut (21) and a short side strut (22) at a height slightly below the middle of each strut (21, 22). ) Between them. The opening (27, 28) is divided into an upper opening (27) and a lower opening (28) by a reinforcing material (25). Each reinforcing material (25) is provided along each air heat exchanger (37, 37, 38, 38), and one reinforcing material (25) is provided with one air heat exchanger (37, 37, 38, 38). ) Is placed. By doing so, the reinforcing material (25) supported each air heat exchanger (37, 37, 38, 38) from below and generated from this air heat exchanger (37, 37, 38, 38). It is configured to store drain water. That is, each reinforcing material (25) functions as a support member that supports each air heat exchanger (37, 37, 38, 38) and also functions as a drain pan. The reinforcing material (25) constitutes a reinforcing member according to the present invention.

    In the upper opening (27), air heat exchangers (37, 37, 38, 38) are formed between the long side strut (21) and the short side strut (22), and the lower opening (28 ) Is formed with a machine room cover (32) extending linearly between the two short side struts (22, 22) in the longitudinal direction of the casing (12). That is, the opening (27, 28) is formed with an air heat exchanger (37, 37, 38, 38) arranged so as to expand outward in a plan view upward, while being linear in a plan view below. A machine room cover (32) extending in the direction is formed. The machine room cover (32) is disposed inside the side surfaces of the first and second heat exchanger bodies (35, 36), and the machine room (29) is formed inside the machine room cover (32). Has been. In addition, a central passage (45) is formed between each long side support (21) and the machine room cover (32).

    The short side of the casing (12) forms a front part and a back part. The front portion on the short side of the casing (12) is formed on the front wall (23). A front opening for maintaining equipment such as the compressor (50) in the casing (12) is formed in the front wall (23), and a front door (23a) is provided in the front opening. Moreover, the back part of the short side of the casing (12) is formed on the back wall (24). The back wall (24) has a back opening for maintaining equipment such as the electrical component box (53) in the casing (12), and a back door (24a) is provided in the back opening. .

    The air heat exchanger (37, 37, 38, 38) is constituted by four air heat exchangers (37, 37, 38, 38). The air heat exchangers (37, 37, 38, 38) are fitted in the four upper openings (27, 27, 27, 27) formed on both side surfaces of the casing (12). . That is, the air heat exchangers (37, 37, 38, 38) constitute the outer wall of the casing (12).

    Each of the air heat exchangers (37, 37, 38, 38) is formed in a flat plate shape, and is configured by an air heat exchanger that extends linearly in a plan view. The four air heat exchangers (37, 37, 38, 38) are disposed two by two for each side surface in the longitudinal direction of the main body (20) of the casing (12). Specifically, each air heat exchanger (37, 37, 38, 38) includes a reinforcing member (25) for the casing (12), a fan casing (13), a short side post (22), and a long side post. The upper opening (27) is surrounded by (21). And each air heat exchanger (37, 37, 38, 38) comprises the heat exchange part, respectively.

    Of the four air heat exchangers (37, 37, 38, 38), two air heat exchangers (37, 37) disposed on one side surface of the long side of the main body (20) of the casing (12) 38) constitute one first heat exchanger main body (35), and two air heat exchangers (37, 38) arranged on the other side surface of the long side of the main body (20) of the casing (12) Constitutes one second heat exchanger body (36). Specifically, in FIG. 2, the first heat exchanger body (35) is disposed on the side surface of the casing (12) on the front side of the body portion (20), and the second heat exchanger body (36). Is disposed on the side surface portion on the back side of the main body portion (20) of the casing (12).

    The first heat exchanger body (35) includes a first air heat exchanger (37) disposed on one end side in the longitudinal direction of the casing (12) and a second air heat exchanger ( 38). The second heat exchanger body (36) includes a first air heat exchanger (37) disposed on one end side in the longitudinal direction of the casing (12) and a second air disposed on the other end side. And a heat exchanger (38). The first air heat exchanger (37) and the second air heat exchanger (38) are configured independently of each other.

    The intersection of the first air heat exchanger (37) of the first heat exchanger body (35) and the first air heat exchanger (37) of the second heat exchanger body (36) on the extension line is a plan view. It is arranged so as to form an acute angle when viewed at. And the outer-end part of the said 1st air heat exchanger (37, 37) which makes an acute angle is arrange | positioned at predetermined intervals. That is, the front wall (23) described above is formed between the outer ends (37a, 37a) of the two first air heat exchangers (37, 37) forming an acute angle, and the front wall (23) is used for maintenance. Auxiliary openings are formed.

    The intersection of the second air heat exchanger (38) of the first heat exchanger body (35) and the second air heat exchanger (38) of the second heat exchanger body (36) is a plane. It is arranged so as to form an acute angle when viewed visually. And the outer-end part of the 2nd air heat exchanger (38,38) which makes the said acute angle is arrange | positioned at predetermined intervals. That is, the back wall (24) described above is formed between the outer ends (38a, 38a) of the two second air heat exchangers (38, 38) having the acute angle, and maintenance is performed on the back wall (24). An auxiliary opening is formed.

    The first air heat exchanger (37) and the second air heat exchanger (38) of the first heat exchanger body (35) are in a central portion of the first heat exchanger body (35) in plan view. Are arranged so as to form an obtuse angle top (39) located outside the casing (12). A long side support (21) on one side of the main body (20) of the casing (12) is erected in the vertical direction at the position where the top (39) is formed. The first air heat exchanger (37) and the second air heat exchanger (38) of the second heat exchanger body (36) are arranged in the center of the second heat exchanger body (36) in plan view. The part is arranged to form an obtuse apex (39) located outside the casing (12). A long side support (21) on the other side of the main body (20) of the casing (12) is erected in the vertical direction at the position where the top (39) is formed.

    In the first heat exchanger body (35), the inner end (37b) of the first air heat exchanger (37) and the inner end of the second air heat exchanger (38) forming the top (39). The part (38b) is disposed so as to be close to each other. Further, in the second heat exchanger body (36), the inner end (37b) of the first air heat exchanger (37) and the inner end of the second air heat exchanger (38) forming the top (39). (38b) are arranged so as to be close to each other.

    That is, the inner end (37b) of the first air heat exchanger (37) and the inner end (38b) of the second air heat exchanger (38) are outer walls formed in a substantially hexagonal shape in plan view. Forming one of the tops (39). The blower fan (17) is provided in a region surrounded by the first heat exchanger body (35) and the second heat exchanger body (36) in a plan view as viewed from the upper side of the casing (12). It has been. In addition, the 1st air heat exchanger (37) comprises the 1st heat exchange part which concerns on this invention, and the 2nd air heat exchanger (38) comprises the 2nd heat exchange part which concerns on this invention.

    The front door (23a) is formed on a removable sheet metal. The front door (23a) extends from the bottom member (60) of the casing (12) to the fan casing (13) in the front opening for maintenance provided on the front wall (23) on the short side of the casing (12). Are provided. Therefore, the operator can remove the front door (23a) and maintain the electrical component box and the like in the casing (12).

    The back door (24a) is formed as a removable sheet metal. The back door (24a) is provided in the back opening for maintenance provided in the back wall (24) on the short side of the casing (12). Therefore, the operator can remove the back door (24a) and maintain the electrical component box (53) and the like in the casing (12).

    The machine room (29) includes a first machine room (30) and a second machine room (31), and the machine room cover (32) includes a first cover (33), a second cover (34), and the like. It consists of

    The first machine room (30) includes the first air heat exchanger (37) of the first heat exchanger body (35) and the first air heat exchanger (37) of the second heat exchanger body (36). It is formed below. In the first machine room (30), two first covers (33) extending along the longitudinal direction of the casing (12) from the two short side struts (22, 22) constituting the front wall (23), respectively. , 33). In the first machine room (30), as shown in FIG. 10, six compressors (50) for compressing the refrigerant are arranged on the compressor mounting plate (68). The two first covers (33) each form a first recess (43).

    The second machine chamber (31) includes a second air heat exchanger (38) of the first heat exchanger body (35) and a second air heat exchanger (38) of the second heat exchanger body (36). It is formed below. The second machine chamber (31) includes a second cover (34, 34) extending from the two short side struts (22, 22) constituting the back wall (24) along the longitudinal direction of the casing (12). Is erected. In the second machine room (31), as shown in FIG. 10, one water heat exchanger (51) for adjusting the temperature of air conditioning water to be temperature-controlled, two expanders, and an electrical component box (53 ) And the like are provided on the heat exchanger mounting plate (69) and the sealing plate (70). One water heat exchanger (51) is connected to two refrigerant circuits. The two second covers (34, 34) each form a second recess (44).

    Of the four recesses (43, 43, 44, 44), two recesses (43, 44) arranged on one side surface of the long side of the casing (12) form one first body recess (41). The two concave portions (43, 44) that are configured and arranged on the other side surface portion of the long side of the casing (12) constitute one second main body concave portion (42). Specifically, the first main body recess (41) is disposed below the first heat exchanger main body (35) of the casing (12) so as to be recessed inward from the side surface of the first heat exchanger main body (35). The first cover (33) and the second cover (34) are formed. The second body recess (42) is disposed below the second heat exchanger body (36) of the casing (12) so as to be recessed inward from the side surface of the second heat exchanger body (36). A first cover (33) and a second cover (34) are formed.

    The first main body recess (41) includes a first recess (43) disposed on one end side in the longitudinal direction of the casing (12) and a second recess (44) disposed on the other end side. . The second main body recess (42) is similarly formed by a first recess (43) disposed on one end side in the longitudinal direction of the casing (12) and a second recess (44) disposed on the other end side. It is configured.

    The first recess (43) on one side surface of the casing (12) is located below the first air heat exchanger (37) of the first heat exchanger body (35), and the first air heat exchanger (37). It is formed by the 1st cover (33) arrange | positioned inside. The first recess (43) on the other side surface of the casing (12) is located below the first air heat exchanger (37) of the second heat exchanger body (36). It is formed by the 1st cover (33) arrange | positioned inside 37). Each first recess (43, 43) forms a space through which air flows.

    The second recess (44) on one side surface of the casing (12) is located below the second air heat exchanger (38) of the first heat exchanger body (35), and the second air heat exchanger (38). It is formed by the 2nd cover (34) arrange | positioned inside. The second recess (44) on the other side surface of the casing (12) is located below the second air heat exchanger (38) of the second heat exchanger body (36), and the second air heat exchanger (38). It is formed by the 2nd cover (34) arrange | positioned inside. Each second recess (44, 44) forms a space through which air flows.

    The space formed by the first recess (43) and the space formed by the second recess (44) communicate with each other through a central passage (45) described later.

    The compressor (50), the water heat exchanger (51), the four-way selector valve (not shown), the expander, and each of the air heat exchangers (37, 37, 38, 38) have a vapor compression refrigerant circuit. It is composed. The refrigerant circuit includes a first refrigerant circuit and a second refrigerant circuit, and is configured to be able to operate independently. That is, each refrigerant circuit can cool or heat the air conditioning water by reversibly circulating the refrigerant by switching a four-way switching valve (not shown).

    The first refrigerant circuit includes three compressors (50), a water heat exchanger (51), a four-way switching valve (not shown), an expander, and two first air heat exchangers (37, 37). I have. The second refrigerant circuit includes three compressors (50), a water heat exchanger (51), a four-way switching valve (not shown), an expander, and two second air heat exchangers (38, 38). ing. That is, in the chiller device (10) according to the present embodiment, the first refrigerant circuit and the second refrigerant circuit are operated separately, whereby the two first air heat exchangers (37, 37) and the two second refrigerant circuits are operated. The air heat exchangers (38, 38) can be operated independently of each other.

    In addition, what is provided in the machine room (29) is not limited to the compressor (50), the water heat exchanger (51), the expander, and the electrical component box (53). The electrical component box (53) accommodates an electric circuit board, wiring, etc. of an inverter circuit for controlling the operation of the chiller device (10).

    The central passage (45) is an air passage formed between the outer wall of the casing (12) constituted by the machine room cover (32) and the long side strut (21), and the air communication according to the present invention. Part. The central passage (45) allows the space formed by the first recess (43) and the space formed by the second recess (44) to communicate with each other and allow the air in both spaces to pass back and forth. The central passage (45) supplies the air flowing through the first recess (43) to the space formed by the second recess (44), while the air flowing through the second recess (44) is supplied by the first recess (43). The space to be formed can be supplied.

-Air flow in one outdoor unit-
Next, the air flow of the outdoor unit (11) of one heat pump chiller will be described. As shown in FIGS. 14 and 15, the air outside (around) the outdoor unit (11) is exposed to the first heat exchanger body (35) and the second heat exchanger body ( It flows from the outside of 36), passes through the first air heat exchanger (37) and the second air heat exchanger (38), and is taken into the casing (12) (see arrows in FIGS. 14 and 15).

    Moreover, the air which flows through a 1st recessed part (43) among air outside the casing (12) flows upwards there, and is guide | induced to the outer side of a 1st air heat exchanger (37) from the lower side. Thereafter, when passing through the first air heat exchanger (37, 37) of each heat exchanger body (35, 36), heat is exchanged with the refrigerant and taken into the casing (12). Part of the air flowing through the first recess (43) passes through the central passage (45) and is supplied to the second recess (44).

    Moreover, the air which flows through a 2nd recessed part (44) among air outside the casing (12) flows upwards there, and is guide | induced to the outer side of a 2nd air heat exchanger (38) from the lower side. After that, when passing through the second air heat exchanger (38, 38) of each heat exchanger body (35, 36), heat is exchanged with the refrigerant and taken into the casing (12). Part of the air flowing through the second recess (44) passes through the central passage (45) and is supplied to the space formed by the first recess (43).

    As described above, the space formed by the first recess (43) and the space formed by the second recess (44) communicate with each other via the central passage (45), and thus flow through both spaces. Air can go back and forth between each other. For this reason, the flow rate of the air flowing through the central passage (45) increases.

-Driving action-
Next, the driving operation of this embodiment will be described.

    First, when the chiller device (10) operates the blower fan (17), air outside the casing (12) is transferred from the first heat exchanger body (35) and the second heat exchanger body (36) to the casing (12 ). As shown in FIGS. 16 and 17, when the outdoor units (11) of three heat pump chillers are arranged side by side in the width direction, the air outside the casing (12) is mainly in the longitudinal direction of the casing (12). The first air heat exchanger (37) and the second air heat exchanger (38) flow outside the first heat exchanger body (35) and the second heat exchanger body (36) through the gaps formed at both ends. ) Into the casing (12).

    Moreover, the air outside the casing (12) flows into the first recess (43, 43) from the gap at one end in the longitudinal direction of the casing (12). The air flowing through the first recess (43) flows upward, is guided to the outside of the first air heat exchanger (37), passes through the first air heat exchanger (37), and enters the casing (12). Flows in. And this air is heat-exchanged when passing a 1st air heat exchanger (37). Part of the air flowing through the first recess (43) passes through the central passage (45) and flows toward the second recess (44).

    Moreover, the air outside the casing (12) flows into the second recess (44, 44) from the gap at the other end in the longitudinal direction of the casing (12). The air flowing through the second recess (44) flows upward, is guided to the outside of the second air heat exchanger (38), passes through the second air heat exchanger (38), and passes through the interior of the casing (12). Flow into. This air is heat-exchanged when passing through the second air heat exchanger (38, 38). Part of the air flowing through the second recess (44) passes through the central passage (45) and flows toward the first recess (43).

    As described above, the space formed by the first recess (43) and the space formed by the second recess (44) communicate with each other via the central passage (45), and thus flow through both spaces. Air can go back and forth between each other. For this reason, the flow rate of the air flowing through the central passage (45) increases.

    And the air taken in in the casing (12) through each air heat exchanger (37, 37, 38, 38) passes through the blower outlet (14) by the upper blower fan (17), and the casing It blows out above (12).

    Next, the operation of the refrigerant circuit when air conditioning water in the water heat exchanger (51) is used for cooling will be described.

    First, in the first refrigerant circuit, the operation of the compressor (50) is started, and the refrigerant is compressed by the compressor (50). The compressed refrigerant discharged from the compressor (50) flows into the first air heat exchanger (37, 37). In the first heat exchanger body (35) and the second heat exchanger body (36), the external air of the casing (12) is the first air heat exchanger (37, 37) constituting each heat exchanger body (35, 36). , 37), the heat of the refrigerant is radiated to the air to heat the air taken into the casing (12). And the refrigerant | coolant which thermally radiated and cooled to air expand | swells with an expansion valve, Then, it flows in into a water heat exchanger (51). In the water heat exchanger (51), the refrigerant absorbs heat from the air conditioning water flowing in the water heat exchanger (51) to cool the air conditioning water. The cooled water for air conditioning is supplied into the building. The refrigerant that has flowed out of the water heat exchanger (51) is again sucked into the compressor (50) and compressed.

    In the second refrigerant circuit, the operation of the compressor (50) is started, and the refrigerant is compressed by the compressor (50). The compressed refrigerant discharged from the compressor (50) flows into the second air heat exchanger (38, 38). In the first heat exchanger body (35) and the second heat exchanger body (36), the second air heat exchanger (38) in which the external air of the casing (12) constitutes each heat exchanger body (35, 36). , 38), the heat of the refrigerant is radiated to the air to heat the air taken into the casing (12). And the refrigerant | coolant which thermally radiated and cooled to air expand | swells with an expansion valve, Then, it flows in into a water heat exchanger (51). In the water heat exchanger (51), the refrigerant absorbs heat from the air conditioning water flowing in the water heat exchanger (51) to cool the air conditioning water. The cooled water for air conditioning is supplied into the building. The refrigerant that has flowed out of the water heat exchanger (51) is again sucked into the compressor (50) and compressed.

    The operation of the refrigerant circuit in the case where the water for air conditioning in the water heat exchanger (51) is used for heating will be described.

    In the first refrigerant circuit, the operation of the compressor (50) is started, and the refrigerant is compressed by the compressor (50). The compressed refrigerant discharged from the compressor (50) flows into the water heat exchanger (51). In the water heat exchanger (51), the refrigerant dissipates heat to the air conditioning water flowing in the water heat exchanger (51) to heat the air conditioning water. The heated water for air conditioning is supplied into the building. The refrigerant flowing out of the water heat exchanger (51) is expanded by the expansion valve, and then flows into the first air heat exchanger (37, 37). In the first heat exchanger body (35) and the second heat exchanger body (36), the external air of the casing (12) is the first air heat exchanger (37, 37) constituting each heat exchanger body (35, 36). , 37), the refrigerant absorbs heat from the air and cools the air taken into the casing (12). The refrigerant flowing out of the first air heat exchanger (37, 37) is again sucked into the compressor (50) and compressed.

    In the second refrigerant circuit, the operation of the compressor (50) is started, and the refrigerant is compressed by the compressor (50). The compressed refrigerant discharged from the compressor (50) flows into the water heat exchanger (51). In the water heat exchanger (51), the refrigerant dissipates heat to the air conditioning water flowing in the water heat exchanger (51) to heat the air conditioning water. The heated water for air conditioning is supplied into the building. The refrigerant flowing out of the water heat exchanger (51) is expanded by the expansion valve and then flows into the second air heat exchanger (38, 38). In the first heat exchanger body (35) and the second heat exchanger body (36), the second air heat exchanger (38) in which the external air of the casing (12) constitutes each heat exchanger body (35, 36). , 38), the refrigerant absorbs heat from the air and cools the air taken into the casing (12). The refrigerant that has flowed out of the second air heat exchanger (38, 38) is again sucked into the compressor (50) and compressed.

    Next, maintenance of the chiller device (10) by an operator will be described.

    When an operator performs maintenance work, the chiller device (10) is stopped, the machine room cover (32) is removed, and the first machine room (30) and the second machine room (31) are removed from the lower opening (28). ) Maintain the compressor (50). Further, the front door (23a) or the rear door (24a) can be removed, and maintenance of the electrical component box (53) and the like can be performed from the front side or the back side of the casing (12) of the outdoor unit (11).

-Single system operation-
As shown in FIG. 18, the outdoor unit (11) according to the present embodiment can be operated with only one system according to the load. Specifically, the operation can be performed only by the first refrigerant circuit. When operating with only one system, the blower fans (17, 17) corresponding to the second refrigerant circuit are stopped.

    First, the air outside the casing (12) is mainly drawn from the gap formed at one end portion in the longitudinal direction of the casing (12) in the first heat exchanger body (35) and the second heat exchanger body (36). It flows outside and is taken into the casing (12) from the first air heat exchanger (37, 37).

    Moreover, the air outside the casing (12) flows into the first recess (43, 43) from the gap at one end in the longitudinal direction of the casing (12). The air flowing through the space of the first recess (43) flows upward, is guided to the outside of the first air heat exchanger (37), passes through the first air heat exchanger (37), and flows into the casing (12). Flows into the interior. And this air is heat-exchanged when passing a 1st air heat exchanger (37).

    Moreover, the air outside the casing (12) flows into the second recesses (44, 44) from the gap at the other end in the longitudinal direction of the casing (12). As described above, the space formed by the first recess (43) and the space formed by the second recess (44) communicate with each other via the central passage (45). For this reason, the air flowing through the space of the second recess (44) passes through the central passage (45) and is supplied to the first recess (43) side. Therefore, the air flowing through the first recess (43) increases.

    And the air taken in in the casing (12) through the first air heat exchanger (37, 37) passes through the outlet (14) by the upper blower fan (17), and the casing (12) Is blown out above.

-Effect of the embodiment-
According to the embodiment, since the first main body concave portion (41) and the second main body concave portion (42) are provided, in addition to the air flowing outside the first and second heat exchanger main bodies (35, 36), the air It can guide to the outside of the 1st heat exchanger body (35) and the 2nd heat exchanger body (36) from the lower part. For this reason, the flow volume of the air which passes a 1st air heat exchanger (37) and a 2nd air heat exchanger (38) can be increased (refer FIG. 20). Thereby, the heat exchange efficiency of a 1st air heat exchanger (37) and a 2nd air heat exchanger (38) can be improved. As a result, the heat exchange efficiency can be improved in the outdoor unit (11) having the air heat exchangers (37, 37, 38, 38) arranged in a substantially hexagonal shape in plan view.

    In addition, since the central passage (45) is provided to communicate the space formed by the first recess (43) and the space formed by the second recess (44), the space of the first recess (43) is reduced. While the flowing air is supplied to the second recess (44) side, the air flowing through the space of the second recess (44) can be supplied to the first recess (43) side. Thereby, the flow rate of air in both spaces of the first recess (43) and the second recess (44) can be increased. That is, since the lower part of the conventional 1st heat exchanger main body and the 2nd heat exchanger main body becomes far from a ventilation fan, the flow of air worsens (refer FIG. 19). However, in the present embodiment, the flow rate of air flowing through both the first recess (43) and the second recess (44) can be increased by the central passage (45), so the first heat exchanger body (35). And the air flow rate below the second heat exchanger body (36) can be increased (see FIG. 20). Thereby, the heat exchange efficiency of a 1st air heat exchanger (37) and a 2nd air heat exchanger (38) can be improved. As a result, the heat exchange efficiency can be improved in the outdoor unit (11) having the air heat exchangers (37, 37, 38, 38) arranged in a substantially hexagonal shape in plan view.

    Further, since the machine chamber (29) is provided inside the first main body recess (41) and the second main body recess (42), the first main body recess (41) and the second main body recess (42) to the machine chamber (29). It is possible to maintain the internal components.

    Further, a reinforcing member (25) configured to allow drain water to flow is provided along the first heat exchanger body (35) or the second heat exchanger body (36), and the first heat exchanger body from below. (35) or the second heat exchanger body (36) is supported so that the first heat exchanger body (35) or the second heat exchanger body (36) can be reinforced and at the same time the first heat The drain water generated from the exchanger main body (35) or the second heat exchanger main body (36) can be flowed to the reinforcing member (25).

    Finally, since the first air heat exchanger (37) and the second air heat exchanger (38) operate independently of each other, only the first air heat exchanger (37) operates. The air supplied from the second recess (44) to the first recess (43) can be guided to the first air heat exchanger (37). For this reason, the flow rate of the air flowing through the operating first air heat exchanger (37) can be increased. Further, when only the second air heat exchanger (38) operates, the air supplied from the first recess (43) to the second recess (44) is led to the second air heat exchanger (38). Can do. For this reason, the flow rate of the air flowing through the operating second air heat exchanger (38) can be increased.

-Modification of the embodiment-
Next, a modification of this embodiment will be described. The chiller device (10) according to the present modification is different from the chiller device (10) according to the embodiment in the configuration of the bottom member (60). Note that in this modification, only parts different from the above embodiment will be described.

    Specifically, in this modification, as shown in FIG. 21, the main body frame (63) of the second bottom frame (62) is provided with an outlet pipe of the water pipe of the water heat exchanger (51). While the pedestal (72) is provided, the pump pedestal is not provided. Other configurations, operations and effects are the same as those in the embodiment.

<Other embodiments>
The present invention may be configured as follows with respect to the above embodiment.

    A plurality of outdoor units (11) according to the above embodiment may be connected and installed, or one outdoor unit (11) may be installed near the wall.

    In the above embodiment, the machine room cover (32) is provided to form the body recesses (41, 42) to form the machine room (29), but the present invention is not limited to this. Specifically, without providing a machine room cover (32), six compressors (50), a water heat exchanger (51), an expander, an electrical component box (53), etc. are arranged in the air passage. It may be. That is, in this embodiment, six compressors (50), a water heat exchanger (51), an expander, and an electrical component box (53), which are components of the outdoor unit (11), are arranged in the air passage. Yes.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a refrigeration apparatus having a heat exchanger.

DESCRIPTION OF SYMBOLS 10 Chiller apparatus 11 Outdoor unit 12 Casing 17 Blower fan 25 Reinforcement material (reinforcement member)
29 Machine room 35 1st heat exchanger main body 36 2nd heat exchanger main body 37 1st air heat exchanger (1st heat exchange part)
38 Second Air Heat Exchanger (Second Heat Exchanger)
39 Top 41 First body recess 42 Second body recess 43 First recess 44 Second recess 45 Central passage (air communication part)

    The present invention relates to an outdoor unit and a refrigeration apparatus including the outdoor unit, and particularly relates to an external air intake structure.

    Conventionally, as shown in Patent Document 1, a large-scale heat pump chiller disposed on the roof of a building is known as a refrigeration apparatus. The outdoor unit of this heat pump chiller is formed in a substantially hexagonal shape in plan view, and has a casing having air suction ports on opposite sides, a plurality of flat plate heat exchangers disposed in the air suction ports, A blower fan disposed inside an air outlet formed on the upper surface of the casing.

JP 2010-216798 A

    By the way, in the heat pump chiller according to Patent Document 1 described above, for example, three outdoor units are installed side by side, and air is taken in from a gap between adjacent outdoor units.

    However, since the lower part of the casing is separated from the blower fan disposed above, the air hardly flows. For this reason, there existed a problem that the heat exchange performance of the downward direction of a casing fell.

    This invention is made | formed in view of such a point, and it aims at improving the heat exchange efficiency in the outdoor unit which has a heat exchanger arrange | positioned by substantially hexagonal shape by planar view.

    The first invention is a casing (12) and a heat exchanger body (35, 36) that is disposed on a side surface of the casing (12), extends along the side surface, and is exposed to the outside of the casing (12). The heat exchanger body (35, 36) is formed with a top portion (39) having a central portion located outside the casing (12) in a plan view, and the heat exchanger body (35, 36). ) Is an outdoor unit configured to allow air to flow into the casing (12) from the outside of the casing (12), and is disposed above the casing (12). A blower fan (17) that blows out, and a body recess formed below the heat exchanger body (35, 36) of the casing (12) and recessed inward from the side surface of the heat exchanger body (35, 36) (41, 42).

The heat exchanger body (35, 36) is disposed on both side surfaces of the casing (12), and extends along both side surfaces of the casing (12), and the first heat exchanger body (35) and the second heat exchange. An obtuse top (39) having a central portion located outside the casing (12) in a plan view of the first heat exchanger main body (35) and the second heat exchanger main body (36). Are provided with a linear first heat exchange section (37) and a second heat exchange section (38) extending in the outer direction of the casing (12).

On the other hand, the main body recess (41, 42) is formed from the bottom member (60) of the casing (12) to the reinforcing member (25) on which the heat exchanger main body (35, 36) is placed. A space is formed in the casing (12) that opens to the front or back of the casing, and the main body recess (41, 42) is recessed inward from the side surface of the first heat exchanger body (35). A first main body recess (41) and a second main body recess (42) recessed inward from the side surface of the second heat exchanger main body (36) are provided. The first main body concave portion (41) and the second main body concave portion (42) include a first concave portion (43) and a second heat exchanging portion (38) that are recessed inward from the side surface of the first heat exchanging portion (37). ) And a second recess (44) that is recessed inward from the side surface, and an air communication portion that communicates the space formed by the first recess (43) and the space formed by the second recess (44) ( 45).

    In the said 1st invention, the heat exchanger main body (35, 36) is arrange | positioned at the side part of the casing (12). The heat exchanger body (35, 36) extends along the side surface of the casing (12) and is exposed to the outside of the casing (12). The heat exchanger body (35, 36) has a top portion (39) whose central portion is located outside the casing (12) in plan view. Air outside the casing (12) flows from the outside of the heat exchanger body (35, 36) through the heat exchanger body (35, 36) and into the casing (12). The air flowing into the casing (12) is heat-exchanged when passing through the heat exchanger body (35, 36).

    On the other hand, below the heat exchanger body (35, 36), a body recess (41, 42) is provided on the side surface of the casing (12). ing. External air flows through the space formed by the main body recesses (41, 42).

The air flowing through the main body recess (41, 42) is guided to the outside of the heat exchanger body (35, 36) from below the heat exchanger body (35, 36). And it flows into the inside of a casing (12) from the outer side of a heat exchanger main body (35,36). The air flowing in the casing (12), Ru is heat-exchanged while passing through the heat exchanger body (35, 36).

In addition, air outside the casing (12) flows from the outside of the first heat exchanger body (35) and the second heat exchanger body (36) to the first heat exchange part (37) and the second heat exchange, respectively. It passes through the part (38) and flows into the casing (12). The air flowing into the casing (12) is heat-exchanged when passing through the first heat exchange part (37) and the second heat exchange part (38).

    On the other hand, on the lower side of the first heat exchanger body (35) and the second heat exchanger body (36), they are inside the side surfaces of the first heat exchanger body (35) and the second heat exchanger body (36). A first main body recess (41) and a second main body recess (42) are provided. Air outside the casing (12) flows through each of the first main body recess (41) and the second main body recess (42).

The air flowing through the first main body recess (41) is guided to the outside of the first heat exchanger main body (35) from below the first heat exchanger main body (35). And it flows into the inside of a casing (12) through the 1st heat exchange part (37) and the 2nd heat exchange part (38) from the outside of the 1st heat exchanger main part (35). And the air which flows in into the inside of a casing (12) is heat-exchanged when passing a 1st heat exchange part (37) and a 2nd heat exchange part (38). The air flowing through the second main body recess (42) is guided to the outside of the second heat exchanger main body (36) from below the second heat exchanger main body (36). And it flows through the 1st heat exchange part (37) and the 2nd heat exchange part (38) from the outside of the 2nd heat exchanger body (36), and flows into the inside of a casing (12). The air flowing in the casing (12), Ru is heat-exchanged while passing through the first heat exchange unit (37) and the second heat exchange section (38).

Moreover, the 1st main body recessed part (41) below the said 1st heat exchanger main body (35) is comprised by the 1st recessed part (43) and the 2nd recessed part (44). Moreover, the 2nd main body recessed part (42) below the 2nd heat exchanger main body (36) is comprised by the 1st recessed part (43) and the 2nd recessed part (44).

    The first recess (43) is connected to the outside of the casing (12), and the outside air flows. The air flowing through the first recess (43) is guided to the outside of the first heat exchange part (37) from below, and is exchanged when passing through the first heat exchange part (37) to be inside the casing (12). Flow into.

    The second recess (44) is connected to the outside of the casing (12), and the outside air flows. The air flowing through the second recess (44) is guided from below to the outside of the second heat exchanging part (38) and is exchanged when passing through the second heat exchanging part (38), so that the inside of the casing (12). Flow into.

    Here, the air communication part (45) communicates the space formed by the first recess (43) and the space formed by the second recess (44). For this reason, the air which flows through a 1st recessed part (43) and the air which flows through a 2nd recessed part (44) can go back and forth mutually space. That is, the air flowing through the first recess (43) flows into the second recess (44), while the air flowing through the second recess (44) flows into the first recess (43). Thereby, the amount of air flowing below the first heat exchanger body (35) and the second heat exchanger body (36) can be increased.

According to a second aspect of the present invention, in the first aspect , the casing (12) includes a machine room (29) in which components are disposed inside the first main body recess (41) and the second main body recess (42). ).

In the second aspect of the invention, the machine room (29) in which the components are arranged is formed inside the first main body recess (41) and the second main body recess (42) of the casing (12). By doing so, it is possible to perform maintenance on the components in the machine room (29) from the first main body recess (41) and the second main body recess (42).

According to a third invention, in the first or second invention , the reinforcing member (25) extends along the first heat exchanger body (35) and the second heat exchanger body (36). While supporting each heat exchange part (37,37,38,38) from the lower side, it is comprised so that the drain water of this each heat exchange part (37,37,38,38) may flow.

In the said 3rd invention, the reinforcement member (25) is provided in the casing (12) along the 1st heat exchanger main body (35) or the 2nd heat exchanger main body (36). The reinforcing member (25) is configured to support each heat exchange part (37, 37, 38, 38) from below and to allow drain water to flow. By doing so, the reinforcing member (25) becomes a member having both the reinforcing function of each heat exchanging part (37, 37, 38, 38) and the function of the drain pan.

According to a fourth invention, in any one of the first to third inventions, the first heat exchange section (37) and the second heat exchange section (38) are connected to different refrigerant circuits and independently. And is configured to be operable.

In the said 4th invention, a 1st heat exchange part (37) and a 2nd heat exchange part (38) are connected to a respectively different refrigerant circuit, and each can operate | move independently. In this way, when only the first heat exchange part (37) operates, air can flow from the second recess (44) to the first recess (43). For this reason, the air flow rate which flows through the 1st heat exchange part (37) of operation object can be increased. Moreover, when only the 2nd heat exchange part (38) operate | moves, air can be flowed from a 1st recessed part (43) to a 2nd recessed part (44). For this reason, the air flow rate which flows through the 2nd heat exchange part (38) of operation object can be increased.

5th invention is provided with the outdoor unit (11) which concerns on any one invention of the said 1st- 4th invention.

The refrigeration apparatus according to the fifth aspect of the invention includes an outdoor unit (11).

    According to 1st invention, since the main-body recessed part (41, 42) was provided, in addition to the air which flows the outer side of a heat exchanger main body (35, 36), it is on the outer side of a heat exchanger main body (35, 36) from the downward direction. Can lead air. For this reason, the flow rate of the air passing through the heat exchanger body (35, 36) can be increased. Thereby, the heat exchange efficiency of the heat exchanger body (35, 36) can be improved. As a result, heat exchange efficiency can be improved in an outdoor unit having a heat exchanger arranged in a substantially hexagonal shape in plan view.

In addition, since the first main body recess (41) and the second main body recess (42) are provided, in addition to the air flowing outside the first and second heat exchanger bodies (35, 36), the first heat exchange from below is performed. Air can be guided to the outside of the main body (35) and the second heat exchanger main body (36). For this reason, the flow volume of the air which passes a 1st heat exchange part (37) and a 2nd heat exchange part (38) can be increased. Thereby, the heat exchange efficiency of a 1st heat exchange part (37) and a 2nd heat exchange part (38) can be improved. As a result, heat exchange efficiency can be improved in an outdoor unit having a heat exchanger arranged in a substantially hexagonal shape in plan view.

In addition, since the air communication portion (45) is provided to communicate the space formed by the first recess (43) and the space formed by the second recess (44), the air flowing through the first recess (43) Can be supplied to the second recess (44), while air flowing through the second recess (44) can be supplied to the first recess (43). Thereby, the flow volume of the air which flows from a 1st recessed part (43) to a 2nd recessed part (44) can be increased. That is, since the lower part of the first heat exchanger body (35) and the second heat exchanger body (36) is far from the blower fan (17), the air flow is deteriorated. However, in the present invention, the flow rate of the air flowing between the first recess (43) and the second recess (44) can be increased by the air communication portion (45), so that the first heat exchanger body (35) and The air flow rate below the second heat exchanger body (36) can be increased. Thereby, the heat exchange efficiency of a 1st heat exchange part (37) and a 2nd heat exchange part (38) can be improved. As a result, heat exchange efficiency can be improved in an outdoor unit having a heat exchanger arranged in a substantially hexagonal shape in plan view.

According to the second invention, since the machine chamber (29) is provided inside the first main body recess (41) and the second main body recess (42), the first main body recess (41) and the second main body recess (42). From the above, it can be configured to maintain the components in the machine room (29).

According to 3rd invention, while providing the reinforcement member (25) comprised so that drain water may flow along a 1st heat exchanger main body (35) or a 2nd heat exchanger main body (36), from the downward direction Since the first heat exchange section (37) or the second heat exchange section (38) is supported, the first heat exchanger body (35) or the second heat exchanger body (36) can be mounted with one member. At the same time that it can be reinforced, drain water generated from the first heat exchange section (37) or the second heat exchange section (38) can be treated.

According to the fourth aspect of the invention, the first heat exchanging part (37) and the second heat exchanging part (38) operate independently of each other, so that only the first heat exchanging part (37) operates. In this case, air supplied from the second recess (44) to the first recess (43) can be guided to the first heat exchange unit (37). For this reason, the flow volume of the air which flows through the 1st heat exchange part (37) which operate | moves can be increased. Further, when only the second heat exchange section (38) operates, the air supplied from the first recess (43) to the second recess (44) can be guided to the second heat exchange section (38). For this reason, the flow volume of the air which flows through the 2nd heat exchange part (38) which operate | moves can be increased.

FIG. 1 is a schematic perspective view illustrating a chiller device according to an embodiment. Drawing 2 is a perspective view which looked at an outdoor unit of a heat pump chiller concerning an embodiment from one side. Drawing 3 is a perspective view which looked at the outdoor unit of the heat pump chiller concerning an embodiment from the other side. FIG. 4 is a front view showing the outdoor unit of the heat pump chiller according to the embodiment. FIG. 5 is a rear view showing the outdoor unit of the heat pump chiller according to the embodiment. FIG. 6 is a left side view illustrating the outdoor unit of the heat pump chiller according to the embodiment. FIG. 7 is a right side view showing the outdoor unit of the heat pump chiller according to the embodiment. FIG. 8 is a top view showing the outdoor unit of the heat pump chiller according to the embodiment. FIG. 9 is a bottom view showing the outdoor unit of the heat pump chiller according to the embodiment. Drawing 10 is a longitudinal section showing the outdoor unit of the heat pump chiller concerning an embodiment. FIG. 11 is a perspective view showing the structure of the bottom member according to the embodiment. FIG. 12 is a perspective view showing the structure of the first bottom frame according to the embodiment. FIG. 13 is a perspective view showing the structure of the second bottom frame according to the embodiment. FIG. 14 is a perspective view of the air flow of the outdoor unit of the heat pump chiller according to the embodiment as viewed from one side surface. FIG. 15: is the perspective view which looked at the air flow of the outdoor unit of the heat pump chiller which concerns on embodiment from the other side surface side. FIG. 16 is a schematic perspective view showing an air flow of the chiller device according to the embodiment. FIG. 17 is a top view illustrating an air flow of the chiller device according to the embodiment. FIG. 18 is a schematic perspective view illustrating an air flow during one-line operation of the chiller device according to the embodiment. FIG. 19 is a graph showing the relationship between the height and the air volume in an outdoor unit according to a conventional example. FIG. 20 is a graph showing the relationship between the height and the air volume in the outdoor unit according to the embodiment. FIG. 21 is a perspective view showing a structure of a second bottom frame according to a modified example of the embodiment.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

    As shown in FIG. 1, the refrigeration apparatus of the present embodiment constitutes a chiller apparatus (10). The chiller device (10) includes an outdoor unit (11) of a heat pump chiller that is installed on a rooftop of a building or the like and cools or heats air-conditioning water supplied into the building. In the chiller device (10), for example, three outdoor units (11) are arranged in parallel in the width direction on the wall (1).

    As shown in FIGS. 2 to 9, each outdoor unit (11) includes a casing (12) having a refrigerant circuit (not shown).

    The casing (12) includes a fan casing (13) formed at the upper end, a bottom member (60) formed at the lower end, and a main body provided between the fan casing (13) and the bottom member (60). (20). 1 to 9 show a schematic bottom member (60), and a detailed structure will be described later.

    As shown in FIG. 10, the fan casing (13) accommodates the blower fan (17) in the interior thereof and is disposed at the upper end of the casing (12).

    The fan casing (13) is formed in a substantially thin box having a substantially rectangular shape in plan view, and is provided at the upper end of the casing (12). Although not shown, the fan casing (13) is open at a portion corresponding to the lower end main body (20). Further, four air outlets (14, 14, 14, 14) are formed side by side along the longitudinal direction on the upper end surface of the fan casing (13). A fan guard is attached to each air outlet (14) so as to cover the opening surface. The fan guard is a protective net for the blower fan (17). In addition, four blower fans (17) corresponding to each outlet (14) are provided inside the fan casing (13), and a bell mouth (16) is provided around each blower fan (17). ing.

    The fan casing (13) is formed such that both side surfaces (15a, 15b) extend outward to a position corresponding to the outermost part of the main body (20) described later. Specifically, one side surface (15a) of the fan casing (13) is an obtuse top (39) located outside the casing (12) at the center of the first heat exchanger body (35) in plan view. And is formed so as to extend linearly in the longitudinal direction of the casing (12). A portion of the fan casing (13) that projects to the outside of the first heat exchanger body (35) in plan view constitutes a first flange (13a).

    On the other hand, the other side surface (15b) of the fan casing (13) extends from the center of the second heat exchanger body (36) to the position of the obtuse apex (39) located outside the casing (12) in plan view. It is formed so as to protrude and extends linearly in the longitudinal direction of the casing (12). And the part which protruded outside the 2nd heat exchanger main body (36) in planar view among fan casings (13) comprises the 2nd collar part (13b).

    The air blown above the casing (12) from the blower outlet (14) by the first flange part (13a) and the second flange part (13b) flows below the fan casing (13) and is an air heat exchanger. It is possible to prevent a so-called short circuit that flows into (37, 37, 38, 38).

    The blower fan (17) is configured as an axial blower (for example, a propeller fan). The blower fan (17) is provided in four corresponding to the four outlets (14), and sucks air from the outside into the casing (12), and the air is sucked into the fan casing (13) and the outlet. It is configured to blow out through (14). The bell mouth (16) is formed in a substantially cylindrical shape and is provided in the fan casing (13) so as to surround the blower fan (17).

    The said bottom member (60) is a member which is arrange | positioned at the lower end part of a casing (12) as shown in FIG. 11, and mounts the compressor (50) mentioned later and a water heat exchanger (51). The bottom member (60) is configured by connecting a first bottom frame (61) and a second bottom frame (62). The first bottom frame (61) and the second bottom frame (62) are both formed by using a main body frame (63) which is a common member.

    As shown in FIG. 12, the first bottom frame (61) includes a main body frame (63), a dividing plate (65), two compressor mounting plates (68, 68), a wiring cover (67, 67) and three support brackets (66).

    The main body frame (63) is formed in a thin frame having a substantially rectangular shape in plan view. The main body frame (63) is provided with grooves (64, 64) arranged in two rows in the width direction. The groove portions (64, 64) are formed extending in the longitudinal direction of the main body frame (63).

    The compressor mounting plate (68) is formed in a substantially rectangular plate member. Each compressor mounting plate (68) is attached to the main body frame (63) so as to cover the corresponding groove (64). Three compressors (50), which will be described later, are mounted on one compressor mounting plate (68). The compressor mounting plate (68) closes the groove (64), so that the outside air passes through the bottom member (60) without passing through the first and second heat exchanger bodies (35, 36). It is prevented from being taken into the casing (12).

    The dividing plate (65) is formed in a substantially rectangular plate member, and is provided on the other end side of the main body frame (63) of the first bottom frame (61). The dividing plate (65) is disposed so as to extend outward from the approximate center in the width direction of the main body frame (63).

    The wiring cover (67) is a cover member for protecting the electrical wiring of the corresponding outdoor unit (11). The wiring cover (67) is attached along both side surfaces in the longitudinal direction of the main body frame (63).

    As shown in FIG. 13, the second bottom frame (62) includes a main body frame (63), a pump base (71), a dividing plate (65), a heat exchanger mounting plate (69), and a sealing plate ( 70) and three support brackets (66). The configuration of the main body frame (63) is the same as that of the main body frame (63) of the first bottom frame (61).

    The pump base (71) is a base for placing a pump member (not shown). The pump base (71) is provided on one end surface in the longitudinal direction of the main body frame (63) of the second bottom frame (62).

    The sealing plate (70) and the heat exchanger mounting plate (69) are formed in a substantially rectangular plate member. The sealing plate (70) and the heat exchange mounting plate (69) are each attached to the main body frame (63) so as to cover one groove portion (64). A water heat exchanger (51) to be described later is placed on the heat exchanger mounting plate (69). Since the sealing plate (70) and the heat exchanger mounting plate (69) block the groove (64), the outside air does not pass through the first and second heat exchanger bodies (35, 36), and the bottom member ( 60) is prevented from being taken into the casing (12).

    The said division board (65) is formed in the substantially rectangular board member, and is provided in the one end side of the main body frame (63) of a 2nd bottom frame (62). The dividing plate (65) is disposed so as to extend outward from the approximate center in the width direction of the main body frame (63).

    As shown in FIG. 11, the bottom member (60) is formed by connecting the first bottom frame (61) and the second bottom frame (62). When the first bottom frame (61) and the second bottom frame (62) are connected, the bottom surface of the casing (12) is formed without gaps by the dividing plates (65, 65) of the both bottom frames (61, 62). . Moreover, since the main body frame (63) of both bottom frames (61, 62) is a common member, the first bottom frame (61) and the second bottom frame (62) can be assembled separately. Further, it is possible to reduce the inventory of the main body frame (63) reserved for production.

    The main body (20) of the casing (12) is formed to have a substantially hexagonal shape in plan view from the upper direction. The hexagonal apex of the main body (20) of the casing (12) includes two long side struts (21) provided on the long side of the casing (12) and the short side of the casing (12). The four short side struts (22) provided on each of them extend up and down and stand upright. The main body (20) of the casing (12) has four openings (27, 28) on the side surface along the longitudinal direction of the casing (12) by the long side struts (21) and the short side struts (22). Forming. The openings (27, 28) are formed to extend from the bottom member (60) to the fan casing (13). Moreover, the partition plate (26) is formed so that the main-body part (20) of a casing (12) may straddle two long side support | pillars (21, 21). The partition plate (26) is a member for partitioning the interior of the main body (20) into two rooms, and extends vertically from the bottom member (60) to the fan casing (13). doing.

    The main body (20) of the casing (12) is provided with a reinforcing material (25). This reinforcing material (25) is formed in a rod body having a substantially concave cross section, and has a long side strut (21) and a short side strut (22) at a height slightly below the middle of each strut (21, 22). ) Between them. The opening (27, 28) is divided into an upper opening (27) and a lower opening (28) by a reinforcing material (25). Each reinforcing material (25) is provided along each air heat exchanger (37, 37, 38, 38), and one reinforcing material (25) is provided with one air heat exchanger (37, 37, 38, 38). ) Is placed. By doing so, the reinforcing material (25) supported each air heat exchanger (37, 37, 38, 38) from below and generated from this air heat exchanger (37, 37, 38, 38). It is configured to store drain water. That is, each reinforcing material (25) functions as a support member that supports each air heat exchanger (37, 37, 38, 38) and also functions as a drain pan. The reinforcing material (25) constitutes a reinforcing member according to the present invention.

    In the upper opening (27), air heat exchangers (37, 37, 38, 38) are formed between the long side strut (21) and the short side strut (22), and the lower opening (28 ) Is formed with a machine room cover (32) extending linearly between the two short side struts (22, 22) in the longitudinal direction of the casing (12). That is, the opening (27, 28) is formed with an air heat exchanger (37, 37, 38, 38) arranged so as to expand outward in a plan view upward, while being linear in a plan view below. A machine room cover (32) extending in the direction is formed. The machine room cover (32) is disposed inside the side surfaces of the first and second heat exchanger bodies (35, 36), and the machine room (29) is formed inside the machine room cover (32). Has been. In addition, a central passage (45) is formed between each long side support (21) and the machine room cover (32).

    The short side of the casing (12) forms a front part and a back part. The front portion on the short side of the casing (12) is formed on the front wall (23). A front opening for maintaining equipment such as the compressor (50) in the casing (12) is formed in the front wall (23), and a front door (23a) is provided in the front opening. Moreover, the back part of the short side of the casing (12) is formed on the back wall (24). The back wall (24) has a back opening for maintaining equipment such as the electrical component box (53) in the casing (12), and a back door (24a) is provided in the back opening. .

    The air heat exchanger (37, 37, 38, 38) is constituted by four air heat exchangers (37, 37, 38, 38). The air heat exchangers (37, 37, 38, 38) are fitted in the four upper openings (27, 27, 27, 27) formed on both side surfaces of the casing (12). . That is, the air heat exchangers (37, 37, 38, 38) constitute the outer wall of the casing (12).

    Each of the air heat exchangers (37, 37, 38, 38) is formed in a flat plate shape, and is configured by an air heat exchanger that extends linearly in a plan view. The four air heat exchangers (37, 37, 38, 38) are disposed two by two for each side surface in the longitudinal direction of the main body (20) of the casing (12). Specifically, each air heat exchanger (37, 37, 38, 38) includes a reinforcing member (25) for the casing (12), a fan casing (13), a short side post (22), and a long side post. The upper opening (27) is surrounded by (21). And each air heat exchanger (37, 37, 38, 38) comprises the heat exchange part, respectively.

    Of the four air heat exchangers (37, 37, 38, 38), two air heat exchangers (37, 37) disposed on one side surface of the long side of the main body (20) of the casing (12) 38) constitute one first heat exchanger main body (35), and two air heat exchangers (37, 38) arranged on the other side surface of the long side of the main body (20) of the casing (12) Constitutes one second heat exchanger body (36). Specifically, in FIG. 2, the first heat exchanger body (35) is disposed on the side surface of the casing (12) on the front side of the body portion (20), and the second heat exchanger body (36). Is disposed on the side surface portion on the back side of the main body portion (20) of the casing (12).

    The first heat exchanger body (35) includes a first air heat exchanger (37) disposed on one end side in the longitudinal direction of the casing (12) and a second air heat exchanger ( 38). The second heat exchanger body (36) includes a first air heat exchanger (37) disposed on one end side in the longitudinal direction of the casing (12) and a second air disposed on the other end side. And a heat exchanger (38). The first air heat exchanger (37) and the second air heat exchanger (38) are configured independently of each other.

    The intersection of the first air heat exchanger (37) of the first heat exchanger body (35) and the first air heat exchanger (37) of the second heat exchanger body (36) on the extension line is a plan view. It is arranged so as to form an acute angle when viewed at. And the outer-end part of the said 1st air heat exchanger (37, 37) which makes an acute angle is arrange | positioned at predetermined intervals. That is, the front wall (23) described above is formed between the outer ends (37a, 37a) of the two first air heat exchangers (37, 37) forming an acute angle, and the front wall (23) is used for maintenance. Auxiliary openings are formed.

    The intersection of the second air heat exchanger (38) of the first heat exchanger body (35) and the second air heat exchanger (38) of the second heat exchanger body (36) is a plane. It is arranged so as to form an acute angle when viewed visually. And the outer-end part of the 2nd air heat exchanger (38,38) which makes the said acute angle is arrange | positioned at predetermined intervals. That is, the back wall (24) described above is formed between the outer ends (38a, 38a) of the two second air heat exchangers (38, 38) having the acute angle, and maintenance is performed on the back wall (24). An auxiliary opening is formed.

    The first air heat exchanger (37) and the second air heat exchanger (38) of the first heat exchanger body (35) are in a central portion of the first heat exchanger body (35) in plan view. Are arranged so as to form an obtuse angle top (39) located outside the casing (12). A long side support (21) on one side of the main body (20) of the casing (12) is erected in the vertical direction at the position where the top (39) is formed. The first air heat exchanger (37) and the second air heat exchanger (38) of the second heat exchanger body (36) are arranged in the center of the second heat exchanger body (36) in plan view. The part is arranged to form an obtuse apex (39) located outside the casing (12). A long side support (21) on the other side of the main body (20) of the casing (12) is erected in the vertical direction at the position where the top (39) is formed.

    In the first heat exchanger body (35), the inner end (37b) of the first air heat exchanger (37) and the inner end of the second air heat exchanger (38) forming the top (39). The part (38b) is disposed so as to be close to each other. Further, in the second heat exchanger body (36), the inner end (37b) of the first air heat exchanger (37) and the inner end of the second air heat exchanger (38) forming the top (39). (38b) are arranged so as to be close to each other.

    That is, the inner end (37b) of the first air heat exchanger (37) and the inner end (38b) of the second air heat exchanger (38) are outer walls formed in a substantially hexagonal shape in plan view. Forming one of the tops (39). The blower fan (17) is provided in a region surrounded by the first heat exchanger body (35) and the second heat exchanger body (36) in a plan view as viewed from the upper side of the casing (12). It has been. In addition, the 1st air heat exchanger (37) comprises the 1st heat exchange part which concerns on this invention, and the 2nd air heat exchanger (38) comprises the 2nd heat exchange part which concerns on this invention.

    The front door (23a) is formed on a removable sheet metal. The front door (23a) extends from the bottom member (60) of the casing (12) to the fan casing (13) in the front opening for maintenance provided on the front wall (23) on the short side of the casing (12). Are provided. Therefore, the operator can remove the front door (23a) and maintain the electrical component box and the like in the casing (12).

    The back door (24a) is formed as a removable sheet metal. The back door (24a) is provided in the back opening for maintenance provided in the back wall (24) on the short side of the casing (12). Therefore, the operator can remove the back door (24a) and maintain the electrical component box (53) and the like in the casing (12).

    The machine room (29) includes a first machine room (30) and a second machine room (31), and the machine room cover (32) includes a first cover (33), a second cover (34), and the like. It consists of

    The first machine room (30) includes the first air heat exchanger (37) of the first heat exchanger body (35) and the first air heat exchanger (37) of the second heat exchanger body (36). It is formed below. In the first machine room (30), two first covers (33) extending along the longitudinal direction of the casing (12) from the two short side struts (22, 22) constituting the front wall (23), respectively. , 33). In the first machine room (30), as shown in FIG. 10, six compressors (50) for compressing the refrigerant are arranged on the compressor mounting plate (68). The two first covers (33) each form a first recess (43).

    The second machine chamber (31) includes a second air heat exchanger (38) of the first heat exchanger body (35) and a second air heat exchanger (38) of the second heat exchanger body (36). It is formed below. The second machine chamber (31) includes a second cover (34, 34) extending from the two short side struts (22, 22) constituting the back wall (24) along the longitudinal direction of the casing (12). Is erected. In the second machine room (31), as shown in FIG. 10, one water heat exchanger (51) for adjusting the temperature of air conditioning water to be temperature-controlled, two expanders, and an electrical component box (53 ) And the like are provided on the heat exchanger mounting plate (69) and the sealing plate (70). One water heat exchanger (51) is connected to two refrigerant circuits. The two second covers (34, 34) each form a second recess (44).

    Of the four recesses (43, 43, 44, 44), two recesses (43, 44) arranged on one side surface of the long side of the casing (12) form one first body recess (41). The two concave portions (43, 44) that are configured and arranged on the other side surface portion of the long side of the casing (12) constitute one second main body concave portion (42). Specifically, the first main body recess (41) is disposed below the first heat exchanger main body (35) of the casing (12) so as to be recessed inward from the side surface of the first heat exchanger main body (35). The first cover (33) and the second cover (34) are formed. The second body recess (42) is disposed below the second heat exchanger body (36) of the casing (12) so as to be recessed inward from the side surface of the second heat exchanger body (36). A first cover (33) and a second cover (34) are formed.

    The first main body recess (41) includes a first recess (43) disposed on one end side in the longitudinal direction of the casing (12) and a second recess (44) disposed on the other end side. . The second main body recess (42) is similarly formed by a first recess (43) disposed on one end side in the longitudinal direction of the casing (12) and a second recess (44) disposed on the other end side. It is configured.

    The first recess (43) on one side surface of the casing (12) is located below the first air heat exchanger (37) of the first heat exchanger body (35), and the first air heat exchanger (37). It is formed by the 1st cover (33) arrange | positioned inside. The first recess (43) on the other side surface of the casing (12) is located below the first air heat exchanger (37) of the second heat exchanger body (36). It is formed by the 1st cover (33) arrange | positioned inside 37). Each first recess (43, 43) forms a space through which air flows.

    The second recess (44) on one side surface of the casing (12) is located below the second air heat exchanger (38) of the first heat exchanger body (35), and the second air heat exchanger (38). It is formed by the 2nd cover (34) arrange | positioned inside. The second recess (44) on the other side surface of the casing (12) is located below the second air heat exchanger (38) of the second heat exchanger body (36), and the second air heat exchanger (38). It is formed by the 2nd cover (34) arrange | positioned inside. Each second recess (44, 44) forms a space through which air flows.

    The space formed by the first recess (43) and the space formed by the second recess (44) communicate with each other through a central passage (45) described later.

    The compressor (50), the water heat exchanger (51), the four-way selector valve (not shown), the expander, and each of the air heat exchangers (37, 37, 38, 38) have a vapor compression refrigerant circuit. It is composed. The refrigerant circuit includes a first refrigerant circuit and a second refrigerant circuit, and is configured to be able to operate independently. That is, each refrigerant circuit can cool or heat the air conditioning water by reversibly circulating the refrigerant by switching a four-way switching valve (not shown).

    The first refrigerant circuit includes three compressors (50), a water heat exchanger (51), a four-way switching valve (not shown), an expander, and two first air heat exchangers (37, 37). I have. The second refrigerant circuit includes three compressors (50), a water heat exchanger (51), a four-way switching valve (not shown), an expander, and two second air heat exchangers (38, 38). ing. That is, in the chiller device (10) according to the present embodiment, the first refrigerant circuit and the second refrigerant circuit are operated separately, whereby the two first air heat exchangers (37, 37) and the two second refrigerant circuits are operated. The air heat exchangers (38, 38) can be operated independently of each other.

    In addition, what is provided in the machine room (29) is not limited to the compressor (50), the water heat exchanger (51), the expander, and the electrical component box (53). The electrical component box (53) accommodates an electric circuit board, wiring, etc. of an inverter circuit for controlling the operation of the chiller device (10).

    The central passage (45) is an air passage formed between the outer wall of the casing (12) constituted by the machine room cover (32) and the long side strut (21), and the air communication according to the present invention. Part. The central passage (45) allows the space formed by the first recess (43) and the space formed by the second recess (44) to communicate with each other and allow the air in both spaces to pass back and forth. The central passage (45) supplies the air flowing through the first recess (43) to the space formed by the second recess (44), while the air flowing through the second recess (44) is supplied by the first recess (43). The space to be formed can be supplied.

-Air flow in one outdoor unit-
Next, the air flow of the outdoor unit (11) of one heat pump chiller will be described. As shown in FIGS. 14 and 15, the air outside (around) the outdoor unit (11) is exposed to the first heat exchanger body (35) and the second heat exchanger body ( It flows from the outside of 36), passes through the first air heat exchanger (37) and the second air heat exchanger (38), and is taken into the casing (12) (see arrows in FIGS. 14 and 15).

    Moreover, the air which flows through a 1st recessed part (43) among air outside the casing (12) flows upwards there, and is guide | induced to the outer side of a 1st air heat exchanger (37) from the lower side. Thereafter, when passing through the first air heat exchanger (37, 37) of each heat exchanger body (35, 36), heat is exchanged with the refrigerant and taken into the casing (12). Part of the air flowing through the first recess (43) passes through the central passage (45) and is supplied to the second recess (44).

    Moreover, the air which flows through a 2nd recessed part (44) among air outside the casing (12) flows upwards there, and is guide | induced to the outer side of a 2nd air heat exchanger (38) from the lower side. After that, when passing through the second air heat exchanger (38, 38) of each heat exchanger body (35, 36), heat is exchanged with the refrigerant and taken into the casing (12). Part of the air flowing through the second recess (44) passes through the central passage (45) and is supplied to the space formed by the first recess (43).

    As described above, the space formed by the first recess (43) and the space formed by the second recess (44) communicate with each other via the central passage (45), and thus flow through both spaces. Air can go back and forth between each other. For this reason, the flow rate of the air flowing through the central passage (45) increases.

-Driving action-
Next, the driving operation of this embodiment will be described.

    First, when the chiller device (10) operates the blower fan (17), air outside the casing (12) is transferred from the first heat exchanger body (35) and the second heat exchanger body (36) to the casing (12 ). As shown in FIGS. 16 and 17, when the outdoor units (11) of three heat pump chillers are arranged side by side in the width direction, the air outside the casing (12) is mainly in the longitudinal direction of the casing (12). The first air heat exchanger (37) and the second air heat exchanger (38) flow outside the first heat exchanger body (35) and the second heat exchanger body (36) through the gaps formed at both ends. ) Into the casing (12).

    Moreover, the air outside the casing (12) flows into the first recess (43, 43) from the gap at one end in the longitudinal direction of the casing (12). The air flowing through the first recess (43) flows upward, is guided to the outside of the first air heat exchanger (37), passes through the first air heat exchanger (37), and enters the casing (12). Flows in. And this air is heat-exchanged when passing a 1st air heat exchanger (37). Part of the air flowing through the first recess (43) passes through the central passage (45) and flows toward the second recess (44).

    Moreover, the air outside the casing (12) flows into the second recess (44, 44) from the gap at the other end in the longitudinal direction of the casing (12). The air flowing through the second recess (44) flows upward, is guided to the outside of the second air heat exchanger (38), passes through the second air heat exchanger (38), and passes through the interior of the casing (12). Flow into. This air is heat-exchanged when passing through the second air heat exchanger (38, 38). Part of the air flowing through the second recess (44) passes through the central passage (45) and flows toward the first recess (43).

    As described above, the space formed by the first recess (43) and the space formed by the second recess (44) communicate with each other via the central passage (45), and thus flow through both spaces. Air can go back and forth between each other. For this reason, the flow rate of the air flowing through the central passage (45) increases.

    And the air taken in in the casing (12) through each air heat exchanger (37, 37, 38, 38) passes through the blower outlet (14) by the upper blower fan (17), and the casing It blows out above (12).

    Next, the operation of the refrigerant circuit when air conditioning water in the water heat exchanger (51) is used for cooling will be described.

    First, in the first refrigerant circuit, the operation of the compressor (50) is started, and the refrigerant is compressed by the compressor (50). The compressed refrigerant discharged from the compressor (50) flows into the first air heat exchanger (37, 37). In the first heat exchanger body (35) and the second heat exchanger body (36), the external air of the casing (12) is the first air heat exchanger (37, 37) constituting each heat exchanger body (35, 36). , 37), the heat of the refrigerant is radiated to the air to heat the air taken into the casing (12). And the refrigerant | coolant which thermally radiated and cooled to air expand | swells with an expansion valve, Then, it flows in into a water heat exchanger (51). In the water heat exchanger (51), the refrigerant absorbs heat from the air conditioning water flowing in the water heat exchanger (51) to cool the air conditioning water. The cooled water for air conditioning is supplied into the building. The refrigerant that has flowed out of the water heat exchanger (51) is again sucked into the compressor (50) and compressed.

    In the second refrigerant circuit, the operation of the compressor (50) is started, and the refrigerant is compressed by the compressor (50). The compressed refrigerant discharged from the compressor (50) flows into the second air heat exchanger (38, 38). In the first heat exchanger body (35) and the second heat exchanger body (36), the second air heat exchanger (38) in which the external air of the casing (12) constitutes each heat exchanger body (35, 36). , 38), the heat of the refrigerant is radiated to the air to heat the air taken into the casing (12). And the refrigerant | coolant which thermally radiated and cooled to air expand | swells with an expansion valve, Then, it flows in into a water heat exchanger (51). In the water heat exchanger (51), the refrigerant absorbs heat from the air conditioning water flowing in the water heat exchanger (51) to cool the air conditioning water. The cooled water for air conditioning is supplied into the building. The refrigerant that has flowed out of the water heat exchanger (51) is again sucked into the compressor (50) and compressed.

    The operation of the refrigerant circuit in the case where the water for air conditioning in the water heat exchanger (51) is used for heating will be described.

    In the first refrigerant circuit, the operation of the compressor (50) is started, and the refrigerant is compressed by the compressor (50). The compressed refrigerant discharged from the compressor (50) flows into the water heat exchanger (51). In the water heat exchanger (51), the refrigerant dissipates heat to the air conditioning water flowing in the water heat exchanger (51) to heat the air conditioning water. The heated water for air conditioning is supplied into the building. The refrigerant flowing out of the water heat exchanger (51) is expanded by the expansion valve, and then flows into the first air heat exchanger (37, 37). In the first heat exchanger body (35) and the second heat exchanger body (36), the external air of the casing (12) is the first air heat exchanger (37, 37) constituting each heat exchanger body (35, 36). , 37), the refrigerant absorbs heat from the air and cools the air taken into the casing (12). The refrigerant flowing out of the first air heat exchanger (37, 37) is again sucked into the compressor (50) and compressed.

    In the second refrigerant circuit, the operation of the compressor (50) is started, and the refrigerant is compressed by the compressor (50). The compressed refrigerant discharged from the compressor (50) flows into the water heat exchanger (51). In the water heat exchanger (51), the refrigerant dissipates heat to the air conditioning water flowing in the water heat exchanger (51) to heat the air conditioning water. The heated water for air conditioning is supplied into the building. The refrigerant flowing out of the water heat exchanger (51) is expanded by the expansion valve and then flows into the second air heat exchanger (38, 38). In the first heat exchanger body (35) and the second heat exchanger body (36), the second air heat exchanger (38) in which the external air of the casing (12) constitutes each heat exchanger body (35, 36). , 38), the refrigerant absorbs heat from the air and cools the air taken into the casing (12). The refrigerant that has flowed out of the second air heat exchanger (38, 38) is again sucked into the compressor (50) and compressed.

    Next, maintenance of the chiller device (10) by an operator will be described.

    When an operator performs maintenance work, the chiller device (10) is stopped, the machine room cover (32) is removed, and the first machine room (30) and the second machine room (31) are removed from the lower opening (28). ) Maintain the compressor (50). Further, the front door (23a) or the rear door (24a) can be removed, and maintenance of the electrical component box (53) and the like can be performed from the front side or the back side of the casing (12) of the outdoor unit (11).

-Single system operation-
As shown in FIG. 18, the outdoor unit (11) according to the present embodiment can be operated with only one system according to the load. Specifically, the operation can be performed only by the first refrigerant circuit. When operating with only one system, the blower fans (17, 17) corresponding to the second refrigerant circuit are stopped.

    First, the air outside the casing (12) is mainly drawn from the gap formed at one end portion in the longitudinal direction of the casing (12) in the first heat exchanger body (35) and the second heat exchanger body (36). It flows outside and is taken into the casing (12) from the first air heat exchanger (37, 37).

    Moreover, the air outside the casing (12) flows into the first recess (43, 43) from the gap at one end in the longitudinal direction of the casing (12). The air flowing through the space of the first recess (43) flows upward, is guided to the outside of the first air heat exchanger (37), passes through the first air heat exchanger (37), and flows into the casing (12). Flows into the interior. And this air is heat-exchanged when passing a 1st air heat exchanger (37).

    Moreover, the air outside the casing (12) flows into the second recess (44, 44) from the gap at the other end in the longitudinal direction of the casing (12). As described above, the space formed by the first recess (43) and the space formed by the second recess (44) communicate with each other via the central passage (45). For this reason, the air flowing through the space of the second recess (44) passes through the central passage (45) and is supplied to the first recess (43) side. Therefore, the air flowing through the first recess (43) increases.

    And the air taken in in the casing (12) through the first air heat exchanger (37, 37) passes through the outlet (14) by the upper blower fan (17), and the casing (12) Is blown out above.

-Effect of the embodiment-
According to the embodiment, since the first main body concave portion (41) and the second main body concave portion (42) are provided, in addition to the air flowing outside the first and second heat exchanger main bodies (35, 36), the air It can guide to the outside of the 1st heat exchanger body (35) and the 2nd heat exchanger body (36) from the lower part. For this reason, the flow volume of the air which passes a 1st air heat exchanger (37) and a 2nd air heat exchanger (38) can be increased (refer FIG. 20). Thereby, the heat exchange efficiency of a 1st air heat exchanger (37) and a 2nd air heat exchanger (38) can be improved. As a result, the heat exchange efficiency can be improved in the outdoor unit (11) having the air heat exchangers (37, 37, 38, 38) arranged in a substantially hexagonal shape in plan view.

    In addition, since the central passage (45) is provided to communicate the space formed by the first recess (43) and the space formed by the second recess (44), the space of the first recess (43) is reduced. While the flowing air is supplied to the second recess (44) side, the air flowing through the space of the second recess (44) can be supplied to the first recess (43) side. Thereby, the flow rate of air in both spaces of the first recess (43) and the second recess (44) can be increased. That is, since the lower part of the conventional 1st heat exchanger main body and the 2nd heat exchanger main body becomes far from a ventilation fan, the flow of air worsens (refer FIG. 19). However, in the present embodiment, the flow rate of air flowing through both the first recess (43) and the second recess (44) can be increased by the central passage (45), so the first heat exchanger body (35). And the air flow rate below the second heat exchanger body (36) can be increased (see FIG. 20). Thereby, the heat exchange efficiency of a 1st air heat exchanger (37) and a 2nd air heat exchanger (38) can be improved. As a result, the heat exchange efficiency can be improved in the outdoor unit (11) having the air heat exchangers (37, 37, 38, 38) arranged in a substantially hexagonal shape in plan view.

    Further, since the machine chamber (29) is provided inside the first main body recess (41) and the second main body recess (42), the first main body recess (41) and the second main body recess (42) to the machine chamber (29). It is possible to maintain the internal components.

    Further, a reinforcing member (25) configured to allow drain water to flow is provided along the first heat exchanger body (35) or the second heat exchanger body (36), and the first heat exchanger body from below. (35) or the second heat exchanger body (36) is supported so that the first heat exchanger body (35) or the second heat exchanger body (36) can be reinforced and at the same time the first heat The drain water generated from the exchanger main body (35) or the second heat exchanger main body (36) can be flowed to the reinforcing member (25).

    Finally, since the first air heat exchanger (37) and the second air heat exchanger (38) operate independently of each other, only the first air heat exchanger (37) operates. The air supplied from the second recess (44) to the first recess (43) can be guided to the first air heat exchanger (37). For this reason, the flow rate of the air flowing through the operating first air heat exchanger (37) can be increased. Further, when only the second air heat exchanger (38) operates, the air supplied from the first recess (43) to the second recess (44) is led to the second air heat exchanger (38). Can do. For this reason, the flow rate of the air flowing through the operating second air heat exchanger (38) can be increased.

-Modification of the embodiment-
Next, a modification of this embodiment will be described. The chiller device (10) according to the present modification is different from the chiller device (10) according to the embodiment in the configuration of the bottom member (60). Note that in this modification, only parts different from the above embodiment will be described.

    Specifically, in this modification, as shown in FIG. 21, the main body frame (63) of the second bottom frame (62) is provided with an outlet pipe of the water pipe of the water heat exchanger (51). While the pedestal (72) is provided, the pump pedestal is not provided. Other configurations, operations and effects are the same as those in the embodiment.

<Other embodiments>
The present invention may be configured as follows with respect to the above embodiment.

    A plurality of outdoor units (11) according to the above embodiment may be connected and installed, or one outdoor unit (11) may be installed near the wall.

    In the above embodiment, the machine room cover (32) is provided to form the body recesses (41, 42) to form the machine room (29), but the present invention is not limited to this. Specifically, without providing a machine room cover (32), six compressors (50), a water heat exchanger (51), an expander, an electrical component box (53), etc. are arranged in the air passage. It may be. That is, in this embodiment, six compressors (50), a water heat exchanger (51), an expander, and an electrical component box (53), which are components of the outdoor unit (11), are arranged in the air passage. Yes.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a refrigeration apparatus having a heat exchanger.

DESCRIPTION OF SYMBOLS 10 Chiller apparatus 11 Outdoor unit 12 Casing 17 Blower fan 25 Reinforcement material (reinforcement member)
29 Machine room 35 1st heat exchanger main body 36 2nd heat exchanger main body 37 1st air heat exchanger (1st heat exchange part)
38 Second Air Heat Exchanger (Second Heat Exchanger)
39 Top 41 First body recess 42 Second body recess 43 First recess 44 Second recess 1 Central passage (air communication part)

Claims (7)

A casing (12) and a heat exchanger body (35, 36) disposed on a side surface of the casing (12) and extending along the side surface and exposed to the outside of the casing (12), The exchanger main body (35, 36) has a top portion (39) whose central portion is located outside the casing (12) in a plan view, and the casing (35, 36) is formed from the outside of the heat exchanger main body (35, 36). 12) an outdoor unit configured to allow air to flow into the interior,
A blower fan (17) that is disposed above the casing (12) and blows out the air in the casing (12) to the outside;
A body recess (41, 42) formed below the heat exchanger body (35, 36) of the casing (12) and recessed inward from the side surface of the heat exchanger body (35, 36); An outdoor unit characterized by that. In claim 1,
The heat exchanger body (35, 36) is disposed on both side surfaces of the casing (12), and extends along both side surfaces of the casing (12), and the first heat exchanger body (35) and the second heat exchange. An obtuse top (39) having a central portion located outside the casing (12) in a plan view of the first heat exchanger main body (35) and the second heat exchanger main body (36). A linear first heat exchange part (37) and a second heat exchange part (38) extending in the outer direction of the casing (12) so as to form
The body recess (41, 42) is formed below the first heat exchanger body (35) and the second heat exchanger body (36) of the casing (12), and the first heat exchanger body. (35) and the 1st main body recessed part (41) and the 2nd main body recessed part (42) which were dented inward rather than the side surface of the 2nd heat exchanger main body (36), The outdoor unit characterized by the above-mentioned. In claim 2,
The first main body recess (41) and the second main body recess (42) are respectively located below the first heat exchange part (37) and the second heat exchange part (38), and the first heat exchange part ( 37) and a first recess (43) and a second recess (44) recessed inward from the side surfaces of the second heat exchange part (38),
An outdoor unit comprising an air communication part (45) for communicating a space formed by the first recess (43) and a space formed by the second recess (44). In claim 2 or 3,
The said casing (12) is provided with the machine room (29) by which a component apparatus is arrange | positioned inside the said 1st main body recessed part (41) and the said 2nd main body recessed part (42), The outdoor unit characterized by the above-mentioned. In any one of Claims 2-4,
The casing (12) extends along the first heat exchanger body (35) or the second heat exchanger body (36), and the heat exchange portions (37, 37, 38, 38) are arranged from below. An outdoor unit comprising a reinforcing member (25) configured to support and to allow drain water of each of the heat exchange units (37, 37, 38, 38) to flow. In any one of Claims 2-5,
The outdoor unit, wherein the first heat exchange unit (37) and the second heat exchange unit (38) are connected to different refrigerant circuits and are operable independently. A refrigerating apparatus comprising the outdoor unit (11) according to any one of claims 1 to 6.

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