JP5776639B2 - Air curtain device for cooling room - Google Patents

Description

    The present invention relates to an air curtain device for a cooling chamber that is provided at the entrance and exit of a cooling chamber such as a freezer or a refrigerator and forms an air flow for blocking the entrance and exit of air.

    2. Description of the Related Art Conventionally, an air curtain device is provided at an entrance / exit of a cooling chamber having a large temperature difference from the outside, such as a freezer or a refrigerator (for example, see Patent Document 1 below).

    For example, the air curtain device disclosed in Patent Document 1 includes a pair of air blowers in which a fan is housed in a casing in which an air outlet and a suction port are formed. The pair of air blowers are arranged so that the air outlets and the air inlets face each other. In the air curtain device, by driving each fan, an air flow is formed between the blower devices from the air outlet toward the suction port facing the air curtain device. That is, two airflows that face each other in the horizontal direction are formed between the two blowers. And these two air flows became a barrier, and the entrance / exit of the air in the entrance / exit in which an air curtain apparatus is provided was interrupted | blocked.

JP 2008-215724 A

    By the way, in the said air curtain apparatus, it is supposed that a rectification | straightening grid will be provided in the blower outlet of both air blowers, and blowing air will be blown out straight toward the inlet of other air blowers. However, the air blown out straight toward the suction port of the other blower device decreases in wind speed toward the downstream side and swells in the depth direction. For this reason, a part of the blown air leaks indoors and outdoors on the downstream side, and there is a possibility that the circulating air volume between the pair of air blowers is reduced, so that the entrance and exit of the air at the entrance and exit of the cooling chamber cannot be reliably blocked.

    This invention is made | formed in view of this point, The objective is to interrupt | block the entrance / exit of the air in the entrance / exit of a cooling chamber reliably in the air curtain apparatus for cooling chambers.

The first invention includes a casing (21, 31) in which an air inlet (24, 34) and an outlet (25, 35) are vertically formed on one side surface, and the inside of the casing (21, 31). Is accommodated between the inlet (24,34) and the outlet (25,35), and the inlet (24,34) is inserted into the casing (21,31) from the outlet (25,35). ) With a pair of blowers (20, 30) each having a blower fan (22, 32) that forms an internal air flow (f1, f2) toward the air), the pair of blowers (20, 30) being cooled The inlet port (24, 34) and the outlet port (35, 25) of the chamber (1) are provided at one end and the other end in the width direction of the inlet / outlet (2) so as to face each other. The external air flow (F1, F2) from the air outlets (25, 35) toward the suction ports (34, 24) facing the ventilation space (10a) between the air outlets (25, 35) by the internal air flow (f1, f2) Air curtain device for cooling chamber formed In each of the air outlets (25, 35), a large number of ventilation holes are formed so as to pass through in the thickness direction, and the central portion in the depth direction is formed in the casing (21, 31) Perforated plates (25a, 35a) formed in a V-shape that are recessed inside are provided, and the blower fans (22, 32) are accommodated one by one in the casings (21, 31). In the casing (21) formed above the air inlet (24), the air outlet (25) is arranged to blow air upward, while the air outlet (35) is connected to the air inlet ( 34) It is arranged so that air is blown downward in the casing (31) formed on the lower side of the casing (31), and each of the blowers (20, 30) has a flow rate of the external air flow (F1, F2). From the central part in the vertical direction of the ventilation space (10a) to increase upward and downward respectively. A plurality of flow dividing plates (51, 52, 61, 62) for dividing each of the internal air flows (f1, f2) into a plurality of flows having different flow velocities, and the plurality of flow dividing plates (51, 52, 61). 62) is formed in a flat plate shape, and is provided at least between each of the blower fans (22, 32) and the blower outlet (25, 35), and crosses each of the internal air flows (f1, f2). The plurality of flow dividing plates (51, 52, 61, 62) arranged between the blower fans (22, 32) and the air outlets (25, 35) The ratio of the channel cross-sectional area of the outlet to the channel cross-sectional area of the inlets of the plurality of channels partitioned between each other is such that the channels away from the respective outlets (25, 35) become smaller. They are arranged at angles and intervals .

    In 1st invention, when the ventilation fan (22,32) of each air blower (20,30) is driven, in a casing (21,31) of each air blower (20,30), a suction inlet (24,34) An internal air flow (f1, f2) from the air outlet to the air outlet (25, 35) is formed, and the air outlet (25, 35) is formed in the ventilation space (10a) between the air blowers (20, 30). An external air flow (F1, F2) from one side to the other suction port (34, 24) is formed. Here, each of the air outlets (25, 35) is formed with a large number of ventilation holes penetrating in the thickness direction, and the central portion in the depth direction of the casing (21, 31) compared to both ends. Perforated plates (25a, 35a) formed in a V shape that are recessed on the inner side are provided. By blowing air from such a perforated plate (25a, 35a), the external air flow (F1, F2) is blown from the blower outlet (25, 35) and once narrows in the depth direction toward the downstream side. To go. Therefore, even if the external air flow (F1, F2) swells in the depth direction on the downstream side, the amount of bulge in the depth direction is less than when the porous plate (25a, 35a) is formed in a flat shape. . As a result, the external air flow (F1, F2) is sucked into the corresponding blower (20, 30) without leaking into and out of the room.

    In a second aspect based on the first aspect, the perforated plate (25a) provided at the air outlet (25) formed above the inlet (24) is divided into a plurality of parts in the vertical direction. At the same time, the perforated plate (35a) provided at the outlet (35) formed on the lower side of the suction port (34) is divided into a plurality of parts in the vertical direction. In addition, the lower divided piece is inclined toward the indoor side.

    By the way, the pressure difference between the warm air on the outdoor side and the cool air on the indoor side becomes equal at the center in the vertical direction of the ventilation space (10a), while the pressure of warm air increases at the upper layer of the ventilation space (10a). The pressure difference between the cool air and the cool air becomes large, and in the lower layer portion of the ventilation space (10a), the pressure of the cool air becomes high and the pressure difference between the warm air and the cool air becomes large. Due to the pressure difference between the warm air and the cold air, in the ventilation space (10a), the wind speed of the cross wind due to the warm air increases as it goes upward from the central portion in the vertical direction, and the cold air flows toward the downward direction from the central portion in the vertical direction. The wind speed of the crosswind due to increases. Therefore, in the upper part from the center in the vertical direction of the ventilation space (10a), the course of the external air flow (F1) tends to tilt indoors due to the crosswind caused by warm air as it goes upward, and the vertical direction of the ventilation space (10a) In the lower part from the center, the course of the external air flow (F2) is more easily inclined to the outdoor side due to the crosswind caused by cold air as it goes downward.

    Here, in the air curtain device for the cooling chamber, the internal air flow (f1, f2) in each casing (21, 31) and the two external air flows (F1) that flow in the airflow space (10a) facing each other in the horizontal direction. , F2) circulates air between the pair of blowers (20, 30). For this reason, when the course of the external air flow (F1, F2) is greatly inclined by the crosswind due to warm air and cold air, a part of the air circulating between the pair of blowers (20, 30) leaks out of the room while There is a possibility that indoor and outdoor air is mixed into the air circulating between the blower devices (20, 30), and the shut-off efficiency of cool air and warm air is lowered.

    On the other hand, in the second invention, the perforated plate (25a) provided at the upper outlet (25) of the suction port (24) is divided into a plurality of parts in the vertical direction, and the upper divided piece is moved to the outdoor side. The perforated plate (35a) provided at the lower outlet (35) at the lower side of the suction port (34) is divided into a plurality of parts in the vertical direction, and the lower divided piece is inclined toward the indoor side. Thereby, in the upper part from the center in the up-down direction of the ventilation space (10a), the blowing direction of the air blown into the ventilation space (10a) is inclined to the outdoor side as it goes upward. In other words, in the upper part from the center in the vertical direction of the ventilation space (10a), the wind speed of the side wind due to warm air increases as it goes upward, and the course of the external air flow (F1) tends to tilt indoors. The direction on the upstream side of the external air flow (F1) is inclined toward the outdoor side as it goes. As a result, the external air flow (F1) is sucked into the corresponding blower (30) without leaking into the room. On the other hand, in the portion below the center in the up-down direction of the ventilation space (10a), the blowing direction of the air blown into the ventilation space (10a) is inclined toward the indoor side at a larger angle as it goes downward. In other words, in the lower part of the ventilation space (10a) from the center in the vertical direction, the speed of the side wind by the cold air becomes faster and the course of the external air flow (F2) tends to be inclined to the outside of the room. The direction on the upstream side of the external air flow (F2) is inclined toward the indoor side as it goes. Therefore, the external air flow (F2) is sucked into the corresponding blower (20) without leaking outside. That is, in the second invention, a pair of air blowers is provided by inclining the blowing direction of air to the ventilation space (10a) in the upstream direction of the cross wind according to the wind speed distribution in the vertical direction of the cross wind caused by the warm air and the cool air. Leakage of air circulating between (20, 30) to the outside of the room is suppressed.

In the first invention , in addition to the above- described configuration, each of the air blowers (20, 30) is configured so that the air volume of the external air flow (F1, F2) is higher than the vertical center of the ventilation space (10a) and It has a plurality of flow dividing plates (51, 52, 61, 62) that divide each internal air flow (f1, f2) into a plurality of flows with different flow velocities so as to increase stepwise downward. Yes.

    By the way, as described above, in the ventilation space (10a), pressure distribution is generated in the vertical direction due to the temperature difference between the inside and outside of the room, and a large amount of warm air passes through the upper layer portion of the ventilation space (10a), and a large amount of air flows in the lower layer portion. While cold air passes, the middle layer has less air in and out than the upper and lower layers. Therefore, if the external air flow (F1, F2) is formed so that the velocity distribution is uniform in the entire area of the ventilation space (10a), the air flow is reliably ensured in the upper and lower layers of the ventilation space (10a). The rotation speed of the blower fan (22, 32) must be set to be relatively high in order to secure an air volume that can block entry and exit. On the other hand, if the rotational speed of the blower fan (22, 32) is increased so that the air volume is suitable for the upper layer and lower layer of the ventilation space (10a), the air volume becomes larger than necessary in the middle layer, and the fan power It becomes useless and efficiency decreases.

Therefore, in the first invention, each internal air flow is such that the air volume of the external air flow (F1, F2) increases stepwise from the vertical center of the ventilation space (10a) upward and downward. A plurality of flow dividing plates (51, 61) for dividing (f1, f2) into a plurality of flows having different flow velocities are provided. As a result, in the ventilation space (10a), in the upper layer where a large amount of warm air passes and the lower layer where a large amount of cold air passes, the air volume of the external air flow (F1, F2) that blocks the flow of air increases, In the middle layer where there is little air flow, the air volume of the external air flow (F1, F2) that blocks air flow is small.

In the first invention , in addition to the above configuration, the plurality of flow dividing plates (51, 52, 61, 62) are each formed in a flat plate shape in a direction crossing the internal air flows (f1, f2). Arranged at intervals.

In the first invention, each internal air flow (51, 52, 61, 62) is provided by a plurality of plate-like flow dividing plates (51, 52, 61, 62) arranged at intervals in a direction crossing each internal air flow (f1, f2). f1, f2) are distributed to multiple flows with different flow velocities.

According to a third invention, in the first or second invention, a rail member (58) extending in the arrangement direction of the plurality of flow dividing plates (51, 52, 61, 62) and each of the flow dividing plates (51, 52, 61, 62) and mounting members (56, 57) that are slidably attached to the rail members (58) and are rotatable around a rotation axis orthogonal to the rail members (58). A support mechanism (55) for supporting the flow dividing plates (51, 52, 61, 62) is provided.

In the third invention, the plurality of flow dividing plates (51, 52, 61, 62) are supported by the support mechanism (55) having the rail member (58) and the attachment member (56, 57). Further, when each of the flow dividing plates (51, 52, 61, 62) is rotated around the rotation axis orthogonal to the rail member (58), the angle of each flow dividing plate (51, 52, 61, 62) changes, When each of the flow dividing plates (51, 52, 61, 62) is slid in the longitudinal direction of the rail member (58), the distance between the adjacent flow dividing plates (51, 52, 61, 62) changes. That is, the plurality of flow dividing plates (51, 52, 61, 62) are supported by the support mechanism (55) so that the angle and the interval between them can be changed.

According to a fourth invention, in any one of the first to third inventions, each of the blower fans (22, 32) is provided so as to blow out air in parallel to the outlet ( 25, 35 ). The plurality of flow dividing plates (51, 61) are provided at least between the blower fans (22, 32) and the blower outlets (25, 35), and are blown out of the blower fans (22, 32). Between the plurality of flow-dividing plates (51, 61) on the side, the air blown from the blower fan (22, 32) is rectified so as to approach the outlet (25, 35) toward the downstream side. There are provided rectifying members (27, 37) each having an air passage.

In the fourth invention, the blown air from each of the blower fans (22, 32) is rectified by the rectifying member (27, 37) before being diverted by the plurality of diverting plates (51, 61), and also on the downstream side. The flow direction is changed so as to approach the outlet (25, 35). In other words, the blown air from the blower fan (22, 32) is circulated in two stages by the rectifying member (27, 37) and the respective flow dividing plates (51, 61) until it reaches the outlet (25, 35). The direction is changed.

According to a fifth invention, in the fourth invention, each of the rectifying members (27, 37) has a length of the plurality of air passages such that the ventilation space (in the width direction of each casing (21, 31)) The air passage on the side 10a) is formed to be shorter.

In the fifth aspect of the present invention, each of the rectifying members (27, 37) is formed such that the passage length of a large number of air passages becomes shorter as the air passage on the ventilation space (10a) side in the width direction. Therefore, the degree of the rectifying effect by the respective rectifying members (27, 37) becomes lower toward the ventilation space (10a) side in the width direction in which the distance to the air outlet (25, 35) becomes shorter.

According to a sixth aspect of the present invention, there is provided a casing (21, 31) in which an air inlet (24, 34) and an outlet (25, 35) are vertically formed on one side surface, and the inside of the casing (21, 31). Is accommodated between the inlet (24,34) and the outlet (25,35), and the inlet (24,34) is inserted into the casing (21,31) from the outlet (25,35). ) With a pair of blowers (20, 30) each having a blower fan (22, 32) that forms an internal air flow (f1, f2) toward the air), the pair of blowers (20, 30) being cooled The inlet port (24, 34) and the outlet port (35, 25) of the chamber (1) are provided at one end and the other end in the width direction of the inlet / outlet (2) so as to face each other. The external air flow (F1, F2) from the air outlets (25, 35) toward the suction ports (34, 24) facing the ventilation space (10a) between the air outlets (25, 35) by the internal air flow (f1, f2) Air curtain device for cooling chamber formed In each of the air outlets (25, 35), a large number of ventilation holes are formed so as to pass through in the thickness direction, and the central portion in the depth direction is formed in the casing (21, 31) V-shaped perforated plates (25a, 35a) that are recessed on the inner side are provided, and the air blowers (20, 30) have the above-mentioned external air flow (F1, F2) air volume as described above. A plurality of diversions that divide each internal air flow (f1, f2) into a plurality of flows having different flow velocities so as to increase stepwise from the vertical center of the ventilation space (10a). The plate (51, 52, 61, 62) has a plurality of flow dividing plates (51, 52, 61, 62) that are each formed in a flat plate shape and traverse each internal air flow (f1, f2). Rail members (58) arranged at intervals in the direction and extending in the arrangement direction of the plurality of flow dividing plates (51, 52, 61, 62), and the flow dividing plates (51, 52, 61, 62) A mounting member (56, 57) that is slidable with respect to the rail member (58) and is rotatable about a rotation axis orthogonal to the rail member (58). 52, 61, 62) is provided with a support mechanism (55).

According to a seventh aspect of the present invention, there is provided a casing (21, 31) in which an air inlet (24, 34) and an outlet (25, 35) are vertically formed on one side surface, and the inside of the casing (21, 31). Is accommodated between the inlet (24,34) and the outlet (25,35), and the inlet (24,34) is inserted into the casing (21,31) from the outlet (25,35). ) With a pair of blowers (20, 30) each having a blower fan (22, 32) that forms an internal air flow (f1, f2) toward the air), the pair of blowers (20, 30) being cooled The inlet port (24, 34) and the outlet port (35, 25) of the chamber (1) are provided at one end and the other end in the width direction of the inlet / outlet (2) so as to face each other. The external air flow (F1, F2) from the air outlets (25, 35) toward the suction ports (34, 24) facing the ventilation space (10a) between the air outlets (25, 35) by the internal air flow (f1, f2) Air curtain device for cooling chamber formed Because
Each of the air outlets (25, 35) is formed with a large number of ventilation holes penetrating in the thickness direction, and the center portion in the depth direction is the interior of the casing (21, 31) as compared to both ends. A perforated plate (25a, 35a) formed in a V-shape recessed on the side is provided, and each of the air blowers (20, 30) has an air volume of the external air flow (F1, F2) in the ventilation space (10a ) In the vertical direction from the center in the up and down direction, each of the internal air flows (f1, f2) is divided into a plurality of flow plates (51, 52, 61, 62), and the plurality of flow dividing plates (51, 52, 61, 62) are each formed in a flat plate shape, and are spaced in a direction crossing the internal air flows (f1, f2). The air blowing fans (22, 32) are arranged so as to blow air in parallel with the air outlets (25, 35), The flow plates (51, 61) are provided at least between the air blowing fans (22, 32) and the air outlets (25, 35), and are on the air blowing side of the air blowing fans (22, 32). Between the plurality of flow dividing plates (51, 61), there are a number of air passages that rectify the blown air of the blower fan (22, 32) so as to approach the outlet (25, 35) toward the downstream side. The flow regulating member (27, 37) is provided.

According to the first , sixth , and seventh inventions, the perforated plates (25a, 35a) provided in the respective outlets (25, 35) are formed in the casing (21, 31) in the central portion in the depth direction compared to both end portions. It was decided to form in the V shape which is dented inside. Thereby, each external air flow (F1, F2) is blown out from each blower outlet (25, 35), and once narrows in the depth direction toward the downstream side. Therefore, even if each external air flow (F1, F2) swells in the depth direction on the downstream side, the amount of bulge in the depth direction should be reduced compared to the case where the blow grill (25a, 35a) is formed flat. Can do. As a result, the external air flow (F1, F2) is sucked into the corresponding blower (30, 20) without leaking. Therefore, the leakage of the external air flow (F1, F2) to the outside of the room can be suppressed, and the reduction of the air circulation air volume between the pair of air blowers (20, 30) can be suppressed. Therefore, the entrance and exit of air at the inlet / outlet (2) of the cooling chamber (1) can be reliably blocked.

    Further, according to the second invention, the perforated plate (25a) provided at the air outlet (25) on the upper side of the suction port (24) is divided into a plurality of parts in the vertical direction, and the upper divided piece toward the outdoor side. The perforated plate (35a) provided at the lower outlet (35) at the lower side of the suction port (34) is divided into a plurality of parts in the vertical direction, and the lower divided piece is inclined toward the indoor side. Thereby, the blowing direction of the air to the ventilation space (10a) can be inclined in the upstream direction of the cross wind according to the wind speed distribution in the vertical direction of the cross wind due to the warm air and the cool air. Therefore, leakage of the air circulating between the pair of air blowers (20, 30) to the inside and outside of the room can be suppressed, and air outside the room circulates between the pair of air blowers (20, 30). Mixing into the air can be suppressed. Accordingly, it is possible to improve the cooling efficiency of the cool air and the warm air.

Further, according to the invention of a 1, 6, 7, by distributing a plurality of streams of different flow rates by the internal air flows (f1, f2) the shunt plate according to the blower fan (22, 32) (51, 61) Without increasing the number of rotations of the blower fan (22, 32) with one blower fan (22, 32), the upper and lower portions where the air enters and exits the entrance / exit (2) of the cooling chamber (1) The air volume of the external air flow (F1, F2) in the upper layer and the lower layer of the corresponding ventilation space (10a) can be increased. In other words, the internal air flow (f1, f2) is distributed by the flow dividing plates (51, 61), and the velocity distribution in the vertical direction with respect to the external air flow (F1, F2) crossing the inlet / outlet (2) of the cooling chamber (1) Necessary to block air flow in the upper and lower layers of the inlet / outlet (2) where the pressure difference inside and outside of the room increases without increasing the rotational speed of the blower fan (22, 32) Air volume can be secured. As a result, it is possible to efficiently block the entry and exit of air at the entrance (2) of the cooling chamber (1).

    By the way, in each casing (21, 31), the inlet (24, 34) and the outlet (25, 35) are formed vertically on one side. Therefore, the internal air flow (f1, f2) from the suction port (24, 34) to the blowout port (25, 35) has a curved shape. Therefore, in order to divert each internal air flow (f1, f2), it is considered that the diverting plate (51, 61) is constituted by a plate-like body curved along the internal air flow (f1, f2). It is done. However, with such a configuration, the shapes of the plurality of flow dividing plates (51, 61) are diversified, and a flow dividing mechanism for dividing each internal air flow (f1, f2) cannot be easily manufactured.

Therefore, in the invention of a 1, 6, 7, each shunt plate (51, 52, 61) is formed in a flat plate shape, spaced them in a direction transverse to the respective internal air flow (f1, f2) The internal air flow (f1, f2) was distributed to a plurality of flows with different flow velocities. Therefore, it is possible to easily configure a flow dividing mechanism that distributes the internal air flow (f1, f2) into a plurality of flows having different flow velocities.

    By the way, when each internal air flow (f1, f2) is divided by a plurality of flat flow dividing plates (51, 61) as described above, the angle and interval of the flow dividing plates (51, 61) are changed. The wind speed of each air flow to be diverted can be changed.

Therefore, in the third and sixth inventions, the flow dividing plates (51, 52, 61, 62) are supported so that the angles and intervals of the flow dividing plates (51, 52, 61, 62) can be changed. A support mechanism (55) was provided. Therefore, the wind speed of each air flow branched by the plurality of flow dividing plates (51, 52, 61, 62) can be easily changed. Thereby, the air speed of each air flow can be easily changed without replacing the flow dividing plates (51, 52, 61, 62), and after the flow dividing plates (51, 52, 61, 62) are attached, The wind speed of the air flow can be finely adjusted.

    By the way, the length of the air flow (hereinafter simply referred to as the proximity air flow) blown out from the nearest of the blower fan (22, 32) at each outlet (25, 35) is longer than the other air flows. Short on each stage. Therefore, when the rectifying direction by the rectifying member (27, 37) is made equal to the blowing direction of the blower fan (22, 32), the direction of the air flow is rapidly changed only by the flow dividing plate (51, 61) in order to form an adjacent air flow. There was a risk that the adjacent air flow would drift in the vicinity of the flow dividing plate (51, 61). When the proximity air flow drifts near the flow dividing plate (51, 61), air is not blown out from the portion around the proximity air flow at the outlet (25, 35), and the pressure is reduced by the proximity air flow at that portion. For this reason, there was a risk of inhaling air in the ventilation space (10a) rather than blowing out air. If air is sucked into a part of the air outlet (25, 35), the air volume of the external air flow (F1, F2) will be insufficient, so air will flow in and out of the inlet / outlet (2) of the cooling chamber (1). It cannot be shut off.

Therefore, in the 4th and 7th invention, by providing the straightener member blowing air of the blower fan (22, 32) for rectifying so as to approach the more downstream outlet (25, 35) (27, 37), blowing The flow direction of the blown air from the fan (22, 32) is changed in two stages by the rectifying member (27, 37) and each flow dividing plate (51, 61). Thereby, compared with the case where the flow straightening direction and the blowing direction of the blower fan (22, 32) are equal, the direction change amount of the air flow by the flow dividing plate (51, 61) is reduced in order to form a close air flow. Can do. Therefore, the drift of the proximity air flow can be more reliably suppressed.

    By the way, the air passage on the ventilation space (10a) side in the width direction of each rectifying member (27, 37) has a shorter distance to the outlet (25, 35) than the air passage on the other side. The degree of effect is lower than the air passage on the other side. On the other hand, if the degree of the rectifying effect in the air passage on the ventilation space (10a) side in the width direction of each rectifying member (27, 37) is too high, there is a high possibility that the adjacent air flow will drift.

Therefore, in the fifth invention, the flow regulating members (27, 37) are formed such that the passage lengths of a large number of air passages become shorter as the air passages on the ventilation space (10a) side in the width direction. . Therefore, the rectifying effect by each rectifying member (27, 37) becomes lower toward the ventilation space (10a) side in the width direction in which the distance to the outlet (25, 35) becomes shorter. Thereby, the passage length of many air passages can be formed in the length according to the grade of the required rectification effect. Further, by reducing the rectifying effect in the air passage on the ventilation space (10a) side in the width direction of each rectifying member (27, 37), the drift of the adjacent air flow can be further suppressed.

FIG. 1 is a cross-sectional view showing the vicinity of an entrance / exit of a freezer in which an air curtain device according to an embodiment is installed. FIG. 2 is a side view of the air curtain device according to the embodiment as viewed from the freezer side. FIG. 3 is a longitudinal sectional view of the air curtain device according to the embodiment. FIG. 4 is a cross-sectional view of the air curtain device according to the embodiment. FIG. 5 is a schematic view showing a method of manufacturing the rectifying member. FIG. 6 is an exploded perspective view and an assembled perspective view of the blade and the support mechanism. 7 (A) and 7 (B) are side views of the air curtain device according to the embodiment, (A) shows the inner surface of the first blower, and (B) shows the inner surface of the second blower. Show. FIG. 8 is a cross-sectional view illustrating an installation mode of each divided piece of the blowout grill of the air curtain device according to the embodiment. FIG. 9 is a perspective view showing the direction of air flow and the velocity distribution formed in the ventilation space of the air curtain device according to the embodiment.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Hereinafter, as an example of the air curtain device for a cooling chamber according to the present invention, an air curtain device provided at an entrance of a freezer provided adjacent to a processing chamber of a food processing factory will be described.

<< Embodiment of the Invention >>
As shown in FIG. 1, the air curtain device (10) is provided at the entrance / exit (2) of the freezer (cooling chamber) (1). Specifically, an opening (3a) is formed in the partition wall (3) between the freezer (1) and the outside (outdoor) processing chamber, and the air is placed on the freezer (1) side of the opening (3a). A curtain device (10) is provided. An opening / closing door (4) is provided on the processing chamber side of the opening (3a). Between the partition wall (3) and the air curtain device (10), there is a tunnel-shaped blocking wall (5) that closes the gap between the partition wall (3) and the air curtain device (10). Yes.

    In this embodiment, the doorway (2) of the freezer (1) includes the opening (4a) of the open / close door (4), the opening (3a) of the partition wall (3), and the blocking wall (5 ) Opening (5a) and the ventilation space (10a) serving as the opening of the air curtain device (10). The doorway (2) of the freezer (1) is opened and closed by the open / close door (4), while the air curtain device (10) according to the present invention forms when the open / close door (4) is open. The air flow in the direction (F1, F2) blocks the entry and exit of air at the inlet / outlet (2).

-Configuration of air curtain device-
The air curtain device (10) includes a pair of blowers, that is, a first blower (20) and a second blower (30). The first blower (20) and the second blower (30) are separately provided at one end and the other end in the width direction of the entrance (2) of the freezer (1), and a ventilation space ( Section 10a). As shown in FIG.1 and FIG.2, in this embodiment, when seeing the processing chamber direction from the inside of the freezer (1), the first air blower (20) is provided at the left end of the doorway (2), The 2nd air blower (30) is provided in the right end part of the entrance / exit (2).

    As shown in FIGS. 3 and 4, each blower (20, 30) includes a box-shaped casing (21, 31) and a blower fan (22, 32) housed in the casing (21, 31). Respectively.

    Each casing (21, 31) includes a cylindrical portion (23, 33) having a rectangular cross section formed by four side plates, and a top plate (26, 36) that closes the upper end of the cylindrical portion (23, 33). have. The inner plates (23a, 33a) facing each other of the cylindrical portions (23, 33) are configured as hinged doors, and the inner plates (23a, 33a) have an air suction port (24, 34) and an air outlet (25 , 35) are formed. In the present embodiment, the top plates (26, 36) of both casings (21, 31) are integrally formed by one plate member. That is, the air curtain device (10) is configured in a gate shape surrounding the side and upper side of the ventilation space (10a).

    Each inlet (24, 34) and each outlet (25, 35) are each formed by a rectangular opening. In the first blower (20), the air outlet (25) is formed on the upper side, while the suction port (24) is formed on the lower side. On the other hand, in the second blower (30), the suction port (34) is formed on the upper side, and the blower outlet (35) is formed on the lower side. Moreover, the suction grille (24a) is attached to the suction inlet (24) of the first blower (20), and the blowout grille (25a) is attached to the outlet (25). On the other hand, a suction grille (34a) is attached to the suction inlet (34) of the second blower (30), and a blowout grille (35a) is attached to the outlet (35). Although the details will be described later, the blow-out grill (25a, 35a) is constituted by a perforated plate in which a large number of ventilation holes are formed.

    Each blower fan (22, 32) is constituted by a pressure fan, and is arranged near the center in the vertical direction in each casing (21, 31).

    The blower fan (22) of the first blower (20) is provided between the suction port (24) and the blower port (25) in the casing (21) so as to suck air from below and blow it upward. Are provided in an up-blown state. By being provided in this way, in the first blower (20), inside the casing (21), the suction port (24) below the blower fan (22) is directed to the upper blowout port (25). An internal air flow (f1) is formed.

    The blower fan (32) of the second blower (30) is provided between the suction port (34) and the blower port (35) inside the casing (31), and sucks air from above and blows it downward. Is provided in a state of bottom blowing. By being provided in this manner, in the second blower device (30), the suction port (34) on the upper side of the blower fan (32) is directed to the lower blower outlet (35) inside the casing (31). An internal air flow (f2) is formed.

    A flow regulating member (27, 37) is attached to the blowing side of each blower fan (22, 32). The first blower (20) is provided with a plurality of blades (dividing plates) (51, 52) that divide the internal air flow (f1) into a plurality of flows. On the other hand, the second blower (30) is provided with a plurality of blades (61, 62) that divide the internal air flow (f2) into a plurality of flows. Details of the flow regulating members (27, 37) and the blades (51, 52, 61, 62) will be described later.

    With the configuration as described above, when the blower fans (22, 32) of the first blower (20) and the second blower (30) are driven, the internal air flow ( f1 and f2) are formed, and in the ventilation space (10a) defined between the first blower (20) and the second blower (30), the outlet ( 25) to the suction port (34) of the second blower (30) and the air flow (F1) from the blower (35) of the second blower (30) to the suction port (1) of the first blower (20) Air flow (F2) toward 24) is formed. The air flow (F1) and the air flow (F2) are air flows that are arranged in the vertical direction and face each other in the horizontal direction.

<Rectifying member>
The flow regulating members (27, 37) are formed of a honeycomb structure, and a large number of air passages each having a regular hexagonal cross section are formed. A number of air passages are formed so as to penetrate the flow regulating members (27, 37) in the thickness direction. Further, the flow regulating members (27, 37) are formed so that the thickness gradually decreases from one side surface toward the opposite side surface. Thereby, the passage lengths of the multiple air passages of the flow regulating members (27, 37) are gradually shortened from one side surface to the opposite side surface.

    In the present embodiment, as shown in FIG. 5, the two rectifying members (27, 37) are a rectangular parallelepiped rectifying member in which a large number of air passages are formed in the thickness direction. It is formed by cutting so that the cut surface is inclined with respect to both end surfaces. By forming in this way, the two rectifying members (27, 37) whose thickness changes from one side surface toward the opposite side surface can be easily formed without waste.

    As shown in FIG. 3, each rectifying member (27, 37) includes an end face on the inflow side and a blower fan (22, 32) toward the inner plate (23a, 33a) side in the width direction of each casing (21, 31). It is tilted so as to shorten the distance. By arranging the rectifying members (27, 37) in this way, each air passage of each rectifying member (27, 37) is inclined with respect to the blowing direction of each blower fan (22, 32), and the downstream side is Approach the outlet (25,35) side. In addition, each of the rectifying members (27, 37) is provided such that the thickness thereof becomes thinner toward the inner plate (23a, 33a) side in the width direction of each casing (21, 31). In other words, the flow length of each air flow member (27, 37) becomes shorter toward the inner plate (23a, 33a) side (ventilation space (10a) side) in the width direction of each casing (21, 31). It is provided as follows.

    By such a rectifying member (27, 37), the air blown out from each blower fan (22, 32) is stratified by the swirling component being removed by the numerous air passages of the rectifying member (27, 37). And converted into a uniform flow in the axial direction of the air passage. In other words, the air blown out from each blower fan (22, 32) is rectified by the rectifying member (27, 37) before being diverted by the plurality of blades (51, 61), and is further blown out toward the downstream side. The distribution direction is changed to approach (25,35).

<blade>
Each blade (51, 52, 61, 62) has an internal air flow (f1, f2) at each of the inlet (24, 34) and the outlet (25, 35) in each casing (21, 31). Is divided into a plurality of flows with different flow velocities arranged in the vertical direction at the air outlets (25, 35). Each blade (51, 52, 61, 62) is formed of a rectangular flat plate member. In the present embodiment, five blades (51, 61) are provided between the blower fan (22, 32) and the outlet (25, 35) in each casing (21, 31), while each casing ( 21 and 31), five blades (52, 62) are provided between the blower fans (22, 32) and the suction ports (24, 34). At each installation location, the plurality of blades (52, 62) are arranged at intervals in the direction crossing the internal air flows (f1, f2) by the support mechanism (55).

    Specifically, as shown in FIG. 6, each blade (51, 52, 61, 62) is a rectangular flat body extending in the depth direction (left and right direction in FIG. 6) of each casing (21, 31). Part (54a) and an engaging part (54b) that is formed at both ends of the body part (54a) in the depth direction (left-right direction in FIG. 6) and engages with the support mechanism (55). . The engaging portion (54b) is formed by protruding pieces that are folded back from both end portions in the depth direction of the main body portion (54a). A circular hole (54c) is formed in the engaging portion (54b).

    The support mechanism (55) includes a bolt member (56), a nut member (57), and a rail member (58). The bolt member (56) has a male screw part (56a) and a head part (56b). The male thread portion (56a) of the bolt member (56) is inserted through the circular hole (54c) of the engaging portion (54b) of each blade (51, 52, 61, 62). The nut member (57) is screwed into the male screw portion (56a) of the bolt member (56) inserted through the circular hole (54c) of each engagement portion (54b), and each blade (51, 52, 61 62) is rotatably attached to the bolt member (56). The rail member (58) is formed by bending a long plate in the short side direction, and the cross-sectional shape is formed in a shape along the outer shape of the head (56b) of the bolt member (56). The rail member (58) has a head (56b) of a bolt member (56) fitted therein, and holds the head (56b) slidably in the longitudinal direction. Two rail members (58) are provided in each support mechanism (55), and the two rail members (58) correspond to one end surface and the other end surface in the depth direction in each casing (21, 31). Is attached in position. The two rail members (58) are attached in parallel to the suction ports (24, 34) on the suction side of the blower fan (21, 31), and on the blowout side of the blower fan (21, 31), It is attached so that it may approach a ventilation fan (21,31), so that it approaches a blower outlet (25,35).

    With such a configuration, the blades (51, 52, 61, 62) are arranged at intervals in the direction crossing the internal air flows (f1, f2) by the support mechanism (55). Each blade (51, 52, 61, 62) is slidable with respect to the rail member (58) by the bolt member (56) and the nut member (57) and is orthogonal to the rail member (58). A shaft (a central axis of the male thread portion (56a) of the bolt member (56)) is rotatably attached. That is, each blade (51, 52, 61, 62) is supported by the support mechanism (55) so that the angle and the interval between them can be changed.

    The plurality of blades (51, 61) provided between the blower fan (22, 32) and the blower outlet (25, 35) in the casing (21, 31) of each blower (20, 30) The flow speeds of the plurality of divided flows are provided at intervals such that the flow rates away from the blower fans (22, 32) become faster. Specifically, in the plurality of blades (51, 61), the ratio of the channel cross-sectional area of the outlet to the channel cross-sectional area of the inlet of the plurality of channels partitioned by the blade (51, 61) is: They are arranged at such an angle and interval that the flow path away from the air outlet (25, 35) becomes smaller.

    On the other hand, a plurality of blades (52, 62) provided between the blower fan (22, 32) and the suction port (24, 34) in the casing (21, 31) of each blower (20, 30) Are equally spaced at equal angles.

    By providing the blades (51, 52, 61, 62) as described above, they are formed in the respective casings (21, 31) from the suction ports (24, 34) toward the blowout ports (25, 35). The curved internal air flow (f1, f2) is divided into a plurality of flows in the radial direction. The plurality of flows divided by the plurality of blades (51, 61) provided on the blowing side of each blower fan (22, 32) are connected to the blower fan (22, 32) at the blowout port (25, 35). The longer the flow, the faster the flow rate. Thereby, the air flow (F1) which blows off from the blower outlet (25) of the 1st air blower (20) to the ventilation space (10a) and flows toward the suction inlet (34) of the 2nd air blower (30), The wind speed increases stepwise from the lower end (the vertical center of the ventilation space (10a)) toward the upper end, and the air volume increases. On the other hand, the air flow (F2) that is blown from the blower outlet (35) of the second blower (30) to the ventilation space (10a) and flows toward the suction port (24) of the first blower (20) The wind speed increases stepwise from the (vertical center portion of the ventilation space (10a)) toward the lower end, and the air volume increases. That is, the air volume of the air flow (F1, F2) flowing in the horizontal direction in the ventilation space (10a) increases stepwise from the center in the vertical direction of the ventilation space (10a).

<grill>
As shown in FIG. 7, the suction grille (24a, 34a) is formed by a wire mesh, while the blowout grille (25a, 35a) has a thickness formed so that a large number of ventilation holes penetrate in the thickness direction. It is comprised by the plate-shaped body. The blow-out grill (25a, 35a) has a honeycomb structure in which a large number of ventilation holes have a regular hexagonal cross-sectional shape. Further, as shown in FIG. 8, the blow-out grill (25a, 35a) is formed in a V-shape in which the central portion in the depth direction is recessed toward the inside of the casing (21, 31) as compared to both ends.

    Further, each of the blow-out grills (25a, 35a) is divided into three in the vertical direction. The three divided pieces (25a1, 25a2, 25a3, 35a1, 35a2, and 35a3) are provided so that the air blowing directions are different from each other.

    In the first blower (20), the lowermost first divided piece (25a1) is such that the portions on both sides of the vertical surface L passing through the center in the depth direction of the ventilation space (10a) Are symmetrically formed. Thereby, in the first divided piece (25a1), air is blown out in a direction parallel to the vertical plane L. The middle second divided piece (25a2) is provided so as to be inclined to the outdoor side by 5 degrees with respect to the first divided piece (25a1). As a result, the second divided piece (25a2) blows out air in a direction inclined 5 degrees toward the outdoor side with respect to the vertical plane L. The uppermost third divided piece (25a3) is provided so as to be inclined 10 degrees toward the outdoor side with respect to the first divided piece (25a1). As a result, the third divided piece (25a3) blows out air in a direction inclined 10 degrees toward the outdoor side with respect to the vertical plane L. That is, the three divided pieces (25a1, 25a2, 25a3) of the blowing grill (25a) of the first blower (20) are provided so that the air blowing direction is inclined to the outdoor side at a larger angle as the upper divided piece. It has been. Thereby, in the upper part from the center of the up-down direction of the ventilation space (10a), the course on the upstream side of the air flow (F1) is inclined to the outdoor side at a larger angle as it goes upward.

    On the other hand, in the second air blower (30), the uppermost first divided piece (35a1) is such that the portions on both sides of the vertical plane L passing through the center in the depth direction of the ventilation space (10a) are the vertical plane L. It is provided so as to have a symmetrical shape. Thereby, in the first divided piece (35a1), air is blown out in a direction parallel to the vertical plane L. The middle second divided piece (35a2) is provided so as to be inclined to the indoor side by 5 degrees with respect to the first divided piece (35a1). As a result, the second divided piece (35a2) blows out air in a direction inclined 5 degrees toward the indoor side with respect to the vertical plane L. The lowermost third divided piece (35a3) is provided so as to be inclined 10 degrees toward the indoor side with respect to the first divided piece (35a1). As a result, the third divided piece (35a3) blows out air in a direction inclined 10 degrees toward the indoor side with respect to the vertical plane L. In other words, the three divided pieces (35a1, 35a2, 35a3) of the blowing grill (35a) of the second blower (30) are provided so that the air blowing direction is inclined to the indoor side at a larger angle as the lower divided piece. It has been. As a result, in the portion below the center in the vertical direction of the ventilation space (10a), the path on the upstream side of the air flow (F2) is inclined toward the indoor side at a larger angle as it goes downward.

-Driving action-
In the air curtain device (10), when the blower fans (22, 32) of the first blower device (20) and the second blower device (30) are driven, the internal air flow (f1 , f2) and a horizontal air flow (F1, F2) are formed in the ventilation space (10a).

    Specifically, in the first blower (20), when the blower fan (22) is driven, the upper blower outlet from the lower suction port (24) than the blower fan (22) is inserted into the casing (21). A curved internal air flow (f1) towards (25) is formed. On the other hand, in the second blower (30), when the blower fan (32) is driven, the suction port (34) on the upper side of the blower fan (32) into the lower blower outlet (35) in the casing (31). A curved internal air flow (f2) towards is formed.

    The internal air flow (f1) is blown out from the air outlet (25) of the first blower (20) to the ventilation space (10a). The air blown into the ventilation space (10a) is sucked into the suction port (34) of the second blower (30) opposed to the blower outlet (25) of the first blower (20). In this way, an air flow (F1) is formed which flows in the horizontal direction upward from the center in the vertical direction of the ventilation space (10a). On the other hand, the internal air flow (f2) is blown out from the air outlet (35) of the second blower (30) to the ventilation space (10a). The air blown into the ventilation space (10a) is sucked into the suction port (24) of the first blower (20) opposed to the blower outlet (35) of the second blower (30). In this way, an air flow (F2) that flows so as to face the air flow (F1) is formed from the center in the vertical direction of the ventilation space (10a) to the lower side.

    Here, as above-mentioned, a 1st air blower (20) and a 2nd air blower (30) are each provided in the one end part and other end part of the width direction of the entrance / exit (2) of a freezer (1). Yes. Therefore, in the ventilation space (10a) between the first blower (20) and the second blower (30), the air flow (F1, F2) flowing from one side to the other side passes through the doorway (2) in the width direction. Will be crossed. The air flow (F1, F2) crossing the entrance / exit (2) in the width direction blocks the entry / exit of air at the entrance / exit (2) of the freezer (1).

    Also, in the casing (21, 31) of each blower (20, 30), the internal air flow (f1, f2) flowing in a curved manner from the suction port (24, 34) toward the blowout port (25, 35) Are divided into a plurality of flows by a plurality of blades (51, 52, 61, 62). The plurality of flows divided by the plurality of blades (51, 61) provided on the blowing side of each blower fan (22, 32) are connected to the blower fan (22, 32) at the blowout port (25, 35). The longer the flow, the faster the flow rate. Thereby, as shown in FIG. 13, the flow velocity of the air flow (F1, F2) flowing in the horizontal direction in the ventilation space (10a) is changed upward and downward from the center in the vertical direction of the ventilation space (10a), respectively. Get faster step by step. Thereby, the air volume of the air flow (F1, F2) increases stepwise from the center in the vertical direction of the ventilation space (10a) upward and downward.

    By the way, the pressure difference between the warm air on the outdoor side and the cool air on the indoor side becomes equal at the center in the vertical direction of the ventilation space (10a), while the pressure of warm air increases at the upper layer of the ventilation space (10a). The pressure difference between the cool air and the cool air becomes large, and in the lower layer portion of the ventilation space (10a), the pressure of the cool air becomes high and the pressure difference between the warm air and the cool air becomes large. Due to the pressure difference between the warm air and the cold air, in the ventilation space (10a), the wind speed of the cross wind due to the warm air increases as it goes upward from the central portion in the vertical direction, and the cold air flows toward the downward direction from the central portion in the vertical direction. The wind speed of the crosswind due to increases. Therefore, in the upper part from the center in the vertical direction of the ventilation space (10a), the course of the air flow (F1) tends to be inclined toward the indoor side by the crosswind due to warm air as it goes upward, and the center in the vertical direction of the ventilation space (10a) In the lower part, the course of the air flow (F2) is more easily inclined to the outdoor side due to the cross wind caused by cold air as it goes downward.

    However, in the present embodiment, as described above, the blowout grill (25a) of the first blower (20) is divided into three in the vertical direction, and the upper divided piece is provided so as to be inclined toward the outdoor side. Yes. Therefore, in the upper part from the center in the up-down direction of the ventilation space (10a), the blowing direction of the air blown into the ventilation space (10a) is inclined toward the outdoor side at a larger angle as it goes upward. In other words, in the upper part of the ventilation space (10a) from the center in the up-down direction, the wind speed of the side wind due to warm air increases as it goes upward, and the course of the air flow (F1) tends to tilt indoors, but it goes upward The course on the upstream side of the air flow (F1) is inclined toward the outdoor side. As a result, the air flow (F1) is sucked into the second blower (30) without leaking into the room.

    Similarly, the blowing grill (35a) of the second blower (30) is divided into three in the vertical direction, and the lower divided piece is provided so as to be inclined toward the indoor side. Therefore, in the portion below the center in the up-down direction of the ventilation space (10a), the blowing direction of the air blown out to the ventilation space (10a) is inclined indoors at a larger angle toward the lower side. In other words, in the part below the center in the vertical direction of the ventilation space (10a), the wind speed of the cross wind due to cold air increases as it goes downward, and the course of the air flow (F2) tends to tilt outward, but it goes downward The course on the upstream side of the air flow (F2) is inclined toward the indoor side. Therefore, the air flow (F2) is sucked into the first blower (20) without leaking outside the room.

    In addition, the two air flows (F1, F2) may decrease in wind speed toward the downstream side and swell in the depth direction, and some of them may leak into the room on the downstream side. However, in this embodiment, each blowing grill (25a, 35a) is configured by a V-shaped perforated plate in which a number of air passages extending in the thickness direction are formed. Therefore, each air flow (F1, F2) is blown out from each outlet (25, 35) and once narrows in the depth direction toward the downstream side, and then swells in the depth direction on the downstream side, and therefore leaks. It will be sucked into the corresponding blower (30, 20).

-Effect of the embodiment-
According to the above embodiment, each blowing grill (25a, 35a) is constituted by a V-shaped perforated plate in which a number of air passages extending in the thickness direction are formed. Thereby, each air flow (F1, F2) is blown out from each blower outlet (25, 35), and once narrows in the depth direction toward the downstream side. Therefore, even if each air flow (F1, F2) swells in the depth direction on the downstream side, the amount of bulge in the depth direction can be reduced compared to the case where the blow grill (25a, 35a) is formed flat. it can. As a result, the air flow (F1, F2) is sucked into the corresponding blower (30, 20) without leaking. Therefore, leakage of the air flow (F1, F2) to the outside of the room can be suppressed, and a decrease in the amount of air circulation between the pair of air blowers (20, 30) can be suppressed. Therefore, the entrance and exit of air at the inlet / outlet (2) of the cooling chamber (1) can be reliably blocked.

    Incidentally, as described above, in the ventilation space (10a), due to the pressure difference between the warm air and the cool air, the wind speed of the cross wind due to the warm air increases as it goes upward from the central portion in the vertical direction, and downward from the central portion in the vertical direction. The more you head, the faster the crosswind speed is.

    On the other hand, in the above-described embodiment, the blow grill (25a) provided at the blower outlet (25) on the upper side of the suction port (24) is divided into a plurality of parts in the vertical direction and the upper divided piece is inclined toward the outdoor side. The blowing grill (35a) provided at the lower outlet (35) of the suction port (34) is divided into a plurality of parts in the vertical direction and the lower divided piece is inclined toward the indoor side. Thereby, the blowing direction of the air to the ventilation space (10a) can be inclined in the upstream direction of the cross wind according to the wind speed distribution in the vertical direction of the cross wind due to the warm air and the cool air. Therefore, leakage of the air circulating between the pair of air blowers (20, 30) to the inside and outside of the room can be suppressed, and air outside the room circulates between the pair of air blowers (20, 30). Mixing into the air can be suppressed. Accordingly, it is possible to improve the cooling efficiency of the cool air and the warm air.

    Moreover, according to the said embodiment, by distributing the internal air flow (f1, f2) by each ventilation fan (22, 32) into the several flow from which a flow velocity differs with the blade (51, 61) provided in the blowing side, A single blower fan (22, 32) corresponds to the upper and lower layers where air flows in and out of the entrance (2) of the freezer (1) without increasing the rotational speed of the blower fan (22, 32). The air volume (F1, F2) in the upper and lower layers of the ventilation space (10a) can be increased. In other words, the blade (51, 61) distributes the internal air flow (f1, f2) to form a vertical velocity distribution with respect to the air flow (F1, F2) crossing the inlet / outlet (2) of the cooling chamber (1). As a result, the required air volume to block the air flow in the upper and lower layers of the doorway (2) where the pressure difference inside and outside the room increases, without increasing the rotational speed of the blower fans (22, 32). Can be secured. As a result, it is possible to efficiently block the entry and exit of air at the entrance (2) of the cooling chamber (1).

    By the way, in each casing (21, 31), the inlet (24, 34) and the outlet (25, 35) are formed vertically on one side. Therefore, the internal air flow (f1, f2) from the suction port (24, 34) to the blowout port (25, 35) has a curved shape. Therefore, in order to divert each internal air flow (f1, f2), it is conceivable that the blade (51, 61) is constituted by a plate-like body that is curved along the internal air flow (f1, f2). . However, with such a configuration, the shapes of the plurality of blades (51, 61) are diversified, and it is not possible to easily manufacture a flow dividing mechanism for dividing each internal air flow (f1, f2).

    Further, according to the above embodiment, each blade (51, 52, 61, 62) is formed in a flat plate shape, and these are spaced in a direction crossing each internal air flow (f1, f2) by the support mechanism (55). Each internal air flow (f1, f2) was divided into a plurality of flows with different flow velocities by arranging them with a gap. Therefore, it is possible to easily configure a flow dividing mechanism that distributes the internal air flow (f1, f2) into a plurality of flows having different flow velocities.

    By the way, when each internal air flow (f1, f2) is divided by a plurality of flat blades (51, 52, 61, 62) as described above, the angles and intervals of the blades (51, 52, 61, 62) By changing the above, it is possible to change the wind speed of each air flow to be diverted.

    According to the above embodiment, the support mechanism (55) that supports each blade (51, 52, 61, 62) so that the angle and interval of the plurality of blades (51, 52, 61, 62) can be changed. ). Therefore, the wind speed of each air flow branched by the plurality of blades (51, 52, 61, 62) can be easily changed. As a result, the air speed of each air flow can be easily changed without replacing the blades (51, 52, 61, 62), and each air flow can be changed after the blades (51, 52, 61, 62) are attached. The wind speed can be finely adjusted.

    By the way, the length of the air flow (hereinafter simply referred to as the proximity air flow) blown out from the nearest of the blower fan (22, 32) at each outlet (25, 35) is longer than the other air flows. Short on each stage. Therefore, if the rectifying direction by the rectifying member (27, 37) is made equal to the blowing direction of the blower fan (22, 32), the direction of the air flow is rapidly changed only by the blade (51, 61) in order to form an adjacent air flow. It had to be changed, and there was a possibility that the adjacent air flow drifted near the blade (51, 61). If the proximity air flow drifts in the vicinity of the blade (51, 61), air is not blown out from the surrounding area of the proximity air flow at the outlet (25, 35), and the pressure drops due to the proximity air flow in that portion. In addition, the air in the ventilation space (10a) could be sucked in rather than blowing out air. If air is sucked into a part of the air outlet (25, 35), the air flow (F1, F2) becomes insufficient, so the air flow at the inlet / outlet (2) of the cooling chamber (1) is blocked. Can not do.

    On the other hand, in the above embodiment, by providing the rectifying member (27, 37) that rectifies the blown air of the blower fan (22, 32) so as to approach the blower outlet (25, 35) toward the downstream side, The flow direction of the blown air of (22, 32) is changed in two stages by the rectifying member (27, 37) and each blade (51, 61). Thereby, compared with the case where the rectification direction and the blowing direction of the blower fan (22, 32) are equal, the direction change amount of the air flow by the blade (51, 61) can be reduced in order to form a close air flow. it can. Therefore, the drift of the proximity air flow can be more reliably suppressed.

    By the way, the air passage on the ventilation space (10a) side in the width direction of each rectifying member (27, 37) has a shorter distance to the outlet (25, 35) than the air passage on the other side. The degree of effect is lower than the air passage on the other side. On the other hand, if the degree of the rectifying effect in the air passage on the ventilation space (10a) side in the width direction of each rectifying member (27, 37) is too high, there is a high possibility that the adjacent air flow will drift.

    On the other hand, in the above-described embodiment, each of the rectifying members (27, 37) is formed such that the passage lengths of a large number of air passages become shorter as the air passage on the ventilation space (10a) side in the width direction. did. Therefore, the rectifying effect by each rectifying member (27, 37) becomes lower toward the ventilation space (10a) side in the width direction in which the distance to the outlet (25, 35) becomes shorter. Thereby, the passage length of many air passages can be formed in the length according to the grade of the required rectification effect. Further, by reducing the rectifying effect in the air passage on the ventilation space (10a) side in the width direction of each rectifying member (27, 37), the drift of the adjacent air flow can be further suppressed.

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About the said embodiment, it is good also as the following structures.

    In the above embodiment, the plurality of blades (51, 52, 61, 62) and the support mechanism (55) for supporting them may be omitted. Even in such a case, each of the blow grills (25a, 35a) is constituted by a V-shaped perforated plate in which a large number of air passages extending in the thickness direction are formed. ) Can be prevented from leaking into and out of the room, so that the entry and exit of air at the inlet / outlet (2) of the cooling chamber (1) can be reliably blocked.

    Moreover, in the said embodiment, the braid | blade (52,62) provided in the suction inlet (24,34) side of each ventilation fan (22,32) and the support mechanism (55) which supports these are abbreviate | omitted, and a blower outlet The blade (51, 61) and the support mechanism (55) for supporting these may be provided only on the (25, 35) side. Even in such a configuration, the blades (51, 61) distribute the internal air flow (f1, f2) and move up and down with respect to the air flow (F1, F2) crossing the entrance (2) of the freezer (1). By forming the speed distribution in the direction, the air flow at the upper and lower layers of the inlet / outlet (2) where the pressure difference between the inside and outside of the chamber increases without increasing the rotational speed of the blower fan (22, 32) is blocked. It is possible to secure the necessary air volume for Therefore, it is possible to efficiently block the entry / exit of air at the entrance / exit (2) of the cooling chamber (1).

    Moreover, in the said embodiment, it is good also as installing several ventilation fans (22, 32) in each casing (21, 31).

    Moreover, in the said embodiment, the braid | blade (52, 62) provided in the suction side of each ventilation fan (22, 32) was arranged at equal intervals at the same angle. However, the blades (52, 62) on the suction side of each blower fan (22, 32) are connected to the flow path cross-sectional area of the flow paths of the plurality of flow paths defined by the blades (52, 62). It is good also as arranging at the angle and space | interval that the ratio of a road cross-sectional area becomes large, so that the flow path away from the ventilation fan (22, 32) becomes large. When formed in this way, the flow velocity of the plurality of flows divided by the blades (52, 62) increases as the flow moves away from the blower fans (22, 32). Therefore, the width of the vertical velocity distribution of the air flow (F1, F2) crossing the entrance (2) of the cooling chamber (1) is increased. Therefore, the entrance / exit of air at the entrance / exit (2) of the cooling chamber (1) can be more efficiently blocked.

    The number of blades (51, 61) provided on the blow-out side of the blower fan (22, 32) in each casing (21, 31) and the number of blades (52, 62) provided on the suction side are those of the above embodiment. Not limited to.

    Further, each blowing grill (25a, 35a) may be formed with a large number of ventilation holes, and the shape of the ventilation holes is not limited to a regular hexagon. It may be simply formed in a square lattice shape.

    In addition, the arrangement of the three divided pieces (25a1, 25a2, 25a3, 35a1, 35a2, 35a3) of each blowing grill (25a, 35a) is limited to the angles (0 degrees, 5 degrees, 10 degrees) of the above embodiment. Absent. Moreover, the division | segmentation number of the up-down direction of each blowing grill (25a, 35a) is not restricted to the number (three) of the said embodiment.

    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 an air curtain device for a cooling chamber that is provided at the entrance and exit of a cooling chamber such as a freezer or a refrigerator and that forms an air flow for blocking the entry and exit of air.

1 Freezer (cooling room)
2 doorway
10 Air curtain device
10a Ventilation space
20 First blower (blower)
30 Second blower (blower)
21, 31 Casing
22, 32 Fan
24, 34 Suction port
25, 35 outlet
25a, 35a Outlet grill (perforated plate)
25a1, 35a1 first divided piece
25a2, 35a2 Second segment
25a3, 35a3 3rd piece
51, 52, 61, 62 Blade
55 Support mechanism
56 Bolt member (mounting member)
57 Nut member (mounting member)
58 Rail member

Claims (7)

A casing (21, 31) in which an air inlet (24, 34) and an outlet (25, 35) are vertically formed on one side surface, and the inlet (24, 24) in the casing (21, 31) , 34) and the internal air flow from the inlet (24, 34) to the outlet (25, 35) in the casing (21, 31) accommodated between the outlet (25, 35) A pair of blowers (20, 30) each having a blower fan (22, 32) forming (f1, f2),
The pair of blowers (20, 30) are connected to the inlet (24, 34) and the outlet (35) at one end and the other end in the width direction of the inlet / outlet (2) of the cooling chamber (1). , 25) are opposed to each other, and the air inlet space (10a) is opposed to each of the air outlets (25, 35) by the internal air flow (f1, f2). 24) An air curtain device for a cooling chamber in which an external air flow (F1, F2) toward the
Each of the air outlets (25, 35) is formed with a large number of ventilation holes penetrating in the thickness direction, and the center portion in the depth direction is the interior of the casing (21, 31) as compared to both ends. Perforated plates (25a, 35a) formed in a V-shape recessed on the side ,
The blower fan (22, 32) is housed in each casing (21, 31) one by one, and the blower outlet (25) is formed above the suction port (24). In the casing (31), the air outlet (35) is disposed below the suction port (34), while the air (35) is arranged to blow air downward. ,
Each of the air blowers (20, 30) is configured such that the air volume of the external air flow (F1, F2) increases stepwise from the vertical center of the ventilation space (10a) upward and downward. A plurality of flow dividing plates (51, 52, 61, 62) for dividing the internal air flows (f1, f2) into a plurality of flows having different flow velocities,
The plurality of flow dividing plates (51, 52, 61, 62) are each formed in a flat plate shape, provided at least between each of the blower fans (22, 32) and the outlet (25, 35), Arranged in a direction transverse to each internal air flow (f1, f2),
The plurality of flow dividing plates (51, 52, 61, 62) provided between the air blowing fans (22, 32) and the blower outlets (25, 35) The ratio of the channel cross-sectional area of the outlet to the channel cross-sectional area of the inlet of the channel is arranged at an angle and an interval such that the channel away from each of the outlets (25, 35) becomes smaller. An air curtain device for a cooling chamber characterized by the above. In claim 1,
The perforated plate (25a) provided at the air outlet (25) formed on the upper side of the suction port (24) is divided into a plurality of parts in the vertical direction, and the upper divided piece is inclined toward the outdoor side. ,
The perforated plate (35a) provided at the outlet (35) formed below the suction port (34) is divided into a plurality of parts in the vertical direction, and the lower divided piece is inclined toward the indoor side. An air curtain device for a cooling chamber. In claim 1 or 2 ,
A rail member (58) extending in the arrangement direction of the plurality of flow dividing plates (51, 52, 61, 62), and the flow dividing plates (51, 52, 61, 62) are slid relative to the rail member (58). A mounting member (56, 57) that can be freely and rotatably mounted around a rotation axis orthogonal to the rail member (58), and supports each of the flow dividing plates (51, 52, 61, 62) A cooling chamber air curtain device comprising a mechanism (55). In any one of Claims 1 thru | or 3 ,
Each of the blower fans (22, 32) is provided so as to blow out air in parallel with the air outlet ( 25, 35 ), while the plurality of flow dividing plates (51, 61) include at least each of the blower fans (22 , 32) and the outlet (25, 35),
Between the plurality of flow dividing plates (51, 61) on the blowing side of each of the blower fans (22, 32), the blown air of the blower fans (22, 32) is sent to the outlet ( 25, 35) An air curtain device for a cooling chamber, characterized in that a rectifying member (27, 37) having a large number of air passages that rectify so as to approach 25, 35) is provided. In claim 4 ,
Each of the rectifying members (27, 37) is formed such that the passage length of the plurality of air passages becomes shorter as the air passage on the ventilation space (10a) side in the width direction of each casing (21, 31). An air curtain device for a cooling chamber. A casing (21, 31) in which an air inlet (24, 34) and an outlet (25, 35) are vertically formed on one side surface, and the inlet (24, 24) in the casing (21, 31) , 34) and the internal air flow from the inlet (24, 34) to the outlet (25, 35) in the casing (21, 31) accommodated between the outlet (25, 35) A pair of blowers (20, 30) each having a blower fan (22, 32) forming (f1, f2),
The pair of blowers (20, 30) are connected to the inlet (24, 34) and the outlet (35) at one end and the other end in the width direction of the inlet / outlet (2) of the cooling chamber (1). , 25) are opposed to each other, and the air inlet space (10a) is opposed to each of the air outlets (25, 35) by the internal air flow (f1, f2). 24) An air curtain device for a cooling chamber in which an external air flow (F1, F2) toward the
Each of the air outlets (25, 35) is formed with a large number of ventilation holes penetrating in the thickness direction, and the center portion in the depth direction is the interior of the casing (21, 31) as compared to both ends. Perforated plates (25a, 35a) formed in a V-shape recessed on the side,
Each of the air blowers (20, 30) is configured such that the air volume of the external air flow (F1, F2) increases stepwise from the vertical center of the ventilation space (10a) upward and downward. A plurality of flow dividing plates (51, 52, 61, 62) for dividing the internal air flows (f1, f2) into a plurality of flows having different flow velocities,
The plurality of flow dividing plates (51, 52, 61, 62) are each formed in a flat plate shape and are arranged at intervals in a direction crossing the internal air flows (f1, f2),
A rail member (58) extending in the arrangement direction of the plurality of flow dividing plates (51, 52, 61, 62), and the flow dividing plates (51, 52, 61, 62) are slid relative to the rail member (58). A mounting member (56, 57) that can be freely and rotatably mounted around a rotation axis orthogonal to the rail member (58), and supports each of the flow dividing plates (51, 52, 61, 62) With mechanism (55)
An air curtain device for a cooling chamber. A casing (21, 31) in which an air inlet (24, 34) and an outlet (25, 35) are vertically formed on one side surface, and the inlet (24, 24) in the casing (21, 31) , 34) and the internal air flow from the inlet (24, 34) to the outlet (25, 35) in the casing (21, 31) accommodated between the outlet (25, 35) A pair of blowers (20, 30) each having a blower fan (22, 32) forming (f1, f2),
The pair of blowers (20, 30) are connected to the inlet (24, 34) and the outlet (35) at one end and the other end in the width direction of the inlet / outlet (2) of the cooling chamber (1). , 25) are opposed to each other, and the air inlet space (10a) is opposed to each of the air outlets (25, 35) by the internal air flow (f1, f2). 24) An air curtain device for a cooling chamber in which an external air flow (F1, F2) toward the
Each of the air outlets (25, 35) is formed with a large number of ventilation holes penetrating in the thickness direction, and the center portion in the depth direction is the interior of the casing (21, 31) as compared to both ends. Perforated plates (25a, 35a) formed in a V-shape recessed on the side,
Each of the air blowers (20, 30) is configured such that the air volume of the external air flow (F1, F2) increases stepwise from the vertical center of the ventilation space (10a) upward and downward. A plurality of flow dividing plates (51, 52, 61, 62) for dividing the internal air flows (f1, f2) into a plurality of flows having different flow velocities,
The plurality of flow dividing plates (51, 52, 61, 62) are each formed in a flat plate shape and are arranged at intervals in a direction crossing the internal air flows (f1, f2),
Each of the blower fans (22, 32) is provided so as to blow out air in parallel with the air outlet (25, 35), while the plurality of flow dividing plates (51, 61) include at least each of the blower fans (22 , 32) and the outlet (25, 35),
Between the plurality of flow dividing plates (51, 61) on the blowing side of each of the blower fans (22, 32), the blown air of the blower fans (22, 32) is sent to the outlet ( 25, 35) are provided with rectifying members (27, 37) having a number of air passages that rectify so as to approach
An air curtain device for a cooling chamber.

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