JP7096508B2 - air conditioner - Google Patents

Description

The present invention relates to an air conditioner provided with a heat exchanger inside a housing having an opening for taking in air and a blower for sending out temperature-controlled air by heat exchange.

Generally, in buildings, apartment houses, factories, etc., air conditioners for supplying temperature-controlled air are installed in these indoor spaces. When using such an air conditioner for a relatively large indoor space, does the air conditioner always emit the designed air volume, not to mention the initial operation and test run after the air conditioner is installed? Need to be measured.

Conventionally, some air conditioners are equipped with an anemometer for measuring the air volume inside the housing. For example, in the air conditioner described in Patent Document 1, an anemometer is arranged on an anemometer that communicates with the inside and the outside of the housing, and the amount of air sent from the air conditioner is derived from the wind speed detected by the anemometer. (See Patent Document 1).

Japanese Unexamined Patent Publication No. 9-105549 (Page 3, Fig. 1)

However, the outlet grill on which the anemometer of the air conditioner shown in Patent Document 1 is arranged is formed in a duct shape, and the wind speed distribution inside the grill is not uniform, so that the measurement results vary. , The air volume of the air conditioner passing through the inside of this grill could not be measured accurately. Further, since the wind speed sensor is arranged on the blow-out grill which is the air flow passage, the arranged wind speed sensor itself disturbs the air flow path, and the accurate air volume cannot be measured accurately.

For this reason, workers sometimes entered the air conditioner housing and measured the air volume using a handy type anemometer, but the worker's body affected the air flow inside the housing. Therefore, it was not possible to measure the air volume accurately.

The present invention has been made by paying attention to such a problem, and an object of the present invention is to provide an air conditioner capable of accurately measuring whether or not an air conditioner emits a designed air volume.

In order to solve the above problems, the air conditioner of the present invention is used.
A housing having an opening for introducing air and having an air flow passage formed therein, and air and heat distributed in a duct forming a part of the flow passage in the housing and flowing in the duct. An air conditioner including a heat exchanger that exchanges heat with a medium and a blower that sends out the air heat exchanged by the heat exchanger to the outside of the housing.
Inside the housing, a first recess that communicates with the flow passage on the upstream side of the heat exchanger and projects to the outer peripheral side of the duct in which the heat exchanger is arranged, and the heat exchanger. A second recess that communicates with the flow passage on the downstream side of the water and projects to the outer peripheral side of the duct in which the heat exchanger is arranged is formed.
The air conditioner includes a first pressure detecting unit disposed in the first recess, a second pressure detecting unit disposed in the second recess, a first pressure detecting unit, and the second pressure. It is characterized by including a derivation unit for deriving the air volume sent from the air conditioner based on the differential pressure detected by the detection unit.
According to this feature, since the first recess and the second recess are formed so as to project to the outer peripheral side of the flow passage through which air flows, the wind speed distribution is substantially uniform in the first recess and the second recess. A space is formed, and the first pressure detecting unit and the second pressure detecting unit arranged in the first recess and the second recess detect the pressure in the space where the wind speed distribution is substantially uniform, respectively. Since the outlet can accurately derive the air volume of the air conditioner from the differential pressure, it is possible to accurately measure whether the air conditioner is discharging the designed air volume.

The first pressure detecting unit is a first static pressure detecting unit that detects the static pressure in the first concave portion, and the second pressure detecting unit is a second static pressure detecting unit that detects the static pressure in the second concave portion. It is characterized by being a pressure detection unit.
According to this feature, the accuracy of air volume calculation of the air conditioner can be improved based on the static pressure in the first recess and the second recess detected by the first static pressure detecting unit and the second static pressure detecting unit.

The first recess is characterized in that it is formed on the outer peripheral side of the duct over the entire circumference.
According to this feature, the air in the flow passage before heat exchange temporarily stays in the first recess, so that the air is uniformly sent from the first recess to the heat exchanger on the downstream side. It can be allowed to exchange heat.

The air conditioner is characterized in that an air filter is arranged in a substantially sealed shape on a frame forming a part of the flow passage on the upstream side of the first recess.
According to this feature, since the first recess and the second recess in which the first pressure detection unit and the second pressure detection unit are arranged are both arranged on the downstream side of the air filter, one of them is provided. Only the detection unit is not affected by the clogging of the air filter, and an accurate flow rate can be derived.

The second recess is characterized in that it is formed on the outer peripheral side of the duct over the entire circumference.
According to this feature, the air in the flow passage after heat exchange temporarily stays in the second recess, so that the air can be uniformly sent from the second recess toward the downstream side. ..

The air conditioner is characterized in that a humidifier for humidifying the air flowing through the flow passage is provided on the downstream side of the second recess.
According to this feature, before the heat-exchanged air is humidified by the humidifier, the pressure is detected by the second detection unit arranged in the second recess, so that it is affected by the pressure change of the air due to the humidification. It is possible to derive an accurate flow rate.

The cross-sectional area of the frame in which the air filter is arranged is formed to be larger than the cross-sectional area of the duct in which the heat exchanger is arranged.
According to this feature, the frame in which the air filter is arranged is opened larger than the duct, so even if there is resistance from the air filter, air is stably sent to the heat exchanger side and heat is smoothly generated. Can be exchanged.

The air conditioner is characterized by including a display unit for displaying the air volume derived by the out-licensing unit.
According to this feature, it is possible to easily inform users and managers of the air volume of the air conditioner.

It is a perspective view which shows the air conditioner in Example 1. FIG. (A) shows a partial side sectional view of an air conditioner, and (b) shows a top view. (A) shows an enlarged side sectional view inside the housing, and (b) shows an air flow passage. A cross-sectional view taken along the line AA of the air conditioner is shown. In the modified example of this embodiment, the enlarged side sectional view inside the housing is shown. (A) shows a partial side sectional view of the air conditioner in Example 2, and (b) shows the top view. (A) shows a side sectional view inside a housing, and (b) shows an air flow passage. (A) to (d) show a modification of this invention.

A mode for carrying out the air conditioner according to the present invention will be described below based on examples.

The air conditioner according to the first embodiment will be described with reference to FIGS. 1 to 4. First, reference numeral 1 in FIG. 1 is an air conditioner to which the present invention is applied, which generates and sends out air (air-conditioned air) whose temperature and humidity are adjusted as described later.

As shown in FIG. 1, the air conditioner 1 includes a housing 2 having a substantially rectangular parallelepiped opening 5 having an opening 5 for taking in outside air before air conditioning and an opening 6 (see FIG. 2) for sending out air-conditioned air. ing. The housing 2 is composed of a top plate 2A, side plates 2B, 2B, a back plate 2C, a front plate 2D, and a bottom plate 2E, and has a space inside these plate materials, and each plate excluding the bottom plate 2E. Consists of a sandwich panel in which a heat insulating material such as urethane is sandwiched between two thin plates. Further, the housing 2 is provided with a plurality of doors that communicate with the internal space inside the housing and can be opened and closed.

As shown in FIGS. 2 (a), 2 (b) and 3, the housing 2 has a heat exchanger 7 disposed inside the housing 2 for heat exchange between the refrigerant and air, and the heat exchanger 7 heats up. A humidifier 9 that appropriately humidifies the exchanged air, a blower 8 equipped with a motor 18 that heats and exchanges heat inside the housing 2 and sends the humidified air to the outside of the housing 2, and a first pressure detector. An air volume derived by a pressure gauge 4 having a first detection unit 4A and a second detection unit 4B as a second pressure detection unit, an operation unit 30 that controls the outputs of the motor 18 and the humidifier 9, and a lead-out unit described later. A control unit 3 having a display unit 31 for displaying the above is mainly arranged.

That is, the air conditioner 1 is configured as a unit in which a set of equipment such as the heat exchanger 7, the humidifier 9, and the blower 8 described above is arranged in the housing 2, and the unit is transported and installed at a desired location. At the same time, it will be used by performing plumbing work and wiring work, which will be described later, as incidental work.

Hereinafter, the structure of the air conditioner 1 will be described in detail. As referred to in FIG. 2, the opening 5 side where the air flows in is the left side or the upstream side, and the opening 6 side where the air after heat exchange is sent out is the right side or the downstream side, in order from the upstream side. explain. Further, the flow passage in the first embodiment refers to a main moving passage of air formed between the openings 6 through which the air flows in and the openings 6 through which the air is discharged (see the shaded portion in FIG. 3B). ).

As shown in FIGS. 2A and 2B, the opening 5 as an opening for introducing air is formed on the left side of the drawing of the housing 2 and is arranged on substantially the entire surface of the opening surface. The inside and outside of the housing 2 are communicated with each other through the filter 5a. A duct (not shown) is connected to the opening 5 from the outside so as to take in air such as outside air before air conditioning into the housing.

As shown in FIG. 2B, the inside of the housing 2 communicating with the opening 5 is composed of an inner surface of the housing 2, a back plate 3a of the control unit 3, and a front surface of an air filter 12 described later. Space S1 is formed. The air that has flowed into the housing 2 from the opening 5 first flows into the space S1.

On the downstream side of the space S1, the air filter 12 is arranged fixedly over the entire circumference on a short tubular frame 21 having a substantially rectangular cross-sectional view and extending in the left-right direction in the drawing. The frame 21 is installed vertically and horizontally apart from the inner surface of the housing 2. Further, the air filter 12 is arranged to remove particles such as dust in the air flowing in from the opening 5, and is formed on a substantially rectangular aluminum frame 12b assembled to the frame 21 with a synthetic fiber non-woven fabric. Alternatively, a glass fiber filter medium 12a is stretched and formed. The cross-sectional direction here refers to a direction orthogonal to the left-right direction of the paper surface through which the air in the housing 2 flows. Therefore, the air in the space S1 passes through the air filter 12, particles in the air are removed, and further passes through the frame 21.

As shown in FIGS. 2A and 3, on the downstream side of the frame 21 in which the air filter 12 is arranged, a large opening is made in the vertical and horizontal directions from the frame 21 and the upstream side. A short tubular outer portion 22a extending from the outer portion 22a to the downstream side, a front side portion 22b extending inward from the upstream end portion of the outer portion 22a, and a downstream end portion of the outer portion 22a to the housing 2. A first bulging duct 22 is provided, which is composed of a rear side portion 22c extending inward and is open in the air flow direction. As shown in FIGS. 2 (a) and 2 (b) and FIG. 3, the first bulging duct 22 is arranged over the entire circumference of the space S1 of the housing 2, and the outer side portion 22a, described above. A substantially U-shaped cross-sectional shape opened toward the inside of the housing 2 by the front side portion 22b and the rear side portion 22c is uniformly formed over the entire circumference. Further, the outer surface of the outer surface 22a of the first bulging duct 22 is formed on the inner surface of the top plate 2A, the side plate 2B, the back plate 2C, the bottom plate 2E, and the back plate 3a of the control unit 3 constituting the space S1 of the housing 2. It is fixed in contact with the entire circumference. Further, the upstream front side portion 22b extending from the outer side portion 22a of the first bulging duct 22 to the inward side of the housing 2 divides the space S1 and the space S2 on the downstream side thereof, which will be described later, in a sealed manner. Further, the downstream rear side portion 22c extending from the outer side portion 22a to the inward side of the housing 2 further seals the space S2 and the space S3'described later on the downstream side thereof.

Further, the frame body 21 described above has one end fixedly connected to the front surface of the front side portion 22b by welding or the like, and is arranged toward the upstream side from the front side portion 22b. A space S2 having a lower pressure than the space S1 is formed on the inner side of the frame 21 and the inner side of the first bulging duct 22 from the downstream side on the rear surface side of the air filter 12. Further, since the first bulging duct 22 is larger than the frame 21 and is arranged close to the inner surface side of the housing 2, it bulges outward from the frame 21 in the space S2. The space N as the first recess is formed over the entire circumference of the inner surface side of the housing 2.

As shown in FIG. 3, the downstream rear side portion 22c extending from the outer portion 22a of the first bulging duct 22 toward the flow passage side extends inwardly of the housing 2 with respect to the above-mentioned front side portion 22b. It is formed. A short tubular duct 23 extending in the direction of the opening 6 on the downstream side is fixedly connected to the inner end of the rear side portion 22c by welding or the like.

A heat exchanger 7 is arranged inside the duct 23. As shown in FIG. 4, the heat exchanger 7 penetrates the fin group F in which a plurality of thin plate-shaped metal plates are arranged in parallel with a gap through which air flows in the flow path direction, and the fin group F. It is mainly composed of a heat transfer tube 17 through which a refrigerant flows, and an expansion valve (not shown) for reducing the pressure of the refrigerant. Further, the heat transfer tube 17 penetrates a hole formed in the housing 2, and both ends 7a and 7b thereof are arranged outside the housing 2 and communicate with a refrigerant pipe (not shown). Further, a refrigerant compressed by a compressor (not shown) arranged outside the housing 2 is supplied from the end portion 7a to the heat exchanger 7 via the above-mentioned refrigerant pipe, and is heat-exchanged with air by the heat exchanger 7. The refrigerant is discharged from the end portion 7b to the compressor so that the refrigerant circulates. In this embodiment, a refrigerant (R410A) is applied as a kind of heat medium, but it can be applied not only to other alternative CFCs, refrigerants such as ammonia and carbon dioxide, but also to all heat media such as water and brine.

As shown in FIGS. 2 (a) and 2 (b) and FIG. 3, on the downstream side of the duct 23 in which the heat exchanger 7 is arranged, in the vertical and horizontal directions from the duct 23 and the frame 21. A short tubular outer portion 24a that is large and opens smaller than the outer portion 22a of the first bulging duct 22 and extends from the upstream side to the downstream side, and the housing 2 from the upstream end portion of the outer portion 24a. A second bulging duct 24 consisting of a front side portion 24b extending inward and a rear side portion 24c extending inward from the downstream end portion of the outer portion 24a to the inward side of the housing 2, and the air flow passage side is open. Are arranged. Further, in the second bulging duct 24, the inner end portion of the front side portion 24b is fixedly arranged with the downstream end portion of the duct 23 by welding or the like. As shown in FIGS. 2A, 2B and 3, the second bulging duct 24 is opened toward the inside of the housing 2 by the outer side portion 24a, the front side portion 24b and the rear side portion 24c described above. The substantially U-shaped cross-sectional shape is uniformly formed over the entire circumference. Further, the outer side portion 24a, the front side portion 24b, and the rear side portion 24c of the second bulging duct 24 separately partition the inner space S3 and the space S3'described later in a sealed manner. A space S3 having a lower pressure than the space S2 is formed from the inner side of the second swelling duct 24, which is the downstream side of the heat exchanger 7, and the upstream side of the humidifier 9, which will be described later. In this way, the air after heat exchange passes through the space S3 defined by the second swelling duct 24.

Further, since the second bulging duct 24 is larger than the duct 23 and is formed so as to extend toward the top plate 2A of the housing 2 and the side plate 2B on one side, the second bulging duct 24 is formed in the space S3 more than the duct 23. A space M is formed as a second recess that bulges outward. In the present embodiment, as shown in FIG. 2A, a space that bulges only on the top plate 2A of the housing 2 and the side surface plate 2B on one side is formed. However, the present invention is not limited to this, and may be formed over the entire circumference of the housing 2.

As shown in FIGS. 2A and 3A, a short tubular frame 25 having a substantially rectangular cross section is fixedly connected to the downstream side of the second bulging duct 24 by welding or the like. ing. A humidifier 9 is disposed inside the frame 25. The humidifier 9 is composed of a water supply pipe 9a for humidifying the air exchanged by the heat exchanger 7, and is a casing. The water supplied to the water supply pipe 9a that communicates with the inside and outside of the body 2 is sprayed to the heat exchanger 7 side from a plurality of spray ports 9b, ... It has become.

On the downstream side of the humidifier 9, a space S3'composed of an upper surface 2A, side plates 2B, 2B, front plate 2D, bottom surface 2E of the housing 2 and a rear side portion 22c of the first bulging duct 22 is formed. Has been done. The space S3'is a space having substantially the same pressure as the space S3 before humidification but having a slightly different pressure, and the air humidified by the humidifier 9 is discharged into the space S3'.

A part of the bottom plate 2E provided at the lowermost part of the space S2 of the housing 2 is configured as a drain pan 10. The drain pan 10 is formed with a concave tapered surface whose bottom is the lowest in the central portion in the left-right direction in the drawing, and rainwater or rainwater flowing into the housing 2 with the intake air taken into the space S1 from the opening 5 Condensed water, water generated by heat exchange in the heat exchanger 7, and water sprayed from the humidifier 9 can be received as drain water.

Further, a drain port 10a that communicates the lowest bottom portion of the drain pan 10 with the outside of the housing 2 is formed in the lower part of the front surface of the housing 2, and as will be described later, incidental work is performed when installing the air conditioner 1. Therefore, it is necessary to sequentially connect a drain pipe and a drain trap to the drain port 10a, and to connect the drain trap to a drain pipe such as a sewer pipe.

As shown in FIGS. 2A and 2B, a blower 8 having a motor 18 arranged on the bottom plate 2E as a drive source is arranged in the space S3'on the downstream side. The blower 8 of the present embodiment is a sirocco fan in which vertically elongated plate-shaped blades are attached in a cylindrical shape, and a motor 18 is driven to rotate an impeller (not shown) in the space S3'. The air is sent out toward the outside of the housing 2 through the opening 6 formed in the front plate 2D of the housing 2.

That is, inside the housing 2, a space S1 formed by the inner surface of the housing 2, the front side portion 22b of the first bulging duct, and the upstream side of the air filter 12, and the frame 21 from the downstream side of the air filter 12 And the space S2 formed on the inner side of the first swelling duct 22 from the downstream side of the heat exchanger 7 to the upstream side, and the humidifier on the inner side of the second swelling duct 24 from the downstream side of the heat exchanger 7. It is defined as a space S3 formed on the upstream side of the humidifier 9 and a space S3'formed by the inner surface of the housing 2 and the rear side portion 22c of the first bulging duct from the downstream side of the humidifier 9. In addition, the spaces S1, S2, S3 and S3'are in a communicative state in the order of air circulation. Further, the space S1 and the space S2 are partitioned before and after the front side portion 22b, and the space S2 and the space S3'are partitioned before and after the rear side portion 22c. As a result, the air that has flowed into the space S1 of the housing 2 through the opening 5 passes through the air filter 12 and flows into the space S2, and the air in the space S2 moves toward the downstream side, thereby causing the heat exchanger. After the heat is exchanged in 7, the air flows into the space S3, and the air in the space S3 moves toward the downstream side, and as it passes through the humidifier 9, it is humidified and flows into the space S3'. There is.

Further, as shown in FIGS. 2 (a) and 2 (b) and FIG. 3, a pressure gauge 4 is arranged in the space N that bulges toward the inner surface side of the housing 2 from the frame body 21 in the space S2. Has been done. The pressure gauge 4 is fixedly arranged on the back plate 3a of the control unit 3, and is electrically connected to a lead-out unit (not shown) arranged in the control unit 3.

The pressure gauge 4 includes two tubes C1 and C2 for air extending from the pressure gauge 4, and the opening at the tip of the tube C1 is a first detection unit that detects static pressure. It is arranged as a part 4A, and the tip opening of the tube C2 is arranged as a second detection part 4B which is a second static pressure detecting part for detecting the static pressure. The pressure gauge 4 takes in the air of the pressure in the space N through the first detection unit 4A, and also takes in the air of the pressure in the space M through the second detection unit 4B, and outputs the data of the differential pressure of these pressures. As a signal, it is transmitted to a derivation unit in the control unit 3. Further, the lead-out unit in the control unit 3 is from the air conditioner 1 based on the differential pressure between the pressure (static pressure) detected by the first detection unit 4A and the pressure (static pressure) detected by the second detection unit 4B. The amount of air sent out (the amount of air per unit time) is derived.

As shown in FIG. 3A, the tube C1 extending from the pressure gauge 4 is arranged in the space N in the first bulging duct 22, and the first detection unit 4A which is the tip opening thereof is arranged. The air in the space N is taken into the pressure gauge 4 through the space N. Further, the tube C2 extending from the pressure gauge 4 is hermetically inserted into the through hole 22d formed in the rear side portion 22c of the first bulging duct 22, and further inserted into the front side portion 24b of the second bulging duct 24. It is hermetically inserted into the formed through hole 24d, arranged in the space M in the second bulging duct 24, and the air in the space M is pressure gauged through the second detection unit 4B which is the tip opening thereof. It is incorporated in 4 to detect the differential pressure of these pressures. A grommet (not shown) is fitted in the through hole 22d and the through hole 24d to prevent the tube C2 from being worn and to prevent the air in the space S2 from leaking to the space N and the space M side. ..

As shown in FIG. 3B, the opening area of the frame 21 in which the air filter is arranged is formed to be larger than the opening area of the duct 23 in which the heat exchanger 7 is arranged. The air in the space S1 is smoothly moved toward the space S3 side through the space S2. As a result, an air flow path R is generated from the opening surface of the frame 21 through the opening surface of the duct 23, and the space N and the space N projecting from the flow path R toward the outer peripheral side in the housing 2 In the space M, air is difficult to flow and is in a stagnant state, and is formed as a space in which stable static pressure can be detected.

The first detection unit 4A arranged in the space N and the second detection unit 4B arranged in the space M project to the outer peripheral side of the flow passage R, so that air does not easily flow and stays. Since the pressure can be detected in the space, that is, in the space of stable static pressure where dynamic pressure is unlikely to occur, the derivation unit in the control unit 3 is the static pressure detected by the first detection unit 4A and the second detection unit. The surface wind velocity of the heat exchanger 7 is calculated based on the differential pressure from the static pressure detected by 4B, and the air volume of the air conditioner 1 is accurately derived by multiplying the surface wind velocity by the ventilation area of the heat exchanger 7. You can do it. The relationship between the differential pressure of static pressure and the surface wind speed of the heat exchanger 7 is the tube diameter, tube pitch, fin thickness, fin pitch, fin shape, tube row pitch, number of tube rows, etc. of the members constituting the heat exchanger 7. Because it is affected by the structural conditions of the above and the operating conditions such as cooling / heating, the relationship between the static pressure difference of the heat exchanger 7 of the air exchanger 1 and the surface wind speed of the heat exchanger 7 and heat in advance. The ventilation area of the exchanger 7 is input to the lead-out unit in the control unit 3. Further, by displaying the air volume derived by the out-licensing unit on the display unit 31 arranged on the side plate 2B of the housing 2, the administrator or the user can easily check the air volume of the air conditioner 1. You can do it.

Further, in this embodiment, the second detection unit 4B is arranged in the space M in the space S3 to detect the pressure, but the present invention is not limited to this, and the rear side portion 22c forming the first bulging duct 22 is not limited to this. The tube C2 may be inserted through the through hole 22d of the above, and the second detection unit 4B may be arranged in the space S3'to detect the pressure in the space S3'. However, since the pressure of the humidified air that has passed through the humidifier 9 is detected, the detection blur and the pressure difference between before and after humidification will occur as compared with the detection in the space M in the space S3. 2 It is preferable that the detection unit 4B is arranged in the space M in the space S3 to detect the static pressure.

As a modification of this embodiment, for example, as shown in FIG. 5, a plate material 27 having a small hole 27a communicating these is arranged between the space N in which the first detection unit 4A is arranged and the space S2. At the same time, a plate material 28 having a small hole 28a communicating these may be arranged between the space M in which the second detection unit 4B is arranged and the space S3. By doing so, the dynamic pressure generated in the space N and the space M can be reliably reduced, and the static pressure in the space N and the space M can be detected with high accuracy.

Next, the second embodiment of the air conditioner according to the present invention will be described with reference to FIGS. 6 (a), 6 (b) and 7. The same components as those shown in the first embodiment are designated by the same reference numerals, and duplicate description will be omitted.

FIG. 6A shows a partial side sectional view of the air conditioner 11 in the second embodiment. The air conditioner 11 has a structure in which the humidifier, the frame for arranging the humidifier, and the second bulging duct are omitted from the air conditioner 1 of the first embodiment described above.

As shown in FIGS. 6A and 6B, the air conditioner 11 in the second embodiment is formed from the downstream side of the opening 5 to the upstream side of the air filter 12, and is formed on the inner surface of the housing 2 and the control unit. Space S1 formed by the back plate 3a of 3 and the upstream side of the air filter 12, and upstream of the heat exchanger 7 on the inner side of the frame 21 and the first bulging duct 22 from the downstream side of the air filter 12. It is defined as a space S2 formed on the side and a space S4 formed by the inner surface of the housing 2 and the rear side portion 22c of the first bulging duct 22 from the downstream side of the heat exchanger 7 to the opening 6. Has been done. Further, in the space S4, a space L is formed as a second recess that bulges outward from the duct 23.

As shown in FIG. 7, a pressure gauge 4 is arranged in the space N that bulges toward the inner surface side of the housing 2 from the frame body 21 in the space S2. The tube C1 extending from the pressure gauge 4 is arranged in the space N in the first bulging duct 22, and the air in the space N is introduced into the pressure gauge 4 through the first detection unit 4A which is the tip opening thereof. It is designed to be incorporated into. Further, the tube C2 extending from the pressure gauge 4 is hermetically inserted into a through hole 22d formed in the rear side portion 22c of the first bulging duct 22, and is arranged in the space L in the space S4. , The air in the space L is taken into the pressure gauge 4 through the second detection unit 4B which is the tip opening thereof, the pressure gauge 4 detects the differential pressure between the space N and the space M, and the outlet unit in the control unit 3 It is designed to transmit electrically.

The space L in the space S4 is a space that overhangs the outer peripheral side in the housing 2 from the air flow passage R, and a space is formed in which air is difficult to flow and stable static pressure can be detected. It has become like.

That is, the first detection unit 4A arranged in the space N and the second detection unit 4B arranged in the space L project to the outer peripheral side of the flow passage R, so that it is difficult for air to flow. Since the pressure can be detected in the stagnant space, that is, in the stable static pressure space where dynamic pressure is unlikely to occur, the derivation unit in the control unit 3 detects the pressure detected by the first detection unit 4A and the second detection unit. Based on the differential pressure of the pressure detected by 4B, the air volume of the air conditioner 1 can be accurately derived.

In this way, it is arranged in the housing 2 having the opening 5 for introducing air and forming the flow passage R through which the air flows, and the duct 23 forming a part of the flow passage R in the housing 2. An air conditioner provided with a heat exchanger 7 that exchanges heat between the air flowing in the duct 23 and a heat medium, and a blower 8 that sends out the air exchanged by the heat exchanger 7 to the outside of the housing. No. 1, in the housing 2, the first one that communicates with the flow passage R on the upstream side of the heat exchanger 7 and projects to the outer peripheral side of the duct 23 in which the heat exchanger 7 is arranged. The space N as a recess and the space M as a second recess that communicates with the flow passage R on the downstream side of the heat exchanger 7 and projects to the outer peripheral side of the duct 23 in which the heat exchanger 7 is arranged. , And the air conditioner 1 has a first detection unit 4A arranged in the space N, a second detection unit 4B arranged in the space M, a first detection unit 4A, and a second. Since the space N and the space M are provided with a derivation unit for deriving the air volume sent from the air conditioner 1 based on the differential pressure detected by the detection unit 4B, the space N and the space M are located on the outer peripheral side of the flow passage R through which air flows. Since it is formed overhanging, a space having a substantially uniform wind velocity distribution is formed in the space N and the space M, and the first detection unit 4A arranged in the space N and the space M is formed. Since the second detection unit 4B can detect the pressure in the space where the wind velocity distribution is substantially uniform, the derivation unit can accurately derive the air volume of the air conditioner 1 from the differential pressure, so that the air conditioner 1 is designed. It is possible to accurately measure whether or not the air volume is being discharged.

Further, the accuracy of air volume calculation of the air conditioner 1 can be improved based on the static pressures of the space N and the space M detected by the first detection unit 4A and the second detection unit 4B.

Further, since the space N is formed on the outer peripheral side of the duct 23 over the entire circumference, the air in the flow passage R before heat exchange temporarily stays in the space N, and from the space N. Air can be uniformly sent to the heat exchanger 7 on the downstream side to exchange heat.

Further, in the air conditioner 1, since the air filter 12 is arranged in a substantially sealed shape on the frame 21 forming a part of the flow passage R on the upstream side of the space N, the first detection unit 4A and the first 2 Since the space N and the space M in which the detection unit 4B is arranged are both arranged on the downstream side of the air filter 12, only one of the detection units is affected by the clogging of the air filter 12. Accurate flow rate can be derived without any problem.

Further, the space M may be formed on the outer peripheral side of the duct 23 over the entire circumference, and the air in the flow passage R after heat exchange temporarily stays in the space M, so that the space M is temporarily retained. Air can be uniformly sent from the to the downstream side.

Further, since the air conditioner 1 is provided with a humidifier 9 for humidifying the air flowing through the flow passage R on the downstream side of the space M, before the heat exchanged air is humidified by the humidifier 9. In addition, since the pressure is detected by the second detection unit 4B arranged in the space M, it is possible to derive an accurate flow rate without being affected by the change in air pressure due to humidification.

Further, since the cross-sectional area of the frame 21 in which the air filter 12 is arranged is formed to be larger than the cross-sectional area of the duct 23 in which the heat exchanger 7 is arranged, there is resistance due to the air filter 12. It is also possible to stably send air to the heat exchanger 7 side and smoothly exchange heat.

Further, since the air conditioner 1 includes a display unit 31 that displays the air volume derived by the out-licensing unit, the air volume of the air conditioner 1 can be easily made known to users and managers.

Although examples of the present invention have been described above with reference to the drawings, the specific configuration is not limited to these examples, and any changes or additions that do not deviate from the gist of the present invention are included in the present invention. Will be.

For example, the arrangement position of the duct 23 may be moved to the upstream side. For example, as in the modification shown in FIG. 8A, the end of the rear side portion 22c of the first bulging duct 22 is the duct 23. Welding may be performed at a substantially central position in the front-rear direction on the outer peripheral side of the above.

Further, as in the modified example shown in FIG. 8B, the outer side portion 122a of the first bulging duct 122 is extended in the front-rear direction of the housing 2, and the rear side portion 122c of the first bulging duct 122 is ducted. It may be welded to the downstream end of 23.

Further, as in the modified example shown in FIG. 8 (c), the pressure gauge 4 is arranged outside the housing of the housing 2, and the through hole 2x that communicates the outside of the housing and the space N in a sealed manner and the housing. A through hole 2x'that communicates the outside of the body and the space L in a sealed manner may be provided, the first detection unit 4A may be arranged in the space N, and the second detection unit 4B may be arranged in the space L.

Further, as in the modified example shown in FIG. 8D, the pressure gauge 4 is moved from the space N in the first swelling duct 22 into the space L, and the tube C1 is extended from the space L toward the space N. The first detection unit 4A, which is the opening at the tip thereof, may be arranged in the space N, and the second detection unit 4B may be arranged in the space L.

Further, the pressure gauge 4 of this embodiment takes in the air in the space N from the first detection unit 4A, takes in the air in the space M from the second detection unit 4B, and controls the data of the differential pressure of these pressures. It is designed to electrically transmit to the lead-out unit in the unit 3, but the present invention is not limited to this. For example, two cords are extended from the pressure gauge instead of the tube, and the first detection unit at the tip of one of the cords is extended. 4A detects the pressure in the space N, the second detection unit 4B at the tip of the other cord detects the pressure in the space M, the pressure gauge 4 derives the difference between the respective pressures, and the control unit 3 receives the difference. You may send it.

1 Air conditioner 2 Housing 3 Control unit 4 Pressure gauge 4A 1st detection unit (1st static pressure detection unit)
4B 2nd detection unit (2nd static pressure detection unit)
5 Opening 6 Opening 7 Heat exchanger 8 Blower 9 Humidifier 9a Water supply pipe 9b Spray port 10 Drain pan 11 Air conditioner 12 Air filter 18 Motor 21 Frame 22 1st bulging duct 23 Duct 24 2nd bulging duct 25 Frame Body 31 Display unit N space (first recess)
M space (second recess)
L space (second recess)
R flow passage

Claims (6)

A housing having an opening for introducing air and having an air flow passage formed therein, and air and heat distributed in a duct forming a part of the flow passage in the housing and flowing in the duct. An air conditioner including a heat exchanger that exchanges heat with a medium and a blower that sends out the air heat exchanged by the heat exchanger to the outside of the housing.
Inside the housing, it communicates with the flow passage on the upstream side of the heat exchanger and extends in the flow direction, and all around the outer periphery of the duct in which the heat exchanger is arranged. The first bulging duct that overhangs and communicates with the flow passage on the downstream side of the heat exchanger and extends in the flow direction, and is the outer periphery of the duct in which the heat exchanger is arranged. A second bulging duct that overhangs the entire circumference is formed on the side.
The air conditioner includes a first pressure detecting unit arranged in the first bulging duct , a second pressure detecting unit arranged in the second swelling duct , and the first pressure detecting unit. An air conditioner comprising: a lead-out unit for deriving an air volume sent from the air conditioner based on a differential pressure detected by the second pressure detection unit. The first pressure detecting unit is a first static pressure detecting unit that detects the static pressure in the first swelling duct , and the second pressure detecting unit detects the static pressure in the second swelling duct . The air conditioner according to claim 1, wherein the air conditioner is a second static pressure detecting unit. Claim 1 or 2 of the air conditioner is characterized in that an air filter is arranged in a substantially sealed shape on a frame constituting a part of the flow passage on the upstream side of the first bulging duct . The air conditioner described in. The invention according to any one of claims 1 to 3 , wherein the air conditioner is provided with a humidifier for humidifying the air flowing through the flow passage on the downstream side of the second swelling duct . air conditioner. The air conditioner according to claim 3 , wherein the cross-sectional area of the frame body in which the air filter is arranged is formed to be larger than the cross-sectional area of the duct in which the heat exchanger is arranged. The air conditioner according to any one of claims 1 to 5 , wherein the air conditioner includes a display unit for displaying the air volume derived by the out-licensing unit.

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