KR102260546B1 - distribution-type cold-temperature wind multi-stage duct - Google Patents

Abstract

The present invention relates to a distribution-type multistage cold and warm wind duct, which is connected to an air outlet port (HA) of a heating and cooling device (H) used to control the indoor temperature of a facility such as a plastic greenhouse in which crops (F) are cultivated, so as to evenly deliver cold and warm air to the indoors and equalize a temperature and an air volume of cold and warm air coming out from air outlet ports of ducts located near and far from the heating and cooling device (H), thereby providing an indoor environment which is good for the crops to grow. More specifically, the present invention comprises: a duct part (10) of which cold and warm air coming out from an air outlet port (HA) of a heating and cooling device (H) passes through an inside passage so as to be discharged to the indoors; a distribution pipe (20) which is made of a rigid material with a cross section having a shape corresponding to that of a duct outlet provided in an end of the duct part (10) in a direction in which the heating and cooling device (H) is located; and a sagging preventing part (30) which is connected to an upper portion of the duct part (10) and is configured to prevent the duct part (10) from sagging.

Description

Distribution-type cold-temperature wind multi-stage duct

The present invention relates to a facility such as a plastic house for growing crops (F) and a heating/cooling device (H) for controlling the indoor temperature, it is connected to the air outlet (HA) of the air-conditioning device (H) to evenly deliver hot and cold air to the room, , It relates to a distribution-type cold and hot air multi-stage duct that provides a good indoor environment for crops to grow by equalizing the temperature and air volume of the cold and hot air coming out of the ducts located near and far from the air conditioner (H).

In general, in crop cultivation facilities such as plastic greenhouses, a cooling and heating system is installed to provide an environment with an optimal temperature for crops to grow in summer or winter, and a duct is used to evenly deliver cold and hot air from the air conditioning system to the room. .

When cold and hot air passes through the duct, heat loss occurs through the duct surface as the distance from the air conditioner increases, resulting in a large temperature difference between the area near and far from the air conditioner in the duct, and unevenness of crop growth This causes the quality to deteriorate and productivity to decrease. Therefore, in order to control the temperature far away from the heating and cooling device, the output of the heating and cooling device must be increased, thereby increasing the maintenance cost.

As an example of a technique for improving the above problems, Korean Patent No. 20-0344742 "double duct for a warm air heater" is disclosed.

This technology consists of an outer duct having a discharge port at regular intervals and an inner duct having discharge ports at regular intervals, so that the warm air generated by the warm air heater is transmitted to the outside through the inner and outer ducts. A technique for reducing the temperature difference between the hot air coming from the outlet near the heater and the outlet far away was presented.

However, this technology reduces the temperature difference between the hot air coming from the outlet near and far from the hot air heater by blocking the hot air from the inner duct at the outer duct by constructing a double duct. Because the hot air is blocked by the external duct, the speed of the cold and hot air coming out of the outlet of the external duct is reduced, and there is a risk that the heat may not be evenly transferred to the room as the warm air is not spread far away.

As another example of a technique for improving the above problems, Korean Patent Publication No. 10-2017854 "return type double duct type cold and hot air circulation system" is disclosed.

The technology consists of a double structure of an inner tube and an outer tube, and the hot and cold air generated by the cold and hot air blower passes through the inner tube and moves in the reverse direction between the inner and outer tubes at the end, and passes through the cold and hot air outlet of the outer tube to the outside. A technique for reducing the temperature difference between the cold and hot air discharged from the cold and hot air outlets near and far from the cold and hot air fan is proposed through heat exchange between the air in the inner and outer tubes.

However, in this technology, in order to help the cold and hot air generated from the cold and hot air blower pass through the inner tube and move in the reverse direction between the inner tube and the outer tube at the end, a blower that blows wind in the reverse direction is configured, and the wind and cold and temperature of the blower There is a possibility that the temperature of the cold and hot air is neutralized in the direction of room temperature due to the mixing of the wind. In addition, in an embodiment without a corresponding blower, as the flow direction of the cold and hot air is bent by 180 degrees, the speed of the cold and hot air is lowered, the force propagating to the outside is weakened, and consequently, inefficiency in which heat is not evenly transmitted to the room may occur.

Republic of Korea Patent Publication No. 20-0344742 "Double duct for hot air heater" Republic of Korea Patent Publication No. 10-2017854 "Return type double duct type cold and hot air circulation system"

The present invention was created to more actively solve the above problems, and in a distribution-type cold and hot air multi-stage duct of a crop cultivation facility such as a plastic house, the temperature of the cold and hot air coming from the vents near and far from the air conditioning system The main challenge is to provide technology that can minimize the difference.

In addition, another solution is to provide a technology that minimizes heat loss inside the duct by configuring multiple ducts and at the same time does not reduce the speed due to the cold and hot air coming out of the ventilation hole being blocked by the external duct.

In addition, it is another solution to provide a technology that not only minimizes the temperature difference between the cold and hot air coming from the ventilation holes near and far from the air conditioning system, but also distributes the heat energy to the room by evenly distributing the air volume to be.

The configuration of the distribution-type cold and hot air multi-stage duct proposed in the present invention in order to achieve the above-mentioned problem is as follows.

The distribution-type cold and hot air multi-stage duct of the present invention receives the hot and cold air generated from the vent (HA) of the air-conditioning device (H) in a facility such as a plastic house for growing crops (F) and supplies it indoors. In the duct, the end of the duct part 10 in the direction in which the cooling and heating device (H) is located; and the duct part (10) through which cold and hot air from the air outlet (HA) of the air conditioner (H) is discharged into the room through the internal passage. A distribution pipe 20 made of a rigid body having a duct inlet-shaped cross-section provided in the; and an anti-sag portion 30 for preventing the duct portion 10 from sagging by combining with the upper portion of the duct portion 10; characterized by including.

In addition, the duct part 10 is a first duct 11 having a cross section of a size and shape corresponding to the air outlet HA of the air conditioning unit H and a diameter of one to one; and the first duct 11 . A second duct having the same cross-section and shape but a smaller diameter, located inside the first duct 11, and extending from the first duct 11 by the length of the first duct 11 ( 12); and the cross section and shape of the second duct 12 are the same, but have a smaller diameter, are located inside the second duct 12, and the second duct (11) by the length of the first duct (11) 12) is configured to extend from the third duct (13); characterized in that it comprises a.

In addition, the first duct 11 is formed with a plurality of first vents 11a at regular intervals on the side surface, and the second duct 12 has a plurality of second vents 12a on the side surface at regular intervals. And, the third duct 13 is characterized in that a plurality of third ventilation holes (13a) are formed at regular intervals on the side.

In addition, the first duct 11 has a first extension duct 11 ′ is formed on the side surface at regular intervals, and a plurality of first vent holes 11 a are formed on the side surface of the first extension duct 11 ′ at regular intervals. The second duct 12 is formed with second extension ducts 12' formed at regular intervals on the side surface, and a plurality of second vents 12a at regular intervals on the side surface of the second extension duct 12'. is formed, and the third duct 13 has third extension ducts 13' formed at regular intervals on the side surface, and a plurality of third vent holes 13a at regular intervals on the side surface of the third extension duct 13'. ) is formed.

In addition, the second vent 12a is larger than the first vent 11a, and the third vent 13a is formed to be larger than the second vent 12a.

In addition, a first cross-sectional area M11 excluding the inner cross-sectional area of the second duct 12 from the inner cross-sectional area of the first duct 11 and. a second cross-sectional area M12 excluding the inner cross-sectional area of the third duct 13 from the inner cross-sectional area of the second duct 12; It is characterized in that the size of the third cross-sectional area (M13) of the internal cross-sectional area of the third duct (13) is the same.

In addition, the first to third ducts 11, 12, 13 are composed of a double structure of an outer vinyl (o) and an inner vinyl (i), and have a set interval between the outer vinyl (o) and the inner vinyl (i). It is characterized in that a plurality of straight wires (w) are configured in the longitudinal direction of the first to third ducts (11, 12, 13).

In addition, the first to third ducts 11, 12, 13 are characterized in that a plurality of wire connectors (h) are formed on the outer vinyl (o).

In addition, the anti-sag portion 30 is a pulley 31 configured in a plurality on the upper portion of the duct portion 10; and a tension wire 32 configured to span half a turn of the pulley 31; and the tension wire ( A turnbuckle 33 for adjusting the tension of the tension wire 32 in a screw tightening manner by combining both ends of the 32) in a ring fashion; and a vertical wire 34 configured in a plurality by being hung over the tension wire 32 in a ring manner ); characterized in that it can be configured to include.

In addition, an oval-shaped ring (34a) is configured at the end of the vertical wire (34), and the ring (34a) passes through the wire connector (h), characterized in that it spans the wire (w) therein.

The anti-sag portion 30 is a turnbuckle (33') attached to a plurality of structures (Z) of the facility; and a tension wire (32') coupled in a ring shape between the turnbuckle (33'); and the tension wire It is characterized in that it can be configured to include a; vertical wire 34 configured in a plurality of loops over (32').

According to the invention of the ball consisting of the above configuration,

By configuring the duct part 10 in multiple stages, the air with low thermal conductivity serves as a thermal insulation material, thereby minimizing the heat loss of the cold and hot air in the duct, and the temperature of the cold and hot air coming out of the vents near and far from the air conditioner. This has the effect of minimizing the difference.

In addition, the duct part has a multi-stage structure to reduce the heat loss of the cold and hot air, and has a structure without obstacles outside the vent through which the cold and hot air comes out, so that the speed of the cold and hot air from the vent does not decrease, so that the heat energy is transferred from the duct to the room away from the duct. can have an effect.

In addition, the first to third extension ducts (11', 12', 13') are additionally configured on the side surfaces of the first to third ducts (11, 12, 13) and provided in close proximity to the crop (F), There is an effect that can minimize the heat loss that occurs as the cold and hot air moves to the crop (F).

1 is a perspective view of a distribution type cold and hot air multi-stage duct constructed according to a preferred embodiment of the present invention.
Fig. 2 is a perspective view seen from another direction of Fig. 1;
Figure 3 is a state diagram of the use of the distribution type cold and hot air multi-stage duct constructed according to a preferred embodiment of the present invention.
Figure 4 is a cross-sectional view of the distribution type cold and hot air multi-stage duct constructed according to a preferred embodiment of the present invention.
5 is a perspective view of the distribution pipe 20 proposed by the present invention.
6 is a cross-sectional view taken from A to A' in FIG. 4;
7 is a perspective cross-sectional view showing the coupling relationship between the first to third ducts 11, 12, 13 and the vertical wire 34 presented in the present invention.
Fig. 8 is an enlarged view of B in Fig. 4;
9 is an enlarged view of B in FIG. 4 in a state in which the insulating material 13d is configured on the outer circumferential surface of the third duct 13 according to another embodiment of the present invention.
10 is a perspective view of a state in which the cap 13b and the peninsula 13c are not formed at the end of the third duct 13 according to another embodiment of the present invention.
11 is a perspective view of a state in which a ring (r) and a fixing member (s) are configured on the outer peripheral surfaces of the first to third ducts 11, 12, and 13 according to another embodiment of the present invention.
12 is a state diagram of a distribution type cold/hot air multi-stage duct configured by adding first to third extension ducts 11', 12', and 13' according to another embodiment of the present invention.
13 is a state diagram of a distribution type cold/hot air multi-stage duct configured without a pulley 31 in the anti-sag unit 30 according to another embodiment of the present invention.

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

Advantages and features of the present invention, and a method for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only this embodiment serves to complete the disclosure of the present invention, and common knowledge in the technical field to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. In addition, the same reference numerals refer to the same components throughout the specification.

The present invention is disclosed with respect to a distribution-type cold and hot air multi-stage duct.

(Example 1)

1 is a perspective view of a distribution-type cold/hot air multi-stage duct constructed according to a preferred embodiment of the present invention, FIG. 2 is a perspective view viewed from the other direction of FIG. 1, and FIG. 3 is a distribution constructed according to a preferred embodiment of the present invention. 4 is a cross-sectional view of a distribution type cold/hot air multi-stage duct constructed according to a preferred embodiment of the present invention, and FIG. 5 is a perspective view of the distribution pipe 20 proposed by the present invention, 6 is a cross-sectional view from A to A' in FIG. 4, and FIG. 7 is a perspective cross-sectional view showing the coupling relationship between the first to third ducts 11, 12, 13 and the vertical wire 34 presented in the present invention. , FIG. 8 is an enlarged view of B in FIG. 4 .

1 to 8, the distribution-type cold and hot air multi-stage duct of the present invention accommodates the cold and hot air generated from the air outlet (HA) of the air conditioning unit (H) in a facility such as a plastic house where crops (F) are grown to receive indoor air. In the distribution-type cold and hot air multi-stage duct for supplying to the air conditioner (H), the duct part (10) through which the cold and hot air from the air outlet (HA) of the air conditioner (H) is discharged into the room through the internal passage; and the air conditioner (H) is located A distribution pipe 20 made of a rigid body having a duct inlet-shaped cross-section provided at the end of the duct part 10 in the direction; and the upper portion of the duct part 10 to prevent sagging of the duct part 10 It includes a sag prevention part 30;

The duct part 10 is a first duct 11 having a cross section of a size and shape corresponding to the tuyere HA of the air-conditioning device (H) in a one-to-one diameter; and a cross section of the first duct 11 A second duct 12 having the same shape but a smaller diameter cross section, located inside the first duct 11 and extending from the first duct 11 by the length of the first duct 11 ) and the cross-section and shape of the second duct 12 are the same, but have a smaller diameter, are located inside the second duct 12, and the second duct 12 by the length of the first duct 11 and a third duct 13 configured to extend from.

The first duct 11 has a plurality of first vents 11a formed on the side surface at regular intervals, and the second duct 12 has a plurality of second vent holes 12a formed on its side surface at regular intervals, The third duct 13 is provided with a plurality of third vents 13a at regular intervals on the side surface. In addition, the second vent 12a is larger than the first vent 11a, and the third vent 13a is larger than the second vent 12a.

The material of the duct part 10 is preferably vinyl, but a material such as plastic, rubber, or iron plate may be used.

In an embodiment of setting the length of the first to third ducts 11, 12, 13, when the length of the first duct 11 is 30 m, the length of the second duct 12 is 60 m, and the length of the first duct 11 is The length protruding from the end is 30 m, the length of the third duct 13 is 90 m, and the length protruding from the end of the second duct 12 is 30 m. 3 Set so that the length of the section in which the surface of the ducts 11, 12, and 13 is in contact with the indoor air is equal to 30 m, respectively.

As described above, by setting the length of the section in which the surface of the first to third ducts 11, 12, and 13 is in contact with the indoor air is the same, the section in which heat loss occurs due to contact with the indoor air of the cultivation facility becomes the same. , the first to third ducts (11, 12, 13) aims to have the same amount of heat loss.

In addition, as shown in FIG. 2 or FIG. 4 , the end of the first duct 11 opposite to the air conditioning unit H is joined or sewn to the outer peripheral surface of the second duct 12 in a thermal fusion method ( 11b). is configured to prevent the cold and hot air inside the first duct from moving in the direction in which the first duct 11 extends, and induces it to move to the first vent 11a.

Similarly, the end of the second duct 12 located on the opposite side of the air conditioning unit H is configured with a second connection part 12b that is joined or sewn to the outer peripheral surface of the third duct 12 in a thermal fusion method, so that the second duct It prevents the internal cold and hot air from moving in the direction in which the second duct 12 extends, and induces it to move to the second vent 12a.

As the length of the duct increases, the amount of air inside the duct increases in proportion to the length, and the amount of air that the cold and hot air from the tuyeres HA must push increases to increase the resistance, and the first to third vents 11a, 12a. If the sizes of 13a) are the same, the amount of hot and cold air coming out of the third vent 13a of the longest third duct 13 compared to the cold and hot air coming out of the first vent 11a of the first duct 11 with the shortest length. This decrease may occur, resulting in temperature imbalance in the room.

Therefore, as described above, the sizes of the first to third vents 11a, 12a.13a configured in the first to third ducts 11, 12, 13 were configured in stages so that as the duct lengthens, the vents become larger. Therefore, the longer the distance of the duct, the lower the resistance of the cold and hot air coming out of the duct to push the air inside the duct, so that the air volume of the cold and hot air coming out of the first to third vents 11a, 12a. made it possible

As described above, since the second duct 12 is located inside the first duct 11, the cold and hot air inside the second duct 12 is the cold and hot air between the first duct 11 and the second duct 12. By acting as an insulator to prevent heat loss, heat loss is minimized until the cold and hot air is discharged to the second vent 12a, and the third duct 13 is also located inside the second duct 12, so that the third The cold and hot air inside the duct 13 serves as an insulator that prevents the cold and hot air between the second duct 12 and the third duct 13 from losing heat, so that the heat until the cold and hot air is discharged through the third vent 13a. losses were minimized. As a result, there is an effect that can minimize the temperature difference between the cold and hot air coming out of the first vent 11a close to the air conditioner (H) and the third vent 13a far away.

In addition, as described above, the duct portion 10 is formed in a multi-stage structure to reduce heat loss of cold and hot air, and the first to third vents 11a, 12a, 13a through which cold and hot air are emitted have a structure without obstacles outside, Since the speed of the cold and hot air coming out of the first to third vents 11a, 12a, and 13a does not decrease, there is an effect of maximally transferring thermal energy from the duct to the indoor space away from the duct.

As shown in FIG. 6 , a first cross-sectional area M11 excluding the inner cross-sectional area of the second duct 12 from the inner cross-sectional area of the first duct 11 and. a second cross-sectional area M12 excluding the inner cross-sectional area of the third duct 13 from the inner cross-sectional area of the second duct 12; The size of the third cross-sectional area (M13), which is the internal cross-sectional area of the third duct (13), is configured to be the same, so that the air volume of the hot and cold air generated from the air outlet (HA) of the air-conditioning device (H) is received in the same way. The air volume of the hot and cold air supplied to the room from the first vent 11a to the third vent 13a is set to be the same, so that the temperature difference in the room can be reduced as a result.

In addition, as shown in FIG. 8 , the third duct 13 has a cap 13b inserted into the inner end of the air conditioner H in the opposite direction; and the third duct 13 at the position where the cap 13b is inserted. It is configured to further include a peninsula (13c) for fixing to the outer peripheral surface of the third duct (13) by bolting to the outer peripheral surface.

The cap 13b is configured to have the same shape and size as the inner surface of the third duct, has a closed pipe shape, and prevents hot and cold air from escaping to the end of the third duct 13 . In particular, when the material of the third duct 13 is vinyl, the shape of the third duct 13 is held in a circular shape so as not to be distorted.

The distribution pipe 20 is a pipe 21 that is closely inserted into the inner surfaces of the first to third ducts 11, 12, 13 located in the direction of the air conditioner (H); and the pipe 21 The first to third ducts 11, 12, 13 are tightened to the outer peripheral surface of the pipe 21 by fastening the bolt (B) to the outer peripheral surface of the first to third ducts 11, 12, 13 at the inserted position. (21) and a peninsula 22 for fixing the first to third ducts 11, 12, 13; includes.

The pipe 21 is preferably manufactured in a circular shape by bending an iron plate, and may be configured in a shape other than a circular shape if necessary. In addition, one end of the pipe 21 must be installed in close contact with the air outlet HA of the air conditioning system H, and the first to third ducts 11, 11, 12, 13), and in particular, when the material of the first to third ducts 11, 12, 13 is vinyl, the shape of the first to third ducts 11, 12, 13 is not distorted. Hold it in a circular shape to avoid it.

In addition, as shown in FIG. 5 , semicircular irregularities larger than the diameter of the pipe 21 protrude from both ends of the outer circumferential surface of the pipe 21 to prevent the peninsula 22 from sliding off.

The anti-sag portion 30 is a pulley 31 configured in plurality on the upper portion of the duct portion 10; and a tension wire 32 configured to span half a turn of the pulley 31; and the tension wire 32 A turnbuckle 33 for adjusting the tension of the tension wire 32 in a screw tightening manner by combining both ends of the ring in a ring fashion; and a vertical wire 34 configured in plurality by being hung over the tension wire 32 in a ring manner; It may be composed of

In addition, as shown in FIG. 7 , the first to third ducts 11 , 12 , and 13 have a double structure of an outer vinyl (o) and an inner vinyl (i), and are formed between the outer vinyl (o) and the inner vinyl (i). A plurality of straight wires w at set intervals are configured in the longitudinal direction of the first to third ducts 11, 12, and 13, and the first to third ducts 11, 12, 13 are made of an external vinyl o ), a plurality of wire connectors (h) are formed.

When drilling the connector (h) on the outer vinyl (o), be careful not to make a hole in the inner vinyl (i), so that the cold and hot air inside the first to third ducts 11, 12, 13 does not flow out to the outside. shall.

An elliptical ring 34a is formed at the end of the vertical wire 34, and the ring 34a passes through the wire connector h, and is spanned with the wire w therein.

At this time, by adjusting the screw length of the turnbuckle 33 to be short, as shown in FIG. 3, the tension wire 32 in a drooping state rises to the upper side, and the vertical wire 34 coupled with the tension wire 32 is looped. will rise

When the material of the first to third ducts 11, 12, and 13 is vinyl, by allowing the wire w to be spanned inside the ring 34a as described above, the vinyl portion to which a tensile force is applied to the ring 34a is Torn or deformed, the wire (w) is in contact with the ring (34a) does not leave the first to third ducts (11, 12, 13).

Accordingly, as the vertical wire 34 rises, the wire w connected to the ring 34a rises at the same time, so that the first to third ducts 11.12.13 do not sag down by gravity. Therefore, with the above structure, the passages inside the first to third ducts 11.12.13 are prevented from being narrowed, so that hot and cold air can pass smoothly.

(Second embodiment)

The second embodiment is the same as the first embodiment, except that the insulating material 13d is further configured on the outer circumferential surface of the third duct 13 .

In this regard, FIG. 9 is an enlarged view of FIG. 4B in a state in which the insulating material 13d is configured on the outer circumferential surface of the third duct 13 according to another embodiment of the present invention.

As shown in FIG. 9 , the heat insulating material 13d is formed on the outer circumferential surface of the third duct 13 to prevent the cold and hot air inside the third duct 13 from losing heat to the outside.

The first duct 11 is the closest to the cold and hot air device (H), so the time until the cold and hot air is sprayed to the first vent 11a is the shortest, resulting in the least heat loss, and the second duct 12 also Insulation is made by the cold and hot air between the first duct 11 and the second duct 12 until it is sprayed from the second vent 12a, and the cold and hot air of the third duct located inside the second duct 12 and Heat loss due to heat exchange is not large. However, in the case of the third duct 13, some heat loss may occur before moving to the third vent 13a because the distance from the air conditioner H is farthest. As a way to minimize this, the third duct 13 is placed on the outer circumferential surface. The heat insulating material 13d may be configured.

As a material of the heat insulating material 13d, it is preferable to use a material having low thermal conductivity, such as a urethane sponge or a fiber material.

(3rd embodiment)

The third embodiment is the same as the first embodiment except that the cap (13b) and the peninsula (13c) at the end of the third duct (13).

In this regard, Figure 10 is a perspective view of a state in which the cap (13b) and the peninsula (13c) are not configured at the end of the third duct according to another embodiment of the present invention.

As shown in FIG. 10 , airtightness can be performed by forming a knot 13e without using the cap 13b and the peninsula 13c for airtightness of the end of the third duct 13 . When this method is used, there is an advantage that the cap 13b and the peninsula 13c are not used, thereby reducing the cost and making the installation simpler.

In addition, it will be natural that the airtightness of the end of the third duct 13 can be performed by joining or sewing by thermal fusion in addition to the knot.

(Example 4)

The fourth embodiment is the same as the first embodiment except that the ring (r) and the fixing member (s) is configured on the outer peripheral surface of the first to third ducts (11, 12, 13).

In this regard, Figure 11 is a perspective view of a state in which the ring (r) and the fixing member (s) are configured on the outer peripheral surface of the first to third ducts (11, 12, 13) according to another embodiment of the present invention.

11, a plurality of rings (r) arranged at regular intervals on the outer peripheral surface of the first to third ducts (11, 12, 13); and the first to third ducts (11) surrounding the circumference of the ring (r) The fixing member (s) for fixing the ring (r) to the outer peripheral surface of the first to third ducts (11, 12, 13) by bonding to the outer peripheral surface of the 12, 13; may be configured to further include.

The above configuration is for preventing the shapes of the first to third ducts 11, 12, and 13 from being disturbed when the material of the first to third ducts 11, 12, and 13 is vinyl.

The ring (r) is preferably made of a metal material for durability, and the fixing member (s) is preferably made of the same material as the first to third ducts (11, 12, 13) and vinyl. In addition, both ends of the fixing member (s) are attached to the outer peripheral surface of the first to third ducts (11, 12, 13) by bonding or sewing by thermal fusion.

With the above structure, the outer peripheral surfaces of the first to third ducts 11, 12, 13 are fixed to the ring r so that the shape is not disturbed, so that the cross-sectional area of the inside of the first to third ducts 11, 12, 13 is to prevent narrowing. Accordingly, since the resistance received by the cold and hot air passing through the first to third ducts 11, 12, and 13 is reduced, there is an effect of smoothly supplying cold and hot air into the room.

(Example 5)

The fifth embodiment is the first embodiment, except that the first to third extension ducts 11', 12', 13' are additionally formed on the side surfaces of the first to third ducts 11, 12, 13. same as example

In this regard, FIG. 12 is a state diagram of a distribution type cold/hot air multi-stage duct configured by adding the first to third extension ducts 11', 12', and 13' according to another embodiment of the present invention.

12 , in order to directly transmit hot and cold air to the crop F as shown in FIG. 12 , first extension ducts 11 ′ are formed on a side surface of the first duct 11 at regular intervals, and the first extension duct 11 ′ ), a plurality of first vents 11a are formed at regular intervals on the side surface of the second duct 12, and second extension ducts 12' are formed on the side surface at regular intervals, and the second extension duct 12 '), a plurality of second vents 12a are formed at regular intervals on the side surface of the third duct 13, and third extension ducts 13' are formed on the side surface at regular intervals, and the third extension duct ( 13'), a plurality of third vents 13a may be formed at regular intervals on the side surface.

The first extension duct 11 ′, the second extension duct 12 ′, and the third extension duct 13 ′ are installed close to each other at regular intervals of the crop F, so that the crop F is cooled and warmed. Since the air is directly supplied, it is possible to more reliably create a temperature environment for the crop F as compared to the first embodiment.

As in the first embodiment, when there is a large deviation in the distance between the first to third vents 11a, 12a, 13a and the crop F, the cold and temperature emitted from the first to third vents 11a, 12a, 13a Heat loss may occur while the wind moves from the crop F close to the first to third vents 11a, 12a, 13a to the crop F farther away, so the method of the fifth embodiment By further supplementing this problem, it is possible to maintain the environmental temperature of the crop (F) more uniformly.

Also, as in the first embodiment, the second vent 12a is larger than the first vent 11a, and the third vent 13a is formed larger than the second vent 12a, and the first to third The air volume of the hot and cold air coming out of the ventilation holes 11a, 12a.13a can be uniformly adjusted.

The first to third extension ducts 11', 12', 13' on the side surfaces of the first to third ducts 11, 12, 13 are not bonded or sewn in a thermal fusion method when the material is vinyl. This is a preferred method, and when the material is plastic, bonding by silicon is used, or in the case of metal, it can be connected using welding.

(6th embodiment)

The fifth embodiment is the same as the first embodiment, except that the anti-sag portion 30 is configured without the pulley 31, and the turnbuckle 33' is installed in the frame (Z).

13 is a state diagram of a distribution type cold/hot air multi-stage duct configured without a pulley 31 in the anti-sag unit 30 according to another embodiment of the present invention.

The anti-sag unit 30 is a turnbuckle 33' attached to a plurality of frames (Z) used for door frames or pillars of plastic house facilities; and a tension wire coupled in a ring shape between the turnbuckle 33' ( 32'); and a vertical wire 34 configured in a plurality of loops over the tension wire 32'.

When the anti-sag portion 30 is configured and installed as described above, compared to the first embodiment, the pulley 31 is eliminated, and the length of the tension wire 32 ′ required for installation is shortened in half to reduce the installation cost. do.

On the other hand, the present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it is intended that such variations or modifications fall within the scope of the claims of the present invention.

H. Air conditioning system HA. Air outlet Z. Frame
B. Vault F. Crop
10. Duct
11. 1st duct 11'. 1st extension duct
11a. 1st ventilation hole 11b. 1st connection part
12.Second duct 12'.Second extension duct
12a. 2nd vent 12b. 2nd connection part
13. 3rd duct 13'. 3rd extension duct
13a. Third vent 13b. Cap
13c. Peninsula 13d. Insulation
13e. Knot
i.Inner vinyl o.Outer vinyl w.Wire
r.ring s.fixing member h.wire connector
20. Distribution pipe 21. Pipe 21a. Concave and convex
22. Peninsula
30. Deflection prevention part 31. Pulley 32. Tension wire
33.Turnbuckle 34.Vertical Wire

Claims (10)

In the distribution type cold and hot air multi-stage duct that receives the hot and cold air generated from the air outlet (HA) of the air conditioning system (H) in the facility for cultivating the crop (F) and supplies it indoors,
a duct part 10 through which hot and cold air from the air outlet (HA) of the air conditioner (H) is discharged into the room through the internal passage;
a distribution pipe 20 made of a rigid body having a cross section in the shape of a duct inlet provided at the end of the duct portion 10 in the direction in which the air conditioner (H) is located;
a sag prevention part 30 coupled with the upper part of the duct part 10 to prevent sagging of the duct part 10;
including ,
The duct part 10 is
a first duct 11 having a cross section of a size and shape corresponding to the tuyere HA of the air-conditioning device (H) and one-to-one diameter;
The cross section and shape of the first duct 11 are the same, but the diameter has a smaller cross section, is located inside the first duct 11 , and extends from the first duct 11 by the length of the first duct 11 . The second duct 12 is configured to be;
The cross section and shape of the second duct 12 are the same, but the diameter has a smaller cross section, is located inside the second duct 12 , and extends from the second duct 12 by the length of the first duct 11 . The third duct 13 is configured to be;
includes,
a first cross-sectional area (M11) excluding the inner cross-sectional area of the second duct (12) from the inner cross-sectional area of the first duct (11);
a second cross-sectional area (M12) excluding the inner cross-sectional area of the third duct (13) from the inner cross-sectional area of the second duct (12);
Distribution type cold/hot air multi-stage duct, characterized in that the size of the third cross-sectional area (M13) of the internal cross-sectional area of the third duct (13) is the same. delete According to claim 1,
The first duct 11 is formed with a plurality of first vents 11a at regular intervals on the side surface,
The second duct 12 is formed with a plurality of second vents 12a at regular intervals on the side surface,
The third duct (13) is a distribution type cold and hot air multi-stage duct, characterized in that a plurality of third vents (13a) are formed at regular intervals on the side surface.
According to claim 1,
The first duct 11 is formed with a first extension duct 11' at regular intervals on the side surface, and a plurality of first vent holes 11a are formed on the side surface of the first extension duct 11' at regular intervals. ,
The second duct 12 is formed with a second extension duct 12' at regular intervals on the side surface, and a plurality of second ventilation holes 12a are formed on the side surface of the second extension duct 12' at regular intervals. ,
The third duct 13 has a third extension duct 13' formed on the side surface at regular intervals, and a plurality of third ventilation holes 13a are formed on the side surface of the third extension duct 13' at regular intervals. Distribution type cold and hot air multi-stage duct, characterized in that.
5. The method of claim 3 or 4,
The second vent (12a) is larger than the first vent (11a), and the third vent (13a) is formed to be larger than the second vent (12a).
delete According to claim 1,
The first to third ducts 11, 12, 13 are composed of a double structure of an outer vinyl (o) and an inner vinyl (i), and are formed in a straight line at a set interval between the outer vinyl (o) and the inner vinyl (i). Distribution type cold and hot air multi-stage duct, characterized in that the wire (w) is configured in plurality in the longitudinal direction of the first to third ducts (11, 12, 13).
8. The method of claim 7,
The first to third ducts (11, 12, 13) are distribution-type cold and hot air multi-stage duct, characterized in that a plurality of wire connectors (h) are formed on the outer vinyl (o).
According to claim 1 ,
The anti-sag portion 30 is
A plurality of turnbuckles (33') attached to the frame (Z);
Tension wire (32') coupled in a ring type between the turnbuckle (33');
a vertical wire 34 configured in a plurality of loops over the tension wire 32 ′;
Distribution-type cold and hot air multi-stage duct comprising a.
10. The method of claim 9,
Distributed cold and hot, characterized in that an oval-shaped ring (34a) is configured at the end of the vertical wire (34), and the ring (34a) passes through the wire connector (h) and spans the wire (w) inside Wind multistage duct.

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