KR102391936B1 - Beehives using flow path assembly based heated floor panel. - Google Patents

Abstract

The present invention relates to a beehive using a hot water floor-based flow panel assembly, and more particularly, to a beehive comprising: a body part having a hollow and having an entrance at the bottom so that bees can enter and exit; a cover portion mounted on the upper portion of the support jaw 130 formed along the upper periphery of the outer surface of the main body; Doedoe installed in the lower part of the main body, a flow path panel assembly to supply heat to the main body by the fluid supplied through the boiler is circulated. It relates to a beehive using a hot water floor-based flow panel assembly, characterized in that it is maintained at a temperature.

Description

{Beehives using flow path assembly based heated floor panel.}

The present invention relates to a beehive using a hot water floor-based Europanel assembly, and by allowing the heat generated at an appropriate temperature to be transmitted to the inside of the beehive through the circulation of a fluid, the temperature inside the hive is kept constant, so that the bees grow and spawn It relates to a beehive using a hot water floor-based flow panel assembly that prevents this from being disturbed.

In general, in order for the queen bee to lay eggs and raise the larvae, the temperature inside the hive should be maintained at 20~25℃. Eggs of bees freeze at 10°C and larvae at 5°C, while adults become paralyzed at -5°C. In order to prevent such bees from freezing in winter, beekeepers often covered their hives with rice straw, styrofoam, and thermal blankets. very low So, recently, some beekeepers have been using the method to keep the hive warm by inserting heating objects such as light bulbs, heaters, and heating wires inside the hive.

However, the electric heating means generates electromagnetic waves inside the hive, so bees sensitive to electromagnetic waves lose their stability and flutter their wings, and growth and activity are reduced. As the phenomenon occurred, the larvae dried up and died, so there was a problem that the colony was not formed.

In addition, some methods are implemented to transfer heat from the outside of the beehive, such as installing a heating wire for house seedlings on the bottom of the beehive or attaching a heating wire for seedlings to the insulation cover of the beehive. Heat was not transmitted, so it was difficult to control the temperature inside the hive, and the application of excessive current to generate a lot of heat exposed the hive to the risk of fire.

[Prior Document 1] Korean Patent Publication No. 10-1581307 (2015.12.30.) [Prior Document 2] Korean Patent Publication No. 10-0757998 (2007.09.11.) [Prior Document 3] Korean Patent Publication No. 10-2012-0031324 (2012.04.03.)

An object of the present invention is to provide a beehive using a hot water floor-based Europanel assembly that uses a flow path panel assembly that generates heat by circulating a fluid so that the inside of the hive is kept warm so that bees can grow at an appropriate temperature. do.

The beehive using the flow path panel assembly of the present invention has a hollow 120 formed therein, the main body 100 is formed with an entrance 110 at the bottom so that bees can enter and exit; a cover portion 200 that is placed on the upper portion of the fulcrum 130 formed along the upper periphery of the outer surface of the body portion 100; It is characterized in that it is configured to include a; is installed in the lower portion of the body part 100, the fluid supplied through the boiler to supply heat to the body part 100 by circulation; .

The flow path panel assembly 300 includes a flow panel 310 disposed adjacent to each other and having a plurality of flow channels 313 formed side by side in the longitudinal direction therein; a cap member 320 coupled to both ends of the flow path panel 310; It is characterized in that it comprises a; leak collecting unit 360 for collecting the fluid leaked from the coupling portion of the cap member 330 and the flow path panel (310).

An adapter frame 400 including a communication part 410 for communicating with the body part 100 is further provided between the body part 100 and the flow path panel assembly 300 .

The communication part 410 is characterized in that it is formed in the same shape and size as the hollow 120 of the body part (100).

A coupling groove 150 is formed on the lower surface of the main body 100 , and the adapter frame 400 is provided with a coupling jaw 450 inserted into the coupling groove 150 , the main body 100 . It is characterized in that it is fixed.

A functional coating film is applied to the inner wall of the main body 100 .

A heat insulating member 500 having a plurality of through-holes formed between the flow path panel assembly 300 and the adapter frame 400 is further provided.

The composition of the fluid is characterized in that it contains a Dolby phenomenon inhibitory crystal.

It is placed on the upper end of the body portion 100, characterized in that it further comprises a cooling portion 600, the outer surface is covered by the cover portion (200).

The present invention has the effect of preventing the activity force of the bees from being reduced even if the external temperature is lowered by heating the inside of the main body of the beehive by the circulation of the fluid.

In addition, the present invention does not use a heating wire, and by supplying heat to the body part by circulating a heated fluid flow path formed in the panel, there is an effect that the bees are protected from harmful factors such as electromagnetic wave interference and electric shock.

In addition, the present invention has the effect of providing a beehive that prevents dew condensation from being generated by moisture inside the main body and prevents the growth of bacteria due to moisture.

In addition, the present invention has an effect of protecting bees from the danger of burns by preventing the bees inside the main body from coming into direct contact with the flow path panel assembly by using the heat insulating member.

In addition, the present invention provides a beehive that is further provided with a cooling unit including a flow path panel assembly at the upper end of the main body, thereby cooling the inside of the main body in a hot season to prevent softening of the honeycomb, and to prevent the honeybee's mining activity from lowering. can have an effect.

In addition, in the present invention, the cooling air flow is generated from the upper portion and the heated air flow is generated from the lower portion, so that natural convection circulation is generated, thereby improving cooling efficiency or heat retention efficiency.

1 is a perspective view of a beehive using a hot water floor-based flow panel assembly according to an embodiment of the present invention.
2 is an exploded view of a beehive using a hot water floor-based flow panel assembly according to an embodiment of the present invention.
3 is an exploded view illustrating a state in which an adapter frame is provided between a main body and a flow panel assembly in a beehive using a hot water floor-based flow panel assembly according to another embodiment of the present invention.
4 is a cross-sectional view showing the body portion and the adapter frame of FIG. 3 .
5 and 6 show the shape of the adapter frame and the state in which the adapter frame and the main body are coupled according to another embodiment of the present invention.
7 is a view showing a state in which a heat insulating member is further provided between the adapter frame and the flow path panel assembly in a beehive using a hot water floor-based flow panel assembly according to another embodiment of the present invention.
8 is a perspective view illustrating the structure of a flow path panel assembly in a beehive using a hot water floor-based flow panel assembly according to an embodiment of the present invention.
9A and 9B are block diagrams illustrating an element for supplying a fluid to a hose.
10 is an exploded perspective view showing a flow path panel and a cap member in a beehive using a hot water floor-based flow panel assembly according to an embodiment of the present invention.
11 is a plan view showing the arrangement of the channel panel and the hose in the beehive using the hot water floor-based channel panel assembly according to the embodiment of the present invention.
12 is a side view for explaining that the material of the upper part and the lower part of the channel panel is different in the beehive using the hot water floor-based channel panel assembly according to the embodiment of the present invention.
13 is a view showing a water leak collecting part in a beehive using a hot water floor-based flow panel assembly according to an embodiment of the present invention.
14 is a diagram illustrating a hot water floor-based flow panel assembly in which a cooling unit is provided at the upper end of the main body to supply cold air from the upper part of the main body in the hot water floor-based flow panel assembly according to another embodiment of the present invention. .

Next, a preferred embodiment of a beehive using a hot water floor-based europanel assembly according to the present invention will be described in detail with reference to the drawings. The present invention can be implemented in many different forms, and is not limited to the embodiments described below. Hereinafter, in order to clearly describe the present invention, detailed descriptions of parts not closely related to the present invention are omitted, and the same reference signs are attached to the same or similar components throughout the description of the invention, and repeated descriptions are omitted. .

1 to 2, in the beehive using the hot water floor-based europanel assembly of the present invention, a hollow 120 is formed, and the main body in which the entrance 110 is formed so that the bees can enter and exit. part 100; a cover portion 200 that is placed on the upper portion of the fulcrum 130 formed along the upper periphery of the outer surface of the body portion 100; It is preferable to include; a flow path panel assembly 300 installed in the lower portion of the main body 100 and configured to supply heat to the main body 100 by circulating a fluid supplied through a boiler.

To increase the temperature of the hive, the user connects the pipe 810 to the flow panel assembly 300 to supply boiler fluid.

In this case, the fluid heated to an appropriate temperature from the boiler is supplied to the flow path panel assembly, so that heating is performed uniformly through heat exchange, and thermal efficiency can be maximized by the heat storage performance of the fluid. In addition, compared to the conventional technology that uses an electric heater to keep the hive warm, it protects the bees from the influence of electromagnetic waves and the construction is simple, so even if the position of the hive is moved, the effect of construction without generating environmental waste is improved. there is.

By installing the flow path panel assembly 300 in the lower part of the body part 100 to receive boiler fluid from the outside, the heat source generated by the circulation of the fluid rises along the hollow 120 of the body part 100 . , it is possible to keep the temperature of the hive at an appropriate level even in winter. That is, even if the external temperature falls, it is possible to prevent the activity force of the bees from being reduced.

In addition, in the beehive using the hot water floor-based Europanel assembly, the outer surface of the main body 100 and the outer surface of the cover 200 are prevented so that the heat supplied to the main body 100 is emitted to the outside, so that the thermal efficiency is not reduced. It is preferably made of a heat insulating material that blocks heat transfer, or coated with a heat insulating composition. In addition, since the heat supplied from the main body 100 is generated by the flow path panel assembly 300, a pedestal 700 capable of separating the flow path panel assembly 300 from the ground by a predetermined distance is further provided. It is desirable to reduce the transfer of heat generated in the panel assembly 300 to the ground.

The doorway 110 may further include a front plate (not shown) so that the opening and closing amount can be adjusted according to the temperature and humidity inside the accommodation space 110 .

A functional coating film is applied to the inner wall of the body part 100, and the composition of the functional coating film is SiO2 60~75wt%, Al2O3 10~20wt%, Fe2O3 1~5%, MgO 1~5wt%, K2O 1~5wt %, Na2O 0.1~3wt%, CaO 0.1~3wt%, TiO2 0.1~3wt%, more preferably, SiO2 75wt%, Al2O3 15wt%, Fe2O3 4.7%, MgO 1.3wt%, K2O 3.5wt %, Na2O 1wt%, CaO 1wt%, TiO2 1wt%. This suppresses the occurrence of dew condensation inside the body part 100 and has an antibacterial effect on strains that may be generated by moisture, so that the quality of the honeycomb provided on the inner wall of the body part 100 is prevented from being deteriorated. can have an effect.

As shown in FIG. 3 , according to another embodiment of the present invention, a communication part 410 communicating with the body part 100 is included between the body part 100 and the flow path panel assembly 300 . The adapter frame 400 may be configured to be provided. More specifically, the adapter frame 400 is made of a heat insulating material, and as the size of the communication part 410 decreases, the size of the cross-sectional area facing the flow path panel assembly 300 is preferably increased. This minimizes heat loss by blocking the heat source of the flow path panel assembly 300 from being transmitted to the outside, and the heat source rises along the communication part 410 to be intensively transmitted to the hollow 120 of the body part 100 . be able to

As shown in FIG. 4 , a coupling groove 150 is formed on the lower surface of the main body 100 , and the adapter frame 400 is a coupling protrusion 450 inserted into the coupling groove 150 is formed. , it is preferable to receive heat in a state in which the body part 100 is stably fixed, and the coupling jaw 450 may be manufactured in various shapes by those skilled in the art, as shown in FIG. 6 .

By providing the adapter frame 400 , the hive can be uniformly heated regardless of the size and shape of the body part 100 .

More specifically, as shown in FIG. 4 or 6, the communication part 410 is formed to have the same shape and size as the hollow 120 of the body part 100, so that the size of the hollow 120 or Even with a change in shape, heat generated from the flow path panel assembly 300 may be efficiently transferred to the hollow 120 . More specifically, when the hollow 120 of the main body 100 is used for a beehive with a small size, it is preferable that the adapter frame 400 uses a small size of the communication unit 410 . This is because the size of the communication part 410 is reduced, so that the cross-sectional area facing the flow panel assembly 300 is relatively large, so that the heat source of the flow panel assembly 300 is not diffused to the outside, and the flow path panel assembly 300 is not diffused to the outside. ), and by moving the remaining heat toward the communication part 410 , it is possible to intensively transfer heat to the hollow 120 of the main body 100 in a short time.

However, in spite of using a beehive for single rods having a small size of the body part 100 , the adapter frame 400 is not used, or the size of the communication part 410 is larger than the hollow 120 of the body part 100 . When the frame 400 is used, heat loss may occur, and a problem may occur in that heat is non-uniformly transferred to the hollow 120 of the main body 100 .

According to another embodiment of the present invention, as shown in FIG. 7 , a heat insulating member 500 having a plurality of through holes formed between the flow path panel assembly 300 and the adapter frame 400 may be further provided. . The insulating member 500 has the effect of protecting the bees from the risk of burns by preventing the bees from contacting the panel assembly 300 by d.

When the total area of the flow path panel 310 of the flow panel assembly 300 is A1 and the area of the flow path panel 310 exposed from the heat insulating member 500 having the plurality of through holes is A2, 0.3 < A2 It is characterized in that the relationship of /A1≤0.9 is established. When A2/A1 is less than 0.3, since the area of the flow path panel 310 exposed from the through hole decreases, there is a risk that heat supply to the main body 100 may not be smooth, and A2/A1 exceeds 0.9 In this case, there is a risk of a bee coming into contact with the flow path panel assembly 300 and getting burned.

When the heat source generated in the flow path panel assembly 300 transfers heat along the hollow 120 of the body part 100 and reaches the uppermost layer, dew condensation is generated on the inner surface of the cover part 200, Moisture or mold may be generated according to the generation of dew, and the quality of the honeycomb may be reduced. Accordingly, it is preferable that the anti-condensation agent is applied to the inner surface of the cover part 200 .

Hereinafter, the flow path panel assembly will be described in detail.

As shown in FIG. 8 or 10 , the flow path panel assembly 300 includes a flow panel 310 disposed adjacent to each other and having a plurality of flow channels 313 formed side by side in the longitudinal direction therein; a cap member 320 coupled to both ends of the flow path panel 310; It characterized in that it is configured to include a water leak collecting part 330 for collecting the fluid leaked from the coupling portion of the cap member 320 and the flow path panel (310).

More preferably, the flow path panel assembly 300 may further include a hose 360 for receiving the flow connection pipe 350 and the boiler fluid and recovering the circulated boiler fluid.

That is, a plurality of flow channels 310 are disposed adjacent to each other, and a plurality of flow channels 313 are formed side by side in the longitudinal direction inside the flow channel panel 310 , and are coupled to both ends of the flow channel panel 310 . By the cap member 320 to be, the plurality of flow paths 313 are communicated with each other, and the fluid supplied from the flow path connection pipe 350 is circulated.

The hose 360 may be directly connected to the boiler so that the heated fluid is supplied to the flow path panel 310 .

In addition, as shown in FIG. 9A , the hose 360 is detachably coupled to the pipe 810 connected to the boiler 820 , so that the heated fluid may be supplied to the flow path panel 310 . At this time, a temperature sensor 850 is further provided in the main body 100, and the boiler 820 is driven to be controlled by a control unit 830, and the control unit 830 has a temperature setting and an on/off button. It can be configured to input a set temperature through the provided manipulation unit 840 . That is, the boiler 820 is controlled to be driven by the control unit 830, and the control unit 830 controls the temperature sensor 850 so that the temperature set by the operation unit 840 can be maintained in the body unit 100. The on/off of the boiler 820 is operated by receiving the temperature information of the main body from the

According to the method, as shown in Figure 9b, the pipe 810 is connected to the boiler, and a solenoid valve 860 is provided at the connection part of the boiler and the pipe 810, so that the opening and closing of the solenoid valve 860 is By being controlled by the operation unit 840 and the control unit 830, it can be configured to selectively supply a heated fluid to a plurality of beehives. In this case, it is preferable that the other end of the pipe 810 is provided with a rotary joint so that it can be easily coupled to the hose 360 .

When the fluid supplied with thermal energy is supplied to the pipe 810 and the flow panel assembly 300 in an overheated state, the flow panel 310 may be damaged due to the overheated fluid due to the rapid expansion of the internal pressure of the pipe. there is. For this purpose, it is preferable that the Dolby phenomenon inhibiting crystal is mixed with the composition of the fluid. Since the Dolby phenomenon inhibiting crystal is included in the composition of the fluid, it is possible to prevent damage due to rapid expansion of the internal pressure of the pipe 810 and the flow panel 310 .

It is preferable that the particle size of the Dolby phenomenon suppressing crystal is 0.5 mm or less, and through this, it is preferable to be uniformly distributed in the inside of the boiler fluid.

At this time, when the amount of the Dolby phenomenon-inhibiting crystal is less than 5 parts by weight based on 100 parts by weight of the composition of the fluid, the number of pores for suppressing the Dolby phenomenon is remarkably small, so the anti-dollar effect of the composition of the fluid is very weak, 10 In the case of exceeding parts by weight, the effect of inhibiting the dolby phenomenon increases, but the volume occupied by the flow passage increases due to the nature of the boiling side or boiling stone having a crystalline form, so that the flow path panel 130 may be damaged by high pressure expansion. may occur, the Dolby phenomenon inhibiting crystal preferably has a critical significance of 5 to 10 parts by weight based on 100 parts by weight of the composition of the fluid.

Based on 100 parts by weight of a composition containing acetone, ethanol, distilled water, potassium dichromate, sodium perborate, sodium sampoldiphosphate, and methylbenzotriazole, it contains at least one crystal of either boiling or boiling stone. can be manufactured. More specifically, acetone, ethanol, distilled water, potassium dichromate, sodium perborate, sodium sampol diphosphate, based on 100 parts by weight of the composition in which methylbenzotriazole is mixed, 5 to 10 parts by weight of the Dolby phenomenon inhibitory crystal is mixed further comprising can be configured.

The composition of the fluid is 50 to 62 parts by weight of acetone, 10 to 15 parts by weight of ethanol, 15 to 20 parts by weight of distilled water, 5 to 10 parts by weight of potassium dichromate, 3 to 6 parts by weight of sodium perborate, 1-4 parts by weight of sodium tripolyphosphate. It is preferable to include 1 to 4 parts by weight of methylbenzotriazole, so that the fluid is heated above the boiling point so that it does not boil suddenly.

As shown in FIG. 10 , the cap member 320 has a protrusion 322 provided, and a protrusion 322 that can use only a part of the flow passages among the plurality of flow passages 313 formed in the flow passage panel 313 . may be provided. By sealing some of the plurality of flow paths 313, the flow of the circulation circuit in which the hot water is circulated is improved (the circulation speed of the hot water is improved). Accordingly, the pump capacity for improving the hot water circulation speed is reduced, and there is an effect of increasing the energy efficiency of the flow path panel assembly. More specifically, the first flow passage 313a, the third flow passage 313c, and the fifth flow passage 313e were sealed, and the hot water was circulated through the second flow passage 313b and the fourth flow passage 313e to be used. When the flow paths 313b and 313d located between the closed flow paths 313a, 313c, and 313e are selectively used, the circulation speed of hot water becomes faster than when using five, so that the hot water supplied from the boiler circulates quickly. This has the effect of increasing energy efficiency.

According to the method, it is possible to circulate hot water in the first flow path 313a, the third flow path 313c, and the fifth flow path 313e, and to seal the second flow path 313b and the fourth flow path 313d to use it, The flow path used is not limited thereto since it can be varied according to those skilled in the art.

As shown in FIG. 11 , it has been described that three flow panels 310 are formed in one group and arranged adjacent to each other in odd (3) or even (4) groups. By adjusting the number of 310 (for example, 3 to 5), the boiler fluid is supplied and circulated at the same time to form a plurality of groups by adjusting the number (for example, 3 to 5). Also, depending on the arrangement position of the hose 360 to be recovered, the tank of the flow path panel 310 is formed into an even tank or an odd tank. It has the advantage of being able to place it.

In addition, a pair of connector is provided at both ends of the cap member 320, respectively, and the flow path connector 350 is installed by being coupled to the end of each connector. In addition, by forming a thread on the outer circumferential surface of the connector of the cap member 320 and firmly fixing the flow path connector 350 coupled to the connector using a hose clamp 370 , the flow path connector 350 is separated. and drop-out was prevented.

Meanwhile, the cap member 320 is thermally bonded to both ends of the flow path panel 310 , thereby reducing the risk of separation and allowing the fluid supplied from the flow path connection pipe 350 to stably circulate through the flow path panel 310 . As the fluid supplied from the flow path connection pipe 350 is horizontally supplied to the flow path panel 310 , the total height of the flow path panel assembly 300 is reduced.

10 or 12, joint grooves 315 are formed at both corners of the flow path panel 310, and “ㅛ” It is characterized in that the joint 380 in the shape of a ruler is inserted and installed. By inserting the "ㅛ"-shaped joint 380 into the joint groove 150, there is an effect of securely connecting and fixing the plurality of flow path panels 310 to each other.

A water leakage collecting part 330 having an open upper surface for collecting fluid leaked from the coupling surface is formed on the bottom surface of the coupling portion of the cap member 320 and the flow path panel 310 .

” 형상의 체결고리(331a) 또는 끝단이 화살촉과 같은 걸림부의 탄성에 의해 끼워질 수 있도록 하여 상기 유로패널(310)에 구비된 체결고리 결합홈(316)에 삽입되어 결합하는 구조를 갖고, 상기 덮개(331)의 타측은 결합돌기(331b)가 구비되고, 상기 누수수집부(330)의 상부 일단의 덮개 결합홈(미도시)에 삽입되어 서로 결합될 수 있는 구조를 갖는 것을 특징으로 한다.13, according to the embodiment of the present invention, the water leak collecting part 330 has an “L” shape, and on one side of the cover 331 covering the upper surface of the water leak collecting part 330, “

”-shaped fastening ring 331a or the end thereof is inserted into and coupled to the fastening ring coupling groove 316 provided in the flow path panel 310 so that it can be fitted by the elasticity of the hooking part such as an arrowhead, and the The other side of the cover 331 is provided with a coupling protrusion 331b, and is inserted into the cover coupling groove (not shown) of the upper end of the leak collecting part 330 to have a structure that can be coupled to each other.

When a fastening ring 331a is formed and installed on the cover 331, the cover 331 and the water leak collecting part 330 are coupled to each other in a concave-convex shape, and the fastening ring 331a is connected to the flow panel by elasticity. It is stably inserted into the fastening ring coupling groove 316 provided in the 310 so that the cover is not easily separated, and has an effect of having a structure that beautifully covers the water leak collecting part 330 .

According to the method, a plurality of bare wires, which are not covered with insulation, are buried in half (semi-buried) in parallel in the bottom surface of the water leak collecting part 340, so that the leakage current can be detected and the user can take action on the water leakage. can make it Since this is a known technique, a detailed description thereof will be omitted.

The flow path panel assembly 300 may be further provided on one or more sidewalls of the beehive, so that the lower part and the side part of the beehive can be kept warm at the same time.

According to another embodiment of the present invention, it may be manufactured to further include a cooling unit 600 that is placed on the upper end of the body unit 100 and whose outer surface is covered by the cover unit 200 .

At this time, as shown in FIG. 14 , when a through hole (not shown) is provided on one side of the cover part 200 so that a cold water supply pipe (not shown) can be coupled to the through hole (not shown), the cooling unit At 600 , a flow path panel assembly capable of generating cold air by circulation of cold water may be used. By further providing a cooling unit including the europanel assembly at the upper end of the main body, it is possible to provide a hive that cools the inside of the main body in a hot season to prevent softening of the honeycomb, and prevents the honeybee's harvesting activity from lowering. .

Depending on the method, the cold water may be supplied from the water tank by installing a water tank in the apiary. In addition, in the case of an apiary located in a mountainous region, it may be configured such that valley water flows into the flow path panel assembly through a pipe.

100: main body 110: entrance
120: hollow 130: support jaw
150: coupling groove 200: cover part
300: euro panel assembly 310: euro panel
311: upper 312: lower
313: Euro 315: Joint groove
316: fastening ring coupling groove 320: cap member
330: leak collection unit 331: cover
331a: fastening hook 350: flow path connector
360: hose 380: fitting
370: hose clamp 400: adapter frame
410: communication unit 500: insulation member
600: cooling unit 700: pedestal

Claims (9)

The hollow 120 is formed, the main body 100 is formed with an entrance 110 at the bottom so that the bees can enter and exit;
a cover portion 200 that is placed on the upper portion of the fulcrum 130 formed along the upper periphery of the outer surface of the body portion 100;
A flow path panel assembly 300 installed in the lower portion of the main body 100 to supply heat to the main body 100 by circulation of a fluid supplied through a boiler; includes;
An adapter frame 400 including a communication part 410 for communicating with the body part 100 is further provided between the body part 100 and the flow path panel assembly 300,
A coupling groove 150 is formed on the lower surface of the main body 100 , and the adapter frame 400 is provided with a coupling jaw 450 inserted into the coupling groove 150 , the main body 100 . to be fixed,
A hot water floor-based flow panel assembly, characterized in that a heat insulating member 500 having a plurality of through holes is further provided between the flow panel assembly 300 and the adapter frame 400 to protect bees from the risk of burns. beehive using . delete The method of claim 1,
The communication part (410) is a beehive using a hot water floor-based flow panel assembly, characterized in that it is formed in the same shape and size as the hollow (120) of the main body part (100). delete delete The method of claim 1,
A beehive using a hot water floor-based flow panel assembly, characterized in that a functional coating film is applied to the inner wall of the main body (100). The method of claim 1,
The flow path panel assembly 300 includes: a flow panel 310 disposed adjacent to each other and having a plurality of flow channels 313 formed side by side in the longitudinal direction therein; a cap member 320 coupled to both ends of the flow path panel 310; A beehive using a hot water floor-based flow panel assembly, characterized in that it includes; a water leak collecting unit (360) for collecting fluid leaking from the coupling portion between the cap member (320) and the flow path panel (310). 8. The method of claim 7,
A beehive using a hot water floor-based flow panel assembly, characterized in that the composition of the fluid contains a Dolby phenomenon inhibiting crystal. According to any one of claims 1, 3, 6, 7, 8,
A beehive using a hot water floor-based flow panel assembly, characterized in that it further comprises a cooling unit (600) that is placed on the upper end of the body unit (100) and whose outer surface is covered by the cover unit (200).

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