JPH0311319Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) The present invention relates to a snow melting device that melts snow accumulated on the roof of a building.

(Prior Art) Conventionally, as shown in FIG. 2, a combustion device 20 housed inside a machine room 10, an exhaust duct 30 for discharging combustion gas from the combustion device 20, and one end of the exhaust duct 30 are provided. A snow melting device is known that includes a supply duct 40 that is connected to the snow melting device and supplies exhaust gas to an attic space.

(Problems to be solved by the invention) In the conventional snow melting device, the combustion device 20
Since the water vapor contained in the combustion gas is sent to the attic space through the exhaust duct 30 and the supply duct 40 together with the combustion gas, the temperature in the attic space decreases to atmospheric temperature after the snow melting device is stopped. This causes a problem in that the water vapor contained in the combustion gas condenses, increasing the humidity in the attic space.

(Purpose of the invention) In view of the above-mentioned conventional problems, the present invention aims to provide a snow melting device in which the humidity in the attic space does not increase even if the temperature of the attic space drops to atmospheric temperature when the snow melting device stops operating. be.

(Means for solving the problem) In order to achieve the above-mentioned purpose, the present invention is installed in a machine room adjacent to another room, sucks air from the machine room, heats it, generates hot air, and discharges it to the machine room. A hot air generating device that generates hot air, a supply blower mechanism that sucks the discharged hot air and sends it to the attic space, and a return blower mechanism that sucks air from the attic space and returns it to the machine room. Therefore, the total pressure of recirculation of the recirculation blower mechanism was set to be higher than the total supply pressure of the recirculation blower mechanism.

(Function) According to the present invention, the total return pressure of the return blower mechanism is set higher than the total supply pressure of the feed blower mechanism, so when the snow melting device is in operation, the internal pressure of the machine room is lower than that of other The air is higher than the room, so the humid waste heat air from other rooms does not flow into the machine room, and the warm air sent to the attic is circulated through the machine room and the attic. Even if the snow melting equipment is stopped and the temperature in the attic drops to atmospheric temperature, the humidity in the attic will never rise above the atmospheric humidity. do not have.

(Embodiment) FIG. 1 shows an embodiment of the present invention, in which the same components as those of the conventional example are denoted by the same reference numerals. That is, 1
0 is a machine room, and a ventilation port 11 is provided in the partition wall with the linen room 70, and a ventilation port 12 is provided in the partition wall with the living room 80.

20 is a hot air generator that sucks air from the machine room 10 from below, heats it, and discharges hot air into the machine room 10 from above. Reference numeral 30 denotes an intake/exhaust duct for taking in combustion air and exhausting combustion gas, which penetrates the partition wall between the machine room 10 and the living room 80 and extends from the living room 80 further outdoors. Reference numeral 40 denotes a supply duct for supplying warm air to the attic, one end of which is installed vertically below the hot air generator 20 in the upper part of the machine room 10 with an appropriate distance therebetween. 41 is stored, and the other end penetrates the ceiling of the machine room 10.
It is inserted into one end of the flexible tube 42. Also flexible tube 4
2 is arranged along the attic and the other end is open.

Reference numeral 50 denotes a return duct, which is attached to one end of the ceiling penetrating part 13 of the machine room 10 and is installed vertically downward.The other end has an appropriate distance from the hot air generator 20, and there is a return duct inside. A blower 51 is housed therein.
The recirculation blower 51 has a higher output than the supply blower 41, and its recirculation total pressure is set higher than the total supply pressure of the supply blower 41. 6
0 is an attic space, inside which is the flexible pipe 42.
is provided, and an outside air intake port 61 is provided on the side wall of the attic.
has been established.

A linen room 70 is adjacent to the machine room 10 via a side wall. A ventilation opening 11 is provided at the bottom of the side wall between the machine room 10 and a ventilation fan 71 at the top of the partition wall from the outside.
has been established.

According to this embodiment, when the snow melting device is in operation, when the air flow rate Q3 by the supply air blower 41 is 1000 m ³ /hour, the recirculation air blower 51 blows the entire air flow rate Q3 into the machine room 10 . The air flow rate Q1 is
When air leaks from the machine room 10 to the outside, the amount of air is increased by flowing in from the outside air intake port 61. For example, if the inflow amount Q5 from the outside air intake port 61 is
When the air flow rate is 150m ³ /hour, the air flow rate Q1 is 1150m ³ /hour. The hot air generator 20 has a supply amount Q2'
Assuming that the flow rate is 900 m ³ /hour, part Q2 of the air flow rate Q1 returned to the inside of the machine room 10 from the circulation blower 51 is sucked in at a rate of 900 m ³ /hour. Then, heat is exchanged by a heat exchanger inside the hot air generator 20, and a supply amount Q2' of hot air is generated and discharged into the upper space of the machine room 10. Supply blower 41 of the supply duct 40
is the supply amount Q supplied from the hot air generator 20
2′ and a bypass amount Q4 of a part of the air amount Q1 circulated from the recirculation blower 51 = 100
m ³ /hour, and the flexible pipe 42 is installed in the attic space 60.
to be sent via. The warm air supplied to the attic space 60 with a supply amount Q3 and the dry outside air with an inflow amount Q5 flowing into the attic space 60 from the outside through the outdoor air intake 61 are mechanically heated by the recirculation blower 51 at the air flow amount Q1. It is refluxed into the chamber 10. On the other hand, when drying the inside of the linen room 70, the ventilation fan 7
1 is driven. A bypass amount of a portion of the air flow Q1 recirculated from the recirculation blower 51, in this case, Q7 = 150 m ³ /hour, is the dry warm air that flows into the machine room 1.
0 into the linen room 70, and the ventilation fan 71 discharges air at a delivery rate of Q6=150 m ³ /hour to the outside. On the other hand, when heating the inside of the living room 80, if the ventilation fan 71 is stopped and the bypass amount Q7 to the linen room 70 is set to 0, part of the air flow Q1 recirculated from the recirculation fan 51 is bypassed. A quantity of dry warm air, in this case Q8 = 150 m ³ /hour, flows from the machine room 10 into the living room 80 .

According to this embodiment, since the total pressure of the recirculation blower 51 is higher than the total pressure of the recirculation blower 41, the air pressure inside the machine room 10 is higher than the surrounding air pressure. Therefore, when the snow melting equipment is in operation, high humidity waste heat air does not flow into the attic space through the machine room, so even if the attic space cools to atmospheric temperature after the snow melting equipment stops operating, water vapor will not flow into the attic space. It will not condense.

(Effects of the invention) As explained above, according to the invention, since the total pressure of the recirculation by the recirculation blower mechanism is set higher than the total pressure of the recirculation by the recirculation blower mechanism, during the operation of the snow melting equipment, The internal pressure of the machine room is higher than that of other rooms, and the humid domestic waste heat air from other rooms does not flow into the machine room, so the domestic waste heat space is used as the attic space. Since the snow melting equipment is not sent to the attic, it has the effect that moisture will not condense in the attic and the humidity will not increase even after the snow melting equipment stops operating.

[Brief explanation of the drawing]

FIG. 1 is a partially cutaway side view of a snow melting device according to the present invention. FIG. 2 is a partially cutaway side view showing a conventional example. In the figure, 10...Machine room, 20...Hot air generator, 30...Intake/exhaust duct, 40...Feeding duct, 41...Blower for feeding, 50...Return duct, 51...For recirculation Blower, 60...Attic space, 61...Outside air intake, 70...Linen room, 7
1... Ventilation fan, 80... Living room.

Claims (1)

[Scope of utility model registration request] A hot air generator installed in a machine room adjacent to another room, which takes in air from the machine room, heats it, generates hot air, and discharges it into the machine room, and a hot air generator that sucks in the discharged hot air and supplies it to the attic space. It is equipped with a blower mechanism for supplying air, and a blower mechanism for recirculating air that sucks air from the attic space and returns it to the machine room, and the total pressure of the recirculation air blower mechanism is controlled by the blower mechanism for recirculating the air. A snow melting device characterized by being set higher than the total feed pressure.