KR100885702B1 - Energy saving type hot wind heater for cultivation facilities and stalls - Google Patents

Abstract

An energy-saving hot wind heater for an equipment cultivation house and a livestock shed is provided to improve the heating efficiency remarkably in a wide area of house. An energy-saving hot wind heater for an equipment cultivation house and a livestock shed comprises a main body(1); a combustion chamber(2) where a diaphragm(7) is installed at the internal upper part; a heat radiation pipe(5); and an air blower(6), wherein a photocatalyst is installed in the hot air passing hole formed at the back part of the diaphragm to burn the incomplete ventilation gas discharged after the first combustion in the combustion chamber, and the refractory brick(9) is installed the upper surface of the diaphragm to burn completely the incomplete ventilation gas by the radiant heat generated by the heat delivered through the diaphragm.

Description

Energy saving type hot wind heater for cultivation facilities and stalls}

The present invention relates to a facility cultivation house and livestock energy-saving hot air heater, and more particularly, to continuously supply a hot air of a predetermined temperature to farm products grown inside the facility cultivation house, such as various vinyl houses or to use in a barn or the like. In the construction of a warm air heater, a diaphragm is installed in the upper portion of the combustion chamber, a photocatalyst is installed in a hot-passing hole formed in the rear portion of the diaphragm, and a fire brick is installed on the upper surface of the diaphragm. At the inlet of the heat sink, the vortex generator is installed and burned by the burner, and the exhaust gas discharged together with the incomplete gas is returned to the second and third times by the heat of the photocatalyst itself and the radiant heat generated from the refractory brick. After complete combustion, the entire inside of the heat dissipating tube is vortexed and the heat dissipating tube is kept for a long time to be discharged The thermal efficiency of the hot air heater can be greatly improved, and the heating effect can be increased in large areas such as livestock houses and work sites including facility cultivation houses by operating short-time hot air heaters. It can reduce the burden of human resources, improve the competitiveness of cultivated crops and livestock raising, and can also provide economic benefits for facility horticultural farmers and livestock breeding farmers. Since the amount of generated CO gas can be significantly reduced, the invention has been invented to significantly reduce the environmental pollution caused by the exhaust gas generated due to incomplete combustion of the warm air heater.

In general, the configuration of a warm air heater used in a vinyl house or barn is to draw the outside air by the suction force of the blower into the air chamber inside the heater, and the high heat is heated together with the contact with the cylindrical combustion chamber burned by the burner and the combustion tube communicating with it. It consists of a structure that raises the temperature.

In addition, this type of hot air heater is used to maintain an appropriate room temperature in a greenhouse, a flower garden or a barn house.

On the other hand, since the warm air heater mainly uses oil as a fuel, the burden of a lot of fuel costs due to the increase in crude oil in farms is generated.

In addition, the hot air heater used in the prior art has the flame of the burner directly touching the inside of the combustion chamber, which promotes oxidation at a high temperature, which shortens the life of the heater and increases the heat loss emitted by the communication without allowing the heat to stay in the heater for a long time. There is a problem that the energy efficiency is extremely low.

In addition, the heater is composed of one-stage and two-stage heat dissipation pipes connected to the cylindrical combustion chamber, but since the heat source generated in the combustion chamber does not stay inside the heater for a long time, the heat source of the heater is effectively used together with the waste of fuel. There is a discontinuation.

In particular, hot air heaters with 160,000 kcal or less can easily burn fuels, and therefore, the challenges to be overcome in providing various technologies for improving thermal efficiency through full combustion of fuels are easier than medium-sized hot air heaters. It is not reaching the heater.

This is because a significant problem has been raised in attempting to enlarge farming and livestock farming by installing a large area of plain water in farms and livestock farms.

Nevertheless, the hot air heater provided in the conventional farmhouse and barn has a structure in which the heat radiating tubes accommodating the burner are simply installed in the transverse direction between the cylinders so that the hot air is burned in the combustion chamber of the furnace accommodating the burner. The gas quickly exits through the flue (ie the heat sink) in communication with the heat exchanger.

Therefore, in recent years, efforts have been made in a small hot air heater to have a high-efficiency hot air fan out of the conventional method having such a configuration, and is limited to the method described above even in the case of a large hot air heater.

On the other hand, as a method for recovering the waste heat has been variously presented, such as domestic registration room No. 20-0355736 "hot air heater having a multi-stage heat exchanger" and domestic registration room No. 20-0397123 "energy saving heat exchanger".

In the above, Korean Registered Room No. 20-0355736 "Hot air heater having a multi-stage heat exchanger" is a cylindrical combustion chamber for burning the air supplied by the suction power of the blower to the air chamber inside the main body by the oil burner, and the first stage and the second stage. In the agricultural hot air heater for heating the heat exchange tube and supplying the warm air generated through the discharge port, a single stage, two stage, three stage, four stage multi-stage type capable of transferring a heat source to the upper side and one side of the combustion chamber. Means for forming a heat exchange tube, wherein the heat source passing through the first stage heat exchange tube is discharged through a two stage heat exchanger proximate to the separation plate; A heat source passing through the two-stage heat exchanger tube includes a means for inducing a heat source into a three-stage heat exchanger tube separated by a diaphragm; The heat source discharged through the three-stage heat exchanger tube is convection circulated back to the four-stage heat exchanger tube and is configured to escape to the outside through the communication formed at the upper side of the main body.

Therefore, while maintaining the heat source generated in the combustion chamber in a long heat exchanger tube installed in multiple stages for a longer time, the hot air can be continuously supplied to the inside of the plastic house to some extent through a separate discharge port formed in the hot air heater. The hot air heater has only a method of delaying and discharging the heat discharged from the combustion chamber through a multi-stage heat exchanger tube, so that the gas moving speed of the long heat exchanger tube decreases, thus increasing the time of heat exchange. Due to this, the waste heat can be further reduced, while the longer the length of the tube, the lower the waste heat temperature is, so the temperature in the combustion chamber is lowered, leading to incomplete combustion, which in turn results in quenching due to the gas caused by incomplete combustion. By incomplete combustion The generated CO gas is formed of carbon in inner walls of the heat exchange tubes of the updated car exhaust and transfer process, the thus produced carbon is represented as a problem to drop the thermal efficiency by reducing the thermal conductivity.

In addition, the above-mentioned domestic registration room 20-0397123 "energy-saving heat exchanger" is supplied with a flame to the hot air outlet and the lower side of the hot air exhaust outlet is installed on both sides and the air blower is exhausted by the blower at the upper side A warmer main body having a burner; A plurality of bearing balls are drilled in the furnace for accommodating the flame of the burner into the inside of the main body of the hot air blower to form a flame plate accommodating the flame, and a double heat shield cylinder through which the extra flame passes, and an air permeable layer in which the heat passes. A first stagnant chamber having a half moon baffle plate formed with a horizontal diaphragm above the thermal layer and having a heat exchange chamber formed therein, and a half moon bearing ball having a half moon-shaped bore hole formed therein; Two cylinders in which a half moon baffle plate in which a plurality of vandal bearing balls are perforated is installed in a second stagnation chamber communicating with the first stagnation chamber and divided into two stages by the stagnation tube horizontally in the center of the interior to stagnate heat. Congestion tube consisting of; A third congestion chamber communicating with the second congestion chamber and leading to a plurality of transverse tubes in which exhaust heat is moved; The exhaust gas is exhausted through a plurality of transverse pipes of the third stagnation chamber.

However, if a heat exchanger having such a configuration is applied to a real medium-sized hot air heater, the diaphragm itself may be melted by the flame of a large burner, and the technology of stabilizing the exhaust gas in a stagnation chamber equipped with a half moon baffle pipe is applied to the perforated inner wall. It acts as a side effect of inducing the production of carbon rather than the effect of increasing the efficiency due to the thermal stagnation due to the formed projections, which hinders the flow of heat, and the stagnation of heat in the first to third stagnation chambers I have the same problem.

In addition, the structure of the combustion chamber itself is very complicated, which leads to high production cost and labor cost, and high failure rate due to clogging during use. Also, considering the thermal conductivity and material characteristics of the combustion chamber material of the hot air blower, While stainless steels are used a lot, such stainless steels are sensitive to heat reaction speed (ie, the degree of shrinkage and expansion are severe). Thus, when a combustion chamber having the above-described structure is made of such a material, the internal structure of the combustion chamber itself is severe. There is a risk of damage due to deformation, in particular, there is a problem such as shortening the life due to severe corrosion at low temperatures.

The present invention has been made in order to solve such a conventional problem, a plate is installed in the upper portion in the combustion chamber of the warm air heater, a hot catalyst formed in the rear portion of the plate through the photocatalyst, the plate Fireproof bricks are installed on the upper surface of the building, and if necessary, a vortex generator is installed at the inlet of the heat dissipation tube to perform primary combustion by the burner, and then second combustion of incomplete gas through the photocatalyst, and Radiant heat can be completely burned in three stages, and the exhaust gas can vortex the entire inside of the heat dissipation tube and stay and discharge the heat dissipation tube for a long time, which can greatly improve the thermal efficiency of the hot air heater. As a result, it is possible to increase the heating effect of large areas such as barns and workplaces including facility cultivation houses. Expensive and expensive fuel consumption control can reduce the economic burden on the user, and in particular, improve the competitiveness of cultivated crops and livestock raising, as well as provide economic benefits to facility horticultural farmers and livestock breeding farmers. In addition, the amount of CO gas generated can be drastically reduced through 2-3 times of combustion, which can reduce carbon formation on the inner wall of the combustion chamber and the inner surface of the heat dissipation pipe due to incomplete combustion of the warm air heater. The purpose is to provide energy-saving hot air heaters for facility cultivation houses and livestock farms that can greatly reduce pollution.

The present invention for achieving the above object is a rectangular box-type body having a configuration provided with a duct in the lower portion, the front, the rear and a lower side; A combustion chamber having a cylindrical shape and installed in a horizontal direction at the bottom of the main body and releasing the heat of combustion generated by oil burning in a burner installed at one side; Several heat dissipation pipes disposed between the exhaust gas discharge ports of the combustion chamber and the first and second stagnation chambers and the exhaust ports which are zigzag with each other and dissipate heat of the exhaust gas discharged from the combustion chamber to the outside; Installed in the upper part of the main body by sucking the external air forcibly blows air to the outer circumferential surface of the heat dissipation pipes and the combustion chamber to blow the heated air through the duct forced air blowing through the duct to the facility cultivation house and barn In the facility cultivation house and livestock energy-saving hot-air heater provided, the diaphragm is installed in the upper portion of the combustion chamber, the hot air passing hole formed in the rear portion of the diaphragm is discharged after the first combustion in the combustion chamber It is a basic feature to install a photocatalyst for secondary combustion of incomplete exhaust gas.

In addition, if necessary, the refractory brick is installed on the upper surface of the diaphragm so as to completely burn the incomplete exhaust gas three times through radiant heat generated by itself by the heat transferred through the diaphragm.

If necessary, a vortex generator is further provided at the inlet of the heat dissipation tube to vortex the exhaust gas to increase the residence time of the exhaust gas passing through the heat dissipation tube.

At this time, the vortex generator is characterized in that it has a fixed or rotary propeller shape.

As described above, according to the present invention, a diaphragm is installed above the combustion chamber of a large hot air heater used in a facility cultivation house and a barn with a relatively large area. The fireproof brick is installed on the upper surface of the diaphragm, and if necessary, a vortex generator is installed at the inlet of the heat dissipation tube to secondary the incomplete exhaust gas discharged after the first combustion by the burner through the photocatalyst. Combustion can be completely burned through the radiant heat generated from the fire brick again, and the exhaust gas discharged after the third burn is vortexed throughout the inside of the heat dissipation tube. Therefore, the thermal efficiency of the warm air heater can be greatly improved, and the facility cultivation house can be operated by operating the warm air heater for a short time. It can greatly increase the heating effect in a large area such as a livestock house and a work site, and reduce the economic burden on the user through expensive fuel consumption control. In addition to improving the horticultural and livestock raising farmers' economic benefits, and reducing the amount of CO gas generated through 2-3 times of reburning the exhaust gas, incomplete heating wind heaters It is a very useful invention that can reduce the carbon formation on the inner wall of the combustion chamber and the inner surface of the heat dissipation tube due to combustion, as well as greatly reduce environmental pollution due to exhaust gas.

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

Figure 1 shows a perspective view of the present invention warm air heater, Figure 2 shows a front cross-sectional view of the present invention warm air heater.

According to the present invention, the rectangular housing body (1) having a configuration provided with a duct (11) in the lower front and rear, and the upper part of the plurality of blowers (6); A combustion chamber (2) having a cylindrical shape and installed in the horizontal direction at the bottom of the main body (1) to dissipate the heat of combustion generated by oil being burned in the burner (21) installed at one side; First and second stagnation chambers 3 and 4 and exhaust ports 51 zigzag formed on both sides of the exhaust gas outlet 12 formed in the upper portion of the combustion chamber 2 and the outer upper surface of the combustion chamber 2. A plurality of heat dissipation tubes 5 disposed between the plurality of heat dissipation tubes 5 to dissipate heat of exhaust gas discharged from the combustion chamber 2 to the outside; Installed in the upper part of the main body 1 to suck the outside air forcibly blows air to the outer circumferential surface of the heat dissipation pipes 5 and the combustion chamber 2, the air heated by heat exchange is cultivated through the duct 11 In a facility cultivation house and several energy-saving hot air heaters for livestock house equipped with several blowers (6) which are forced to blow to the house and barn,

The diaphragm 7 is installed in the upper portion in the combustion chamber 2, and the hot-passing hole 71 formed in the rear portion of the diaphragm 7 is discharged after primary combustion in the combustion chamber 2. It is characterized in that the further provided a photocatalyst 8 for secondary combustion of incomplete exhaust gas.

In addition, if necessary, the refractory brick 9 is installed on the upper surface of the diaphragm 7 to completely burn the incomplete exhaust gas three times through radiant heat generated by itself by the heat transferred through the diaphragm 7. It is characterized by being able to give.

If necessary, a vortex generator 10 is further provided at the inlet of the heat dissipation tube 5 to vortex the exhaust gas to increase the residence time of the exhaust gas passing through the heat dissipation tube 5. It is characterized by.

At this time, the vortex generator 10 is characterized in that it has a fixed or rotary propeller shape.

Referring to the effect of the facility cultivation house and livestock energy-saving hot air heater of the present invention configured as described above are as follows.

First, the facility cultivation house and livestock energy-saving hot air heater of the present invention is a rectangular box body (1) having a duct (11) in the lower front and rear, a combustion chamber (2) having a burner (21), In a known facility cultivation house having first and second stagnation chambers (3) (4), several heat dissipating tubes (5), and several blowers (6), and an energy-saving hot air heater for livestock, the combustion chamber (2) The inside of the diaphragm (7) is installed in the upper portion, the heat through-holes 71 formed in the rear portion of the diaphragm (7) to further install a photocatalyst (8) as the main technical component.

At this time, the rectangular housing body (1) has a configuration in which the duct 11 is provided in the lower part of the front, rear, and the upper part of the blower 6 is installed, the combustion chamber (2) is basically a cylindrical shape It is installed in the transverse direction at the bottom of the main body 1 has the function of guiding the exhaust gas as well as dissipating the heat generated by the combustion of oil in the burner 21 installed on one side.

In addition, the several heat dissipation pipes 5 are the first and second stagnation chambers zigzag arranged on both sides of the exhaust gas outlet 12 formed in the upper portion of the combustion chamber 2 and the outer upper surface portion of the combustion chamber 2. (3) It is installed in three stages between the (4) and the exhaust port 51 to perform a function to sufficiently dissipate the heat of the exhaust gas discharged from the combustion chamber (2) to the outside, the blower (6) Installed in the upper part of the main body 1 to suck the outside air forcibly blows air to the outer peripheral surface of the heat dissipation pipes 5 and the combustion chamber 2, the air heated by heat exchange is lower than the front and rear of the main body 1 Through the duct 11 formed in the part to perform a function to force the air blowing to the facility cultivation house and barn.

In the present invention, on the other hand, a diaphragm 7 is provided in the upper portion inside the combustion chamber 2 having a cylindrical shape, and is formed in the hot air passing hole 71 formed in the rear portion of the diaphragm 7. By further installing the photocatalyst 8, the incomplete exhaust gas discharged after the primary combustion in the combustion chamber 2 is burned again (that is, the second) through the photocatalyst 8 so that it is harmful to human body. In addition to reducing the amount of gas, the exhaust gas of the high temperature combustion chamber 2 is not discharged directly through the exhaust gas outlet 12 to the heat dissipation pipe 5 at the first stage. Since it passes through the space formed between the upper surface, the residence time becomes longer so that the amount of heat dissipation to the outside through the combustion chamber 2 can be increased, although the warm air heating efficiency of the blower 6 can be increased accordingly.

At this time, if only the space portion is formed between the upper surface and the diaphragm 7 of the combustion chamber 2, even if the exhaust gas is secondary combustion by the photocatalyst 8, complete combustion does not occur and therein At least some of the components are incompletely burned.

Therefore, in the present invention, the refractory brick 9 is further installed on the upper surface of the diaphragm 7, and in the state where the refractory bricks 9 are heated by the heat of the combustion chamber 2 normally transmitted through the diaphragm 7. By allowing radiant heat to be generated, the diaphragm 7 and the combustion chamber after primary combustion in the interior of the combustion chamber 2 and the incomplete exhaust gas are secondaryly burned by the photocatalyst 8 while passing through the heat passage hole 71. Since the third combustion is performed by radiant heat generated from the firebrick 9 while passing through the space formed between the upper surfaces of 2), the space formed between the diaphragm 7 and the upper surface of the combustion chamber 2 is fixed. When passing through the residence time, the third combustion occurs and the combustion state is completely burned, so that the thermal efficiency of the warm air heater can be improved by that much, and the heat dissipation to the outside is made much. As a result, it is possible to increase the heating effect of large areas such as livestock houses and work sites including facility cultivation houses, and to reduce the economic burden on users through expensive fuel consumption control. In addition, it can provide economic benefits for horticultural farmers and livestock raising farmers.

At this time, the temperature of the refractory brick (9) installed on the upper surface of the diaphragm (7) is different depending on the amount of heat of combustion of the combustion chamber (2), but is designed to maintain the normal 600 ℃ or more conventional hot air heater is a blower ( In operation 6), the external temperature of the combustion chamber 2 is lowered below 400 ° C., but the diaphragm 7 is provided in the upper part of the combustion chamber 2 as in the present invention, and the rear part of the diaphragm 7 is provided. In addition, a photocatalyst 8 is further installed in the formed hot-passing hole 71, and when the refractory brick 9 is further installed on the upper surface of the diaphragm 7, the incomplete exhaust gas is further burned in the second and third stages. Since the temperature of the outer circumferential surface of the combustion chamber 2 (that is, the temperature of the upper part of the combustion chamber 2 in which the refractory brick 9 is installed) can be raised to 450 ° C. or higher, which can burn up to CO gas, the hot air heater finally CO gas is contained in the exhaust gas Not only can the environmental pollution be completely prevented, but the CO gas generated during the incomplete combustion can be stuck to the inner wall of the combustion chamber 2 as tar, thereby preventing the lowering of the amount of heat emitted from the combustion chamber 2 itself.

That is, incomplete combustion by first burning the exhaust gas firstly burned in the combustion chamber 2 through the photocatalyst 8 and completely burning it over three times through radiant heat generated from the refractory brick 9 again. The amount of generated CO gas can be greatly reduced, which can significantly reduce carbon formation in the inner wall of the combustion chamber 2 caused by incomplete combustion of the warm air heater, and can significantly reduce environmental pollution due to CO gas emission.

On the other hand, the exhaust gas exhaust port 12 and the combustion chamber formed in the upper portion of the combustion chamber (2) exhaust gas completely burned by the heat generated in the photocatalyst 8 and the refractory brick (9) After passing through several heat dissipating pipes 5 provided between the first and second stagnation chambers 3 and 4 and the exhaust port 51, which are zigzagly arranged on both sides of the outer upper surface of 2), the exhaust port If it is discharged to the outside through (51), the exhaust gas exhaust speed is high, and the heat exchange efficiency with the outside air is not only lowered. There exists a possibility that tar may laminate | stack inside the heat radiating pipe 5 by the temperature which passes through (5).

Therefore, in the present invention, if necessary, a fixed or rotary propeller shape for increasing the residence time of the exhaust gas passing through the heat radiating tube 5 by swirling the exhaust gas at the inlet of the heat radiating tube 5. By further installing the vortex generator 10, the residence time of the exhaust gas in the heat dissipation tube 5 can be increased, and tar is dissipated by the vortex phenomenon of the exhaust gas (that is, the phenomenon of rapidly rotating and rotating). Adsorption on the inner wall of the pipe 5 can be prevented, so that the heating efficiency in the heat dissipating pipe 5 can be greatly improved, and tar can be prevented from being adsorbed on the inner wall of the heat dissipating pipe 5 even after long-term use. Therefore, it is possible to prevent the deterioration of the conductivity of electricity due to the deposition of tar on the inner wall of the heat dissipation tube.

At this time, the vortex generator 10 may be provided with any form as long as it can vortex the exhaust gas. In the present invention, the vortex generator 10 having the propeller shape is fixedly installed at the inlet of the heat dissipation tube 5. Or rotatably installed.

That is, in the present invention, the vortex generator 10 is installed as a fixed propeller so that the exhaust gas flowing into the heat dissipation tube 5 vortexes along the wing surface of the fixed propeller having a shape such as a blade of a fan, or a rotary type. By installing a propeller, the above-described effect can be obtained by allowing the exhaust gas to vortex while the blade itself of the rotary propeller having a shape such as a fan of the fan is rotated by the inlet pressure of the exhaust gas flowing into the heat dissipation pipe 5.

In addition, when the several heat dissipation pipes 5 are installed, the first and second stagnation chambers 3 and 4 are disposed between the exhaust gas discharge port 12 and the exhaust port 51 formed above the combustion chamber 2. By installing zigzag and installing the heat dissipation tube 5 in three stages between them, the thermal efficiency can be significantly improved compared to the prior art, and the temperature and time of exhaust gas can be significantly reduced, according to the results of the present inventors' test. Results data or graphs are not shown) It was confirmed that the hot air heater of the present invention is 10-20% improved in terms of thermal efficiency than the conventional hot air heater, and the temperature of the exhaust gas discharged through the exhaust port 51 is conventionally 250-300. It was confirmed that the temperature was significantly lowered from 150 to 200 ℃, and as a result, the hot air heater of the present invention was able to obtain an average 15-20% fuel savings compared to the hot air heater of the same standard.

Although the above-described embodiments have been described with respect to the most preferred embodiments of the present invention, it is not limited to the above embodiments, and it will be apparent to those skilled in the art that various modifications can be made without departing from the technical spirit of the present invention.

1 is a perspective view of the present invention warm air heater.

Figure 2 is a cross-sectional view of the present invention hot air heater.

Explanation of symbols on the main parts of the drawings

1: main body 2: combustion chamber

3: 1st congestion room 4: 2nd congestion room

5: heat pipe 6: blower

7: diaphragm 8: photocatalyst

9: firebrick 10: vortex generator

11 duct 12 exhaust gas outlet

21: burner 51: exhaust vent

71: hot air hole

Claims (4)

A rectangular enclosure-type main body having ducts in the front and rear lower portions thereof; A combustion chamber having a cylindrical shape and installed in a horizontal direction at the bottom of the main body and releasing the heat of combustion generated by oil burning in a burner installed at one side; Several heat dissipation tubes dissipating heat of exhaust gas discharged from the combustion chamber to the outside; Installed in the upper part of the main body to suck the outside air forcibly blows air to the heat dissipation pipes and the outer peripheral surface of the combustion chamber so that the heated air through the heat exchange inside the main body is forced to the facility cultivation house and barn through the duct In the facility cultivation house with several blowers and the energy-saving hot air heater for livestock, The diaphragm is installed in an upper portion of the combustion chamber, and a photocatalyst for secondary combustion of the incomplete exhaust gas discharged after the first combustion in the combustion chamber is installed in the heat passing hole formed in the rear portion of the diaphragm. , Facility cultivation house and livestock energy, characterized in that the fire brick is installed on the upper surface of the diaphragm to completely burn the incomplete exhaust gas three times through the radiant heat generated by the heat transmitted through the diaphragm. Economy hot air heater. delete The method according to claim 1, An energy-saving hot air heater for facility cultivation house and livestock, characterized in that a vortex generator is further installed at the inlet of the heat dissipation tube to increase the residence time of the exhaust gas passing through the heat dissipation tube. The method according to claim 3, The vortex generator is a facility cultivation house and livestock energy-saving hot air heater characterized in that it has a fixed or rotary propeller shape.

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