A noise reduction energy-saving generator room

Abstract

The present application relates to the technical field of generator room, in particular to a noise reduction and energy saving type generator room; through the setting of the case, the door, the sound absorption layer, the air inlet, the air outlet, the mounting plate, the cross slot, the shock absorbing layer and the mounting box; the water drop on the bending plate one slides to the lower end of the bending plate one, then drops from the end of the bending plate one close to the air outlet, and the dropped water drop falls on the bending plate two, so that the water drop falling on the bending plate two slides along the inclined surface of the bending plate two to the direction of the drain hole, then is discharged from the drain hole, and further makes the steam discharge chamber when discharging steam, so that the water drop condenses on the bending plate one, the water drop falls from the bending plate one to the bending plate two, thereby avoiding the condensation of steam on the upper inner wall of the case, causing the condensed water drop to re-drip into the steam discharge chamber, and further avoiding the water vapor into the mounting chamber.

Description

Technical Field

[0001] This invention relates to the field of generator room technology, specifically a noise-reducing and energy-saving generator room. Background Technology

[0002] In industrial production, construction projects, medical rescue, commercial complexes, data centers, and remote areas without power grid coverage, a stable and continuous power supply is a core prerequisite for ensuring the normal operation of various activities. Power grid supply is susceptible to factors such as natural disasters, line faults, and peak load fluctuations, which can easily lead to power outages and unstable power supply, resulting in serious consequences such as production stoppages, equipment damage, rescue obstruction, and paralysis of critical systems. Therefore, backup power generation systems have become an indispensable supporting facility in various scenarios.

[0003] As the core carrier of the backup power generation system, the generator room is a dedicated space for installing, operating and maintaining generator sets. Its core function is to provide a safe and stable operating environment for the generator sets, while also achieving functions such as noise control, heat dissipation and ventilation, exhaust gas emission and safety protection, taking into account the operating efficiency and service life of the generator sets as well as the safety of the surrounding environment and personnel.

[0004] Furthermore, although existing generator rooms can achieve basic power generation functions, there are still many shortcomings in practical applications. For example, some generator rooms are not equipped with complete steam discharge and condensate collection systems. When using silencer spray for noise reduction and cooling, the sprayed water mist comes into contact with the high-temperature flue gas pipes, which can cause steam to fill the generator room, corrode electrical equipment and sound insulation materials, and shorten the service life of the equipment and generator room.

[0005] In summary, to solve the technical problems raised in this paper, this invention proposes a noise-reducing and energy-saving generator room. Summary of the Invention

[0006] To address the aforementioned shortcomings in practical applications, such as the lack of comprehensive steam discharge and condensate collection systems in some computer rooms, which leads to steam contamination of the room when using silencer spray systems for noise reduction and cooling, corroding electrical equipment and sound insulation materials, and shortening the lifespan of both the equipment and the computer room, this invention proposes a noise-reducing and energy-saving generator room. This generator room includes a chassis, a door, a sound-absorbing layer, an air inlet, and an air outlet. The door is located on the chassis. The sound-absorbing layer is laid on the inner wall of the chassis, and the air inlet and outlet are located on both sides of the chassis. The interior of the chassis also includes:

[0007] The mounting plate is located in the middle of the lower wall of the chassis, and cross grooves are opened at the four corners of the mounting plate; and a shock-absorbing layer is provided in the middle of the upper end of the mounting plate.

[0008] The mounting box is positioned above the mounting plate, with its lower end in contact with the damping layer. Support columns are located at the four corners of the lower end of the mounting box, and these support columns are slidably connected to the center of the cross groove. Springs are installed on all four sides of the cross groove, and the springs are connected to the sides of the support columns. The inner wall of the mounting box is lined with a sound-absorbing layer.

[0009] An isolation plate is installed inside the mounting box, creating two cavities: a steam exhaust chamber and an installation chamber. The upper part of the steam exhaust chamber remains open, while the interior of the installation chamber remains closed. A vent is located at the lower end of the isolation plate, and a one-way valve is installed inside the vent. An air inlet is located at the upper end of the side of the installation chamber furthest from the isolation plate, and a dust filter is installed at the air inlet. An air intake fan is located below the dust filter.

[0010] A flexible sheet is installed at the top of the mounting box, and the upper end of the flexible sheet is connected to the upper inner wall of the chassis. The flexible sheet separates the chassis on both sides of the isolation plate.

[0011] As a preferred embodiment of this application, a bending plate is provided at the upper end of the mounting box. The vertical end of the bending plate is connected to the upper end of the mounting box, and the inclined end of the bending plate is located at the upper end of the opening of the steam exhaust chamber. The inclined end of the bending plate is inclined downward. A bending plate is provided inside the casing. One end of the bending plate is vertically upward, and the other end is fixed to the side wall of the casing. A drain hole is provided on the side wall of the casing, so that the end of the bending plate connected to the side wall of the casing is located at the lower opening of the drain hole.

[0012] As a preferred embodiment of this application, the bending plate is made of an elastic material, and a support rod is provided below the inclined end of the bending plate. The lower end of the support rod is in contact with the side wall of the mounting box, so that when the mounting box vibrates, the support rod and the side wall of the mounting box will have intermittent impacts.

[0013] As a preferred embodiment of this application, a rubber column is provided at the lower end of the support rod, the rubber column is connected to the side wall of the mounting box, and the interior of the rubber column is a hollow structure.

[0014] As a preferred embodiment of this application, a sponge block is provided below the inclined end of the bending plate 1. The sponge block has a triangular structure, and its bottom edge is fixedly connected to the lower part of the inclined end of the bending plate 1. The end of the sponge block with the smallest angle is located at the bending point of the bending plate 1.

[0015] As a preferred embodiment of this application, a rotating plate is rotatably connected to both sides of the end of the bending plate away from the mounting box. A counterweight is provided at the lower end of the rotating plate, and the upper end of the counterweight is inclined so that the inclined surface of the upper end of the counterweight fits into the inclined surface of the sponge block.

[0016] As a preferred embodiment of this application, a rectangular through groove is provided at the lower end of the counterweight, the rectangular channel is connected to the upper end of the counterweight, and the lower end of the counterweight is tapered.

[0017] As a preferred embodiment of this application, the end of the second bent plate near the mounting box is in contact with the mounting box, and the second bent plate is made of elastic material, and a rubber layer is laid on the end of the second bent plate in contact with the mounting box, so that the rubber layer is in contact with the mounting box.

[0018] The beneficial effects of this invention are as follows:

[0019] Water droplets on bending plate one slide down to the lower end of bending plate one and then drip from the end of bending plate one near the air outlet. The dripping water droplets fall onto bending plate two, one end of which is vertical and the other end is inclined downward. The side wall of the casing is provided with a drain hole, and the lower end of the drain hole is located at the end of the bending plate that connects to the inner wall of the casing. This causes the water droplets falling onto bending plate two to slide down along the inclined surface of bending plate two towards the drain hole and then be discharged from the drain hole. As steam is discharged from the steam exhaust chamber, water droplets condense on bending plate one and fall down from bending plate one to bending plate two. This prevents steam from condensing on the upper inner wall of the casing and causing the condensed water droplets to drip back into the steam exhaust chamber, thus preventing water vapor from entering the installation chamber. Attached Figure Description

[0020] Figure 1 This is a perspective view of the generator room in this invention;

[0021] Figure 2 This is a perspective view of the generator room after the enclosure door has been removed in this invention;

[0022] Figure 3 This is an internal structural view of the chassis in this invention;

[0023] Figure 4 This is an internal structural view of the mounting box in this invention;

[0024] Figure 5 yes Figure 4 The front view in the middle;

[0025] Figure 6 yes Figure 4 Front sectional view of the mounting box;

[0026] Figure 7 This is a structural view of the bending plate one in this invention;

[0027] Figure 8 This is a structural view of the mounting plate in this invention;

[0028] Figure 9 This is a structural view of the counterweight block in this invention;

[0029] In the diagram: Chassis 1, door 11, sound-absorbing layer 12, air inlet 13, air outlet 14, mounting plate 15, cross groove 151, damping layer 152, mounting box 2, support column 21, isolation plate 22, steam exhaust chamber 221, mounting chamber 222, vent 223, air inlet 224, flexible sheet 23, bending plate one 24, bending plate two 25, drainage hole 16, support rod 241, rubber column 242, sponge block 243, rotating plate 26, counterweight block 251, rectangular through groove 252, rubber layer 253. Detailed Implementation

[0030] To make the technical means, creative features, objectives and effects of this invention easier to understand, the invention will be further described below in conjunction with specific embodiments.

[0031] Example 1:

[0032] like Figures 1 to 9 As shown; a noise-reducing and energy-saving generator room; the generator room includes a chassis 1, a door 11, a sound-absorbing layer 12, an air inlet 13, and an air outlet 14, the door 11 being disposed on the chassis 1; the sound-absorbing layer 12 being laid on the inner wall of the chassis 1, and the air inlet 13 and air outlet 14 being disposed on both sides of the chassis 1; the interior of the chassis 1 also includes:

[0033] Mounting plate 15 is located in the middle of the lower wall of chassis 1, and cross grooves 151 are provided at the four corners of mounting plate 15; and a shock-absorbing layer 152 is provided in the middle of the upper end of mounting plate 15.

[0034] Mounting box 2 is positioned above mounting plate 15. The lower end of mounting box 2 contacts the damping layer 152. Support columns 21 are provided at the four corners of the lower end of mounting box 2. The support columns 21 are slidably connected to the middle of cross groove 151, and springs are provided on all four sides of cross groove 151. The springs are connected to the sides of support columns 21. The inner wall of mounting box 2 is covered with sound-absorbing layer 12.

[0035] An isolation plate 22 is installed inside the mounting box 2, forming two cavities inside the mounting box 2. One cavity is a steam exhaust chamber 221, and the other is an installation chamber 222. The upper end of the steam exhaust chamber 221 is kept open, while the interior of the installation chamber 222 is kept closed. A vent 223 is provided at the lower end of the isolation plate 22, and a one-way valve is installed inside the vent 223. An air inlet 224 is provided at the upper end of the side of the installation chamber 222 away from the isolation plate 22, and a dust filter is provided at the air inlet 224. An air intake fan is provided at the lower end of the dust filter.

[0036] Flexible sheet 23 is disposed at the upper end of mounting box 2, and the upper end of flexible sheet 23 is connected to the upper inner wall of chassis 1. Flexible sheet 23 separates chassis 1 on both sides of isolation plate 22.

[0037] The upper end of the mounting box 2 is provided with a bending plate 24. The vertical end of the bending plate 24 is connected to the upper end of the mounting box 2. The inclined end of the bending plate 24 is located above the opening of the steam exhaust chamber 221, and the inclined end of the bending plate 24 is inclined downward. The inside of the casing 1 is provided with a bending plate 25. One end of the bending plate 25 is vertically upward, and the other end is fixed to the side wall of the casing 1. The side wall of the casing 1 is provided with a drain hole 16, so that the end of the bending plate 25 connected to the side wall of the casing 1 is located at the lower opening of the drain hole 16.

[0038] The bending plate 24 is made of elastic material, and a support rod 241 is provided below the inclined end of the bending plate 24. The lower end of the support rod 241 is in contact with the side wall of the mounting box 2, so that when the mounting box 2 vibrates, the support rod 241 and the side wall of the mounting box 2 will have intermittent impacts.

[0039] A rubber column 242 is provided at the lower end of the support rod 241. The rubber column 242 is connected to the side wall of the mounting box 2, and the interior of the rubber column 242 is a hollow structure.

[0040] The specific workflow is as follows;

[0041] During use, a mounting plate 15 is installed inside the casing 1. Cross grooves 151 are cut at each of the four corners of the mounting plate 15. A shock-absorbing layer 152, made of wear-resistant fluororubber, is laid in the upper center of the mounting plate 15. A mounting box 2 is installed on the mounting plate 15, with support columns 21 at the four corners of the lower end of the mounting box 2. The support columns 21 are slidably connected inside the cross grooves 151, and springs are installed at each of the four ends of the cross grooves 151, connecting the springs to the sides of the support columns 21. When the generator room is in use, an isolation plate 22 is installed inside the mounting box 2, dividing the mounting box 2 into two parts. The end closest to the exhaust port 14 is for steam. The generator consists of a discharge chamber 221 and an installation chamber 222, where the generator assembly is installed. A vent 223 is located at the lower end of the isolation plate 22, and a one-way valve is installed in the vent 223. This allows gas from the installation chamber 222 to flow into the steam discharge chamber 221, while preventing gas from the steam discharge chamber 221 from flowing into the installation chamber 222. An air inlet 224 is located at the end of the installation chamber 222 furthest from the steam discharge chamber 221. A dust filter is installed in the air inlet 224, and an intake fan is located below the dust filter. When the intake fan is working, it draws gas from inside the installation chamber 222. The upper part of the installation chamber 222... A flexible sheet 23, made of rubber, is provided and connected to the upper inner wall of the enclosure. This allows the flexible sheet 23 to separate the enclosure 1 on both sides of the partition plate 22. When the intake fan rotates, it draws air from the cavity inside the enclosure 1 furthest from the air inlet 13, allowing air to enter through the air inlet 13 at the end of the enclosure 1 closest to the mounting chamber 222. The air entering the enclosure 1 then enters the mounting chamber 222 through the air inlet 224. A dust filter at the air inlet 224 filters the air entering the enclosure 1, preventing dust from entering the mounting chamber 222. Once the air enters the mounting chamber 222, the air pressure inside increases. This allows the gas inside the installation chamber 222 to be discharged into the steam discharge chamber 221 through the vent 223. During this process, as the generator set operates, the spray silencing and cooling occur. The steam discharge chamber 221 has a spray silencing chamber, which is a component of the existing generator set. Specifically, after the gas generated inside the installation chamber 222 is introduced into the spray silencing chamber, a large amount of water vapor is generated inside the spray silencing chamber. At this time, the water vapor rises from the upper end of the steam discharge chamber 221. During this process, the water vapor comes into contact with the lower surface of the bending plate 24, and then, guided by the bending plate 24, the water vapor is discharged from the outlet 14.

[0042] In the above process, on the one hand, if the generator set is continuously generating electricity, it will vibrate. Existing vibrations are usually directly transmitted to the surface of the casing 1, causing resonance in the casing 1 and resulting in noise. However, when the generator set inside the mounting chamber 222 vibrates, the inner wall of the mounting chamber 222 is lined with a sound-absorbing layer 12, which is melamine sound-absorbing sponge as in the prior art. This allows the noise generated by the generator set during operation inside the mounting chamber 222 to be absorbed by the sound-absorbing layer 12. Simultaneously, if the generator set vibrates, it transmits the force generated by the vibration to the mounting box 2. By setting support columns 21 at the lower ends of the four corners of the mounting box 2, the support columns 21 are slidably connected to the cross grooves 151 on the mounting plate 15, ensuring that the mounting box 2 remains stable during vibration. The housing 2 can slide slightly in the cross groove 151 to dampen vibrations, thereby reducing noise generated by vibration. Furthermore, a damping layer 152, made of wear-resistant fluororubber, is provided at the upper center of the mounting plate 15 to dampen vibrations of the housing 2, reducing the direct transmission of vibration force to the chassis 1 and preventing chassis 1 from vibrating. Additionally, a sound-absorbing layer 12 is laid on the inner wall of the chassis 1. After the noise inside the housing 2 is absorbed by the sound-absorbing layer 12, the remaining small amount of noise is also absorbed by the sound-absorbing layer 12 inside the chassis 1, preventing the force generated by the vibration of the housing 2 from being directly transmitted to the chassis 1 and thus preventing chassis 1 from vibrating and generating noise. This achieves noise reduction for the generator.

[0043] On the other hand, based on the above, after the steam is discharged from the steam exhaust chamber 221, the steam will come into contact with the lower part of the bending plate 24, causing the lower part of the bending plate 24 to block the steam. Consequently, after the steam comes into contact with the bending plate 24, the bending plate 24 condenses the moisture in the steam, causing water droplets to condense on the inclined end of the bending plate 24. Because the bending plate 24 is inclined downwards, the water droplets condensed on the bending plate 24 will slide towards the lower end of the bending plate 24 and then drip from the end of the bending plate 24 near the exhaust port 14. The dripping water droplets fall onto the bending plate 25, one end of which is vertical. In this configuration, the other end is tilted downwards, and the side wall of the casing 1 is provided with a drain hole 16. The lower end of the drain hole 16 is located at the end of the bending plate connected to the inner wall of the casing 1. This allows water droplets falling onto the bending plate 25 to slide down along the inclined surface of the bending plate 25 towards the drain hole 16 and then be discharged from the drain hole 16. As a result, when the steam exhaust chamber 221 discharges steam, water droplets condense on the bending plate 24 and fall down from the bending plate 24 to the bending plate 25. This prevents steam from condensing on the upper inner wall of the casing 1, thus avoiding the problem of condensed water droplets dripping back into the steam exhaust chamber 221 and preventing water vapor from entering the installation chamber 222.

[0044] Furthermore, by using the elastic material of the bending plate 24, and by providing two support rods 241 at the lower end of the bending plate 24, with rubber columns 242 at the lower end of the support rods 241, and the rubber columns 242 being hollow inside, and contacting the outer wall of the mounting box 2, when the generator set inside the mounting box 2 is working, the vibration generated by the generator set is transmitted to the mounting box 2, causing the mounting box 2 to vibrate. This vibration in turn causes the bending plate 24 to vibrate. Due to the elastic material of the bending plate 24... Therefore, the bending plate vibrates. During the vibration of the bending plate 24, the support rod 241 at the lower end of the bending plate 24 will slightly impact the mounting box 2. At this time, the rubber column 242 will also impact the mounting box 2. On the one hand, the rubber column 242 will dampen the vibration of the bending plate 24, preventing the bending plate 24 from generating a large vibration force when it vibrates against the mounting box 2; and on the other hand, when the bending plate 24 vibrates, the water droplets condensed on it will drip off more quickly, thus facilitating the subsequent condensation of water droplets in the steam by the bending plate 24.

[0045] Example 2:

[0046] like Figures 2 to 9 As shown; a sponge block 243 is provided below the inclined end of the bending plate 24. The sponge block 243 has a triangular structure. The bottom edge of the sponge block 243 is fixedly connected to the lower part of the inclined end of the bending plate 24. The end of the sponge block 243 with the smallest angle is located at the bending point of the bending plate 24.

[0047] The specific workflow is as follows;

[0048] Based on the above embodiment one, the generator set is installed inside the installation chamber 222. When the intake fan is working, the gas filtered by the dust filter enters the installation chamber 222. After the gas pressure inside the installation chamber 222 increases, the gas is introduced into the steam discharge chamber 221 through the one-way valve of the vent 223 at the lower end of the isolation plate 22. When the generator set is working, the spray silencing and cooling is activated. A large amount of water vapor generated by the spray silencing chamber rises from the upper opening of the steam discharge chamber 221 and then contacts the lower surface of the bending plate 24. During this process... When water vapor rises from the top of the steam exhaust chamber 221, it first comes into contact with the triangular sponge block 243 below the bending plate 24. Because the sponge block 243 has excellent water absorption properties, and the inclination angle of the triangular structure is consistent with that of the bending plate 24, the moisture in the steam is quickly absorbed by the sponge block 243, preventing the moisture from directly separating from the steam and drifting into the interior of the casing 1. This reduces moisture adhesion to the inner wall of the casing 1, the sound-absorbing layer 12, and the surface of electrical equipment. Simultaneously, because the sponge block 243 is close to the exhaust port 14... One end of the sponge block 243 is thicker and is set at an angle. The water absorbed by the sponge block 243 will gradually flow towards the end closer to the air outlet 14 under the influence of gravity, preventing water from accumulating and becoming saturated inside the sponge block 243. This allows water to drip from the bottom of the sponge block 243 onto the bending plate 25. The water droplets on the bending plate 25 slide down the inclined surface of the bending plate 25 towards the drain hole 16 on the side wall of the chassis 1, and then drain out of the chassis 1. This prevents moisture from the steam from entering the mounting box 2, which could cause malfunctions in the power generation components. Furthermore, when the vibration generated by the generator is transmitted to the mounting box 2, causing the bending plate 24 to vibrate, the bending plate 24 will cause the sponge block 243 below to vibrate slightly in sync. This vibration will accelerate the flow of moisture absorbed inside the sponge block 243, preventing moisture from accumulating in the sponge block 243 and further improving the water absorption and drainage efficiency of the sponge block 243, ensuring that it will not fail due to water saturation during long-term use.

[0049] Example 3:

[0050] like Figures 1 to 9 As shown; a rotating plate 26 is rotatably connected to both sides of the end of the bending plate 24 away from the mounting box 2. A counterweight 251 is provided at the lower end of the rotating plate 26. The upper end of the counterweight 251 is inclined, so that the inclined surface of the upper end of the counterweight 251 is in contact with the inclined surface of the sponge block 243.

[0051] The lower end of the counterweight 251 is provided with a rectangular through groove 252, the rectangular channel is connected to the upper end of the counterweight 251, and the lower end of the counterweight 251 is tapered.

[0052] When the bending plate 24 vibrates, the counterweight 251 on the bending plate 24 will swing under the action of gravity, causing the counterweight 251 to squeeze the sponge block 243. During the process, after the sponge block 243 is squeezed, the counterweight 251 will accelerate the effect of water dripping from the sponge block 243. During the process, the water in the sponge block 243 can also drip from the rectangular through groove 252 on the counterweight 251.

[0053] The specific workflow is as follows;

[0054] Based on the above embodiment, the generator set generates steam. After rising, the steam absorbs moisture through the sponge block 243. The moisture flows down the inclined surface of the sponge block 243 to its lower end. Simultaneously, the vibration of the generator set is transmitted to the mounting box 2 and the bending plate 24, causing the bending plate 24 and the sponge block 243 to vibrate synchronously. During this process, when the bending plate 24 vibrates, it drives the rotating plates 26 on both sides to vibrate synchronously. However, the counterweight 251 at the lower end of the rotating plate 26, due to its own weight, will not vibrate violently synchronously with the rotating plate 26, but will instead... The rotating plate 26 undergoes a pendulum motion, and because the inclined surface of the upper end of the counterweight 251 is in close contact with the inclined surface of the sponge block 243, when the counterweight 251 swings, its inclined surface will reciprocate to squeeze the sponge block 243. When the counterweight 251 swings towards the sponge block 243, it squeezes the sponge block 243 and quickly squeezes out the water adsorbed inside the sponge block 243. When the counterweight 251 swings away from the sponge block 243, the sponge block 243 restores its deformation and continues to adsorb water from the steam, thereby accelerating the removal of water from the sponge block 243.

[0055] Based on the above, when the sponge block 243 is compressed, some water will flow along the inclined surface of the sponge block 243 to its lower end, and then drip onto the bending plate 25; while the other part of the water will flow directly into the inclined surface of the upper end of the counterweight block 251, and then drip quickly through the rectangular through-groove 252 at the lower end of the counterweight block 251, without needing to be guided by the lower end of the sponge block 243, further improving the efficiency of water removal from the sponge block 243; at the same time, the lower end of the counterweight block 251 is tapered, which can prevent water from accumulating at the lower end of the counterweight block 251; and the gravity of the counterweight block 251 can ensure that it is always in close contact with the sponge block 243, achieving a stable compression effect regardless of the vibration amplitude of the bending plate 24; the rotating connection design of the rotating plate 26 can adapt to changes in the vibration direction of the bending plate 24, preventing the counterweight block 251 from losing contact with the sponge block 243.

[0056] Example 4:

[0057] like Figures 2 to 9As shown; the end of the second bent plate 25 near the mounting box 2 is in contact with the mounting box 2, and the second bent plate 25 is made of elastic material, and a rubber layer 253 is laid on the end of the second bent plate 25 in contact with the mounting box 2, so that the rubber layer 253 is in contact with the mounting box 2.

[0058] The specific workflow is as follows;

[0059] Based on the above embodiments, the generator set will generate continuous vibration during operation. This vibration is transmitted to the mounting box 2 through the mounting chamber 222. When the mounting box 2 vibrates, its sidewall will repeatedly press against the rubber layer 253 at the contact end of the bending plate 25. The rubber layer 253 will undergo slight deformation after being pressed. When the vibration direction of the mounting box 2 reverses and the pressing force disappears, the bending plate 25 will return to its original position under its own elasticity, thus achieving continuous slight vibration of the bending plate 25. When the bending plate 25 vibrates, the water droplets on its surface will be affected by the vibration force, accelerating the water droplets along the bending plate 25. The flow velocity of the inclined plane 25 prevents water droplets from lingering on the surface of the second bending plate 25. At the same time, the rubber layer 253 laid at the contact end between the second bending plate 25 and the mounting box 2 serves two purposes: firstly, the rubber layer 253 buffers the impact of vibration from the mounting box 2 on the second bending plate 25, preventing damage to the elastic second bending plate 25 due to long-term impact and extending its service life; secondly, the rubber layer 253 achieves a seal between the mounting box 2 and the second bending plate 25, preventing steam in the steam exhaust chamber 221 from escaping from the contact gap between the two and entering other areas inside the casing 1, further preventing steam from spreading.

[0060] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.

Claims

1. A noise-reducing and energy-saving generator room; the generator room includes a chassis (1), a door (11), a sound-absorbing layer (12), an air inlet (13), and an air outlet (14), wherein the door (11) is disposed on the chassis (1); the sound-absorbing layer (12) is laid on the inner wall of the chassis (1), and the air inlet (13) and the air outlet (14) are disposed on both sides of the chassis (1); characterized in that, The chassis (1) also includes: Mounting plate (15) is provided in the middle of the lower wall of the chassis (1), and cross grooves (151) are provided at the four corners of the mounting plate (15); and a shock-absorbing layer (152) is provided in the middle of the upper end of the mounting plate (15). The mounting box (2) is positioned above the mounting plate (15). The lower end of the mounting box (2) is in contact with the damping layer (152). Support columns (21) are provided at the four corners of the lower end of the mounting box (2). The support columns (21) are slidably connected to the middle of the cross groove (151). Springs are provided on all four sides of the cross groove (151). The springs are connected to the sides of the support columns (21). The inner wall of the mounting box (2) is covered with a sound-absorbing layer (12). An isolation plate (22) is installed inside the mounting box (2), forming two cavities inside the mounting box (2). One cavity is a steam exhaust chamber (221), and the other is an installation chamber (222). The upper end of the steam exhaust chamber (221) is kept open, and the interior of the installation chamber (222) is kept closed. A vent (223) is opened at the lower end of the isolation plate (22), and a one-way valve is installed inside the vent (223). An air inlet (224) is provided at the upper end of the side of the installation chamber (222) away from the isolation plate (22), and a dust filter is provided at the air inlet (224). An air intake fan is provided at the lower end of the dust filter. A flexible sheet (23) is provided at the upper end of the mounting box (2), and the upper end of the flexible sheet (23) is connected to the upper inner wall of the chassis (1). The flexible sheet (23) separates the chassis (1) on both sides of the isolation plate (22).

2. A noise-reducing and energy-saving generator room as described in claim 1, characterized in that: A bending plate (24) is provided at the upper end of the mounting box (2). The vertical end of the bending plate (24) is connected to the upper end of the mounting box (2). The inclined end of the bending plate (24) is located at the upper end of the opening of the steam exhaust chamber (221). The inclined end of the bending plate (24) is inclined downward. A bending plate (25) is provided inside the casing (1). One end of the bending plate (25) is vertically upward, and the other end is fixed to the side wall of the casing (1). A drain hole (16) is provided on the side wall of the casing (1), so that the end of the bending plate (25) connected to the side wall of the casing (1) is located at the lower opening of the drain hole (16).

3. A noise-reducing and energy-saving generator room as described in claim 1, characterized in that: The bending plate (24) is made of elastic material, and a support rod (241) is provided below the inclined end of the bending plate (24). The lower end of the support rod (241) is connected to the side wall of the mounting box (2) in contact, so that when the mounting box (2) vibrates, the support rod (241) and the side wall of the mounting box (2) will have intermittent impact.

4. A noise-reducing and energy-saving generator room as described in claim 3, characterized in that: A rubber column (242) is provided at the lower end of the support rod (241). The rubber column (242) is connected to the side wall of the mounting box (2), and the interior of the rubber column (242) is a hollow structure.

5. A noise-reducing and energy-saving generator room as described in claim 3, characterized in that: A sponge block (243) is provided below the inclined end of the bending plate (24). The sponge block (243) has a triangular structure. The bottom edge of the sponge block (243) is fixedly connected to the lower part of the inclined end of the bending plate (24). The end of the sponge block (243) with the smallest angle is located at the bending point of the bending plate (24).

6. A noise-reducing and energy-saving generator room as described in claim 5, characterized in that: A rotating plate (26) is rotatably connected to both sides of the end of the bending plate (24) away from the mounting box (2). A counterweight (251) is provided at the lower end of the rotating plate (26). The upper end of the counterweight (251) is inclined so that the inclined surface of the upper end of the counterweight (251) is in contact with the inclined surface of the sponge block (243).

7. A noise-reducing and energy-saving generator room as described in claim 6, characterized in that: The lower end of the counterweight (251) is provided with a rectangular through groove (252), the rectangular channel is connected to the upper end of the counterweight (251), and the lower end of the counterweight (251) is tapered.

8. A noise-reducing and energy-saving generator room as described in claim 2, characterized in that: The end of the second bending plate (25) close to the mounting box (2) is in contact with the mounting box (2), and the second bending plate (25) is made of elastic material. The end of the second bending plate (25) in contact with the mounting box (2) is covered with a rubber layer (253), so that the rubber layer (253) is in contact with the mounting box (2).

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