CN113294619B - Damping and heat dissipation equipment of refrigerant speed reducer - Google Patents

Abstract

The invention discloses a damping and heat dissipation device of a refrigerant speed reducer, which mainly relates to the field of speed reducers and comprises a fixed bottom plate, a pipeline, a power generation mechanism and a speed reduction mechanism, wherein liquid refrigerant is arranged in the pipeline; speed reduction mechanism includes velocity of flow response piece and speed reduction piece, and the velocity of flow response piece can monitor the speed of the interior liquid velocity of flow of pipeline, can reduce the harm to the pipeline impact through the speed reduction piece when the velocity of flow is too fast.

Description

Damping and heat dissipation equipment of refrigerant speed reducer

Technical Field

The invention mainly relates to the field of speed reducers, in particular to damping and heat dissipation equipment of a refrigerant speed reducer.

Background

Refrigerant, also known as refrigerant and snow, is a medium substance used for energy conversion in various heat engines. These materials generally increase power in a reversible phase change (e.g., gas-liquid phase change). Such as steam in a steam engine, snow in a refrigerator, etc. When a general steam engine works, the heat energy of the steam is released and converted into mechanical energy to generate motive power; the snow of the refrigerator is used for transmitting heat at a low temperature to a high temperature. However, after the refrigerant is used up, the refrigerant storage tank needs to be canned, but the direct canning mode is adopted at present, the impact force of liquid during high-speed canning can possibly damage pipelines and the storage tank, and the liquid can generate impact force during canning.

In the prior art, the patent with the application number of 201921641409.6 discloses a refrigerant canning device, which comprises a base, a canning mechanism and four groups of supporting legs, wherein the left front side, the left rear side, the right front side and the right rear side of the bottom end of the base are respectively provided with four groups of connecting assemblies, the four groups of supporting legs are respectively arranged at the bottoms of the four groups of connecting assemblies, the canning mechanism is arranged at the rear side of the top end of the base, and the bottom end of the front side of the top area of the canning mechanism is provided with an output assembly; the electric cylinder positioning device is characterized by further comprising an adjusting plate, a supporting plate, four groups of reset springs, two groups of mounting plates, two groups of electric cylinders, four groups of inner connecting plates, four groups of outer connecting plates and two groups of positioning blocks, wherein the bottom end of the supporting plate is connected with the front side of the top end of the base, and an adjusting groove is formed in the bottom end of the adjusting plate. This patent is mainly to improving the technical problem of canning efficiency, can be fast for the downside accurate positioning of gas pitcher at the output subassembly of canning mechanism, simplifies the position control flow of gas pitcher. However, the patent does not relate to the technical problem that the impact force of liquid can cause damage to the storage tank pipeline during canning, and further does not relate to the technical problem of energy conservation and environmental protection.

Disclosure of Invention

The invention provides a damping and heat-dissipating device of a refrigerant speed reducer, which aims at the technical problem and comprises a fixed bottom plate, a pipeline, a power generation mechanism and a speed reduction mechanism, wherein liquid refrigerant is arranged in the pipeline; the power generation mechanism comprises a power generation element and a heat dissipation element, the power generation element is driven to move through high-speed operation of liquid when the flow rate of the liquid is suddenly increased, the angle of the power generation element is adjusted to cope with the impact force of the flow rate of the liquid, and the power generation element can generate electric energy to be stored in the power supply element under the impact force of the flow rate of the liquid; when the power supply element generates heat after obtaining electric energy, the heat radiating element transmits the heat into the pipeline to realize the cooling of the power supply element; the speed reducing mechanism comprises a flow speed sensing part and a speed reducing part, wherein the flow speed sensing part can detect the flow speed of liquid in the pipeline, at the moment when the flow speed of the liquid is increased, the speed reducing part can adjust the angle under the driving of the flow speed sensing part to correspond to the impact force of the flow speed of the liquid, and the speed reducing part continues to rotate under the driving of the flow speed force of the liquid after the angle is adjusted to disperse the damage of the liquid flow to the interior of the pipeline.

Furthermore, the power generation part comprises a rotating paddle part, and the rotating paddle part is arranged on the connecting part; the connecting piece is arranged in the pipeline through the fixed base, and when the flow rate of liquid in the pipeline is too high, the connecting piece is pushed to move spirally to drive the rotating paddle component to rotate so as to adapt to the impact force of the liquid; the rotating paddle component drives the connecting piece to rotate under the action of liquid flow speed, so that the belt pulley component drives the power generation device in the power supply component to rotate, kinetic energy is converted into electric energy, the power supply component is arranged outside the pipeline, one end of the radiating component is connected with the power supply component, the other end of the radiating component is arranged inside the pipeline, and the power supply component is cooled through liquid refrigerant.

Further, the flow velocity sensing element comprises a sensing head part and a transmission part, when the flow velocity of the liquid is overlarge, the sensing head part is pushed, and the sensing head part is compressed in the transmission part and transmits the power to the speed reducing element; the speed reducer comprises an angle adjusting part, a speed reducing paddle is arranged on the angle adjusting part, and the angle adjusting part can rotate an angle to respond to the impact force of the liquid flow velocity immediately after the power is transmitted by the transmission part; the angle adjusting component is arranged on the power component, and the power component can control the rotating speed of the angle adjusting component and the rotating speed of the speed reducing paddle.

Furthermore, the connecting piece comprises a driving rod, the driving rod is rotatably arranged on the fixed base, a thread is arranged on the driving rod, and a rotating plate is arranged on the driving rod; the rotating plate is provided with threads, a cooling spring is sleeved between the rotating plate and the driving rod, the rotating plate is connected with the rotating paddle component, and the rotating plate rotates when encountering high-speed liquid flow to drive the rotating paddle component to rotate by an angle so as to adapt to the impact force of the liquid flow; the rotating paddle component can rotate along with the acting force of the liquid flow after rotating by a certain angle to generate electricity, and the electric energy is transmitted to the power supply component.

Furthermore, the induction head part comprises a top flow plate, a compression rod is mounted on the top flow plate, a limit spring is arranged on the compression rod, and a limit clamping rod is arranged at the tail end of the limit spring; when the flow rate of the liquid is increased, the top flow plate is pushed to drive a compression rod to extrude a limiting spring, and power is compressed and transmitted into the transmission component; the transmission component comprises a pressure cylinder, when the compression rod extrudes the pressure cylinder, the speed reduction block is pushed out through the conveying pipe, and the speed reduction block touches the angle adjustment component to transmit power to the angle adjustment component.

Further, angle adjustment part including rotating the snap ring, the rotation snap ring with the piece touching and for not producing the extruded contact of slowing down, rotation snap ring with take connecting rod pivot fixed connection, take the connecting rod pivot to rotate and install on power component, take the connecting rod pivot to rotate with the circle cover that slows down and be connected the circle cover that slows down on be provided with little cassette, the speed reduction oar pass through the mobile jib with little cassette connect, the mobile jib on fixed mounting have little cylinder, through take the connecting rod pivot to drive the speed reduction circle on the speed reduction oar turned angle of installation.

Further, the rotation oar part include the excircle cover, the excircle on be provided with a plurality of rotation oar, a plurality of rotate and be connected with the rand on the oar, the rand be connected with the rotor plate through little connecting rod.

Furthermore, the power supply part is a cooling motor which is used for storing electricity and driving the power generation part to rotate when discharging; the cooling motor on install the copper of radiating piece, copper one end install on power supply unit, the other end is installed on the heat-radiating cylinder, the heat-radiating cylinder install in the pipeline.

Further, the power part include trough of belt cylinder, support frame, the trough of belt cylinder sets up on gear motor, support frame fixed mounting in the pipeline, the rotation of taking the connecting rod pivot on the support frame.

Further, still include the shock pad, the shock pad set up between pipeline and fixed baseplate for when pipeline inside produces the shock attenuation between pipeline and the fixed baseplate.

Compared with the prior art, the invention has the beneficial effects that: 1. according to the invention, through the arrangement of the power generation part of the power generation mechanism, the power generated by the high-speed flowing force of the liquid refrigerant in the pipeline can be utilized, and the redundant kinetic energy is utilized to generate new electric energy, so that the energy-saving and environment-friendly effects are achieved; the heat dissipation operation can be performed on the electric energy storage part through the arrangement of the heat dissipation part; 2. according to the invention, the flow velocity of the liquid in the pipeline can be monitored in real time through the flow velocity sensing part of the speed reducing mechanism; 3. through the monitoring of velocity of flow response piece, can control the gear reduction, through the rotation of gear reduction when the velocity of flow is too high, the impact force is flowed to dispersion liquid, reduces the harm to pipeline inner wall.

Drawings

FIG. 1 is an overall schematic view of the present invention.

Fig. 2-3 are structural diagrams of the power generation mechanism of the present invention.

Fig. 4 to 11 are structural views of the speed reducing mechanism of the present invention.

Detailed Description

The invention will now be further described with reference to specific examples, which are provided by way of illustration and description of the invention, but are not intended to be limiting thereof.

Example (b): as shown in fig. 1 to 11, the damping and heat dissipating device of the refrigerant speed reducer comprises a fixed base plate 1, a pipeline 2, a power generation mechanism 3, a speed reduction mechanism 4 and a damping pad 5. The pipe 2 is arranged on the fixed base plate 1.

As shown in fig. 2 and 3, the power generation mechanism 3 includes a heat dissipation cylinder 301, a copper plate 302, a belt 303, a transmission upper belt pulley 304, a cooling motor 305, a motor base 306, a fixed base 307, a rotating plate 308, a driving rod 309, a cooling spring 310, an outer circle sleeve 311, a transmission lower belt pulley 312, a small connecting rod 313, a collar 314, and a rotating paddle 315; the heat radiation cylinder 301 is arranged on the pipeline 2, one end of the copper plate 302 is arranged on the heat radiation cylinder 301, the other end is arranged on the cooling motor 305, the cooling motor 305 is fixedly arranged on the motor base 306, the motor base 306 is fixedly arranged on the pipeline 2, the upper transmission belt pulley 304 is fixedly arranged on the cooling motor 305, the belt 303 is arranged on the upper transmission belt pulley 304 and the lower transmission belt pulley 312, the belt 303 and the upper transmission belt pulley 304, the transmission lower belt pulley 312 forms belt transmission, the fixed base 307 is fixedly installed in the pipeline 2, the rotating plate 308 is rotatably installed on the driving rod 309, the driving rod 309 is rotatably installed on the fixed base 307, the cooling spring 310 is arranged on the driving rod 309, the outer circle sleeve 311 is rotatably installed on the driving rod 309, one end of the small connecting rod 313 is rotatably installed on the clamping ring 314, the other end of the small connecting rod is rotatably installed on the rotating plate 308, and the rotating paddle 315 is fixedly installed on the clamping ring 314. When the flow rate of the refrigerant in the pipeline increases, the liquid impacts the rotating plate 308 to rotate on the driving rod 309 and retreat, the rotating plate 308 and the driving rod 309 are provided with threads, the driving rod 309 is in threaded fit with the rotating plate 308, the rotating paddle 315 on the collar 314 is driven to rotate by the small connecting rod 313 to rotate for a certain angle while rotating so as to adapt to sudden liquid impact force, the inner wall of the pipeline can be protected while the mechanism is protected, after the rotating paddle 315 is adjusted for the angle, the blades of the rotating paddle 315 are driven by the impact force of the high-speed liquid flow, so that the rotating paddle 315 drives the outer circular sleeve 311 to integrally rotate, electricity is generated in a rotating mode, and the generated electricity is transmitted to the cooling motor 305 through the lower transmitting belt pulley 312 and the upper transmitting belt pulley 304. The cooling motor 305 serves to store the generated electricity on the one hand and to generate electricity to drive the rotating paddle 315 to rotate on the other hand. When the cooling motor 305 receives the power, if the power is too high, the cooling motor 305 generates heat, and at this time, the heat is dissipated through the copper plate 302 arranged on the cooling motor 305, the heat is transferred to the heat dissipating cylinder 301 by utilizing the heat conductivity of the copper plate 302, and the cooling operation is performed in the pipeline by utilizing the heat dissipating cylinder 301 through the refrigerant. The motor used here is of Shanghai wide drive type NB 090.

As shown in fig. 4-11, the decelerating mechanism 4 includes a top flow plate 401, a compression rod 402, a limiting spring 403, a limiting clamping rod 404, a pressure cylinder 405, a conveying pipe 406, a decelerating motor 407, a decelerating support 408, a decelerating block 409, a rotating clamping ring 410, a support frame 411, a decelerating paddle 412, a round seat 413, a grooved column 414, a rotating shaft 415 with a connecting rod, a decelerating round sleeve 416, an expansion rod 417, a small clamping seat 418, a small column 419, and a connecting main rod 420; the top flow plate 401 is fixedly arranged on the compression rod 402, the limit spring 403 is arranged on the compression rod 402, the compression rod 402 is slidably arranged on the pipeline 2, the limit clamping rod 404 is fixedly arranged on the pipeline 2, the pressure cylinder 405 is fixedly arranged on the limit clamping rod 404, the conveying pipe 406 is fixedly arranged on the pressure cylinder 405, the speed reducing motor 407 is fixedly arranged on the speed reducing support 408, the speed reducing support 408 is fixedly arranged on the fixed base plate 1, the speed reducing block 409 is slidably arranged on the conveying pipe 406, the rotary clamping ring 410 is fixedly arranged on the belt connecting rod rotating shaft 415, the belt connecting rod rotating shaft 415 is rotatably arranged on the belt groove cylinder 414 and the support frame 411, the support frame 411 is fixedly arranged on the pipeline 2, the speed reducing circular sleeve 416 is rotatably arranged on the circular seat 413, the circular seat 413 is fixedly arranged on the belt groove cylinder 414, the belt groove cylinder 414 is rotatably arranged on the speed reducing motor 407, one end of the telescopic rod 417 is rotatably arranged on the speed reducing circular sleeve 416, the other end is rotatably installed on a round seat 413, a small clamping seat 418 is fixedly installed on a speed reduction round sleeve 416, a small column 419 is fixedly installed on a main connecting rod 420, and the main connecting rod 420 is fixedly installed on the speed reduction paddle 412. The motor used here is of Shanghai wide drive type NB 090. The flow rate of liquid is monitored in real time by the top flow plate 401 in the pipeline, when the flow rate is too high, the flow rate pushes the top flow plate 401 to move, the flow rate is pressed to the pressure cylinder 405 through the compression rod 402 to generate power in the pressure cylinder 405, then the speed reduction block 409 is pushed out through the conveying pipe 406 to be attached to the rotary clamping ring 410, the speed reduction block 409 and the rotary clamping ring 410 are mutually contacted but do not extrude to generate friction force, when the speed reduction block 409 is attached to the rotary clamping ring 410, the rotary clamping ring 410 is driven to rotate, the rotary clamping ring 410 drives the connecting rod rotating shaft 415 to rotate, the connecting rod rotating shaft 415 drives the speed reduction circular sleeve 416 to rotate, the speed reduction circular sleeve 416 is driven to rotate under the action of the small clamping seat 418, the small cylinder 419 rotates on the small clamping seat 418, so as to drive the connecting main rod 420 to rotate, the rotation of the connecting rod 420 can drive the speed reduction paddle 412 to rotate, the direction of the speed reduction paddle 412 is adjusted, impact force is responded, and the damage of the liquid to the pipeline is reduced, after the rotation angle is completed, the speed reduction paddle 412 rotates along with the acting force of the flowing liquid, liquid flow is dispersed during rotation, the impact force of the high-speed liquid flow on the pipeline is reduced, and the inner wall of the pipeline is protected. The deceleration motor 407 is used to energize the grooved cylinder 414 so that the grooved cylinder 414 rotates in reverse to decelerate, and this function can be used as appropriate. The telescopic bar 417 is used to reposition the angle-adjusted reduction paddle 412. The circular base 413 is provided with a plurality of decelerating paddles 412, each decelerating paddle 412 corresponds to a main connecting rod 420, each main connecting rod 420 is provided with a small cylinder 419, the decelerating circular sleeve 416 is provided with a plurality of small clamping seats 418, the number of the small clamping seats 418 corresponds to the main connecting rod 420, only one of the parts is marked in the figure as an explanation, in addition, the decelerating paddles 412, the telescopic rod 417, the decelerating circular sleeve 416, the small clamping seats 418, the small cylinders 419 and the main connecting rods 420 are all arranged in the circular base 413, if the circular base 413 is used as a supporting body, a plurality of groups of parts with the same internal structures as the circular base 413 and the circular base 413 can be arranged at the position, such as the other two groups shown in the figure, and only one of the parts is marked as an explanation. On the surface of the fixed base plate 1, a shock absorption pad 5 is also arranged below the pipeline 2, and the shock absorption pad 5 is arranged for absorbing shock because the pipeline 2 shakes or impacts the fixed base plate 1 when the impact force of liquid on the pipeline is large.

Claims (8)

1. The shock absorption and heat dissipation equipment of the refrigerant speed reducer comprises a fixed base plate and a pipeline, wherein liquid refrigerant is filled in the pipeline, and the shock absorption and heat dissipation equipment is characterized by further comprising a power generation mechanism and a speed reduction mechanism, wherein the power generation mechanism and the speed reduction mechanism are arranged in the pipeline; the power generation mechanism comprises a power generation element and a heat dissipation element, the power generation element is driven to move through high-speed operation of liquid when the flow rate of the liquid is suddenly increased, the angle of the power generation element is adjusted to cope with the impact force of the flow rate of the liquid, and the power generation element can generate electric energy to be stored in the power supply element under the impact force of the flow rate of the liquid; when the power supply element generates heat after obtaining electric energy, the heat radiating element transmits the heat into the pipeline to realize the cooling of the power supply element;

the power generation part comprises a rotating paddle part, and the rotating paddle part is arranged on the connecting part; the connecting piece is arranged in the pipeline through the fixed base, and when the flow rate of liquid in the pipeline is too high, the connecting piece is pushed to move spirally to drive the rotating paddle component to rotate so as to adapt to the impact force of the liquid; the rotating paddle component drives the connecting piece to rotate under the action of liquid flow speed, so that the belt pulley component drives the power generation device in the power supply component to rotate and convert kinetic energy into electric energy, the power supply component is arranged outside the pipeline, one end of the radiating component is connected with the power supply component, the other end of the radiating component is arranged inside the pipeline, and the power supply component is cooled through liquid refrigerant;

the speed reducing mechanism comprises a flow speed sensing part and a speed reducing part, wherein the flow speed sensing part can detect the flow speed of liquid in the pipeline, at the moment when the flow speed of the liquid is increased, the speed reducing part can adjust the angle under the driving of the flow speed sensing part to correspond to the impact force of the flow speed of the liquid, and the speed reducing part continues to rotate under the driving of the flow speed force of the liquid after the angle is adjusted to disperse the damage of the liquid flow to the interior of the pipeline.

2. The apparatus for damping and dissipating heat of a refrigerant retarder according to claim 1, wherein the flow velocity sensing member includes a sensing head member and a transmission member, the sensing head member is pushed when a flow velocity of the liquid is excessive, the sensing head member is compressed in the transmission member to transmit power to the retarder; the speed reducer comprises an angle adjusting part, a speed reducing paddle is arranged on the angle adjusting part, and the angle adjusting part can rotate an angle to respond to the impact force of the liquid flow velocity immediately after the power is transmitted by the transmission part; the angle adjusting component is arranged on the power component, and the power component can control the rotating speed of the angle adjusting component and the rotating speed of the speed reducing paddle.

3. The shock absorption and heat dissipation equipment of the refrigerant speed reducer according to claim 2, wherein the connecting piece comprises an active rod, the active rod is rotatably installed on the fixed base, a thread is arranged on the active rod, and a rotating plate is installed on the active rod; the rotating plate is provided with threads, a cooling spring is sleeved between the rotating plate and the driving rod, the rotating plate is connected with the rotating paddle component, and the rotating plate rotates when encountering high-speed liquid flow to drive the rotating paddle component to rotate by an angle so as to adapt to the impact force of the liquid flow; the rotating paddle component can rotate along with the acting force of the liquid flow after rotating by a certain angle to generate electricity, and the electric energy is transmitted to the power supply component.

4. The refrigerant retarder damping and heat dissipating device as claimed in claim 3, wherein the induction head unit includes a top flow plate, a compression rod is installed on the top flow plate, a limit spring is installed on the compression rod, and a limit catch rod is installed at a distal end of the limit spring; when the flow rate of the liquid is increased, the top flow plate is pushed to drive a compression rod to extrude a limiting spring, and power is compressed and transmitted into the transmission component; the transmission component comprises a pressure cylinder, when the compression rod extrudes the pressure cylinder, the speed reduction block is pushed out through the conveying pipe, the speed reduction block touches the angle adjusting component, and power is transmitted to the angle adjusting component.

5. The refrigerant reducer shock-absorbing and heat-dissipating device as claimed in claim 4, wherein the angle adjustment unit includes a rotary snap ring, the rotary snap ring is in contact with the speed reduction block and does not generate an extrusion contact, the rotary snap ring is fixedly connected with a rotary shaft with a connecting rod, the rotary shaft with the connecting rod is rotatably mounted on the power unit, the rotary shaft with the connecting rod is rotatably connected with a speed reduction circular sleeve, a small clamping seat is disposed on the speed reduction circular sleeve, the speed reduction paddle is connected with the small clamping seat through a connecting main rod, a small cylinder is fixedly mounted on the connecting main rod, and the rotary shaft with the connecting rod drives the speed reduction paddle on the speed reduction circular sleeve to rotate at an angle.

6. The refrigerant reducer's shock attenuation heat dissipation equipment of claim 3, characterized in that, the rotation oar part include the excircle cover, the excircle cover on be provided with a plurality of rotation oar, a plurality of rotation oar on be connected with the rand, the rand be connected with the rotor plate through little connecting rod.

7. The refrigerant retarder damping and heat dissipating device as claimed in claim 5, wherein the power unit includes a grooved cylinder and a support frame, the grooved cylinder is disposed on the speed reducing motor, the support frame is fixedly installed in the pipe, and the rotating shaft with the connecting rod rotates on the support frame.

8. The apparatus for reducing vibration and dissipating heat of a refrigerant retarder according to claim 1, further comprising a vibration absorbing pad disposed between the pipe and the fixing base plate for absorbing vibration between the pipe and the fixing base plate when an impact is generated inside the pipe.

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