CN113490297A - High-power high-frequency induction power supply device of shock attenuation refrigeration integration - Google Patents

High-power high-frequency induction power supply device of shock attenuation refrigeration integration Download PDF

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Publication number
CN113490297A
CN113490297A CN202111046684.5A CN202111046684A CN113490297A CN 113490297 A CN113490297 A CN 113490297A CN 202111046684 A CN202111046684 A CN 202111046684A CN 113490297 A CN113490297 A CN 113490297A
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China
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longitudinal
piece
damping
cooling
liquid return
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CN202111046684.5A
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CN113490297B (en
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刘扬
虞大力
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JIANGSU EASTONE TECHNOLOGY CO LTD
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JIANGSU EASTONE TECHNOLOGY CO LTD
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B6/00Heating by electric, magnetic or electromagnetic fields
    • H05B6/02Induction heating
    • H05B6/04Sources of current
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16FSPRINGS; SHOCK-ABSORBERS; MEANS FOR DAMPING VIBRATION
    • F16F15/00Suppression of vibrations in systems; Means or arrangements for avoiding or reducing out-of-balance forces, e.g. due to motion
    • F16F15/02Suppression of vibrations of non-rotating, e.g. reciprocating systems; Suppression of vibrations of rotating systems by use of members not moving with the rotating systems
    • F16F15/04Suppression of vibrations of non-rotating, e.g. reciprocating systems; Suppression of vibrations of rotating systems by use of members not moving with the rotating systems using elastic means
    • F16F15/06Suppression of vibrations of non-rotating, e.g. reciprocating systems; Suppression of vibrations of rotating systems by use of members not moving with the rotating systems using elastic means with metal springs
    • F16F15/067Suppression of vibrations of non-rotating, e.g. reciprocating systems; Suppression of vibrations of rotating systems by use of members not moving with the rotating systems using elastic means with metal springs using only wound springs
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K7/00Constructional details common to different types of electric apparatus
    • H05K7/20Modifications to facilitate cooling, ventilating, or heating
    • H05K7/20009Modifications to facilitate cooling, ventilating, or heating using a gaseous coolant in electronic enclosures
    • H05K7/20136Forced ventilation, e.g. by fans
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K7/00Constructional details common to different types of electric apparatus
    • H05K7/20Modifications to facilitate cooling, ventilating, or heating
    • H05K7/20009Modifications to facilitate cooling, ventilating, or heating using a gaseous coolant in electronic enclosures
    • H05K7/20136Forced ventilation, e.g. by fans
    • H05K7/20172Fan mounting or fan specifications
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K7/00Constructional details common to different types of electric apparatus
    • H05K7/20Modifications to facilitate cooling, ventilating, or heating
    • H05K7/20218Modifications to facilitate cooling, ventilating, or heating using a liquid coolant without phase change in electronic enclosures

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  • Engineering & Computer Science (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • General Engineering & Computer Science (AREA)
  • Electromagnetism (AREA)
  • Acoustics & Sound (AREA)
  • Aviation & Aerospace Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Devices That Are Associated With Refrigeration Equipment (AREA)

Abstract

The invention discloses a shock absorption and refrigeration integrated high-power high-frequency induction power supply device, which comprises: a damping member comprising a longitudinal damping member; the longitudinal damping piece comprises a longitudinal damping shell, a longitudinal damping buffer piece and a liquid return piece, the longitudinal damping buffer piece is arranged on the longitudinal damping shell, and the liquid return piece is arranged on the longitudinal damping buffer piece; a power supply cabinet; the refrigerating piece comprises a water cooling piece and a circulating air cooling piece; wherein: when the longitudinal damping shell is vibrated, the injected cooling liquid is extruded by the longitudinal damping buffer piece to enter the water cooling piece to cool the power cabinet, the cooling liquid flowing out of the water cooling piece enters the circulating air cooling piece to push the circulating air in the cabinet to dissipate heat, and the cooling liquid flowing out of the circulating air cooling piece flows back to the longitudinal damping shell through the liquid return piece. The invention has novel design thought, reasonable structural design, simple structure, high damping efficiency and high refrigeration efficiency, does not need additional energy supply for damping and refrigeration, has low manufacturing and use cost and is suitable for popularization and use.

Description

High-power high-frequency induction power supply device of shock attenuation refrigeration integration
Technical Field
The invention relates to the technical field of universal structural parts of electrical equipment, in particular to a damping and refrigerating integrated high-power high-frequency induction power supply device, which aims to improve the cooling and ventilating structure of the power supply device.
Background
Electromagnetic induction heating, referred to as induction heating, is a method of heating conductive materials such as metallic materials. It is mainly used for metal hot working, heat treatment, welding and melting. The induction heating is to generate current in the heated material by using an electromagnetic induction method, and the heating purpose is achieved by means of the energy of the eddy current. The basic components of an induction heating system include an induction coil, an ac power source, and a workpiece. The coil can be made into different shapes according to different heating objects. The coil is connected with a power supply, the power supply provides alternating current for the coil, the alternating current flowing through the coil generates an alternating magnetic field passing through the workpiece, and the magnetic field enables the workpiece to generate eddy current to heat. Therefore, the electromagnetic induction heating technology is widely applied, but the high-power high-frequency induction power supply is often used in a factory building, various large-scale machines are often operated and transport vehicles are often driven in the factory building, the high-power high-frequency power supply cabinet can often vibrate, and meanwhile, when the high-power high-frequency induction heating power supply works, because a large number of electric appliance power elements are arranged in the high-power high-frequency induction heating power supply, a large amount of heat can be generated, if the heat cannot be dissipated in time, the normal operation of the electric appliance elements is easily influenced, and even the electric appliance elements are damaged or accidents are caused.
At present, the refrigeration effect of the high-power high-frequency electromagnetic induction power supply is poor, energy is consumed for refrigeration, energy waste is caused, and the high-power high-frequency electromagnetic induction power supply is not beneficial to efficient production and large-scale use.
Disclosure of Invention
In order to overcome the defects, the invention provides a damping and refrigeration integrated high-power high-frequency induction power supply device, which solves the technical problems that the high-power high-frequency electromagnetic induction power supply device has poor refrigeration effect and needs additional energy, and specifically adopts the following technical scheme:
a shock attenuation refrigeration integration high-power high frequency induction power supply device includes:
the damping piece comprises a longitudinal damping piece and a transverse damping piece, and the transverse damping piece is arranged on the longitudinal damping piece; the longitudinal damping piece comprises a longitudinal damping shell, a longitudinal damping buffer piece and a liquid return piece, the longitudinal damping buffer piece is arranged on the longitudinal damping shell, and the liquid return piece is arranged on the longitudinal damping buffer piece;
the power supply cabinet is arranged on the longitudinal damping piece and is connected with the longitudinal damping buffer piece;
the refrigeration piece is arranged on the power cabinet and comprises a water cooling piece and a circulating air cooling piece, and the water cooling piece and the circulating air cooling piece are both arranged in the power cabinet;
wherein: the coolant liquid of pouring into in will receive when vertical damping shell receives vibrations vertical damping bolster extrusion entering in the water-cooling piece is right the power cabinet cooling, by the water-cooling piece flows the coolant liquid will get into promote the heat dissipation of cabinet inner loop wind in the circulated air-cooling piece, by the circulated air-cooling piece flows the coolant liquid warp it flows back to return liquid spare the vertical damping shell.
Preferably, the longitudinal damping shell comprises a longitudinal damping cylinder, a longitudinal bearing plate and a longitudinal refrigerating conveying pipe, wherein the longitudinal bearing plate and the longitudinal refrigerating conveying pipe are both arranged on the longitudinal damping cylinder; the longitudinal bearing plate is fixedly arranged on the inner wall of the longitudinal damping cylinder, and a longitudinal pressure-bearing cavity formed by the longitudinal bearing plate and the longitudinal damping cylinder is filled with cooling liquid.
Preferably, the longitudinal refrigeration conveying pipe comprises an upper longitudinal branch pipe, a lower longitudinal branch pipe, an upper longitudinal check valve, a lower longitudinal check valve and a conveying main pipe, wherein one end of the upper longitudinal branch pipe is arranged on the longitudinal pressure bearing cavity in a penetrating mode, and the penetrating position of the upper longitudinal branch pipe is located at the upper portion of the longitudinal pressure bearing cavity; one end of the lower longitudinal branch pipe is arranged on the longitudinal bearing cavity in a penetrating mode, the penetrating position of the lower longitudinal branch pipe is located at the lower portion of the longitudinal bearing cavity, the upper longitudinal check valve is arranged on the upper longitudinal branch pipe, the lower longitudinal check valve is arranged on the lower longitudinal branch pipe, and the directions of the upper longitudinal check valve and the lower longitudinal check valve are opposite; the conveying main pipe is respectively arranged at the other end of the upper longitudinal branch pipe and the other end of the lower longitudinal branch pipe in a penetrating way.
Preferably, the longitudinal damping buffer comprises a longitudinal damping buffer plate and a longitudinal damping buffer rod, the longitudinal damping buffer plate is arranged in the longitudinal bearing cavity and divides the longitudinal bearing cavity into an upper longitudinal bearing cavity and a lower longitudinal bearing cavity; the longitudinal damping buffer rod is characterized in that a first liquid return through hole and a second liquid return through hole are formed in one end face of the longitudinal damping buffer rod, one end of the longitudinal damping buffer rod is vertically and fixedly arranged at the center of the longitudinal damping buffer plate, the other end of the longitudinal damping buffer rod penetrates through the longitudinal bearing plate, and the longitudinal damping buffer rod and the longitudinal bearing plate are subjected to sliding sealing treatment.
Preferably, the liquid return piece comprises a first liquid return main pipe and a second liquid return main pipe, the first liquid return main pipe is fixedly embedded in the first liquid return through hole, one end of the first liquid return main pipe penetrates through the longitudinal damping buffer rod, and meanwhile, one end of the first liquid return main pipe is positioned on the upper side of the longitudinal damping buffer plate; the second liquid return main pipe is fixedly embedded in the second liquid return through hole, and one end of the second liquid return main pipe is positioned at the lower side of the longitudinal damping buffer plate; the first liquid return main pipe is provided with a first liquid return one-way valve, the second liquid return main pipe is provided with a second liquid return one-way valve, the direction of the first liquid return one-way valve is opposite to that of the upper longitudinal one-way valve, and the direction of the second liquid return one-way valve is opposite to that of the lower longitudinal one-way valve.
Preferably, the longitudinal shock absorption piece further comprises a longitudinal spring, one end of the longitudinal spring is vertically and fixedly arranged on the longitudinal bearing plate, the number of the longitudinal springs is multiple, and the longitudinal springs are uniformly distributed on the longitudinal bearing plate.
Preferably, the transverse shock absorbing member comprises a transverse damping member, a transverse refrigerating conveying pipe and a transverse spring, the transverse damping member and the transverse spring are both arranged on the longitudinal damping member, and the transverse refrigerating conveying pipe is arranged on the transverse damping member; the transverse damping part comprises a transverse damping pipe and a transverse damping buffer part, the transverse damping pipe is horizontally and fixedly arranged on the inner wall of one side of the longitudinal damping cylinder, the transverse damping buffer part comprises a transverse damping buffer plate and a transverse damping buffer rod, the transverse damping buffer plate is arranged in the transverse damping pipe, and the transverse damping buffer plate divides the transverse damping pipe into a left transverse pressure bearing cavity and a right transverse pressure bearing cavity; the transverse refrigeration conveying pipe comprises a left transverse refrigeration conveying pipe and a right transverse refrigeration conveying pipe, one end of the left transverse refrigeration conveying pipe is arranged on the left side of the left transverse bearing cavity in a penetrating mode, one end of the right transverse refrigeration conveying pipe is arranged on the right side of the right transverse bearing cavity in a penetrating mode, the other end of the left transverse refrigeration conveying pipe and the other end of the right transverse refrigeration conveying pipe are connected to the conveying main pipe in a penetrating mode, meanwhile, a left transverse check valve and a right transverse check valve are correspondingly arranged on the left transverse refrigeration conveying pipe and the right transverse refrigeration conveying pipe respectively, and the directions of the left transverse check valve and the right transverse check valve are opposite; one end of the transverse spring is horizontally and fixedly arranged on the inner wall of one side of the longitudinal damping cylinder; four sets of transverse shock absorbing parts are arranged, and the four sets of transverse shock absorbing parts are correspondingly arranged on the four inner walls of the cylinder openings of the longitudinal damping cylinders one by one.
Preferably, the power cabinet comprises a cabinet body, a cabinet door and a support rod, the cabinet body is arranged on the longitudinal spring, the cabinet body is connected to the other end of the longitudinal damping buffer rod in a penetrating manner, and meanwhile, the four walls of the bottom side of the cabinet body are respectively connected with the other ends of the transverse springs in four directions; one side edge of the cabinet door is hinged to the cabinet body, a quick-opening lockset is arranged on the other side edge of the cabinet door, the supporting rods are provided with a plurality of groups and a plurality of groups, each group of groups are formed by the supporting rods which are horizontally distributed in the cabinet body, and the groups of supporting rods can form a multilayer electrical appliance element installation layer.
Preferably, the water-cooling part comprises a plurality of water-cooling heat absorption plates, a plurality of water-cooling branch pipes, a water-cooling liquid inlet pipe, a water-cooling hose and a water-cooling liquid return pipe, the plurality of water-cooling heat absorption plates are arranged on the plurality of groups of support rods one by one correspondingly, the water-cooling heat absorption plates are provided with water-cooling grooves, the water-cooling branch pipes are embedded in the water-cooling grooves, the plurality of water-cooling branch pipes are arranged, and the plurality of water-cooling branch pipes are embedded in the plurality of water-cooling grooves one by one correspondingly; one end of the water-cooling liquid inlet pipe is arranged at one end of the plurality of water-cooling branch pipes in a penetrating way, and the other end of the water-cooling liquid inlet pipe penetrates through the cabinet body; one end of the water-cooling hose is communicated with the other end of the water-cooling liquid inlet pipe, and the other end of the water-cooling hose is communicated and connected with the conveying main pipe; and one end of the water-cooling liquid return pipe is communicated with the other ends of the water-cooling branch pipes.
Preferably, the circulating air cooling part comprises an impeller shell, an impeller and fan blades, the impeller shell is arranged on the cabinet body, the impeller is arranged on the impeller shell, and the fan blades are arranged on the impeller; the center of the impeller shell is communicated with the first liquid return main pipe and the second liquid return main pipe, and the side edge of the impeller shell is communicated with the other end of the water-cooling liquid return pipe; the impeller is arranged in the impeller shell, a rotating shaft of the impeller penetrates through the impeller shell, and the fan blades are arranged on the rotating shaft of the impeller.
The invention at least comprises the following beneficial effects:
1) the shock absorption and refrigeration integrated high-power high-frequency induction power supply device has the advantages of novel design idea, reasonable structural design, simple structure, high refrigeration efficiency, shock absorption and refrigeration without additional energy supply, low manufacturing and using cost and suitability for popularization and use, and the shock absorption piece is used for driving the refrigeration process;
2) the invention discloses a shock absorption and refrigeration integrated high-power high-frequency induction power supply device, which is provided with a shock absorption piece and a refrigeration piece, wherein the longitudinal shock absorption piece comprises a longitudinal damping shell, a longitudinal damping buffer piece and a liquid return piece; the cooling liquid that pours into in it will receive the extrusion of longitudinal damping bolster to the power cabinet cooling in getting into the water-cooling piece when the longitudinal damping shell receives vibrations, the cooling liquid that flows out by the water-cooling piece will get into promotes the heat dissipation of cabinet inner loop wind in the cold piece of circulated air, the cooling liquid that flows out by the cold piece of circulated air flows back into the longitudinal damping shell through returning the liquid piece, make shock attenuation and refrigeration need not extra energy supply, through rational design in the shock attenuation simultaneously, utilize vibrations extrusion cooling liquid at the power cabinet inner loop heat dissipation, shock attenuation efficiency and refrigeration efficiency have effectively been improved, manufacturing cost and use cost have been showing to have reduceed, and is suitable for being popularized and used.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.
Drawings
FIG. 1 is a front view of the shock-absorbing refrigeration integrated high-power high-frequency induction power supply device of the present invention;
FIG. 2 is a schematic perspective view of the shock-absorbing refrigeration integrated high-power high-frequency induction power supply device of the present invention;
FIG. 3 is a top view of the shock absorption and refrigeration integrated high-power high-frequency induction power supply device of the present invention;
FIG. 4 is a schematic view of a top-down perspective structure of the shock-absorbing refrigeration integrated high-power high-frequency induction power supply device of the present invention;
FIG. 5 is a sectional front view taken along the direction A-A in FIG. 3 of the integrated high-power high-frequency induction power supply device for damping and cooling according to the present invention;
FIG. 6 is a schematic view of the sectional structure of the vibration-damping and refrigeration integrated high-power high-frequency induction power supply device in the direction of A-A in FIG. 3;
FIG. 7 is a front view of the section in the direction B-B in FIG. 3 of the integrated high-power high-frequency induction power supply device for damping and cooling of the present invention;
FIG. 8 is a schematic view of a sectional three-dimensional structure in the direction B-B in FIG. 3 of the shock-absorbing refrigeration integrated high-power high-frequency induction power supply device of the present invention;
FIG. 9 is a schematic top perspective view of the sectional plane in the direction B-B in FIG. 3 of the integrated high-power high-frequency induction power supply device for damping and cooling of the present invention;
FIG. 10 is a front view of the C-C direction section in FIG. 3 of the integrated high-power high-frequency induction power supply device for damping and cooling of the present invention;
fig. 11 is a schematic view of a sectional three-dimensional structure in the direction of C-C in fig. 3 of the shock-absorbing refrigeration integrated high-power high-frequency induction power supply device of the present invention.
Wherein: 1-a longitudinal damping cylinder, 2-a longitudinal bearing plate, 3-an upper longitudinal branch pipe, 4-a lower longitudinal branch pipe, 5-an upper longitudinal check valve, 6-a lower longitudinal check valve, 7-a conveying main pipe, 8-a longitudinal damping buffer plate, 9-a longitudinal damping buffer rod, 14-a first liquid return branch pipe, 15-a second liquid return branch pipe, 16-a first liquid return nozzle, 17-a second liquid return nozzle, 18-a longitudinal spring, 19-a transverse damping pipe, 20-a transverse damping buffer plate, 21-a transverse damping buffer rod, 24-a left transverse refrigeration conveying pipe, 25-a right transverse refrigeration conveying pipe, 26-a left transverse check valve, 27-a right transverse check valve, 28-a transverse spring, 29-a cabinet body, 30-a cabinet door, 31-support rod, 32-quick-opening lock, 33-water-cooling heat absorption plate, 34-water-cooling branch pipe, 35-water-cooling liquid inlet pipe, 36-water-cooling hose, 37-water-cooling liquid return pipe, 38-impeller shell, 39-impeller, 40-fan blade and 41-electrical element.
Detailed Description
Technical solutions of the present invention will be described in detail below by way of embodiments with reference to the accompanying drawings. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto.
The term "and/or" herein is merely an association describing an associated object, meaning that three relationships may exist, e.g., a and/or B, may mean: a exists alone, B exists alone, and A and B exist at the same time, and the term "/and" is used herein to describe another association object relationship, which means that two relationships may exist, for example, A/and B, may mean: a alone, and both a and B alone, and further, the character "/" in this document generally means that the former and latter associated objects are in an "or" relationship.
According to the drawings of fig. 1-11, a shock-absorbing refrigeration integrated high-power high-frequency induction power supply device comprises a shock-absorbing piece, a power supply cabinet and a refrigeration piece, wherein the power supply cabinet is arranged on the shock-absorbing piece, and the refrigeration piece is arranged on the power supply cabinet. The shock absorbing members comprise longitudinal shock absorbing members and transverse shock absorbing members, and the transverse shock absorbing members are arranged on the longitudinal shock absorbing members. The longitudinal damping member includes a longitudinal damping member and a longitudinal spring member disposed on the longitudinal damping member. The longitudinal damping piece comprises a longitudinal damping shell, a longitudinal damping buffer piece and a liquid return piece, the longitudinal damping buffer piece is arranged on the longitudinal damping shell, and the liquid return piece is arranged on the longitudinal damping buffer piece.
The longitudinal damping shell comprises a longitudinal damping cylinder 1, a longitudinal bearing plate 2 and a longitudinal refrigerating conveying pipe, wherein the longitudinal bearing plate 2 and the longitudinal refrigerating conveying pipe are both arranged on the longitudinal damping cylinder 1. The longitudinal damping cylinder 1 is in a rectangular cylinder shape, and one end face of the longitudinal bearing plate 2 is the same as the cross section of the longitudinal damping cylinder 1 in size. The center of the longitudinal bearing plate 2 is provided with a longitudinal damping through hole, and the longitudinal bearing plate 2 is horizontally and fixedly arranged on the inner wall of the longitudinal damping cylinder 1. And a longitudinal pressure-bearing cavity formed by the longitudinal bearing plate 2 and the longitudinal damping cylinder 1 is filled with cooling liquid.
As an option, the coolant is one or the combination of water, refrigerating fluid and bearing oil, and the coolant can meet the pressure-bearing and refrigerating requirements due to the fact that the pressure in the longitudinal damping cylinder 1 is low. The longitudinal refrigeration conveying pipe comprises an upper longitudinal branch pipe 3, a lower longitudinal branch pipe 4, an upper longitudinal check valve 5, a lower longitudinal check valve 6 and a conveying main pipe 7, one end of the upper longitudinal branch pipe 3 is arranged on the longitudinal pressure bearing cavity in a penetrating mode, the penetrating position is located on the upper portion of the longitudinal pressure bearing cavity, meanwhile, the upper longitudinal branch pipe 3 is provided with four upper longitudinal branch pipes 3, and the four upper longitudinal branch pipes 3 are horizontally distributed on four side walls of the longitudinal damping cylinder 1. One end of the lower longitudinal branch pipe 4 is arranged on the longitudinal bearing cavity in a penetrating mode, the penetrating position is located at the lower portion of the longitudinal bearing cavity, meanwhile, four lower longitudinal branch pipes 4 are arranged, and the four lower longitudinal branch pipes 4 are horizontally distributed on four side walls of the longitudinal damping cylinder 1. An upper longitudinal non-return valve 5 is arranged in the upper longitudinal branch 3 and a lower longitudinal non-return valve 6 is arranged in the lower longitudinal branch 4, and the upper longitudinal non-return valve 5 and the lower longitudinal non-return valve 6 are in opposite directions. The conveying main pipes 7 are respectively arranged at the other ends of the four upper longitudinal branch pipes 3 and the other ends of the four lower longitudinal branch pipes 4 in a penetrating way.
The longitudinal damping buffer piece comprises a longitudinal damping buffer plate 8 and a longitudinal damping buffer rod 9, the longitudinal damping buffer plate 8 is arranged in the longitudinal damping cylinder 1, and the longitudinal damping buffer rod 9 is arranged on the longitudinal damping buffer plate 8. The edge of the longitudinal damping buffer plate 8 is provided with a first sealing pressure-bearing adhesive tape, and the longitudinal damping buffer plate 8 is arranged in the longitudinal pressure-bearing cavity and divides the longitudinal pressure-bearing cavity into an upper longitudinal pressure-bearing cavity and a lower longitudinal pressure-bearing cavity. A first liquid return through hole and a second liquid return through hole are formed in one end face of the longitudinal damping buffer rod 9, and the axes of the first liquid return through hole and the second liquid return through hole are parallel to the axis of the longitudinal damping buffer rod 9. Vertical damping buffer rod 9 one end vertical fixation sets up in vertical damping buffer plate 8 center department, and vertical damping buffer rod 9 other end penetrates vertical damping through hole to be provided with the slip sealing washer between vertical damping buffer rod 9 and the vertical damping through hole, make vertical damping buffer rod 9 can slide sealing connection in vertical damping through hole. The other end of the longitudinal damping buffer rod 9 is used for connecting and bearing the longitudinal vibration force of the damping power cabinet.
The liquid return part comprises a first liquid return main pipe, a second liquid return main pipe, a first liquid return branch pipe 14 and a second liquid return branch pipe 15, the first liquid return main pipe and the second liquid return main pipe are both arranged on the longitudinal damping buffer rod 9, and the first liquid return branch pipe 14 and the second liquid return branch pipe 15 are respectively arranged on the first liquid return main pipe and the second liquid return main pipe. The first liquid return main pipe is fixedly embedded in the first liquid return through hole, one end of the first liquid return main pipe penetrates through the longitudinal damping buffer rod 9, and meanwhile one end of the first liquid return main pipe is located on the upper side of the longitudinal damping buffer plate 8. The second liquid return main pipe is fixedly embedded in the second liquid return through hole, and one end of the second liquid return main pipe is positioned on the lower side of the longitudinal damping buffer plate 8. The first liquid return branch pipe 14 is in an annular tubular shape, the first liquid return branch pipe 14 is sleeved outside the longitudinal damping buffer rod 9, and the first liquid return branch pipe 14 is horizontally connected to one end of the first liquid return main pipe in a penetrating mode. The second liquid return branch pipe 15 is in an annular pipe shape, and the second liquid return branch pipe 15 is horizontally connected to one end of the second liquid return main pipe in a penetrating mode.
The first liquid return branch pipe 14 is horizontally provided with eight first liquid return nozzles 16 in a penetrating manner, and the eight first liquid return nozzles 16 are circumferentially and uniformly distributed around the first liquid return branch pipe 14. The second liquid return branch pipe 15 is horizontally provided with eight second liquid return nozzles 17 in a penetrating manner, and the eight second liquid return nozzles 17 are circumferentially and uniformly distributed around the second liquid return branch pipe 15. The first liquid return main pipe is provided with a first liquid return one-way valve, the second liquid return main pipe is provided with a second liquid return one-way valve, the first liquid return one-way valve is opposite to the upper longitudinal one-way valve 5 in direction, and the second liquid return one-way valve is opposite to the lower longitudinal one-way valve 6 in direction.
The longitudinal spring part comprises longitudinal springs 18, one ends of the longitudinal springs 18 are vertically and fixedly arranged on the longitudinal bearing plate 2, the number of the longitudinal springs 18 is four, and the four longitudinal springs 18 are uniformly distributed on the longitudinal bearing plate 2. The longitudinal spring 18 is used for supporting the power cabinet, so that the longitudinal damping buffer plate 8 is positioned in the middle of the longitudinal bearing cavity when the power cabinet is in a non-vibration state. When longitudinal vibration occurs, the longitudinal damping buffer plate 8 applies pressure on the cooling liquid in the upper longitudinal bearing cavity or the lower longitudinal bearing cavity, and then the extruded cooling liquid is conveyed into the power cabinet through the longitudinal refrigeration conveying pipe for refrigeration.
The transverse damping piece comprises a transverse damping piece, a transverse refrigerating conveying pipe and a transverse spring piece, the transverse damping piece and the transverse spring piece are both arranged on the longitudinal damping piece, and the transverse refrigerating conveying pipe is arranged on the transverse damping piece. The transverse damping piece comprises a transverse damping tube 19 and a transverse damping buffer piece, wherein the transverse damping tube 19 is arranged on the longitudinal damping cylinder 1, and the transverse damping buffer piece is arranged on the transverse damping tube 19. Two end faces of the transverse damping tube 19 are sealed, a transverse damping through hole is formed in the center of one end face of the transverse damping tube 19, and the other end of the transverse damping tube 19 is horizontally and fixedly arranged on the inner wall of one side of the longitudinal damping cylinder 1. The transverse damping buffer comprises a transverse damping buffer plate 20 and a transverse damping buffer rod 21, wherein the transverse damping buffer plate 20 is arranged in the transverse damping pipe 19, and the transverse damping buffer rod 21 is arranged on the transverse damping buffer plate 20. And a second sealing pressure-bearing rubber strip is arranged on the edge of the transverse damping buffer plate 20, and the transverse damping buffer plate 20 divides the transverse damping pipe 19 into a left transverse pressure-bearing cavity and a right transverse pressure-bearing cavity.
The horizontal refrigeration conveyer pipe includes horizontal refrigeration conveyer pipe 24 in left side and the horizontal refrigeration conveyer pipe 25 in right side, and the horizontal refrigeration conveyer pipe 24 one end in left side link up the setting in the horizontal bearing chamber left side in left side, and the horizontal refrigeration conveyer pipe 25 one end in right side link up the setting in the horizontal bearing chamber right side in right side. And the other end of the left lateral refrigerating conveying pipe 24 and the other end of the right lateral refrigerating conveying pipe 25 are both connected on the conveying main pipe 7 in a penetrating way. Meanwhile, a left transverse check valve 26 is arranged on the left transverse refrigeration conveying pipe 24, a right transverse check valve 27 is arranged on the right transverse refrigeration conveying pipe 25, and the directions of the left transverse check valve 26 and the right transverse check valve 27 are opposite. The transverse spring element comprises a transverse spring 28, and one end of the transverse spring 28 is horizontally and fixedly arranged on the inner wall of one side of the longitudinal damping cylinder 1. Four sets of transverse shock absorbing parts are arranged, and the four sets of transverse shock absorbing parts are correspondingly arranged on four inner walls of the tube mouths of the longitudinal damping tube 1 one by one.
The power cabinet comprises a cabinet body 29, a cabinet door 30 and a support rod 31, wherein the cabinet body 29 is arranged on the longitudinal spring 18, the cabinet body 29 is connected to the other end of the longitudinal damping buffer rod 9 in a penetrating mode, meanwhile, the four walls of the bottom side of the cabinet body 29 are respectively connected with the other ends of the transverse springs 28 in four directions, and the cabinet door 30 and the support rod 31 are arranged on the cabinet body 29. One side of the cabinet door 30 is hinged on the cabinet body 29, the other side of the cabinet door 30 is provided with a quick-opening lock 32, and the cabinet door 30 is locked on the cabinet body 29 through the quick-opening lock 32. Nine support rods 31 are arranged, the nine support rods 31 are divided into three groups, each group of three support rods 31 are horizontally distributed in the cabinet body 29, and the three groups of support rods 31 can form three layers of electrical appliance element 41 installation layers.
The refrigeration piece includes water-cooling piece and circulation air-cooling piece, and water-cooling piece and circulation air-cooling piece all set up on the power cabinet. The water-cooling part comprises a water-cooling heat absorption plate 33, a water-cooling branch pipe 34, a water-cooling liquid inlet pipe 35, a water-cooling hose 36 and a water-cooling liquid return pipe 37, the water-cooling heat absorption plate 33 is arranged on the support rod 31, the water-cooling branch pipe 34 is arranged on the water-cooling heat absorption plate 33, the water-cooling liquid inlet pipe 35 and the water-cooling liquid return pipe 37 are both arranged on the water-cooling branch pipe 34, and the water-cooling hose 36 is arranged on the water-cooling liquid inlet pipe 35. The water-cooling heat absorbing plates 33 are rectangular plate-shaped, three water-cooling heat absorbing plates 33 are arranged, the three water-cooling heat absorbing plates 33 are correspondingly arranged on the three groups of supporting rods 31 one by one, and the three water-cooling heat absorbing plates 33 are respectively used for directly mounting the electrical element 41 and performing heat absorption, temperature reduction and cooling on the electrical element 41. The water-cooling heat absorption plate 33 is provided with water-cooling grooves which are distributed on the water-cooling heat absorption plate 33 in an S shape. The water-cooling branch pipes 34 are distributed in an S shape, the water-cooling branch pipes 34 are embedded in the water-cooling grooves, the number of the water-cooling branch pipes 34 is three, and the three water-cooling branch pipes 34 are embedded in the three water-cooling grooves one by one correspondingly. One end of the water-cooling liquid inlet pipe 35 is arranged on one end of the three water-cooling branch pipes 34 in a penetrating way, and the other end of the water-cooling liquid inlet pipe 35 penetrates through the cabinet body 29. One end of the water-cooling hose 36 is communicated with the other end of the water-cooling liquid inlet pipe 35, and the other end of the water-cooling hose 36 is communicated with the conveying main pipe 7. One end of the water-cooling liquid return pipe 37 is connected with the other ends of the three water-cooling branch pipes 34 in a penetrating way, and the other end of the water-cooling liquid return pipe 37 is communicated with the circulating air cooling part. The water-cooling heat absorption plate 33 is provided with a circulation through hole which can facilitate the internal circulation of air in the cabinet.
The circulating air cooling part comprises an impeller shell 38, an impeller 39 and fan blades 40, wherein the impeller shell 38 is arranged on the cabinet body 29, the impeller 39 is arranged on the impeller shell 38, and the fan blades 40 are arranged on the impeller 39. The center of the impeller shell 38 is communicated with the first liquid return main pipe and the second liquid return main pipe, and the side edge of the impeller shell 38 is communicated with the other end of the water-cooling liquid return pipe 37. The impeller 39 is disposed in the impeller housing 38, a rotation shaft of the impeller 39 penetrates the impeller housing 38, and the blades 40 are disposed on the rotation shaft of the impeller 39. When the cooling liquid flows to the impeller shell 38 through the water-cooling liquid return pipe 37, the impeller 39 is pushed to rotate, and the rotating impeller 39 drives the fan blades 40 to rotate, so that the air circulation in the cabinet body 29 is promoted, and the refrigeration speed of the electrical element 41 is increased.
From the above, the shock absorption and refrigeration integrated high-power high-frequency induction power supply device is provided with the shock absorption piece and the refrigeration piece, wherein the longitudinal shock absorption piece comprises a longitudinal damping shell, a longitudinal damping buffer piece and a liquid return piece, and the refrigeration piece comprises a water cooling piece and a circulating air cooling piece; the cooling liquid that pours into in it will receive the extrusion of longitudinal damping bolster to the power cabinet cooling in getting into the water-cooling piece when the longitudinal damping shell receives vibrations, the cooling liquid that flows out by the water-cooling piece will get into promotes the heat dissipation of cabinet inner loop wind in the cold piece of circulated air, the cooling liquid that flows out by the cold piece of circulated air flows back into the longitudinal damping shell through returning the liquid piece, make shock attenuation and refrigeration need not extra energy supply, through rational design in the shock attenuation simultaneously, utilize vibrations extrusion cooling liquid at the power cabinet inner loop heat dissipation, shock attenuation efficiency and refrigeration efficiency have effectively been improved, manufacturing cost and use cost have been showing to have reduceed, and is suitable for being popularized and used.
While embodiments of the invention have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims (10)

1. The utility model provides a high-power high frequency induction power supply unit of shock attenuation refrigeration integration which characterized in that includes:
a shock absorbing member including a longitudinal shock absorbing member and a lateral shock absorbing member, the lateral shock absorbing member being disposed on the longitudinal shock absorbing member; the longitudinal damping piece comprises a longitudinal damping shell, a longitudinal damping buffer piece and a liquid return piece;
the power supply cabinet is arranged on the longitudinal damping piece and is connected with the longitudinal damping buffer piece;
the refrigeration piece is arranged on the power cabinet and comprises a water cooling piece and a circulating air cooling piece, and the water cooling piece and the circulating air cooling piece are both arranged in the power cabinet;
during vibrations, the coolant liquid in the vertical damping shell receives vertical damping bolster extrusion gets into in the water-cooling piece right the power cabinet cooling, by the water-cooling piece flows the coolant liquid gets into promote the heat dissipation of cabinet inner loop wind in the circulated air-cooling piece, by the circulated air-cooling piece flows the coolant liquid warp it flows back to the liquid spare the vertical damping shell.
2. The shock-absorbing refrigeration integrated high-power high-frequency induction power supply device as claimed in claim 1, wherein the longitudinal damping shell comprises a longitudinal damping cylinder, a longitudinal bearing plate and a longitudinal refrigeration conveying pipe; the longitudinal bearing plate is fixedly arranged on the inner wall of the longitudinal damping cylinder, and a longitudinal pressure-bearing cavity formed by the longitudinal bearing plate and the longitudinal damping cylinder is filled with cooling liquid.
3. The shock-absorbing refrigeration integrated high-power high-frequency induction power supply device as claimed in claim 2, wherein the longitudinal refrigeration conveying pipe comprises an upper longitudinal branch pipe, a lower longitudinal branch pipe, an upper longitudinal check valve, a lower longitudinal check valve and a conveying main pipe, one end of the upper longitudinal branch pipe is arranged on the longitudinal pressure bearing cavity in a penetrating manner, and the penetrating position of the upper longitudinal branch pipe is located at the upper part of the longitudinal pressure bearing cavity; one end of the lower longitudinal branch pipe is arranged on the longitudinal bearing cavity in a penetrating mode, the penetrating position of the lower longitudinal branch pipe is located at the lower portion of the longitudinal bearing cavity, the upper longitudinal check valve is arranged on the upper longitudinal branch pipe, the lower longitudinal check valve is arranged on the lower longitudinal branch pipe, and the directions of the upper longitudinal check valve and the lower longitudinal check valve are opposite; the conveying main pipe is respectively arranged at the other end of the upper longitudinal branch pipe and the other end of the lower longitudinal branch pipe in a penetrating way.
4. The integrated high-power high-frequency induction power supply device for shock absorption and refrigeration as claimed in claim 3, wherein the longitudinal damping buffer member is arranged on the longitudinal damping shell, the longitudinal damping buffer member comprises a longitudinal damping buffer plate and a longitudinal damping buffer rod, the longitudinal damping buffer plate is arranged in the longitudinal bearing cavity and divides the longitudinal bearing cavity into an upper longitudinal bearing cavity and a lower longitudinal bearing cavity; a first liquid return through hole and a second liquid return through hole are formed in one end face of the longitudinal damping buffer rod, one end of the longitudinal damping buffer rod is vertically and fixedly arranged at the center of the longitudinal damping buffer plate, and the other end of the longitudinal damping buffer rod penetrates through the longitudinal bearing plate.
5. The shock-absorbing refrigeration integrated high-power high-frequency induction power supply device according to claim 4, wherein the liquid return piece is arranged on the longitudinal damping buffer piece, the liquid return piece comprises a first liquid return main pipe and a second liquid return main pipe, the first liquid return main pipe is fixedly embedded in the first liquid return through hole, one end of the first liquid return main pipe penetrates through the longitudinal damping buffer rod, and meanwhile, one end of the first liquid return main pipe is positioned on the upper side of the longitudinal damping buffer plate; the second liquid return main pipe is fixedly embedded in the second liquid return through hole, and one end of the second liquid return main pipe is positioned at the lower side of the longitudinal damping buffer plate; the first liquid return main pipe is provided with a first liquid return one-way valve, the second liquid return main pipe is provided with a second liquid return one-way valve, the direction of the first liquid return one-way valve is opposite to that of the upper longitudinal one-way valve, and the direction of the second liquid return one-way valve is opposite to that of the lower longitudinal one-way valve.
6. The integrated high-power high-frequency induction power supply device for shock absorption and refrigeration as claimed in claim 5, wherein the longitudinal shock absorption member further comprises a longitudinal spring, and one end of the longitudinal spring is vertically and fixedly arranged on the longitudinal bearing plate; horizontal shock attenuation piece includes horizontal damping piece, horizontal refrigeration conveyer pipe and horizontal spring, horizontal damping piece with horizontal spring all sets up on the vertical damping piece, horizontal refrigeration conveyer pipe sets up on the horizontal damping piece, horizontal shock attenuation piece corresponds the setting one by one on four inner walls of vertical damping section of thick bamboo nozzle.
7. The integrated high-power high-frequency induction power supply device for shock absorption and refrigeration as claimed in claim 6, wherein the transverse damping member comprises a transverse damping tube and a transverse damping buffer member, the transverse damping tube is horizontally and fixedly arranged on the inner wall of one side of the longitudinal damping cylinder, the transverse damping buffer member comprises a transverse damping buffer plate and a transverse damping buffer rod, the transverse damping buffer plate is arranged in the transverse damping tube, and the transverse damping buffer plate divides the transverse damping tube into a left transverse bearing cavity and a right transverse bearing cavity;
the horizontal conveyer pipe that refrigerates includes horizontal refrigeration conveyer pipe in left side and the horizontal refrigeration conveyer pipe in right side, horizontal refrigeration conveyer pipe one end in left side link up the setting and is in the horizontal bearing chamber left side in left side, horizontal refrigeration conveyer pipe one end in right side link up the setting and is in the horizontal bearing chamber right side in right side, the horizontal refrigeration conveyer pipe other end in left side with the horizontal refrigeration conveyer pipe other end in right side all link up and is in carry on the trunk line, be equipped with the horizontal check valve in left side on the horizontal refrigeration conveyer pipe in left side, be equipped with the horizontal check valve in right side on the horizontal refrigeration conveyer pipe in right side, the horizontal check valve in left side with the horizontal check valve opposite direction in right side.
8. The shock-absorbing refrigeration integrated high-power high-frequency induction power supply device as claimed in claim 7, wherein the power supply cabinet comprises a cabinet body, a cabinet door and a support rod, the cabinet body is arranged on the longitudinal spring and is connected to the other end of the longitudinal damping buffer rod in a penetrating manner, and four walls on the bottom side of the cabinet body are correspondingly connected with the other end of the transverse spring in four directions respectively; one side edge of the cabinet door is hinged to the cabinet body, a quick-opening lock is arranged on the other side edge of the cabinet door, the supporting rods form a group, each group of supporting rods is horizontally distributed in the cabinet body, and each group of supporting rods form one layer of electrical component mounting layer.
9. The shock-absorbing refrigeration integrated high-power high-frequency induction power supply device as claimed in claim 8, wherein the water cooling member comprises a water-cooling heat absorbing plate, water-cooling branch pipes, a water-cooling liquid inlet pipe, a water-cooling hose and a water-cooling liquid return pipe, one water-cooling heat absorbing plate is arranged on each support rod, water-cooling grooves are arranged on the water-cooling heat absorbing plates, and the water-cooling branch pipes are embedded in the water-cooling grooves one by one; one end of the water-cooling liquid inlet pipe is arranged at one end of the plurality of water-cooling branch pipes in a penetrating way, and the other end of the water-cooling liquid inlet pipe penetrates through the cabinet body; one end of the water-cooling hose is communicated with the other end of the water-cooling liquid inlet pipe, and the other end of the water-cooling hose is communicated and connected with the conveying main pipe; and one end of the water-cooling liquid return pipe is communicated with the other ends of the water-cooling branch pipes.
10. The shock-absorbing refrigeration integrated high-power high-frequency induction power supply device as claimed in claim 9, wherein the circulating air cooling part comprises an impeller shell, an impeller and fan blades, the impeller shell is arranged on the cabinet body, the impeller is arranged on the impeller shell, and the fan blades are arranged on the impeller; the center of the impeller shell is communicated with the first liquid return main pipe and the second liquid return main pipe, and the side edge of the impeller shell is communicated with the other end of the water-cooling liquid return pipe; the impeller is arranged in the impeller shell, a rotating shaft of the impeller penetrates through the impeller shell, and the fan blades are arranged on the rotating shaft of the impeller.
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