CN211434544U - Needleless water light instrument - Google Patents

Abstract

A needleless hydrological instrument comprising: the air pump is mounted on the damping device and communicated with the heat dissipation device through the air guide tube, and the heat dissipation device and the damping device are both mounted in the case; the shock-absorbing device includes: the damping device comprises a first damping unit, a second damping unit and a guide rod, wherein the first damping unit is arranged at the upper end of the guide rod, and the second damping unit is arranged at the lower end of the guide rod; first shock attenuation unit include with guide bar sliding connection's first shock attenuation board, the top of first shock attenuation board is equipped with first spring, first spring housing is established on the guide bar, second shock attenuation unit include with guide bar sliding connection's second shock attenuation board, the below of second shock attenuation board is equipped with the support frame. Compared with the prior art, the utility model discloses simple structure adopts multiple shock attenuation, and the shock attenuation performance is good, and separately the heat dissipation design can dispel the heat to high-pressure gas fast, and the radiating effect is good.

Description

Needleless water light instrument

Technical Field

The utility model belongs to the technical field of cosmetic equipment, especially, relate to a needleless water light appearance.

Background

With the development of society and the improvement of living standard, people have further pursuit to the external beauty of the body of the people on the premise of meeting the self health, and the rapid development of scientific technology lays a foundation for the requirement. The needleless hydrophotometer produces high-pressure gas through the air pump, and the high-pressure gas drives the skin nutrient solution to be sprayed on the skin so as to achieve the beautifying method for correcting the skin defects, and can be used for local wrinkle removal, shaping, scar repair and the like. The existing air pump can generate great vibration during working, so that the working quality and efficiency of the existing air pump are greatly reduced.

Therefore, there is a need to provide a new needleless hydrological gauge to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is to provide a needleless water light instrument with multiple shock absorption and rapid heat dissipation.

The technical proposal of the utility model for solving the technical problem is a needleless water-light instrument, which comprises: the air pump is mounted on the damping device and communicated with the heat dissipation device through the air guide tube, and the heat dissipation device and the damping device are both mounted in the case;

the shock-absorbing device includes: the damping device comprises a first damping unit, a second damping unit and a guide rod, wherein the first damping unit is arranged at the upper end of the guide rod, and the second damping unit is arranged at the lower end of the guide rod;

the first damping unit comprises a first damping plate, a guide rod is inserted into the first damping plate and is connected with the guide rod in a sliding mode, a first spring is arranged above the first damping plate, and the first spring is sleeved on the guide rod;

the second damping unit comprises a second damping plate, the second damping plate is inserted with a guide rod and is in sliding connection with the guide rod, a support frame is arranged below the second damping plate, the support frame is sleeved on the guide rod, a second spring is arranged below the support frame, and the second spring is sleeved on the guide rod.

Preferably, the heat sink includes: the first heat dissipation unit is fixed with the second heat dissipation unit through the connecting rod; the first heat dissipation unit comprises a heat conduction base body, a heat pipe is embedded in the lower end face of the heat conduction base body, and a plurality of heat dissipation fins are distributed on the upper end face of the heat conduction base body; the fan is arranged above the radiating fins, the heat pipe is wound into a vortex shape, the structure of the first radiating unit is the same as that of the second radiating unit, and the heat pipe of the first radiating unit is communicated with that of the second radiating unit.

Preferably, the thermal conductivity of the connection rod is lower than that of the thermally conductive base.

Preferably, the first damping plate comprises two first base material layers and a first buffer layer arranged between the two first base material layers, and the second damping plate comprises two second base material layers and a second buffer layer arranged between the two second base material layers.

Preferably, the first buffer layer and the second buffer layer are made of rubber materials.

Preferably, the first damper plate is provided with a lightening hole.

Preferably, the support frame comprises: the connecting plate is fixedly connected with the base and the sliding plate respectively, and the sliding plate is sleeved on the guide rod.

Preferably, the connecting plate is an arc plate which is concave downwards.

Preferably, the joint of the heat pipe of the first heat dissipation unit and the heat pipe of the second heat dissipation unit is located below the center of the heat-conducting base body.

Preferably, a handle is arranged on the case so as to drag the needleless hydrological instrument; four rollers are arranged at the bottom of the case, and braking parts are arranged on at least two of the four rollers.

Preferably, the sliding plate is provided with a guide hole, and the diameter of the guide hole is larger than the diameter of the guide rod, so that the sliding plate can slide up and down along the guide rod.

Preferably, the guide rod, the connecting plate and the sliding plate are all provided in plurality.

Preferably, the heat pipe is a copper pipe.

Preferably, the connecting rod is a plurality of connecting rods.

Preferably, the first heat dissipation unit is cylindrical in shape.

Compared with the prior art, the utility model discloses simple structure adopts multiple shock attenuation, and the shock attenuation performance is good, and separately the heat dissipation design can dispel the heat to high-pressure gas fast, and the radiating effect is good.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the damping device of the present invention;

FIG. 3 is a schematic view of a part of the structure of the shock absorber of the present invention;

fig. 4 is a schematic view of the heat dissipation device of the present invention;

fig. 5 is a front view of the heat dissipation device of the present invention.

In the figure:

1. the air pump comprises an air pump body, a case, a damping device, a heat radiating device, a handle, a roller, a braking part, a first damping unit, a second damping unit, a guide rod, a weight reducing hole, a first damping plate, a first spring, a second damping plate, a supporting frame, a second spring, a base plate, a connecting plate, a sliding plate, a guide hole, a first radiating unit, a second radiating unit, a connecting rod, a heat conducting base body, a heat pipe, a heat radiating fin and a supporting frame, wherein the air pump body comprises an air pump body, a first damping unit, a second damping unit, a.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-5, the present embodiment includes: the air pump 1 is arranged on the damping device 3, the air pump 1 is communicated with the heat dissipation device 4 through the air duct, and the heat dissipation device 4 and the damping device 3 are both arranged in the case 2;

the damper device 3 includes: the damping device comprises a first damping unit 31, a second damping unit 32 and a guide rod 33, wherein the first damping unit 31 is arranged at the upper end of the guide rod 33, and the second damping unit 32 is arranged at the lower end of the guide rod 33;

the first damping unit 31 comprises a first damping plate 311, the first damping plate 311 is inserted with a guide rod 33 and is slidably connected with the guide rod 33, a first spring 312 is arranged above the first damping plate 311, and the first spring 312 is sleeved on the guide rod 33;

the second damping unit 32 includes a second damping plate 321, the second damping plate 321 is inserted with the guide rod 33 and is slidably connected to the guide rod 33, a support frame 322 is disposed below the second damping plate 321, the support frame 322 is sleeved on the guide rod 33, a second spring 323 is disposed below the support frame 322, the second spring 323 is sleeved on the guide rod 33, and the air pump 1 is respectively fixedly connected to the first damping plate 311 and the second damping plate 321.

The heat sink 4 includes: the first heat dissipation unit 41, the second heat dissipation unit 42 and the connecting rod 43, wherein the first heat dissipation unit 41 is fixed with the second heat dissipation unit 42 through the connecting rod 43; the first heat dissipation unit 41 includes a heat conduction base 411, a heat pipe 412 is embedded in a lower end surface of the heat conduction base 411, and a plurality of heat dissipation fins 413 are distributed on an upper end surface; a fan is disposed above the heat sink 413, the heat pipe 412 is wound in a spiral shape, the structure of the first heat dissipation unit 41 is the same as that of the second heat dissipation unit 42, and the heat pipe 412 of the first heat dissipation unit 41 is communicated with the heat pipe 412 of the second heat dissipation unit 42.

The thermal conductivity of the connection bar 43 is lower than that of the heat conductive base 411, reducing the conduction of heat between the heat conductive bases 411.

The first damper plate 311 includes two first base material layers 3111 and a first cushion layer 3112 disposed between the two first base material layers 3111, and the second damper plate 321 includes two second base material layers and a second cushion layer disposed between the two second base material layers.

The first cushion layer 3112 and the second cushion layer are made of rubber.

The first damper plate 311 is provided with lightening holes 34 to lighten the whole damper device 3 while ensuring the damping effect.

The supporting bracket 322 includes: the base 3221, the connecting plate 3222 and the sliding plate 3223, the connecting plate 3222 is respectively and fixedly connected with the base 3221 and the sliding plate 3223, and the sliding plate 3223 is sleeved on the guide rod 33.

The connecting plate 3222 is a downward-recessed arc-shaped plate, which has good elasticity and is beneficial to shock absorption.

The joint of the heat pipe 412 of the first heat dissipation unit 41 and the heat pipe 412 of the second heat dissipation unit 42 is located below the center of the heat conductive substrate 411, and the first heat dissipation unit 41 and the second heat dissipation unit 42 are laminated, so as to reduce the overall length of the heat dissipation device 4.

A handle 5 is arranged on the case 2 so as to drag the needleless hydrological instrument; four rollers 6 are arranged at the bottom of the case 2, and braking members 7 are arranged on at least two rollers 6 in the four rollers 6.

The slider 3223 is provided with a guide hole 32231, and the diameter of the guide hole 32231 is larger than the diameter of the guide rod 33, so that the slider 3223 slides up and down along the guide rod 33.

The guide rod 33, the connecting plate 3222 and the slide plate 3223 are all plural. In this embodiment, four guide rods 33, four connecting plates 3222 and four sliding plates 3223 are provided to help balance the first damping unit 31 and the second damping unit 32 and to damp the air pump 1.

The heat pipe 412 is a copper pipe.

The plurality of connecting rods 43 is beneficial to the stability of the heat sink 4.

The first heat dissipation unit 41 has a cylindrical shape.

Base 3221 and guide rod 33 are both mounted on chassis 2.

The utility model provides a needleless water light appearance's working process does:

(1) a worker drags the needleless hydrological instrument to a working place through the handle 5 and then puts down the brake part 7, so that the needleless hydrological instrument cannot move around.

(2) Starting the needleless hydrological instrument, the air pump 1 starts to work, and the air pump 1 transmits the manufactured high-pressure gas to the copper pipe of the first heat dissipation unit 41 of the heat dissipation device 4 through the air guide pipe.

When the air pump 1 works, the first damping unit 31 buffers the air pump 1 when vibrating upwards, the second damping unit 32 buffers the air pump 1 when vibrating downwards, and the arrangement of the double damping units improves the damping performance of the air pump 1. The concrete expression is as follows: when the air pump 1 vibrates upwards, the first damping plate 311 of the first damping unit 31 firstly buffers the air pump 1, and then the first spring 312 buffers the air pump 1, so that the double damping arrangement ensures the damping effect of the air pump 1. When the air pump 1 vibrates downwards, the second damping plate 321 of the second damping unit 32 firstly buffers the air pump 1, then the supporting frame 322 and the second spring 323 buffer the air pump 1, and the double damping arrangement ensures the damping effect of the air pump 1.

Air pump 1 is because its self weight, and when it shakes downwards, the power that second shock attenuation board 321 received can be great, and support frame 322 and second spring 323 mutually support air pump 1 jointly and to the shock attenuation of air pump 1, can effectively prevent support frame 322 and second spring 323 from damaging or losing efficacy when guaranteeing the shock attenuation effect, make damping device 3 more durable.

(3) When high-pressure gas passes through the copper pipe of the first heat dissipation unit 41, the heat of the high-pressure gas is conducted to the heat conduction base 411 and the heat dissipation fins 413, the high-pressure gas in the copper pipe can be rapidly cooled, and then the second heat dissipation unit 42 can cool the high-pressure gas in the copper pipe for the second time through the copper pipe of the second heat dissipation unit 42. If the cooling is once accomplished, because the heat conductivity of heat conduction base member 411 is high, the heat of conducting to heat conduction base member 411 can influence the high-pressure gas temperature of copper pipe exit, and separately dispel the heat and can guarantee that the heat among the high-pressure gas conducts on heat conduction base member 411, can prevent effectively again that the heat of heat conduction base member 411 from influencing the temperature of copper pipe exit high-pressure gas. Secondly, the copper pipe is set to the swirl form firstly, the contact area of the copper pipe and the heat conduction substrate 411 can be increased, secondly, the pipeline is smoother, high-pressure gas circulation is facilitated, under the same circulation speed, the energy consumption is less, and the cost is lower. The overlapping of the first heat dissipating unit 41 and the second heat dissipating unit 42 can reduce the overall length of the heat dissipating device 4, so that it can adapt to more environments.

This application simple structure adopts multiple shock attenuation, and the damping performance is good, and separately the heat dissipation design can dispel the heat to high-pressure gas fast, and the radiating effect is good.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A needleless hydrological instrument comprising: the air pump is mounted on the damping device and communicated with the heat dissipation device through the air guide tube, and the heat dissipation device and the damping device are both mounted in the case;

the shock-absorbing device includes: the damping device comprises a first damping unit, a second damping unit and a guide rod, wherein the first damping unit is arranged at the upper end of the guide rod, and the second damping unit is arranged at the lower end of the guide rod;

the first damping unit comprises a first damping plate, a guide rod is inserted into the first damping plate and is connected with the guide rod in a sliding mode, a first spring is arranged above the first damping plate, and the first spring is sleeved on the guide rod;

the second damping unit comprises a second damping plate, the second damping plate is inserted with a guide rod and is in sliding connection with the guide rod, a support frame is arranged below the second damping plate, the support frame is sleeved on the guide rod, a second spring is arranged below the support frame, and the second spring is sleeved on the guide rod.

2. The needleless hydrological gauge of claim 1, wherein the heat sink comprises: the first heat dissipation unit is fixed with the second heat dissipation unit through the connecting rod; the first heat dissipation unit comprises a heat conduction base body, a heat pipe is embedded in the lower end face of the heat conduction base body, and a plurality of heat dissipation fins are distributed on the upper end face of the heat conduction base body; the fan is arranged above the radiating fins, the heat pipe is wound into a vortex shape, the structure of the first radiating unit is the same as that of the second radiating unit, and the heat pipe of the first radiating unit is communicated with that of the second radiating unit.

3. The needleless hydrological gauge of claim 2, wherein the thermal conductivity of the connecting rod is lower than the thermal conductivity of the thermally conductive matrix.

4. The needleless hydrological gauge of claim 3, wherein the first shock absorbing plate comprises two first substrate layers and a first buffer layer disposed between the two first substrate layers, and the second shock absorbing plate comprises two second substrate layers and a second buffer layer disposed between the two second substrate layers.

5. The needleless hydrological gauge of claim 4, wherein the first buffer layer and the second buffer layer are made of a rubber material.

6. The needleless hydrological gauge of claim 5, wherein the first shock absorbing plate is perforated with weight-reducing holes.

7. The needleless hydrological gauge of claim 6, wherein the support frame comprises: the connecting plate is fixedly connected with the base and the sliding plate respectively, and the sliding plate is sleeved on the guide rod.

8. The needleless hydrological gauge of claim 7, wherein the connecting plate is a downwardly concave arcuate plate.

9. The needleless hydrological gauge of claim 8, wherein the junction of the heat pipe of the first heat dissipating unit and the heat pipe of the second heat dissipating unit is located below the center of the thermally conductive base.

10. The needleless hydrological instrument of any one of claims 1 to 9, wherein a handle is provided on the housing for pulling the needleless hydrological instrument; four rollers are arranged at the bottom of the case, and braking parts are arranged on at least two of the four rollers.

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