KR20110091312A - Decompression massage machine and decompress filtering device, manifold device, massage device for the same - Google Patents

Abstract

By increasing the pressure reduction efficiency, energy efficiency can be increased and the size of the equipment can be made more compact.In addition, the pressure can be reduced by inhaling air to increase the filtering efficiency of foreign substances generated during skin pressure reduction and to minimize the pressure loss during the filtering process. A driving unit including an air pump for generating a pressure, a distributor connected to the air inlet of the air pump, and configured to change the direction of air; and at least one massager and the distributor connected to the driving unit to apply pressure to the skin. It is provided between each of the massager to provide a pressure-reducing massage equipment comprising at least one pressure-sensitive filter for filtering foreign matter contained in the intake air.

Description

Pressure Reducing Massager and Decompressor, Distributor and Massager for Pressure Relief Massage Equipment {DECOMPRESSION MASSAGE MACHINE AND DECOMPRESS FILTERING DEVICE, MANIFOLD DEVICE, MASSAGE DEVICE FOR THE SAME}

The present invention relates to a facility for massaging the skin and the like of the human body. More specifically, the present invention relates to a vacuum filter, a dispenser, and a massager provided in the pressure-reducing massage equipment and the pressure-reducing massage equipment using pressure.

Recently, with increasing interest in skin, various instruments or methods for skin care have been developed.

In the human body, the skin is formed with the brain in the mother. The skin is on the outermost side of the body and plays an important role in protecting and maintaining life and internal organs from various external influences. In addition, the skin plays a very important role socially as a part that is visible to the outside in addition to the life support function. Normally, when your skin loses its elasticity, you won't get makeup, and you'll get a drooping impression. Therefore, it is very important to maintain and maintain the skin for health or social activities.

In general, appropriate massage with skin cleansing is known to prevent skin aging and keep skin elastic.

Therefore, massage devices for stimulating the skin have been developed and used, such as physically stimulating the skin or applying a poultice effect by applying heat.

In order to increase the pressure reduction efficiency to increase the energy efficiency and to reduce the size of the equipment to provide a reduced pressure massage device and a reduced pressure filter device, a distributor and a massage device of the reduced pressure massage equipment.

In addition, the present invention provides a reduced pressure massage device, a dispenser, and a massage device for reducing pressure massage equipment, and reducing pressure massage equipment to improve filtering efficiency of foreign substances generated during skin pressure reduction and minimize pressure loss during the filtering process.

In addition, the present invention provides various types of massage functions, and provides a reduced pressure massage device, a dispenser, and a massage device of a reduced pressure massage device and a reduced pressure massage device, which are capable of increasing the massage effect.

To this end, the apparatus is provided with a driving unit for generating a decompression, a massager connected to the driving unit to apply a decompression force to the skin, and installed between the driving unit and the massager to rectify suction air and filter out foreign substances contained in the air. It may include a filter.

The driving unit may include an air pump and a distributor connected to the air pump and provided with at least one pressure reducing filter to change the direction of air to each pressure reducing filter.

The driving unit may further include a silencer connected to the air pump.

The driving unit may further include a pressure control valve installed on an air line connecting between the distributor and the pressure reducing filter.

The driving unit may further include a direction switching valve connected to the air pump, and an air brush connected to the direction switching valve to eject air.

The distributor may include a manifold in which a pipe line connected to an air pump and a pipe line connected to the pressure reducing filter respectively pass through the length direction, and a solenoid valve installed in the manifold and connected to the respective pipe lines to change the air direction. Can be.

In this way, the pipeline is formed through the manifold in a straight direction, making the manifold very easy and reducing the pressure loss.

The pressure reducing filter includes a housing forming an outer shape, a cover coupled to a front end of the housing, an air inlet installed in the cover, an air outlet formed at a bottom surface of the housing facing the air inlet, and installed between the air inlet and the air outlet. The filter is passed through the air, the filter is installed in the filter side may be open to the filter side and the lower end of the communication with the air outlet, and the filter top block may include a filter fixing member which is installed with a gap with the air inlet.

Here, the filter may be formed in a hollow cylindrical shape.

In addition, the housing may further include a stopper for opening and closing the discharge port and the discharge port for discharging the foreign matter at one side lower.

The filter fixing member may include an upper fixing member fixed to the upper end of the filter and a lower fixing member fixed to the lower end of the filter. The upper fixing member has a structure of covering the upper filter in the form of a disk, the upper surface may be a structure formed with a plurality of protrusions protruding at intervals to maintain a gap with the inner surface of the cover. In addition, the lower fixing member may have a structure in which a central portion is opened and a coupling portion is formed at the lower end thereof while maintaining an airtightness at a tip of a passage installed in the housing so as to communicate with the air outlet.

The massaging machine may include a frame having a lower end and a suction port through which air is sucked therein, and a pair of adhesion rolls installed to face the skin at both ends of the open lower end of the frame.

In addition, the massager may further include a handle that is connected to the frame and the air passage formed therein in communication with the suction port.

Accordingly, when the negative pressure is applied to the inside of the frame by the air pressure, the skin is sucked into the inside of the frame. At this time, the adhesion roll installed on the frame is freely rotated to facilitate the movement of the skin.

The massager may further include a plurality of protrusions protruding from the inside of the frame to contact the skin.

In addition, the massager may include a high frequency unit that can apply a high frequency to the skin.

The massaging machine includes a decompression cup having a suction opening through which a lower end thereof is opened and air is sucked therein, and a handle having an air passage formed in the decompression cup and communicating with the suction opening therein, and the decompression cup is in contact with the skin. It may have a structure in which a conductive layer plated with a conductive metal is formed.

As such, the device can increase the decompression force, thereby maximizing the massage effect through various massage functions as well as the massage effect due to skin swelling.

In addition, the device is easy to manufacture the equipment can reduce the production cost, thereby increasing the cost competitiveness.

In addition, the device can reduce the energy loss generated during the decompression to increase the decompression efficiency, thereby reducing the size of the equipment and can increase the decompression force.

In addition, it is possible to increase the filtering efficiency of the foreign substances generated during the decompression of the skin, it is more effective in the maintenance of the facility.

1 is a schematic diagram showing the configuration of a reduced pressure massage equipment according to the present embodiment.
2 is a perspective view showing a dispenser of the reduced pressure massage equipment according to the present embodiment.
3 is a plan sectional view showing a dispenser of the reduced pressure massage equipment according to the present embodiment.
4 is an exploded perspective view illustrating a reduced pressure filter of the reduced pressure massage equipment according to the present embodiment.
5 is a cross-sectional view showing a pressure reduction filter of the pressure reduction massage equipment according to the present embodiment.
6 is a perspective view showing a massager of the pressure-sensitive massage equipment according to the present embodiment.
7 is a side cross-sectional view showing the massager of the pressure-sensitive massage equipment according to the present embodiment.
8 is a plan sectional view showing the massager of the pressure-sensitive massage equipment according to the present embodiment.
Figure 9 is a side cross-sectional view showing the massager of the reduced pressure massage equipment according to another embodiment.
10 is a cross-sectional view illustrating a pressure reducing cup of the massager according to the embodiment of FIG. 9.
FIG. 11 is a cross-sectional view illustrating a handle of the massage machine according to the embodiment of FIG. 9.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures have been exaggerated or reduced in size for clarity and convenience in the figures and any dimensions are merely exemplary and not limiting. And the same structure, element or part that appears in more than one figure the same reference numerals are used in different embodiments to indicate corresponding or similar features.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a,” “an,” and “the” include plural forms as well, unless the phrases clearly indicate the opposite. As used herein, the term "comprising" embodies a particular characteristic, region, integer, step, operation, element, and / or component, and other specific characteristics, region, integer, step, operation, element, component, and / or group. It does not exclude the presence or addition of.

Unless defined otherwise, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. Commonly defined terms used are additionally interpreted to have a meaning consistent with the related technical literature and the presently disclosed contents, and are not interpreted in an ideal or very formal sense unless defined.

Embodiments of the invention described with reference to a perspective view specifically illustrate an ideal embodiment of the invention. As a result, various variations of the illustration, for example variations in the manufacturing method and / or specification, are expected. Thus, embodiments are not limited to the specific forms of the illustrated areas. Thus, the regions shown in the figures are merely approximate, and their shapes are not intended to depict the exact shape of the regions, nor are they intended to limit the scope of the present invention.

1 shows a configuration of a reduced pressure massage equipment according to the present embodiment.

In the following description, the decompression means reducing the pressure, and means reducing the pressure to a negative pressure which is a pressure below atmospheric pressure.

As shown, the facility 10 includes a driving unit 100 for generating a decompression, a massager 200 connected to the driving unit 100 to apply a decompression force to the skin, and the driving unit 100 and the massager 200. It is installed between the) to rectify the air and includes a decompression filter 300 for filtering foreign matter contained in the intake air.

Here, the driving unit 100 and the pressure reduction filter 300 may be installed in a housing of a predetermined form to form one facility. The shape of the housing constituting the facility 10 can be variously changed in design and is not particularly limited. In addition, the driving unit 100 may further include a control unit 102 for controlling and operating the facility. The control unit 102 is organically coupled to a controller with a logic circuit and an operation unit, a display unit and the like provided with a switch to control the equipment to a desired condition.

The massaging machine 200 may be provided with one or two or more and is connected to each of the pressure reducing filter 300 via an air hose 210.

Accordingly, when the driving unit 100 is operated, a vacuum pressure is applied to the pressure reduction filter 300, and air is sucked into the massager 200 connected to the pressure reduction filter 300. Thus, the pressure is applied to the skin in which the massager 200 is in close contact with the massager. And the foreign matter contained in the air sucked from the massager 200 is removed while passing through the pressure-sensitive filter (300).

The driving unit 100 includes an air pump 110 for sucking air to generate a decompression force, and a distributor 120 connected between the air pump 110 and the pressure reduction filter 300.

The air pump 110 has an air suction port 112 for sucking air and an air discharge port 114 for discharging air, and the distributor 120 is connected to the air suction port 112 of the air pump 110. Is installed. When the air pump 110 is driven, the air is sucked through the distributor 120.

The distributor 120 selectively connects the plurality of pressure reducing filters 300 installed in the distributor 120 to the air pump 110 by changing the direction of the pipe through which the air to be sucked is distributed.

In addition, the distributor 120 has a structure in which the pressure reducing filter 300 communicates with the atmosphere to remove the pressure reducing force applied to the pressure reducing filter 300 in a short time. The dispenser 120 is provided with a silencer 140 on a line communicating with the atmosphere so as to reduce the generation of noise in the process of the air is distributed to the decompression filter 300 through the distributor 120. The detailed structure of the distributor 120 will be described later.

The driving unit 100 is installed on the air line 150 connecting between the distributor 120 and the decompression filter 300 to communicate the air line 150 with the atmosphere so as to be caught by the decompression filter 300. It further includes a pressure control valve 160 for adjusting the pressure.

The pressure control valve 160 is composed of a plurality of electronic solenoid valve 162 that is controlled by the electric signal. The amount of external air flowing into the air line 150 varies according to the number of operations of the electronic solenoid valve 162, thereby controlling the depressurization force applied to the pressure reducing filter 300. In this embodiment, three electromagnetic solenoid valves 162 are installed on the air line to control the air inflow rate in three stages.

In addition, the pressure control valve 160 may further include a manual open / close valve 164 that is manually controlled and operated in addition to the electronic solenoid valve 162. The manual opening and closing valve 164 is a rotary knob structure to manually adjust the opening and closing amount of the pipeline is configured to adjust the air inflow amount flowing into the air line 150.

In this way, through the electronic solenoid valve 162 constituting the pressure control valve 160 and the manual opening and closing valve 164 to distribute the outside air to the air line 150 it is possible to adjust the pressure reducing force applied to the pressure reduction filter 300. .

The driving unit 100 is provided with a silencer 170 to reduce the noise generated when the air is discharged in accordance with the drive of the air pump 110. In addition, the driving unit 100 is further provided with an airbrush 172 for spraying the air discharged connected to the discharge port 114 of the air pump 110 to perform the necessary work.

In this embodiment, the silencer 170 and the air brush 172 are connected to the air discharge port 114 of the air pump 110 via the direction switching valve 174. The directional valve 174 is composed of a 3-way solenoid valve. The air discharged from the air pump 110 according to the operation of the direction switching valve 174 is discharged to the air brush 172 or the silencer 170.

The airbrush 172 is a structure in which the injection nozzle 176 is provided at the tip to inject air, and the airbrush 172 is not particularly limited in structure or form.

The air brush 172 cleans the reduced pressure filter 300 or the massager 200 by spraying the air discharged from the air pump 110 at a predetermined pressure and a flow rate through the injection nozzle 176. A pressure reducing filter 178 may be further installed between the direction switching valve 174 and the air brush 172 to supply air supplied by the air brush at a uniform flow rate.

[Distributor]

2 and 3 show a distributor according to the present embodiment.

According to the above drawings, the distributor 120 has a first conduit 124 connected to the air pump 110 and a second conduit 126 connected to the pressure reduction filter 300 and a third conduit communicating with the atmosphere. 128 includes a manifold 122 formed through the longitudinal direction, respectively, and a solenoid valve 130 mounted to the manifold 122 and connected to the respective pipe lines to change the air direction.

The manifold 122 is a block-like structure, three pipes are formed in a straight line through the longitudinal direction. In this embodiment, the solenoid valve 130 is installed along one surface of the manifold 122 as a 3-way solenoid valve for selectively communicating three lines. One surface of the manifold 122 is formed with a hole in communication with each pipe, the solenoid valve 130 is connected to each pipe through the hole to selectively connect each pipe.

Here, the distributor 120 has a structure in which the first conduit 124, the second conduit 126, and the third conduit 128 formed in the manifold 122 penetrate in a straight line. It can be manufactured easily.

In the present embodiment, both ends of the first duct 124 are connected to the air inlet 112 of the air pump 110. In addition, both ends of the second conduit 126 are connected to the pressure reduction filter 300, respectively. Both ends of the remaining third conduit 128 are connected to the silencer 140. In addition, two solenoid valves 130 are installed at both sides of the center of the manifold 122 along the longitudinal direction of the pipe line to control the pipe connections to the respective pressure reducing filter 300.

As such, in the manufacture of the distributor 120 for distributing air pressure to the plurality of pressure reducing filters 300, the manifold 122 may be easily manufactured by forming a pipe through a straight line.

With this structure, the distributor 120 connects the first conduit 124 to the second conduit 126 according to the control operation of the solenoid valve 130. In this way, the air pump 110 and the decompression filter 300 are in communication with each other, so that the skin massage can be performed through the massager 200 connected to the decompression filter 300. And if necessary, according to the operation of the solenoid valve 130, the second conduit 126 connected to the pressure reduction filter 300 and the third conduit 128 connected to the silencer is connected to remove the negative pressure on the massager (200).

Here, the manifold 122 is the input and output of air through both side ends of the manifold 122 as the pipe passes through the both ends. This can minimize the pressure loss in the manifold (122).

The manifold 122 connects the massager to the air pump or the atmosphere to create a pressure such as a decompression force or an atmospheric pressure on the massager. In the case of the structure in which the pipeline formed in the manifold penetrates in the longitudinal direction as in the present embodiment, air is sucked and discharged at both ends of the pipeline in comparison with the structure in which the pipeline is formed only on one side. Thus, the manifold can make the generation and release of vacuum pressure faster than when air is sucked in and discharged from only one side.

In other words, suctioning air from the pumps from both ends of the manifold increases the flow cross sectional area of the air, so that the air in the massager can be sucked up more quickly. Similarly, atmospheric air flows in from both ends of the manifold to increase the flow cross sectional area of the air, thereby releasing the vacuum pressure in the massaging machine more quickly. Accordingly, the manifold can apply the speed of the vacuum vibration applied to the massager to 10 Hz or more. However, in the case of the manifold of the structure in which a pipeline is formed only at one end and air flows in and out, the above vibration speed cannot be expected. Manifolds formed with only one end of the pipe may also increase the vibration speed, but this is only possible electrically, which also has the disadvantage that the actual vacuum pressure is not smoothly released.

[Pressure Reduction Filter]

4 and 5 show a pressure reduction filter according to the present embodiment.

The pressure reduction filter 300 has a structure that serves to remove foreign substances contained in the air together with the rectifying action to evenly and uniformly maintain the air pressure and flow rate.

To this end, the pressure reduction filter 300 includes a housing 310 forming an outer shape as shown, a cover 312 coupled to the front end of the housing 310, an air inlet 314 formed in the cover 312, It is installed between the air outlet 316 formed on the bottom surface of the housing 310 facing the air inlet 314, the air inlet 314 and the air outlet 316 to distribute the air at a predetermined pressure and flow rate Filter 320, the filter 320 is installed on the filter side is open to the filter side and the lower end of the filter communicates with the air outlet 316, the filter is blocked by the filter inlet is installed with a gap with the air inlet 314 330.

In the present embodiment, the pressure reduction filter 300 is disposed such that the air inlet 314 installed in the cover 312 faces upward and the air outlet 316 formed in the housing 310 faces the ground. The upper end of the filter 320 means the end of the air inlet 314 and the lower end of the filter 320 means the end of the air outlet 316 on the ground side.

Therefore, the air does not proceed immediately through the air inlet 314 to the filter 320 but is blocked by the filter fixing member 330 blocking the top of the filter 320 so that the air exits through the air outlet 316 through the side of the filter 320. do. In this process, foreign matter contained in the air is more easily separated and collected in the housing 310.

The housing 310 has a cylindrical structure with an open top. The cover 312 is installed at the open upper end of the housing 310 to completely block the inside of the housing 310 from the outside. An O-ring 313 for airtightness is inserted into the coupling portion between the cover 312 and the housing 310.

An air outlet 316 through which air is discharged is formed at the center of the bottom of the housing 310. In addition, a passage 318 communicating with the air outlet 316 is formed to protrude perpendicularly to the inner bottom surface of the housing 310.

In addition, the housing 310 has a groove 340 in which foreign matter is guided on the inner circumferential surface thereof is formed along the longitudinal direction. In addition, a discharge port 342 is formed at a bottom of the housing 310 connected to the groove 340 to discharge foreign substances to the outside. The outlet 342 has a structure in which a stopper 344 is detachably installed to open and close the outlet.

The air outlet 316 formed in the housing 310 is connected to the second conduit 126 of the distributor 120 through the air line 150. The air outlet 316 is provided with a fastener 346 so that the air line 150 is coupled.

In the present embodiment, the cover 312 is fastened to the housing 310 via a bolt or the like, the fastening structure of the cover 312 is not limited thereto and can be variously implemented. The air suction opening 314 formed in the cover 312 is connected to the massager 200 through the air hose 210.

The inside of the cover 312 is a rib 350 protruding to the coupling with the filter fixing member 330.

The filter 320 is coupled to the filter fixing member 330 and positioned between the rib 350 and the passage 318.

In the present embodiment, the filter 320 has a cylindrical shape with a central portion. The filter 320 maintains a constant depressurizing force applied to the massager 200 by making the flow rate of air constant. In addition, in the present embodiment, the filter 320 is manufactured by foaming a PE resin so as to have a pore of approximately 1 μm. The material of the filter and the degree of voids are not particularly limited.

The filter fixing member 330 includes an upper fixing member 332 fixedly installed on the upper end of the filter 320 and a lower fixing member 334 fixedly installed on the lower end of the filter 320. The upper fixing member 332 and the lower fixing member 334 may be separated separately and may be integrally connected.

The side surface of the filter 320 between the upper fixing member 332 and the lower fixing member 334 is exposed to the outside.

The upper fixing member 332 has a structure to block the upper portion of the filter 320 in the form of a disc clogged front. The upper surface of the upper fixing member 332 has a structure in which a plurality of protrusions 352 protruding at intervals to maintain a gap with the inner surface of the cover 312. The protrusion has a structure fitted between the ribs 350 formed inside the cover 312.

As the protrusion 352 formed on the upper fixing member 332 is fitted to the rib 350, the position of the filter 320 installed on the upper fixing member 332 is fixed to prevent flow. In addition, while the protrusion 352 is in contact with the inner surface of the cover 312, a gap D is formed and maintained between the cover 312 and the upper fixing member 332.

The air introduced through the air inlet 314 of the cover 312 is introduced into the housing 310 through the gap (D) to proceed to the passage 318 through the open side of the filter 320. .

Here, the upper surface of the upper fixing member may be further provided with a cone member inclined in the center and inclined side. Accordingly, the inclined side surface of the cone member guides the air, and thus, the foreign matter contained in the air can be more easily moved into the housing 310.

The lower fixing member 334 is configured to maintain the airtightness with the passage 318 while fixing the lower position of the filter 320.

To this end, the lower fixing member 334 has a structure in which a central portion is opened and a coupling portion is coupled to the lower end while maintaining airtightness at the tip of the passage 318 communicating with the air outlet 316.

The coupling part has a groove 360 having an inner diameter corresponding to the distal end of the passage 318 so that the distal end of the passage 318 may be fitted, and an O-ring 362 is installed in the groove to maintain airtightness.

The length between the upper fixing member 332 and the lower fixing member 334 provided with the filter 320 is such that airtightness between the lower fixing member 334 and the passage 318 can be maintained. When the cover 312 is fastened to the housing 310, the O-ring 362 is closely contacted between the fastening portion of the lower fixing member 334 and the front end of the passage 318, so that the filter 320 is coupled to the passage 318. do.

Through the structure as described above, the pressure reduction filter 300 can minimize the pressure drop and secure the flow rate while reducing the size.

This is because the pressure reduction filter 300 does not interfere with the flow of air as much as possible in removing foreign matters contained in the air. That is, the air is introduced into the housing 310 through the gap D between the upper fixing member 332 and the cover 312 after colliding with the upper fixing member 332. The gap D is large enough and formed in all directions to minimize the pressure loss. And the upper fixing member 332 is placed in the direction of the air inlet through the air inlet 314, the air impinges on the upper fixing member 332. In this process, foreign matter contained in the air is separated. Foreign matter separated from the air is collected to fall to the bottom of the housing (310). The air introduced into the housing 310 passes through the filter 320 through the side of the filter 320 and then exits through the passage 318 to the air outlet 316. The side surface of the filter 320 passes through the filter 320 through the front side of the filter 320 while the air introduced into the housing 310 is opened in the front along the outer circumferential surface. The air passing through the filter 320 exits through the air outlet 316 through a passage 318 communicating with the filter 320. As such, the air is discharged to the air discharge port 316 communicating with the center of the filter 320 through the side of the filter 320, thereby minimizing the pressure drop and filtering a large amount of air.

The foreign matter separated from the air may be collected on the bottom of the housing 310 and discharged through the outlet 342 formed on the bottom of the housing 310.

[Massage cooker]

The massager 200 is a component for performing a massage by applying a pressure to the skin.

6, 7 and 7 show the massager according to the present embodiment.

As shown, the massaging machine 200 is provided with a frame 210 having a lower end and an inlet port 212 formed therein for inhaling air therein, and facing the skin at both ends of the open lower part of the frame 210. It includes a pair of adhesion rolls 220.

In addition, the frame 210 is provided with a handle 230 having an air passage 232 communicating with the suction port 212 therein.

The outer end of the handle 230 is connected to the air inlet 314 formed in the cover 312 of the pressure reduction filter 300 via the air hose 210. A fastener 240 is coupled to the front end of the handle 230 for detachable coupling with the air hose 210.

When air is sucked through the air inlet 314, the air is sucked into the inlet 212 of the frame 210, and a pressure reducing force is formed in the massager.

The frame 210 has a support 214 protrudingly installed at both sides thereof, and a pair of adhesion rolls 220 are rotatably installed at both ends of the support 214. The adhesive roll 220 is rotatably coupled to both ends of the support 214 and disposed opposite to both open lower ends of the frame 210. The adhesive roll 220 is exposed downward through the support 214 to contact the skin.

Accordingly, when the negative pressure is applied to the inside of the frame 210 by the air pressure, the skin is sucked into the inside of the frame 210. At this time, the adhesion roll 220 installed on the support 214 of the frame 210 rotates freely. This will make it easier to move the skin.

The massager 200 has a structure in which the adhesion roll 220 moves freely with respect to the supporter 214 to pull the skin.

To this end, the massaging machine has long grooves 270 formed in both supports 214 installed in the frame 210 along the longitudinal direction, and the rotation shafts 222 of both ends of the contact rolls move in the grooves 270. The structure is fitted as much as possible. The width of the groove 270 is approximately the size corresponding to the rotation axis 222 of the contact roll and is formed in a predetermined length toward the center from the tip of the support.

Accordingly, the close contact roll 220 pulls the user's skin while moving toward the center along the groove 270 when a vacuum pressure is applied to the frame 210.

In addition, the massaging machine 200 is installed in the groove 270 and elastically on the rotating shaft 222 of the adhesion roll in order to return the adhesion roll 220 moved along the groove 270 to its original position as described above. It further includes an elastic member 272 is installed.

Therefore, the adhesion roll 220 compresses the elastic member 272 while moving toward the center of the massager, thereby generating an elastic restoring force on the elastic member. When the vacuum pressure applied to the frame 210 is released, the contact roll 220 is pushed back to its original position by the elastic restoring force of the elastic member 272. In this process, the skin drawn by the contact roll 220 is stretched back to its original state.

In this embodiment, the elastic member 272 is made of an elastic spring.

In addition, the massaging machine 200 has a structure in which a plurality of protrusions 250 for pressing the skin inside the frame 210 protrude. The protrusions 250 are formed at intervals along the periphery of the suction port 212 formed inside the frame. In the present embodiment, the protrusion 250 is formed in the shape of a hemispherical rounded tip. The protrusion 250 may be formed integrally with the frame 210 or may be manufactured separately and attached to the frame 210. The protrusion 250 may be made of various materials such as the same material as the frame or a material capable of emitting magnets or far infrared rays, and is not particularly limited.

In the present embodiment, the massager 200 has a structure capable of applying a high frequency to the skin.

In this embodiment, the adhesion roll 220 has a structure that serves as an electrode rod for applying a high frequency to the skin. The adhesion roll is made of a conductive material such as stainless steel.

The high frequency unit (see 260 of FIG. 1) for applying a high frequency signal to the adhesion roll 220 may be provided separately from the present facility or may be provided in the present facility.

In addition, the wire electrically connected to the contact roll 220 extends through the frame 210 and the handle 230 to the fastener 240 installed at the tip of the handle 230. The fastener is provided with a connector 242 connected to the wire to make the electrical connection more easily. The connector may be connected to the high frequency unit 260 through a separate wire or may be electrically connected to the high frequency unit through the air hose 210. Of course, in the case of the structure using the air hose 210, the wire is connected to the air hose 210 is connected to the connector is installed and the front end should be a structure in which the connector and the wire is connected when combined with the fastener.

The handle 230 is provided with a wire 280 electrically connected to the connector 242 therein, the wire 280 extends to the frame 210 along the inside of the handle.

In this embodiment, the electrical connection between the wire 280 and the contact roll 220 is made through the elastic member 272. The elastic member 272 is made of a conductive material.

The support member 214 is provided with a terminal member 282 extending to the groove 270 formed in the support member to which the front end of the elastic member 272 is coupled. The wire 280 extends to the support 214 and is connected to the front end of the terminal member 282.

The terminal member 282 is installed separately for each contact roll 220. The two wires 280 extending to the frame are connected to each terminal member 282 and electrically connected to each of the contact rolls 220.

The high frequency applied through the power is applied to the terminal member 282 and the elastic member 272 connected to the terminal member, and to each contact roll 220 through the rotating shaft 222 which is in contact with the other end of the elastic member. It can be approved last.

Here, the brush member 284 is further installed at the front end of the elastic member 272 to smoothly maintain the contact state regardless of the rotation of the rotating shaft.

The brush member 284 is a conductive material coupled to the elastic member 272, the contact surface with the rotating shaft 222 is formed in an arc shape so as to correspond to the rotating shaft is in close contact with the rotating shaft.

9-11 show yet another embodiment of the present massager.

As shown, the massager according to the present embodiment is connected to the decompression cup 290 and the inlet 291 of the decompression cup 290, the lower end of which is opened in the form of a cup and the air inlet 291 is formed therein It is installed, and includes a handle 293 is formed in the air passage 294 communicating with the inlet. A conductive metal is plated on the open lower portion of the pressure reducing cup 290 in contact with the skin to form a conductive layer 292. The conductive layer 292 may be formed over the entire surface of the pressure reducing cup 290, and may be formed only at a lower side contacting the skin as shown.

Accordingly, the conductive layer 292 may be used as an electrode that transmits an electrical signal generated by equipment such as a low frequency device, an ion device, or a blood circulation circuit when using the decompression cup 290.

The wire connected to the conductive layer 292 serving as an electrode extends through the handle 293 to the decompression cup 290. The side of the pressure reducing cup is provided with a connector 295 for electrically connecting the wire with the conductive layer. Accordingly, by inserting a terminal or the like installed at the tip of the wire into the connector 295, the wire can be electrically connected to the conductive layer.

In addition, a groove 296 into which an electric wire is inserted is formed at a side of the handle 293. The groove 296 is provided with a band (not shown) formed of a material such as rubber to cover and protect the electric wire. The band is of a size corresponding to the groove and is not particularly limited in form.

In addition, the decompression cup 290 is provided with an installation tool 297 to be installed in the upper upper mechanism such as a laser mechanism for irradiating the laser to the skin or a lamp for color therapy. The installation tool is not limited to the illustrated structure and can be variously modified. The wire connected to the installation port extends through the handle to the decompression cup, and is connected to the installation port inside the decompression cup through a hole formed in the upper center of the decompression cup. The hole can be closed with a plug or the like after the wire is installed to maintain the airtightness inside the decompression cup.

In addition, the handle 293 is connected to the air inlet 314 formed in the cover 312 of the pressure reduction filter 300 via an air hose connected to the outer end. When air is sucked through the air inlet 314, the air is sucked into the suction port 291 of the pressure reducing cup 290, and a pressure reducing force is formed in the massager.

Hereinafter, the operation of the equipment will be described.

When the user controls the control unit 102 to drive the facility, the air pump 110 is operated and air is sucked into the air inlet 112 of the air pump 110 according to the operation of each valve.

The dispenser 120 connected to the air suction port 112 of the air pump 110 and the pressure reducer 300 connected to the distributor 120 and the massager connected to the pressure hose 300 via the air hose 210 as a medium. Air is sucked into 200.

Therefore, the air is sucked through the inlet 212 of the massaging machine 200. The sucked air passes through the pressure reduction filter 300 and the distributor 120 and is discharged to the air discharge port 114 of the air pump 110. Here, the direction switching valve 174 connected to the air discharge port 114 is driven so that the air discharge port 114 is connected to the silencer 170, and the air is discharged to the outside through the silencer 170. As such, the air sucked through the massager 200 is finally discharged through the silencer 170, thereby minimizing the noise generated when the air is sucked.

The user may perform skin massage by bringing the frame 210 of the massager 200 into close contact with the skin S in the air suction state as described above. When the massager 200 comes into close contact with the skin, a negative pressure is generated between the skin and the skin by the decompression force applied to the frame 210 and the skin is pushed into the frame 210.

At this time, the contact roll 220 installed in the frame 210 is freely rotatable with respect to the frame 210 and is movable along the groove 270. The adhesion roll 220 is to pull the skin in accordance with the negative pressure applied to the frame, as well as the contact roll 220 is rotated in accordance with the movement of the skin so that the skin is flexibly pushed into the frame 210.

As the skin is pushed up into the frame 210, the skin is stretched while being pulled tight. Accordingly, massage effects such as improved blood circulation as capillaries and pores of the skin are expanded can be obtained.

As mentioned above, the protrusions 250 protrude from the inside of the frame 210 so that the skin pushed up into the frame 210 is pressed against the protrusions 250. As such, the protrusion 250 pressurizes the skin to additionally obtain the acupressure effect.

In addition, the massaging machine 200 receives a current from the high frequency unit 260 under the control of the control unit 102 to apply a high frequency to the skin if necessary.

The current applied from the control unit 102 is converted through the high frequency unit 260 and applied to the adhesion roll 220 of the massaging machine 200. The pair of adhesion rolls 220 installed on the massager 200 serve as electrodes for applying high frequency to apply high frequency to the skin in close contact. Therefore, it is possible to additionally apply a massage by the high frequency to the skin.

On the other hand, the air sucked from the massaging machine 200 is introduced into the housing 310 of the pressure reduction filter 300 through the air hose 210. The air contains various foreign substances such as oil or keratin applied to the skin, and these foreign substances are removed while passing through the vacuum filter 300. Air introduced into the housing 310 of the pressure reduction filter 300 is sucked into the air pump 110 via the filter 320. The filter 320 passes a large amount of air at a constant flow rate to maintain a uniform pressure reducing force applied to the massager 200.

Here, if necessary, by controlling the control unit 102 to adjust the decompression force applied to the skin through the massager (200).

When the electronic solenoid valve 162 is operated according to the control signal of the controller 102, the air line 150 communicates with the atmosphere, and the air of the atmosphere flows into the air line 150. Therefore, the negative pressure applied to the air line 150 is lowered, so that the air inhaled by the pressure reduction filter 300 is reduced, so that the decompression force is reduced. The air inflow into the atmosphere is adjusted according to the number of driven solenoids, and the controller controls the depressurization force by controlling each electronic solenoid according to the set value.

In addition, the user may operate the manual open / close valve 164 that is manually controlled in addition to the electronic solenoid valve to finely adjust the decompression force. When the manual opening and closing valve 164 of the rotary knob structure is turned, the opening and closing degree of the pipe connected to the air line 150 is changed to adjust the air amount of the air flowing into the air line 150.

In this way, the air pressure is distributed to the air line 150 through the electronic solenoid valve and the manual opening / closing valve constituting the pressure control valve, thereby controlling the depressurizing force applied to the pressure reducing filter 300.

When the solenoid valve 130 of the distributor 120 is operated according to the signal of the controller 102 during the massage operation as described above, it is possible to quickly remove the depressurization force applied to the massager 200.

When the solenoid valve 130 installed in the manifold 122 of the distributor 120 is operated, a third pipeline (126) formed in the manifold 122 and connected to the pressure reducing filter 300 is connected to the atmosphere. 128). Accordingly, the air in the air flows into the decompression filter 300 through the air line 150 within a short time to make the negative pressure applied to the decompression filter 300 equal to the atmospheric pressure. Therefore, the negative pressure applied to the massager 200 connected through the pressure reduction filter 300 and the air hose 210 is removed. The skin is then returned to its original state in an expanded state.

Here, the silencer 140 is installed in the third conduit 128 connected to the atmosphere of the manifold 122 to block noise generated when air enters the atmosphere.

According to the operation of the solenoid valve 130, the first conduit 124 connected to the air pump 110 of the manifold 122 is connected to the second conduit 126 connected to the pressure reduction filter 300 or the third connected to the atmosphere. It is optionally connected to conduit 128. Thus, the skin swelling and the return of the original state through the massager 200 can be repeatedly implemented.

On the other hand, if necessary, by controlling the direction switching valve 174 it is possible to inject the air discharged through the air pump 110 to the air brush 172.

When the direction control valve 174 is controlled by the control unit 102, the air discharge port 114 of the air pump 110 is connected to the air brush 172. The air discharged from the air pump 110 is injected through the injection nozzle 176 of the air brush.

By using the air injected through the injection nozzle 176 of the air brush, it is possible to easily clean the filter 320 or the like of the massager 200 or the vacuum filter 300.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

100: drive unit 110: air pump
120: divider 122: manifold
130,162: Solenoid Valve 140,170: Silencer
150: air line 160: pressure control valve
164: manual open and close valve 172: air brush
174: direction change valve 178: pressure reducing filter
200: Massager 210: Frame
212: suction port 220: contact roll
230: handle 240: fastener
270: groove 272: elastic member
290: decompression cup 292: conductive layer
300: pressure reduction filter 310: housing
312 cover 314: air intake
316: air outlet 318: passage
320: filter 340: groove
342: outlet 350: rib
360: home 362: O-ring

Claims (15)

A driving unit including an air pump for sucking air and generating a decompression force, and a distributor connected to an air inlet of the air pump to change the direction of air;
At least one massager connected to the drive unit to apply pressure to the skin;
At least one pressure reducing filter installed between the distributor and each of the massaging machines to rectify suction air and filter out foreign substances contained in the air
Decompression massage equipment comprising a. The method of claim 1,
The distributor includes a manifold in which a pipe line connected to an air pump and a pipe line connected to the pressure reducing filter respectively pass through the length direction, and a solenoid valve installed in the manifold and connected to the respective pipe lines to change the air direction. Decompression massage equipment. The method according to claim 1 or 2,
The pressure reducing filter includes a housing forming an outer shape, a cover coupled to a front end of the housing, an air inlet installed in the cover, an air outlet formed at a bottom surface of the housing facing the air inlet, and installed between the air inlet and the air outlet. And a filter for filtering impurities, which is installed in the filter, the filter side is opened, the lower end of the filter communicates with the air outlet, and the upper end of the filter is blocked so that the filter fixing member is provided with a gap with the air inlet. The method of claim 3, wherein
The massaging machine is a pressure massage device comprising a frame formed with a suction port for opening the air in the lower end and a center, and a pair of adhesion rolls facing each other in contact with the skin on the lower open end of the frame. The method of claim 4, wherein
The driving unit is connected to the air discharge port of the air pump is provided with an air brush for ejecting air, and a pressure reducing massage equipment further comprises a direction switching valve for changing the direction of the air to the silencer or air brush. In the dispenser of the reduced pressure massage equipment that is connected between the air intake port of the air pump and the massager that applies pressure to the skin to change the direction of the air,
The distributor includes a manifold having a pipe line connected to the air pump and a pipe line connected to the massager, respectively, and a solenoid valve installed in the manifold and connected to each of the pipe lines to change the air direction. . The method according to claim 6,
The distributor is a distributor in the manifold, the passage communicating with the atmosphere is formed through the longitudinal direction, the solenoid valve is a three-way solenoid valve for selectively communicating the three pipelines. In the pressure reduction filter of the pressure reduction massage equipment comprising a pressure reduction filter for rectifying the air is installed between the air inlet of the air pump and the massager for applying pressure to the skin,
The pressure reducing filter includes a housing forming an outer shape, a cover coupled to a front end of the housing, an air inlet installed in the cover, an air outlet formed at a bottom surface of the housing facing the air inlet, and installed between the air inlet and the air outlet. And a filter through which the air passes, the filter side being opened to open the filter side and the lower end of the filter communicate with the air outlet, and the filter top is blocked by the filter fixing member provided with a gap with the air inlet. The method of claim 8,
The housing is a pressure reduction filter further comprises a stopper for opening and closing the discharge port and the discharge port for discharging the foreign matter on one side. The method according to claim 8 or 9,
The filter fixing member includes an upper fixing member fixed to the top of the filter and a lower fixing member fixed to the bottom of the filter,
The upper fixing member has a structure of covering the upper filter in the form of a disk, the upper surface is formed with a plurality of protrusions for protruding at intervals to maintain a gap with the inner surface of the cover,
The lower fixing member has a central portion is open, the lower end of the reduced pressure filter structure having a coupling portion coupled to maintain the airtight to the front end of the passage installed in the housing so as to communicate with the air outlet. In the massager of the reduced pressure massage equipment including a massager installed in the air inlet of the air pump to apply a pressure to the skin,
The massaging machine includes a frame having a lower end and a suction port through which air is sucked in the center, and a pair of adhesion rolls facing each other to contact the skin at both ends of the open lower part of the frame. The method of claim 11,
The massaging machine has a long groove is formed along the longitudinal direction in the support is provided on both sides of the frame, the rotating shaft of the front end of the contact roll is installed so as to be movable in the groove. The method of claim 12,
The massaging machine further includes an elastic member installed in the groove and elastically installed on the rotating shaft of the adhesion roll. The method according to any one of claims 11 to 13,
The massager includes a high frequency unit for generating a high frequency, the adhesion roll is made of a conductive material and electrically connected to the high frequency unit is a massager of the structure to apply a high frequency to the skin through the adhesion roll. In the massager of the reduced pressure massage equipment including a massager installed in the air inlet of the air pump to apply a pressure to the skin,
The massaging machine includes a decompression cup having a suction opening through which a lower end thereof is opened and air is sucked therein, and a handle having an air passage formed in the decompression cup and communicating with the suction opening therein, and the decompression cup is in contact with the skin. A massager having a structure in which a conductive layer plated with a conductive metal is formed.

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