KR20200028212A - Air sensor - Google Patents

Abstract

The present invention relates to an air sensor, which is provided by being coupled to an air inlet of an air filling product in which air is filled while maintaining a shape. The air sensor comprises: a connector coupled to an air inlet and provided with air in the product for air filling to communicate therewith; a silicon sensor provided in the connector and operated by air pressure of the product for air filling; an impact detection sensor detecting an impact due to the operation of the silicon sensor; and a substrate indicating the number of times in accordance with a detection signal of the impact detection sensor.

Description

Air sensor

The present invention relates to an air sensor, and more particularly, to an air sensor installed in an air inlet of a product filled with air to detect a change in pressure of the air filled in the product.

In recent years, people's interest in weight control for health or beauty has increased, but as the computer becomes more popular and various games are developed, outdoor activities are reduced, which often leads to overweight or lack of exercise. So, people do simple exercises such as jumping rope or jogging indoors at home or in the office.

In general, rope skipping is a structure made of a long string made by extruding a long length of a flexible synthetic resin material, and a pair of handles installed at both ends of the string. After holding the handles with both hands, the string is rotated around the body and then rotated. It is an exercise that counts the movement beyond the line that is rotated by jumping by counting it as a single operation by jumping over the line and jumping over the line before it reaches the floor.

Since this rope skipping exercise is an exercise that uses the entire body, including the arm that rotates the rope and the legs used for jumping, it is a popular exercise that can be easily enjoyed by both men and women, as it is possible to get a sufficient exercise effect even after 10 minutes of running.

In addition, the characteristic of the rope skipping movement is that it is a vertical movement that runs to the front of the sole of the foot. It is effective in strengthening each body's function because it gives a strong stimulus to the ankle, extremity, knee, and waist every time it jumps to jump rope.

These stimuli are known to promote the growth of adolescents because they also affect the osteoclasts of bone, but they are also effective in preventing osteoporosis in adults.

In addition, the rope skipping exercise is a rhythmic small jump continuous exercise, which strengthens the heart and lungs and improves the coordination of timing of hands and feet. This coordination improves wits, flexibility, agility, balance, and endurance, and stress can be relieved.

Jump rope exercise can be enjoyed with a variety of exercises only by jumping rope. Depending on how you jump, you can enjoy jumping rope by using various ways of skipping, such as two-legged jumping, two-legged skipping, one-legged jumping, and continuous running.

The rope skipping exercise has the advantage that you can enjoy it at any time with a simple exercise device called skipping rope, but due to the nature of the rope skipping, people who jump over the rope must make a continuous leap. There is a problem of inter-floor noise, so there are many restrictions to enjoy the rope skipping exercise indoors.

In consideration of these points, air mats or air boards that allow people to enjoy rope skipping or jumping movements indoors as well as Korean Patent No. 10-1280223 (hereinafter referred to as "Prior Art Document 1") and Korean Patent Publications It has been developed and proposed as in 10-2011-0015067 (hereinafter referred to as 'Prior Art Document 2').

In the prior art documents 1 and 2, the volume is expanded to a predetermined size by the air injected through the air inlet, and a plurality of fiber yarns formed therein are made of a double space paper to space the inner space to a certain height, and a reinforcement part is provided at the bottom. It is fixedly coupled, a second coupling portion is formed on the reinforcing portion, and the first coupling portion of the air scaffold is coupled to the second coupling portion to hold the handle while the air board is positioned on the water surface for the user's jump movement. A multi-function air board is disclosed in which a third coupling portion of a handle is engaged when it is intended to be used for any one of a kick board or a mat.

These air boards are installed on the indoor living room or floor, as well as on the outdoor flat surface, and even if the user climbs on the air board and skips ropes, walks in place, jumps and lands, and jumps repeatedly, interlayer noise is generated. By suppressing it, it is possible to enable continuous exercise indoors.

However, during exercise such as jumping rope or jumping using the conventional air board disclosed in the prior art documents 1 and 2, repetitive leaping and landing, walking in place, etc., the number of times the exercised user directly exercised or directly assisted There is the inconvenience of counting the number of workouts.

Domestic registered patent No. 10-1280223 Domestic published patent No. 10-2011-0015067

Therefore, the present invention was devised to solve the problems of the prior art as described above, and is provided in the air inlet of the product for filling air stored with air filled therein to change the pressure of air by pumping the product for filling air. An object of the present invention is to provide an air sensor that indicates and displays the number of pumping by sensing.

The air sensor according to the present invention for achieving the above object is an air sensor provided to be coupled to the air inlet of an air filling product that maintains its shape by filling the air therein, and is coupled to the air inlet for air filling A connector in which air in the product is provided to communicate therewith; A silicon sensor provided in the connector and operated by air pressure of a product for air filling; Impact detection sensor for detecting the impact by the operation of the silicon sensor; It may include a; connected to the shock detection sensor to indicate the number of times according to the detection signal of the shock detection sensor.

In addition, the connector may include a plate provided therein to partition the inner space of the connector, and an inlet and an outlet through which the air pressure of the product for air filling is introduced and discharged through the plate.

In addition, the inlet port may be formed such that its diameter becomes narrower toward the silicon sensor side on the plate, and the outlet port may be formed such that its diameter becomes narrower toward the product side for air filling on the diaphragm.

In addition, the silicon sensor is provided with a sensor film facing the diaphragm of the connector therein, the sensor film may be provided to be stretched and contracted toward the impact sensor by air pressure through the inlet of the diaphragm to be sensed by the impact sensor.

And, between the silicon sensor and the shock sensor is provided with a separator for isolating the silicon sensor and the shock sensor, the separator is provided with a grid hole so that the extension force of the sensor film of the silicon sensor is transmitted to the shock sensor can be detected. You can.

Accordingly, a user who jumps rope or jumps in the product for air filling can easily recognize the number of jumps and accurately recognize the amount of exercise or learning.

According to the air sensor of the present invention, by being detachably installed and installed in the air inlet of the product for filling air stored with air filled therein, the pump is operated and pumped every time when pumping by an external force applied to the product for air filling Since the number of times is accurately displayed, the user can easily recognize the correct amount of exercise or learning.

1 is a configuration diagram of an air sensor according to the present invention.
2 is an exploded view of the air sensor according to the present invention.
3 is an exploded cross-sectional view of the air sensor according to the present invention.
4 is a combined cross-sectional view of the air sensor according to the present invention.
5 is a cross-sectional view showing the operating state of the air sensor according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Terms used in the present invention are terms defined in consideration of functions in the present invention, which may vary depending on the intention or custom of the user or operator, and thus, definitions of these terms are consistent with technical matters of the present invention. And should be interpreted as a concept.

In addition, the embodiments of the present invention are not intended to limit the scope of the present invention, but are merely exemplary of the components presented in the claims of the present invention, and are included in the technical idea throughout the specification of the present invention and of the claims. It is an embodiment including a component that can be substituted as an equivalent in the component.

In addition, the optional terms in the embodiments below are used to distinguish one component from other components, and the component is not limited by the terms.

Accordingly, in describing the present invention, detailed descriptions of related well-known technologies that may unnecessarily obscure the subject matter of the present invention are omitted, and the same reference numerals are assigned to the same parts as in the prior art, and overlapping descriptions are omitted.

1 to 5 are views showing the air sensor and its components according to the present invention.

The air sensor 100 according to the present invention is installed in the air inlet of the product for air filling 200, as shown in the drawing, and detects a pressure change of air according to the pumping of the product 200 for air filling, thereby filling the air It is a device that counts the number of times the product 200 has been pumped and represents it with numbers.

1 to 3, the air sensor 100 includes an upper case 110 and a lower case 120, a connector 130 provided in the lower case 120, and a silicon sensor 140 ), A guide bushing 150, an impact detection sensor 160, and the like.

2 and 3, the upper case 110 is a hemispherical member and a PCB (printed circuit board, hereinafter referred to as "substrate") is intersected and fixed in the radial direction.

On the outer periphery of the substrate 111, a power switch 112 for turning on / off the power of the air sensor 100 and a lighting lamp indicating whether the air sensor 100 is operating when the power switch 112 is turned on. 113 is provided. That is, the lighting lamp 113 is preferably provided to be turned on when the air sensor 100 is operating, and turned off when not operating.

In addition, the upper surface of the substrate 111 is provided with a display unit 114 for electrically indicating the number of pumping of the product 200 for air filling in numbers, and a transparent cover 115 is provided on the upper surface of the display unit 114 Is provided to protect the display unit 114. The cover 115 is fastened and fixed as a screw to the inner surface of the upper case 110, and the outer surface of the cover 115 is provided to form the same surface as the outer surface of the upper case 110.

In addition, the substrate 111 is electrically connected to the impact detection sensor 160 to be described later by a wire to convert the detection signal of the impact detection sensor 160 into an electrical signal to detect the detection signal detected by the impact detection sensor 160. The number of times is displayed as a number through the display unit 114, and may be linked by wireless communication with a server such as a smartphone, tablet PC, or desktop.

The lower case 120 is a hemispherical member that is fastened to the lower surface of the upper case 110, and therein, a sensing part of the air sensor 100 to be described later, that is, a connector 130, a silicon sensor 140, and a guide bushing (150), the shock detection sensor 160 is equipped with a mounting portion 121 is provided.

The mounting portion 121 is formed in a cross-sectional shape of a “∩” shape with an open bottom surface, and is fastened and fixed as a screw on the inner surface of the lower case 120.

Meanwhile, as illustrated in FIGS. 4 and 5, the upper portion of the connector 130 is inserted into and fixed to the mounting portion 121 of the lower case 120, between the connector 130 and the mounting portion 121. The ring-shaped packing 122 for sealing is interposed.

The connector 130 is formed of a cylindrical tube with its upper and lower surfaces open, and the upper end of the connector 130 is provided on the inner surface of the mounting part 121 by being sealed through the packing 122, and the connector 130 The lower portion of the air filling product 200 is provided to be fastened and fixed as it is rotated in one direction while being inserted into the air inlet. As described above, when the connector 130 is connected to the air inlet of the product 200 for air filling, the product 200 for air filling and the connector 130 communicate with each other so that the air charged in the product 200 for air filling is a connector. (130) It is introduced into the interior and filled.

And, the inside of the connector 130 is formed with a diaphragm 131 that blocks the conduit of the connector 130, and based on the diaphragm 131, an air filling product 200 is provided in the lower connector 130. ) Is connected to the air inlet, and the connector 130 on the top of the diaphragm 131 is provided with a silicon sensor 140, a guide bushing 150, and an impact detection sensor 160 in turn.

In particular, a circular coupling protrusion 135 for accommodating the inlet 132 and the outlet 133, which will be described later, is formed protruding upward in the upper surface of the diaphragm 131, and a silicon sensor is formed in the coupling protrusion 135. 140 is provided in combination.

The silicon sensor 140 is a cylindrical tube that is opened on the upper and lower surfaces, and on the lower surface thereof, engaging grooves 142 corresponding to the engaging protrusions 135 of the diaphragm 131 are formed and fitted into and fixed to the engaging protrusions 135. , In the interior of the silicon sensor 140, a sensor film 141 is provided to block the pipeline of the silicon sensor 140.

The sensor film 141 is formed of a silicone material having elasticity in a thin film, and is stretched upward by the air pressure of the product 200 for air filling flowing into the connector 130, and then is restored by its own restoring force (elastic force). Returning to the original position to maintain a flat state within the silicon sensor 140.

As a result, the air pressure of the product 200 for air filling acting in the connector 130 is blocked by the sensor film 141 of the silicon sensor 140 so that the sensor film 141 is prevented from flowing into the upper part of the sensor film 141. As a reference, the upper and lower portions of the silicon sensor 140 are provided in a state where air flow is completely blocked.

The upper portion of the silicon sensor 140 is provided with a cylindrical guide bushing 150, the lower surface of the guide bushing 150 is seated on the upper surface of the silicon sensor 140 is provided.

The guide bushing 150 is provided with a separator 151 for partitioning the inner space of the guide bushing 150 vertically therein, and a plurality of grid holes 152 are formed in the separator 151.

Here, the reason for forming the separator 151 in the guide bushing 150 is, when there is no separator 151 in the guide bushing 150 by the air pressure acting on the sensor film 141 of the silicon sensor 140 When the sensor film 141 is extended to the upper portion and is sensed by the impact detection sensor 160 to be described later, a malfunction may occur in which the sensor film 141 does not stick to the impact detection sensor 160 and does not fall. In order to prevent the separating plate 151 is formed in the guide bushing 150 to prevent the adhesion of the sensor film 141 to the impact detection sensor 160 in advance.

In addition, the reason for forming the lattice hole 152 in the separator 151 is that the sensor film 141 is not bent to the separator 151 even if the sensor film 141 is curved upward and sticks to the separator 151 and does not fall. The air sensor 100 functions as the elongation and contraction force of one part of 141) can be transferred to the impact detection sensor 160 by changing the air pressure inside the sealed mounting portion 121 through the grid hole 152. I did it so I could do it.

Meanwhile, the upper surface of the separator 151 of the guide bushing 150 is fixed to the guide bushing 150 in a state where the shock sensor 160 is seated, and the shock sensor 160 is a silicon sensor ( A sensing signal is generated through elongation and contraction (vibration) with the sensor film 141 of 140). At this time, the magnitude of the stretching force of the sensor film 141 transmitted to the impact detection sensor 160 is due to the external impact force, and the magnitude of the stretching of the sensor membrane 141 is determined by the pumping force due to the external impact acting on it. Therefore, the impact detection sensor 160 may calculate and measure a user's jumping height by the stretching force transmitted from the sensor film 141.

In addition, the inlet 132 and outlet 133 through which the air pressure of the product 200 for air filling acting on the connector 130 can pass is formed through the plate 131 of the connector 130, respectively. , The inlet 132 is formed to gradually decrease in diameter from the bottom of the plate 131 to the top, and the outlet 133 is formed to gradually decrease in diameter from the top of the plate 131 to the bottom.

The air pressure of the product 200 for air filling, which has been introduced into the connector 130 by the inlet 132 and the outlet 133 formed as described above, is rapidly passed between the diaphragm 131 and the silicon sensor 140 through the inlet 132. The sensor membrane 141 may be introduced to extend the sensor membrane 141 toward the upper impact detection sensor 160, and the air pressure applied to the sensor membrane 141 has a flow that is quickly discharged through the outlet 133.

As a result, the flow of air pressure is rapidly made by the inlet 132 and the outlet 133 of the diaphragm 131, so that the sensor film 141 can also be quickly returned to its original shape and maintained.

In addition, when the connector 130 is connected to the air inlet of the product for air filling 200 at the center of the lower surface of the diaphragm 131, the air in the product is introduced into the connector 130 by pressing the air bleed valve of the air inlet. One pressing protrusion 134 is formed to protrude.

The operating relationship of the air sensor according to the present invention as described above will be described.

After inserting the connector 130 of the air sensor 100 into the air inlet of the product for air filling 200 to install the air sensor 100, rotate the air sensor 100 in one direction to rotate the connector 130 Fasten and fasten to the air inlet.

Then, the connector 130 of the air sensor 100 is fastened and fixed to the air inlet of the product 200 for air filling, so that the flow paths of the air inlet and the connector 130 are connected to each other to communicate with each other. Air is introduced into the connector 130 to be filled, and the air filled into the connector 130 is provided through the inlet 132 and outlet 133 of the plate 131 and the plate 131 and the silicon sensor 140. It is filled in a state where the space between the sensor layers 141 is filled.

In this state, the power switch 112 of the air sensor 100 is turned on to turn on the lighting lamp 113 and operate the display unit 114, and then, such as jumping in the product for air filling 200 to perform air filling, etc. When the product 200 is pumped, the air pressure of the product 200 for air filling is further introduced into the connector 130 by the load applied to the product 200 for air filling, and the air pressure introduced in this way is a plate ( Through the inlet 132 of the 131) is rapidly flowing into the space between the diaphragm 131 and the sensor film 141 of the silicon sensor 140 acts on the sensor film 141.

Then, the sensor film 141 is bent upward in the upward direction by the air pressure acting on it, and stretch force is applied to the impact detection sensor 160 through the grid hole 152 formed in the separator 151 of the guide bushing 150. Will be delivered. At this time, since the extension force, that is, the impact force of the sensor film 141 transmitted to the shock sensor 160 is determined by the air pressure acting on the sensor film 141 of the silicon sensor 140, the impact force transmitted to the shock sensor 160 By doing so, the user's jumping height can also be calculated and measured.

Due to the stretching force of the sensor film 141, a detection signal is generated from the impact detection sensor 160 and applied to the substrate 111, and the display unit 114 displays the number of detection signals received from the substrate 111. Through this, it is represented by a number for easy recognition by the user.

Accordingly, the user of the product for air filling 200 can accurately recognize the amount of exercise or learning because the number of jumps is accurately displayed through the air sensor 100.

On the other hand, the air pressure acting on the sensor film 141 as described above is quickly discharged through the outlet 133 of the diaphragm 131, so that the elongated sensor film 141 is quickly returned to its original state by its own restoring force, and the silicon sensor (140) is provided flat inside.

Although the present invention has been described in detail through specific embodiments, the present invention is specifically for describing the present invention, and the present invention is not limited to this, and by those skilled in the art within the technical spirit of the present invention. It is clear that the modification and improvement are possible.

All simple modifications or changes of the present invention belong to the scope of the present invention, and the specific protection scope of the present invention will be clarified by the appended claims.

100: air sensor 110: upper case
111: board 112: switch
113: lighting lamp 114: display unit
115: cover 120: lower case
121: mounting portion 122: packing
130: connector 131: plate
132: inlet 133: outlet
134: pressing projection 135: engaging projection
140: silicon sensor 141: sensor membrane
142: coupling groove 150: guide bushing
151: separator 152: grating
160: shock sensor 200: air filling products

Claims (5)

As the air sensor is provided by being coupled to the air inlet of the product for air filling to maintain its shape by filling the air therein,
A connector coupled to the air inlet and provided with air in the product for air filling to communicate therewith;
A silicon sensor provided in the connector and operated by air pressure of a product for air filling;
An impact detection sensor that detects an impact caused by the operation of the silicon sensor;
Air sensor comprising a; connected to the shock detection sensor substrate showing the number of times according to the detection signal of the shock detection sensor.
The method according to claim 1,
The connector is provided therein, and an air sensor including a diaphragm partitioning the internal space of the connector and an inlet and an outlet through which the air pressure of the product for air filling is introduced and discharged through the plate.
The method according to claim 2,
The inlet port is formed so that its diameter becomes narrower toward the silicon sensor side on the diaphragm, and the outlet port is formed such that its diameter becomes narrower toward the product side for air filling on the diaphragm.
The method according to claim 3,
The silicone sensor is provided with a sensor membrane facing the diaphragm of the connector therein, and the sensor membrane is stretched and contracted toward the impact detection sensor by air pressure through the inlet of the diaphragm, and is sensed by the impact detection sensor.
The method according to claim 4,
Between the silicon sensor and the shock sensor, a separator is provided to isolate the silicon sensor and the shock sensor, and the separator is provided with an air sensor provided with a grid so that the extension force of the sensor membrane of the silicon sensor is transmitted to the shock sensor and can be detected. .

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