KR101733938B1 - Multi air pump and injection equipment using the air pump - Google Patents

Abstract

The present invention relates to a multi air pump and an injection device using the same The multi air pump according to one embodiment of the present invention includes: a plurality of intake and exhaust units positioned in parallel to be spaced apart from each other so as to suck or discharge air; a compression unit compressing air while reciprocating between the plurality of intake and exhaust units; and a driving unit connected to the compression unit for horizontally moving the compression unit in such a manner that a rotating output end is connected to the compression unit to horizontally move the compression unit. Accordingly, the rotation of a motor is converted into a horizontal motion, and a plurality of air pumps is alternately compressed to enable high-speed pumping.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a multi-air pump,

The present invention relates to a multi air pump and a jetting apparatus using the same, and more particularly, to a technique for increasing a jetting force by compressing a plurality of air pumps in accordance with rotation of a motor.

Conventional injection devices are widely used for fire extinguishing and spraying. The injection device can be used for various purposes such as cleaning with high pressure, spraying of pesticide, and fire suppression. The conventional injection apparatus has a limitation on the amount and speed of the jetted liquid discharged by pumping the jetted liquid using one jetting pump. In addition, the conventional injection device has pumped due to a difference in air pressure caused by a user manually moving the lever, and thereafter, a technique of spraying using a DC power source has been developed.

Korean Patent Laid-Open No. 10-2011-0089287 (published on Aug. 05, 2011) discloses a portable airless fluid dispensing apparatus including a pump, a driving unit, and an orifice, wherein the pump directly pressurizes the fluid, The drive unit provides power to the pump and the orifice is sprayed at a particle size of less than about 70 microns at Dv (50), which is connected to the pump and does not dilute the building coating.

However, there is a limitation in expecting a large output in terms of the capacity of the DC motor used in the injector and the portability. Therefore, there is a need for a technology that complements the high-speed pumping function and portability.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide an air conditioner capable of pumping a plurality of air pumps alternately while switching the rotation of the motor to horizontal motion, And to provide a multi-air pump capable of controlling the operation of the motor and an injection device using the same.

A multi-air pump according to an embodiment of the present invention includes a plurality of intake and exhaust units that are disposed in parallel and spaced apart from each other to suck or discharge air, a compression unit that compresses air while reciprocating between the plurality of intake and exhaust units, And a driving unit connected to the compression unit to horizontally move the compression unit.

The compression section includes a connecting section connecting the plurality of intake and exhaust sections, a first compression rod formed on one side of the first intake and exhaust unit, and a second compression rod formed on the other side thereof inserted into the second intake and exhaust unit And a pressure plate on which a guide groove is formed at one side of the body to move along the connection portion and a receiving groove is formed at the center of the body to insert the output end of the driving unit.

The inlet and outlet of the intake and exhaust unit may include an intake unit to which external air is sucked, a flow pipe to which one end is connected to the intake unit to move air, and the other end to which the first compression rod or the second compression rod is inserted, And an exhaust unit formed at a lower side of the flow pipe and discharging air downward according to movement of the first compression rod or the second compression rod.

The driving unit includes a motor having the output end thereof rotated, a bracket fixedly coupled to upper and lower portions of the motor, and a circular disk shaped to be connected to the output end and rotating, And may include a driving wheel.

According to another aspect of the present invention, there is provided an injection device using a multi-air pump, comprising: a case having a nozzle formed on one side thereof and closing an opened upper portion of the container; A plurality of intake and exhaust devices for sucking or discharging the plurality of intake and exhaust devices, a compression section for compressing the air while reciprocating between the plurality of intake and exhaust devices, and a drive section for rotating the output section in connection with the compression section to horizontally move the compression section An air pump, and a control unit for controlling the driving unit according to the air pressure in the container.

As a result, the rotation of the motor is converted into a horizontal motion, and a plurality of air pumps are alternately compressed to enable high-speed pumping. Further, the operation of the motor can be controlled by using the air pressure inside the container. Also, the operation of the motor can be controlled by sensing the tilt.

1 is a configuration diagram of a multi air pump according to an embodiment of the present invention;
Fig. 2 is a sectional view of the multi-air pump according to Fig. 1,
Fig. 3 is an exploded perspective view of the multi-air pump according to Fig. 1,
FIG. 4 is an exemplary view for explaining the movement of the pressure plate of the multi-air pump according to FIG. 1;
5 is a configuration diagram of an injection device using a multi air pump according to another embodiment of the present invention,
Fig. 6 is an exploded perspective view of the injection apparatus using the multi-air pump according to Fig. 5;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms used are terms selected in consideration of the functions in the embodiments, and the meaning of the terms may vary depending on the user, the intention or the precedent of the operator, and the like. Therefore, the meaning of the terms used in the following embodiments is defined according to the definition when specifically defined in this specification, and unless otherwise defined, it should be interpreted in a sense generally recognized by those skilled in the art.

FIG. 1 is a configuration diagram of a multi air pump according to an embodiment of the present invention, FIG. 2 is a sectional view of the multi air pump according to FIG. 1, FIG. 3 is an exploded perspective view of the multi air pump according to FIG. 4 is an exemplary view for explaining the movement of the pressure plate of the multi-air pump according to FIG.

1 to 4, a multi air pump 100 according to an embodiment of the present invention includes a plurality of intake and exhaust units 110, a compression unit 120, and a driving unit 130.

The plurality of intake and exhaust units 110 are spaced apart from each other and arranged in parallel to each other to suck or discharge air. The plurality of intake and exhaust units 110 are alternately compressed by the compressing unit 120 to suck outside air and discharge the inside air into the closed space. As the external air is injected into the hermetically sealed interior by the compression unit 120, the internal air pressure is increased.

Specifically, the plurality of intake and exhaust units 110 include a first intake and exhaust unit 111 and a second intake and exhaust unit 112, and a compression unit 120, which will be described later, alternately includes a first intake and exhaust unit 111, So that the portion 112 is compressed. The first intake and exhaust unit 111 includes a first intake unit 111-1, a first flow pipe 111-2, and a first exhaust unit 111-3. The first intake unit 111-1 sucks outside air. In this case, the outside air is sucked through the first intake unit 111-1 due to the difference of the air pressure by the compression unit 120. [ The first flow pipe 111-2 is a passage through which the outside air sucked due to the air pressure difference moves while the first compression rod 122-1 of the compression unit 120 moves. The first exhaust pipe 111-3 is connected to the first flow pipe 111-2 to exhaust the sucked outside air. It is preferable that the space exhausted through the first exhaust part 111-3 is hermetically closed.

The second intake and exhaust unit 112 includes a second intake unit 112-1, a second flow pipe 112-2, and a second exhaust unit 112-3. The second intake unit 112-1 sucks outside air. In this case, the outside air is sucked through the second intake unit 112-1 due to the difference of the air pressure by the compression unit 120. [ The second flow pipe 112-2 is a passage through which the outside air sucked due to the difference in air pressure moves while the second compression rod 122-2 of the compression unit 120 moves. The second exhaust portion 112-3 is connected to the second flow pipe 112-2 to exhaust the sucked outside air. The space discharged through the second exhaust portion 112-3 is preferably sealed.

The compression unit 120 serves to compress air while reciprocating between the plurality of intake and exhaust units 110. The compression unit 120 can sequentially compress the plurality of intake and exhaust units 110 while moving left and right in the horizontal direction. For example, when the compression section 120 compresses the first intake and exhaust section 111, external air is sucked in the second intake and exhaust section 112, and the compression section 120 compresses the second intake and exhaust section 112 External air is sucked in from the first intake and exhaust unit 111.

More specifically, the compression section 120 includes a connection section 121 and a pressure plate 122. The connection portion 121 is a rod connecting between the plurality of intake and exhaust portions 110. For example, at least one connection portion 121 is horizontally connected between the first intake and exhaust unit 111 and the second intake and exhaust unit 112. In this case, the connection portion 121 may have a circular or elliptical cross-section, and serves to guide the pressure plate 122 to move left and right in the horizontal direction along the connection portion 121. Accordingly, the rotation of the motor 131 of the driving unit 130 can be converted into the horizontal motion, and the pressing plate 122 can be supported so as not to deviate from the path.

The pressure plate 122 of the compression unit 120 has a first compression rod 122-1 formed on one side of the body and a second compression rod 122-2 protruded on the other side. The first compression rod 122-1 is inserted and moved in the first flow pipe 111-2 of the first intake and exhaust unit 111 and the second compression rod 122-2 is inserted into the second intake and exhaust unit 112, And is then moved into the second flow pipe 112-2. In this case, the end surface of the first compression rod 122-1 is formed in a shape corresponding to the end surface of the first flow pipe 111-2, and the end surface of the second compression rod 122-2 is formed in the second flow pipe And is formed in a shape corresponding to the cross-section of the base 112-2. A guide groove 122-3 is formed at one side of the body of the pressure plate 122 to move along the connection portion 121. [ In this case, the guide grooves 122-3 may be formed corresponding to the number of the connection portions 121. [ A receiving groove 122-4 is formed at the center of the body of the pressure plate 122 so that the output 131-1 of the driving unit 130 is inserted.

The driving unit 130 is connected to the compression unit 120 to rotate the output unit 131-1 so that the compression unit 120 moves horizontally. More specifically, the driving unit 130 includes a motor 131, a bracket 132, and a driving wheel 133. The motor 131 may be driven by an AC or DC power source. A driving wheel 133 is inserted into the output 131-1 of the motor 131 and formed at a position orthogonal to the receiving groove 122-4 of the pressing plate 122. [ In other words, the pressure plate 122 and the motor 131 may be connected in a '?' Shape, but are not limited thereto. The motor 131 may be connected at various angles to the pressure plate 122 using a gear combination.

The bracket 132 is formed in a shape in which the upper part and the lower part are assembled and serves to fix the motor 131. The bracket 132 is formed with a heat radiating groove (not shown) to discharge the heat generated by the motor 131 to the outside. In order to prevent the motor 131 from being overheated, a predetermined pattern of heat dissipating grooves is formed in the bracket 132, which is in contact with the outer surface of the motor 131, have.

The driving wheel 133 is a rotating body inserted into the output 131-1 of the motor 131. [ The driving wheel 133 may have a circular disk shape and a pressing protrusion 133-1 protruded on one side thereof. The pressing projection 133-1 also rotates as the driving wheel 133 rotates by the motor 131. [ In this case, the pressing projection 133-1 is inserted into the receiving groove 122-4 of the pressing plate 122 and rotated. As the pressing projection 133-1 rotates while being inserted into the receiving groove 122-4, the pressing plate 133 moves the pressing plate 122 horizontally in the horizontal direction.

Referring to FIG. 4, (a) and (b) show that the pressure plate 122 is moved by the pressure projection 133-1. R1 represents the radius of the width of the receiving groove 122-4, R2 represents the turning radius of the pressing projection 133-1, and R3 represents the horizontal moving distance of the pressing plate 122. [ In this case, a relationship such as "R3 = R2 - R1" is formed. In other words, when the pressing projection 133-1 rotates clockwise at 9 o'clock at (b) at 6 o'clock when rotated, the first compression rod 122-1 moves to the left by R3 do. An inscribed circle 122-41 and a circumscribed circle 122-42 are formed in the receiving groove 122-4 and the radius of the inscribed circle 122-41 is R1 and the radius of the circumscribed circle 122-42 is R2 . The upper and lower portions of the receiving groove 122-4 are brought into contact with the circumscribed circles 122-42. If the horizontally moving distance of the pressure plate 122 is to be long, the width of the receiving groove 122-4 is narrowed and set, and when the horizontal moving distance is shortened, the receiving groove 122-4 is widened and set .

FIG. 5 is a configuration diagram of a multi-air injection device using a multi-air pump according to another embodiment of the present invention, and FIG. 6 is an exploded perspective view of a multi-air injection device using the multi-air pump.

5 and 6, the multi-air injection device 1000 includes a case 1100, a multi air pump 1200, and a control unit 1300.

The case 1100 is made of synthetic resin or metal, and closes the opened top of the container 2000. In this case, the container 2000 is made of a synthetic resin material or a metal material, and is formed in such a form that the inside is empty and the top is opened. The jetting material contained in the vessel 2000 may be a gaseous or liquid material. A nozzle 1110 is formed on one side of the case 1100 to discharge the jetting material in the container 2000. On the other side of the case 1100, a handle 1120 can be integrally formed or can be coupled by a connecting member.

A transfer pipe 1130 is formed on the lower side of the case 1100 to allow the injection material in the container 2000 to move to the lever 1140. A lever 1140 is formed in the case 1100 to open and close the transfer pipe 1130. For example, when the lever 1140 is in the correct position, the transfer tube 1130 is closed, and when the lever 1140 is retracted backward, the transfer tube 1130 is opened. The function of the lever 1140 may be changed to any structure capable of opening and closing the transfer pipe 1130.

The multi air pump 1200 includes a plurality of intake and exhaust units 1210 that are formed inside the case 1100 and are spaced apart from each other to be in parallel to each other to suck or discharge air and a plurality of intake and exhaust units 1210 And a driving unit 1230 connected to the compressing unit 1220 to horizontally move the compressing unit 1220. The compressing unit 1220 compresses air. In this case, the plurality of intake and exhaust unit 1210, the compression unit 1220, and the drive unit 1230 are connected to the plurality of intake and exhaust units 110, compression unit 120, And the driving unit 130, detailed description thereof will be omitted.

The control unit 1300 controls the driving unit according to the air pressure in the container 2000. The controller 1300 is set to turn on or off the power using the switch 1310. [ The control unit 1300 senses the air pressure in the container 2000 using the air pressure sensor 1320. For example, when the air pressure in the container 2000 is equal to or higher than a preset air pressure, the operation of the motor can be stopped if the consumed current of the motor of the driving unit is greater than a predetermined amount. This is for discharging all of the injected material in the container 2000 so that there is no injection material to be discharged, or when the user does not operate the lever 1140, the operation of the motor is automatically stopped to save power.

Further, the controller 1300 senses the inclination of the case 1100 and controls driving of the driving unit. The controller 1300 senses the inclination of the case 1100 using the inclination sensor 1330. [ For example, when the inclination of the case 1100 exceeds a predetermined inclination, the operation of the motor can be stopped. This is because it is determined that the use of the injection apparatus 1000 is abnormal, and in order to prevent a safety accident when the injection material is a material requiring handling attention in use. This setting may be released by the user.

Meanwhile, the jetting apparatus 1000 using the multi air pump according to the present invention may further include a power supply unit 1400. The power supply unit 1400 may be formed in a region of the handle 1120 of the case 1100. The power supply unit 1400 can be implemented using a battery. The power supply unit 1400 supplies power to the driving unit 130 and the control unit 1300. The power supply unit 1400 supplies power to the smart injection apparatus 1000 where power is required. And may output a warning sound through a speaker (not shown) when the remaining power level is less than the preset reference level.

Meanwhile, the jetting apparatus 1000 using the multi-air pump according to the present invention may further include an illumination unit (not shown). The illumination unit may be implemented by an LED, and may be formed so as to irradiate illumination toward the nozzle 1110. The illumination unit can be turned on and off via the switch 1310. [ It is also possible to use an illuminance sensor (not shown) to automatically output illumination when the surroundings become dark. Accordingly, the user can use the smart injection apparatus 1000 even in the dark night.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, Therefore, the present invention should be construed as a description of the claims which are intended to cover obvious variations that can be derived from the described embodiments.

100: air pump
110:
111: first intake /
111-1: first intake portion
111-2: First flow pipe
111-3: First exhaust part
112: second intake /
112-1: second intake portion
112-2: a second flow pipe
112-3: Second exhaust part
120:
121:
122: pressure plate
122-1: first compression rod
122-2: a second compression rod
122-3: Guide groove
122-4: receiving groove
122-41: inscribed circle
122-42: circumcircle
130:
131: Motor
131-1: Output stage
132: Bracket
133: drive wheel
133-1:
1000: Injection device
1100: Case
1110: Nozzles
1120: Handle
1130: Transfer pipe
1140: Lever
1200: Multi air pump
1210:
1220:
1230:
1300:
1310: Switch
1320: Air pressure sensor
1330: tilt sensor
1400:

Claims (3)

A plurality of intake and exhaust units positioned in parallel and spaced apart from each other to suck or discharge air;
A first compression rod formed on one side is inserted and moved in the first intake and exhaust unit and a second compression is formed on the other side of the first and second intake and exhaust units, A compression unit including a pressing plate having a rod inserted and moving in the second intake and exhaust unit and having a guide groove formed at one side of the body to move along the connection unit and a receiving groove formed at the center of the body; And
A drive wheel is formed in a circular disk shape on an output end for rotational movement, and a protrusion protruding from one side of the drive wheel is formed and connected to the receiving groove, and a radius of a circumscribed circle of the receiving groove, And a driving unit for horizontally moving the compression unit such that a difference in radius is a moving distance of the first compression rod or the second compression rod in the horizontal direction. delete A case in which a nozzle is formed on one side and an upper portion of the container is closed;
A plurality of intake and exhaust units formed in the case and spaced apart from each other to be in parallel to each other to suck or discharge air; and a plurality of intake and exhaust units that compress air while reciprocating between the plurality of intake and exhaust units, A second compression rod formed on the other side is inserted and moved, and a guide groove is formed on one side of the body, so that the first compression rod is inserted into the first intake / And a pressure plate on which a receiving groove is formed at a center of the body, a driving wheel having a circular disk shape formed at an output end for rotating, a pressing projection projecting from one side of the driving wheel And the difference between the radius of the circumscribed circle of the receiving groove and the radius of the inscribed circle of the receiving groove is larger than the difference between the radius of the circumscribed circle of the receiving groove and the radius of the inscribed circle of the receiving groove, And a driving unit for horizontally moving the compression unit so that the second compression rod is moved in the horizontal direction. And
And a control unit for controlling the driving unit in accordance with the in-container air pressure.

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