KR100850485B1 - fixed fluid quantity feeding apparatus - Google Patents

Abstract

The present invention is provided with a pressure pin at regular intervals around the wheel to be rotated, wound around a part of the pressure pin and ejecting the supply tube for transporting fluids such as ink liquid by quantitatively pressing the pressure pin periodically during rotation of the wheel. It relates to a fluid metering device for supplying.

Plotter, Fluid, Ink Liquid, Metering, Supply

Description

   Fixed fluid quantity feeding apparatus

   1 is a perspective view of a fluid metering device according to the present invention.

   2 is an exploded perspective view of the fluid metering device according to the present invention.

   3a and 3b is a front view showing an operating state of the fluid metering device according to the present invention.

Figure 4 is an exploded perspective view showing a grip portion of the fluid metering device according to the present invention.

Figures 5a and 5b is a cross-sectional view showing the operating state of the grip portion of the fluid metering device according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: supply tube 100: plate

110: drive motor 120: rotary wheel

130: pressure pin 140: cover

142: hinge pin 144: locking member

145: fixed block 146: rotary block

147: locking pin 150: pressure gauge

160: grip portion 162: body

166: elastic member 168: knob

The present invention relates to a fluid metering supply device, and more particularly, a pressure supply pin is provided around the wheel to be rotated at regular intervals and wound around a portion of the pressure pin to transfer a fluid such as ink liquid to the wheel of the wheel. It relates to a fluid quantitative supply device to eject the quantity by cyclic pressure of the pressure pin during rotation.

In general, a printer is a device for outputting computer-generated data on an output paper, and there are various types of printing output methods, but a laser printer for printing data on paper using a laser beam and toner / drum, and a nozzle Inkjet printers for directly injecting ink onto paper sheets are widely used.

In recent years, due to the widespread use of large-scale due diligence, wide color, banners, etc., the demand for the plotter is increasing in order to output it, the plotter is increasing in size.

In addition, the plotter generally embodies the color of the printout with a color of 2 degrees or more in order to attract people's eyes when printing.

Therefore, the plotter has a plurality of ink cartridges storing ink for each color so as to supply ink to the head on one side of the main body in a row in the cartridge case, and these ink cartridges can be attached and detached individually.

Each ink cartridge has a storage pack filled with ink therein, a case of a rectangular box to protect the storage pack, and is formed on one side of the storage pack and touches a separate detection switch when ink is consumed. It consists of a working plate to notify the replacement time.

In particular, the ink liquid is supplied from the ink container to the ink cartridge of the head through the supply tube.

Then, the ink liquid is pumped by the driving pump.

However, the conventional plotter has a problem that it is difficult to continuously supply a fixed amount to the ink cartridge of the head when the ink liquid is pumped by the operation of the driving pump.

The present invention is proposed to solve the above problems of the prior art, the supply tube for guiding fluid, such as ink liquid is wound around the rotating wheel to form a pressing pin spaced at regular intervals around the rotating wheel to rotate The present invention provides a fluid metering supply device for ejecting a metered amount of fluid by pressurizing the supply tube periodically by a rotating wheel.

The present invention for achieving the above object is a rotatable wheel that is rotatably installed on the plate is rotated during the drive of the drive motor and the fluid is stored around the supply tube for guiding the flow by storing the fluid, and on the circumferential surface of the rotary wheel The pressure pin is formed at regular intervals and repeatedly presses the lower part of the supply tube by the rotation of the rotary wheel, and the pressure pin is discharged on the plate to support the upper part of the supply tube wound on a part of the rotary wheel. The pressure pin is formed to catch the supply tube is formed on the plate and exposed on both sides of the cover and the cover to improve the pressing force when pressing the supply tube by the pressure pin to discharge the fluid by the same amount; It comprises a grip formed to prevent the movement of the supply tube by the rotation of It is to propose a fluid metering device characterized by.

The present invention is to propose a fluid quantitative supply device, characterized in that to reduce the friction with the supply tube by inserting a pressure tube to the pressure pin.

The present invention is rotatably provided by a hinge pin at a position spaced by the diameter of the feed tube with respect to the tangent of the rotary wheel on the plate, and connected to the other end of the cover and the plate by a locking member. It is to propose a fluid quantitative supply device, characterized in that the bearing capacity of the feed tube is kept constant.

The present invention is a locking member fixed to the plate fixed to the plate at a position spaced by the diameter of the supply tube with respect to the tangent of the rotary wheel as a locking member, a rotary block rotatably inserted on top of the fixed block, the circumference of the rotary block A locking pin extending to be rotated together with the rotary block, a hook hole protruding around the locking pin, and recessed in a size equal to the diameter of the locking pin from the other end of the cover to the outside and the other end of the cover; It is to propose a fluid quantitative supply device, characterized in that the locking groove is formed in the locking groove to prevent the locking pin to escape from the upper direction.

The present invention is coupled to the plate as a grip portion and the body formed with receiving grooves on both sides for receiving the supply tube, an elastic member inserted therein in the longitudinal direction of the body, and each end of each end of the body The present invention is to propose a fluid metering supply device comprising a knob configured to support and fix each end to both ends of the elastic member so that the other end can be elastically rotated to open and close the receiving groove.

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

   1 is a perspective view of a fluid metering device according to the present invention, FIG. 2 is an exploded perspective view of a fluid metering device according to the present invention, and FIGS. 3A and 3B show an operating state of the fluid metering device according to the present invention. Front view.

And, Figure 4 is an exploded perspective view showing a grip portion of the fluid metering device according to the present invention, Figures 5a and 5b is a plan sectional view showing the operating state of the grip portion of the fluid metering device according to the present invention.

As shown in FIG. 1 and FIG. 2, the fluid metering device according to the present invention includes a plate 100, a driving motor 110, a rotary wheel 120, a joining pin, a cover 140, and a grip part 160. It is composed.

The plate 100 serves to install the drive motor 110, the rotary wheel 120, the cover 140, and the grip 160.

In addition, the drive motor 110 is fixedly installed on the plate 100, and the drive motor 110 connects the drive shaft 112.

In addition, the rotary wheel 120 is fixed to the other side of the plate 100.

At this time, the rotary wheel 120 is inserted into the drive shaft 112 the center.

Therefore, when the driving motor 110 is driven, the drive shaft 112 is rotated, the rotary wheel 120 is rotated in the same direction with the drive shaft 112.

In addition, the pressing pin 130 is formed at a predetermined interval around the rotation wheel (120).

At this time, the supply tube 10 is wound around a part of the circumference of the rotary wheel 120.

For convenience, the feed tube 10 is shown to be wound around the top of the rotary wheel 120.

In addition, the supply tube 10 guides the transfer of fluid such as ink liquid.

The pressing pin 130 is moved along the circular trajectory during the rotation of the rotary wheel 120, each pressing pin 130 is pressed down the supply tube (10).

The cover 140 covers the upper portion of the rotary wheel 120 and simultaneously supports the upper portion of the supply tube 10.

Therefore, since the cover 140 supports the upper portion of the supply tube 10, each of the pressing pins 130 ejects the same amount of fluid while pressing the lower portion of the supply tube 10 at regular intervals.

In particular, the pressing pin 130 is rotatably inserted into the pressure tube 132 around.

That is, the diameter of the pressure tube 132 is larger than the diameter of the pressure pin 130.

Thus, the pressure pin 130 to prevent the maximization of the friction force by the direct contact between the supply tube 10, the pressure pin to move along the circle trajectory by the rotary wheel 120 in contact with the supply tube 10. Since the pressure tube 132 is rotated by the 130 itself, the moving speed of the pressure pin 130 moving along the circular trajectory becomes uniform.

On the other hand, the cover 140 is formed in an arc shape to cover the upper portion of the rotary wheel (120).

Then, the cover 140 is inserted into the hinge pin 142 at one end, the hinge pin 142 is inserted and fixed to the other side of the plate 100.

Thus, the cover 140 is rotated starting from the hinge pin 142.

At this time, the gap between the hinge pin 142 and the tangent at the circumferential position of the rotary wheel 120 adjacent thereto is similar to or larger than the diameter of the supply tube 10 to maintain the interval between the supply tube 10 through the supply tube 10. To prevent interference to the fluid being conveyed;

In addition, the cover 140 locks the other end of the cover 140 to be unlocked by providing a locking member 144 between the other end and the plate 100.

The locking member 144 is a fixed block 145 fixed to the plate 100 at a position spaced by the diameter of the supply tube 10 with respect to the tangent of the rotary wheel 120 and the upper portion of the fixed block 145 Rotating block 146 is rotatably inserted into the locking block 146, extending around the rotation block 146 is rotated with the rotation block 146, and around the locking pin 147 Hanging protrusion 148 protruding from the other end of the cover 140 is formed to be recessed to the size of the locking pin 147 to the outside, and the other end of the cover 140 is hooked to the hook hole 148 locking pin ( It consists of a locking groove 149 to prevent the departure of the 147 in the upper direction.

The fixing block 145 is fixedly coupled to the plate 100 as a screw 145a.

The rotation block 146 extends the connecting pin 146a to couple the connecting pin 146a to the fixed block 145 so as to be rotatable.

In particular, the connection pin 146a is preferably coupled to the fixing block 145 by a screw method.

In addition, the locking pin 147 extends in a direction perpendicular to the circumference of the rotary block 146.

The locking pin 147 is rotated in the same direction together with the rotating block 146 and is inserted into or removed from the locking groove 149 of the cover 140.

Here, the locking pin 147 is limited because of the rotation angle of the rotary wheel 120, so that the connecting pin 146a and the fixed block 145 of the rotary block 146 is not coupled even when screwed.

On the other hand, the rotary block 146 is further provided with a coupling member 143 therein, the locking pin 147 is inserted into the rotary block 146 is firmly supported by being coupled to the coupling member 143.

In more detail, the rotary block 146 forms a tab 146b around the inner side, and the coupling member 143 forms a tab 143a around the outer side.

Thus, the coupling member 143 is engaged inside the rotary block 146.

In particular, the coupling member 143 forms a tap hole 143b around the periphery.

In addition, the rotary block 146 is formed to communicate with the insertion hole (146c).

Therefore, the coupling member 143 is fitted to the inside of the rotary block 146 and to match the tap hole (143b) and the insertion hole (146c).

Then, the locking pin 147 is firmly installed by inserting a lower end into the insertion hole 146c and engaging the tab hole 143b.

At this time, the coupling member 143 is preferably made of a metal material.

In addition, the hook tool 148 allows the locking pin 147 to contact the upper surface of the cover 140 corresponding to the circumference of the locking groove 149 when the locking pin 147 is inserted into the locking groove 149.

Here, the cover 140 preferably presses the supply tube 10 at a predetermined pressure, and the hook tool 148 serves to maintain the action force of the cover 140 pressing the supply tube 10.

In addition, the locking pin 147 forms a tab 147a on the outer circumferential surface, and the hook hole 148 forms the tab 148a on the inner circumferential surface.

Thus, the hook 148 is able to adjust the height in the axial direction on the locking pin 147.

Therefore, the cover 140 may vary the pressing force for pressing the supply tube 10 according to the position of the hook hole 148 on the locking pin 147.

Here, as the pressure of the cover 140 pressing the supply tube 10 increases, the distance between the cover 140 and the pressure pin 130 or the pressure tube 132 is narrowed, thereby providing a more accurate quantity of fluid. It can be transported.

In particular, when the pressing force for pressing the supply tube 10 to the cover 140 is too large, the supply tube 10 is damaged.

In addition, the cover 140 must be in contact with at least a pair of pressure pins 130 or pressure tubes 132 at the same time to be able to transfer the quantitative fluid through the supply tube (10).

In addition, since the fluid inside the supply tube 10 is forced to flow when moving on the circular locus of the pressure pin 130 or the pressure tube 132, bubbles are prevented from occurring.

On the other hand, the gap between the locking pin 147 and the tangent at the circumferential position of the rotary wheel 120 adjacent thereto is similar to or greater than the diameter of the supply tube 10 to maintain the interval through the supply tube 10 To prevent interference to the fluid being conveyed;

In addition, the supply tube 10 is provided with a pressure gauge 150 on the outlet side of the fluid.

Thus, while the cover 140 is pressing the upper portion of the supply tube 10, the user can check the fluid pressure of the supply tube 10 through the pressure gauge 150 while rotating the hook hole 148. .

In addition, the supply tube 10 may move in the rotation direction of the rotary wheel 120 due to friction with the pressure pin 130 and the pressure tube 132 moved along the circle trajectory in one direction.

As shown in Figure 3a and 3b, the rotary wheel 120 is rotated so that the pressure tube 132 is moved along the circular trajectory.

In particular, since at least one pair of pressure tubes 132 is located below the cover 140, the supply tube 10 located between the pressure tubes 132 and the cover 140 is pressed at two or more points, The fluid in the supply tube 10 remaining between the points pressed along is forced out.

Thus, the supply tube 10 is fixed to the portions exposed to both sides of the cover 140 by the grip unit 160.

As shown in FIGS. 4 to 5B, the grip part 160 includes a body 162, an elastic member 166, and a knob 168.

The body 162 is coupled by a screw 169 on the plate 100 corresponding to the opposite side of the cover 140 starting from the rotary wheel 120.

In addition, the elastic member 166 is located at the edge of the body 162 in contact with the plate 100.

At this time, the body 162 is formed by recessed recess 165 to accommodate the elastic member 166 to prevent the external exposure of the elastic member 166.

Here, the elastic member 166 is assumed to be a coil spring.

In addition, the knob 168 is located on both sides of the body 162 to connect each edge with both ends of the coil spring.

Each of the knobs 168 supports one end relatively close to a portion connected to the elastic member 166 to the side edge of the body 162.

Thus, each of the knobs 168 is rotatably provided at the other end while supporting one end on the side of the body 162.

In particular, the body 162 recesses the installation grooves 164 on both sides to prevent separation of the knob 168.

In addition, the body 162 is formed to accommodate the supply tube 10 by forming the receiving groove 163 on both sides, that is, the installation groove 164.

At this time, the open inlet of the receiving groove 163 is blocked by the knob 168, the supply tube 10 is fixed to the inside of the receiving groove 163 by a predetermined push by the knob 168.

5A and 5B show the operating state of the knob 168.

Although not shown, the fluid metering supply device according to the present invention may not only continuously supply the fluid by quantity but also prevent bubbles from being generated inside the fluid, and may be installed in various ways such as between the head of the plotter and the ink container. .

According to the fluid quantitative supply device according to the present invention as described above, by pressing the circumference of the supply tube continuously with a plurality of pressure pins or pressure pipes provided around the rotation wheel effect of discharging the fluid of the supply tube quantitatively There is.

In addition, the present invention has the effect of preventing the occurrence of bubbles by reducing the impact on the fluid flowing in the supply tube by moving while pressing the outside of the supply tube with a pressure pin or pressure tube.

Claims (10)

A rotation wheel rotatably installed on the plate and wound around a driving tube, the rotation wheel winding a supply tube for storing the fluid to guide the flow; Pressure pins formed on a circumferential surface of the rotary wheel at a predetermined interval to prevent the occurrence of bubbles in the fluid by repeatedly pressing the lower portion of the supply tube by the rotation of the rotary wheel; A cover formed on the plate so as to be in contact with an upper portion of the supply tube wound on a part of the rotating wheel, and to improve the pressing force when pressing the supply tube by the pressure pin to discharge the fluid by the same amount; And a grip part formed on the plate to hold the supply tube exposed to both sides of the cover, and to prevent movement of the supply tube due to friction when moving on the circular locus of the pressure pin. The cover is rotatably provided at one end by a hinge pin at a position spaced apart by the diameter of the feed tube with respect to the tangent of the rotary wheel on the plate, and connects the other end to the plate with a locking member to support the feed tube. While keeping it constant The locking member includes a fixed block fixed to the plate at a position spaced apart by the diameter of the feed tube with respect to the tangent of the rotary wheel; A rotary block rotatably inserted in an upper portion of the fixed block; A locking pin extending around the rotary block and rotating together with the rotary block; A hook mechanism protruding around the locking pin; The other end of the cover is formed to be recessed out of the size as much as the diameter of the locking pin, and the other end of the cover is formed as a locking groove for preventing the departure in the upper direction of the locking pin to hang the hook. Fluid metering supply device. The method of claim 1, The pressure pin is fixed to the fluid supply device, characterized in that for inserting the pressure pipe rotatably to reduce the friction with the supply tube. delete delete The method of claim 1, The rotating block further has a coupling member therein; The locking pin is inserted into the rotary block is fixed to the fluid supply device characterized in that it is firmly supported by the coupling member. The method of claim 1, The locking pin and the hook is fixed to each fluid supply device, characterized in that for forming a tab on the mating surface to vary the pressing force of the supply tube in order to change the transfer amount of the fluid. The method of claim 6, The supply tube is fluid supply device, characterized in that for connecting the pressure gauge to the portion corresponding to the discharge side of the fluid. The method of claim 1, The grip unit is coupled to the plate, the body formed with receiving grooves on both sides for receiving the supply tube; An elastic member inserted therein in the longitudinal direction of the body; It is characterized by consisting of a knob for supporting each end on both side edges of the body, and the other end is elastically rotatable by fastening each end to both ends of the elastic member to enable the other end to rotate elastically. Fluid metering device. The method of claim 8, The body is fixed to the fluid supply device, characterized in that to form the recessed grooves on each side to receive the knob to prevent the outer deviation. The method of claim 8, The body is fixed fluid supply device, characterized in that to form a buried groove for embedding and protecting the elastic member.

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