KR20200014507A - A Dispensing Device - Google Patents

Abstract

A fluid supply mechanism according to the present invention relates to a fluid supply mechanism including: a housing unit, i.e., a hollow body of which a top portion is opened, and in a lower end portion of which a discharge nozzle coupling part that is a vertically penetrated through-hole is formed, a syringe unit, i.e., a hollow body which is provided inside the housing unit and is vertically penetrated; a driving discharge member which is provided in a bottom portion of the syringe unit such that the driving discharge member can be slid into the housing unit in a vertical direction; a driving means which is coupled to the driving discharge member; and a discharge nozzle unit which is provided in the housing unit in a state that the discharge nozzle unit is coupled to the discharge nozzle coupling part so that the discharge nozzle unit is positioned in a bottom portion of the driving discharge member. The discharge nozzle unit has a discharge nozzle provided in a lower end portion thereof to discharge a fluid; a discharge flow path which is upwardly opened and has a discharge flow path-extending hole formed in a lower end portion thereof and opened in a side direction is formed in the driving discharge member, and the driving discharge member is provided with a driving member-extending unit which is extended to a bottom portion of the discharge flow path-extending hole; a fourth sealing member is provided between the housing unit and the driving discharge member in an upper part of the discharge flow path-extending hole to prevent a fluid flown to the outer side of the driving discharge member from flowing upward through the discharge flow path-extending hole; and the fluid injected into the syringe unit flows to the outer side through the discharge flow path-extending hole along a discharge flow path of the driving discharge member, flows downwardly along a flow gap formed between the driving member-extending unit and the housing unit, and is discharged downwardly through the discharge nozzle provided in a lower part after passing between the driving member-extending unit and the discharge nozzle unit. The fluid supply mechanism according to the present invention can accurately control a discharge flow amount of fluid and can prevent generation of supply fault such as lack in fluid supply although air contained in the fluid is separated.

Description

Fluid supply mechanism {A Dispensing Device}

The present invention relates to a fluid supply mechanism, and more particularly, to a fluid supply mechanism capable of precise control of the fluid supply amount and to prevent a fluid supply failure by air contained in the supplied fluid.

The fluid supply mechanism is a mechanism for discharging and supplying various fluids such as grease and oil in an accurate amount. A volume chamber with a built-in piston actuated by a fluid inside, an air chamber with a piston operating a spool, and a predetermined position to supply fluid to the lower part of the volume chamber or to supply fluid to the upper part of the volume chamber. Fluid supply ring, spool packing, and fluid supply passage and fluid discharge passage for supplying and discharging the fluid to the volume chamber are comprised.

1 is a longitudinal sectional view showing the configuration of a fluid supply mechanism according to the prior art, and FIG. 2 is a longitudinal sectional view showing the configuration of the fluid supply mechanism of FIG. 1 from another direction.

As shown in FIG. 2, the fluid supply mechanism according to the related art has a polygonal columnar shape in which a first internal flow path 12 is formed and a discharge flow path 14 communicating with the first internal flow path 12 is provided. A first housing 10 provided below and a second inner flow passage 22 formed therein in a polygonal column shape and an inflow passage 24 communicating with the second inner flow passage 22 are provided on one side. The second housing 20, one end of which is in communication with the first housing 10, and a third internal flow path 32 formed therein in a polygonal column shape, and an upper end inside the third internal flow path 32. A first flow path 34 and a second flow path 36 for supplying a fluid to the lower end are formed, and one end thereof has a third housing 30 communicating with the second housing 20, and a polygonal pillar shape therein. A fourth inner flow passage 42 is formed, the first housing 40 and one end is in communication with the third housing 30, the other end is blocked, and the first housing 10 ) Is inserted between the second housing 20 and the sheet 50 having a first through hole 52 formed therein, and a second through hole 62 formed therein, thereby forming the second housing 20. The guide bush 60 is inserted into the lower end of the second inner flow passage 22 of the c) and communicates with the first through hole 52 of the sheet 50, and the third through hole 72 is disposed therein. And a first packing 70 formed on an upper surface of the guide bush 60 to communicate with a second through hole 62 of the guide bush 60, and an edge of the first packing 70. The first O-ring 80, a packing sheet 90 provided between the first packing 70, the layer of the first O-ring 80, and an inner surface of the first housing 10, and a first inside thereof. A through passage 102 is provided, the first guide 100 is fixed to the inner wall of the second inner flow path 32 of the second housing 30, and the outer surface of the first guide 100 and A second o-ring inserted between an inner wall of the second inner flow passage 22 104 and a second guide passage 112 formed therein, the second guide 110 is fixed to the inner wall of the third internal passage 32 of the third housing 30, and the second guide passage 112 is fixed. A third O-ring 114 is inserted between the outer surface of the guide 110 and the inner wall of the third inner passage 32 and a third through passage 122 is provided therein, and the second guide 110 is disposed therein. A third guide 120 that is spaced apart from and fixed to an inner wall of the third internal flow path 32 of the third housing 30, and an outer surface of the third guide 120 and the third internal flow path A fourth O-ring 124 inserted between the inner walls of the 32 and a fourth through passage 132 are provided therein, and are in close contact with the upper end of the fourth inner passage 42 of the fourth housing 40. The fifth O-ring is inserted between the support guide 130 and the upper surface of the support guide 130 and the upper end of the fourth internal flow path 42 of the fourth housing 40 to decrease the outer diameter toward the lower ( 134) with a bar shape And a spool 140 formed through the fourth housing 40 and the third housing 30 and slidable along the fourth internal passage 42 and the third internal passage 32. It is formed in the shape of a bar that becomes smaller in cross section, and one end thereof is connected to the spool 140, and is provided in the second internal flow passage 22 of the second housing 20, so that the second through hole 62 and the first agent are formed. The other end is joined to the three through holes 72 and the other end is fixed to the pin portion 150 engaged with the first through holes 52 of the seat 50 and the spool 140, and the second guide 110 and the The first piston 160 provided between the third guide 120 and the second piston 170 fixed to the spool 140 and provided between the third guide 120 and the fourth housing 40. ), A spring 180 elastically supported between the second piston 170 and the support guide 130, and a sixth O-ring 190 provided between the spool 140 and the support guide 130. To The first passage 34 is positioned between the second guide 110 and the first piston 160 and between the third guide 120 and the second piston 170. The second flow path 36 is positioned between the third guide 120 and the first piston 160 and between the third piston 170 and the fourth housing 40.

In the fluid supply mechanism according to the prior art as described above, the air contained in the fluid flowing through the inflow passage 24 is separated and gathered upwards, and various fluids such as grease or oil are supplied at the beginning, but the amount of air collected If the increase is supplied with the fluid, the amount of fluid is reduced and more air is supplied than the fluid, and the fluid supply amount is controlled only by the gap between the fin part 50 and the seat 50 and the pressure of the supplied fluid. There was a problem that the amount of feed fluid could not be precisely controlled.

Patent Registration No. 10-1198551

The present invention has been proposed to solve the problems of the prior art as described above, it is possible to provide a fluid supply device capable of precise control of the fluid supply amount, the defect that the air separated from the fluid is supplied with the fluid is prevented The purpose.

To this end, the present invention is a housing which is a hollow body formed in the upper portion and the discharge nozzle coupling portion is a through-hole through the upper and lower portions at the lower end, the syringe portion provided in the housing portion and the hollow body penetrated up and down, and the syringe portion A drive discharge member slidably disposed in the housing portion in a lower portion of the housing portion, a drive means coupled to the drive discharge member, and an upper portion coupled to the discharge nozzle coupling portion so as to be positioned below the drive discharge member; A discharge nozzle unit provided; The discharge nozzle unit has a discharge nozzle for discharging the fluid at the lower end; The drive discharge member is formed with a discharge passage having an discharge passage extension hole opening upwardly and laterally opened at a lower end thereof, and including a drive member extension portion extending below the discharge passage extension hole; A fourth sealing member is provided between the housing part and the drive discharge member to the upper portion of the discharge path extension hole to prevent the fluid flowing out of the drive discharge member through the discharge path extension hole to rise; The fluid introduced into the syringe flows along the discharge flow path of the drive discharge member, flows outward through the discharge flow path extension hole, and flows downward along the flow gap formed between the drive member extension part and the housing part, and the drive member extension part and the discharge part. It provides a fluid supply mechanism that is discharged downward through the discharge nozzle provided in the lower portion passing between the nozzle portion.

The discharge nozzle part has a discharge nozzle extension part which is a hollow body and a discharge nozzle inclination part which is provided below the discharge nozzle extension part and whose cross-sectional area decreases toward the lower part; The drive discharge member further includes a drive member discharge extension part extending from the lower end of the drive member extension part to the discharge nozzle part and having a drive member extension part having an increased cross-sectional area at the lower end thereof; When the drive discharge member is lowered, the drive member expansion portion is located in the discharge nozzle inclined portion.

In the above, the lower surface of the drive member extension portion is characterized in that formed in a flat.

In the above, the housing portion is characterized in that the at least one second housing side hole is formed through the side of the fourth sealing member and the inner end extending to the outer surface of the drive discharge member.

In the above, the first sealing member and the second sealing member is spaced apart from the upper portion of the fourth sealing member between the housing portion and the drive discharge member is provided up and down, the housing between the first sealing member and the second sealing member At least one fourth coupling member side hole is formed through the side and the inner end portion extends to the outer surface of the driving discharge member.

In the above, a second sealing member is provided between the housing portion and the drive discharge member spaced apart from the upper portion of the fourth sealing member, the operating space is formed inside the housing portion between the fourth sealing member and the second sealing member ; The driving means includes a drive coupling member inserted into the drive discharge member to move integrally with the drive discharge member and positioned in the working space, and the drive coupling member inserted and moving integrally with the drive coupling member in the working space, the outside of which is operated. A drive sealing member movable up and down on an inner surface of the housing forming a space; When the working fluid flows into the working space of the lower portion of the drive coupling member, the driving discharge member moves upwardly integrally with the driving coupling member, and when the working fluid flows into the working space of the upper portion of the drive coupling member, the driving fluid is integrated with the driving coupling member. The drive discharge member moves downward; The fluid in the discharge nozzle portion under the drive discharge member is pressurized downward by the drive discharge member downward, and is discharged through the discharge nozzle.

According to the fluid supply mechanism 100 according to the present invention, it is possible to precisely control the discharge flow rate, it is possible to prevent the occurrence of supply failure, such as lack of fluid supply even if the air contained in the fluid is separated.

1 is a longitudinal sectional view showing the configuration of a fluid supply mechanism according to the prior art,
2 is a longitudinal cross-sectional view showing the configuration of the fluid supply mechanism of FIG. 2 from another direction;
3 is a schematic longitudinal sectional view showing a fluid supply mechanism according to the present invention;
4 is an enlarged cross-sectional view of a portion “A” of FIG. 3.
5 is an enlarged cross-sectional view of a portion “B” of FIG. 3.
6 is an enlarged cross-sectional view of a portion “C” of FIG. 3.

Hereinafter, a fluid supply mechanism according to the present invention will be described in detail with reference to the drawings.

Figure 3 is a schematic longitudinal cross-sectional view showing a fluid supply mechanism according to the present invention, Figure 4 is an enlarged cross-sectional view of the "A" part of Figure 3, Figure 5 is an enlarged cross-sectional view of the "B" part of FIG. 6 is an enlarged cross-sectional view of a portion “C” of FIG. 3.

In the following description, the vertical direction in FIGS. 3 to 6 will be described as "up and down direction".

As shown in FIG. 3, the fluid supply mechanism 100 according to the present invention includes a housing part 120, a discharge nozzle part 140, a syringe part 110, a drive discharge member 130, and a drive. Means 150.

The housing part 120 is formed of a hollow body opened upward. The housing part 120 includes a first housing 121, a first coupling member 122, a second coupling member 123, a fourth coupling member 129, and a third coupling member 124. And a second housing 125, a guide member 126, and a third housing 127.

The first housing 121 is provided as a cylindrical hollow body opened in the vertical direction. The heating means 101 may be further provided inside the first housing 121. The heating means 101 may be a heater.

A lower first housing jaw surface 1211a is formed on the lower inner surface of the first housing 121 and extends downward to form a first housing coupling part 1211.

The first coupling member 122 is provided in a cylindrical shape. The first coupling member 122 is inserted into the first housing coupling portion 1211 so that an upper end of the first coupling member 122 is in contact with the first housing jaw surface 1211a. The first coupling member 122 slides upward from the lower portion of the first housing 121 and is inserted into the first housing coupling portion 1211. The first coupling member 122 may be inserted into the first housing coupling portion 1211 by interference fit.

The first coupling member 122 has a first coupling member inner diameter portion 1224 penetrated in the vertical direction. The first coupling member screw portion 1221, which is a female screw, is formed on an upper portion of the first coupling member inner diameter part 1224. The lower end of the first coupling member screw portion 1221 is spaced upwardly from the lower end of the first coupling member 122.

A downward jaw surface is formed below the first coupling member inner diameter part 1224, and a first coupling insertion part 1223 is formed below the jaw surface.

The first coupling member 122 has a first coupling screw groove 1223 which is opened laterally and has an internal thread formed therein, and has a first housing coupling hole penetrating laterally under the first housing 121. 1213).

The first coupling member 122 and the first housing 121, the coupling bolt 180 is inserted into and coupled to the first housing coupling hole 1213 and the first coupling screw groove 1223 in turn and the first coupling member The 122 and the first housing 121 are coupled to each other by the coupling bolt 180.

The second coupling member 123 is provided as a cylindrical hollow body opened in the vertical direction. The second coupling member 123 is provided below the first coupling member 122. The second coupling member 123 has an outer diameter larger than the inner diameter of the first coupling insertion portion 1223 and is inserted into the first coupling insertion portion 1223 by interference fit. The second coupling member 123 is inserted into the first coupling insertion portion 1223 so that the lower portion protrudes downward from the first coupling member 122.

An upper jaw surface is formed at an inner upper end of the second coupling member 123, and a second coupling groove portion 1231 is formed. The second coupling groove 1231 is provided with a first sealing member 171 made of rubber. The first sealing member 171 may be an O-ring, for example. The first sealing member 171 is provided between the second coupling member 123 and the drive discharge member 130, the fluid flowing into the first coupling member 122 through the syringe 110, the second coupling member It serves to prevent leakage between the 123 and the drive discharge member (130).

The fourth coupling member 129 is provided as a cylindrical hollow body opened in the vertical direction. The inner diameter of the fourth coupling member 129 is formed to the same diameter as the inner diameter of the second coupling member 123. The fourth coupling member 129 is provided below the second coupling member 123.

A fourth coupling upper insertion part 1293 is formed on the inner upper end of the fourth coupling member 129, and a fourth coupling is formed on the inner lower end of the fourth coupling member 129. The lower insert 1295 is formed.

The fourth coupling upper insertion part 1293 has an inner diameter smaller than the outer diameter of the second coupling member 123 so that the second coupling member 123 is inserted by interference fit.

A fourth coupling member side hole 1291 is formed in the fourth coupling member 129 under the fourth coupling upper insertion part 1293. The fourth coupling member side hole 1291 is formed between the fourth coupling upper insertion part 1293 and the fourth coupling lower insertion part 1295. The fourth coupling member side hole 1291 is spaced apart from the fourth coupling upper insertion part 1293 and the fourth coupling lower insertion part 1295 in the vertical direction. The fourth coupling member side hole 1291 is formed to penetrate from the outer surface to the inner surface of the fourth coupling member 129. The fourth coupling member side hole 1291 may be formed in plural.

 The fluid may leak between the second coupling member 123 and the driving discharge member 130 through the fourth coupling member side hole 1291.

The third coupling member 124 is provided as a cylindrical hollow body opened in the vertical direction. The third coupling member 124 is provided below the fourth coupling member 129. The third coupling member 124 is inserted into the fourth coupling lower insertion portion 1295 so that a lower portion thereof protrudes downward from the fourth coupling member 129. The third coupling member 124 has an outer diameter larger than the inner diameter of the fourth coupling lower insertion part 1295 and is inserted into the fourth coupling lower insertion part 1295 by interference fit.

An upper jaw surface is formed at an inner upper end of the third coupling member 124 and a third coupling groove portion 1241 is formed. The third coupling groove 1241 is provided with a second sealing member 173 made of rubber. The second sealing member 173 may be an O-ring, for example. The second sealing member 173 is provided between the third coupling member 124 and the drive discharge member 130, the working fluid flowing in the working space (S1) is the third coupling member 124 and the drive discharge member ( 130) to prevent leakage between.

The second housing 125 is provided below the third coupling member 124. The second housing 125 is provided as a cylindrical hollow body opened in the vertical direction.

An upper jaw surface is formed on an inner upper portion of the second housing 125, and a second housing upper insertion part 1251 is formed. An upper end of the second housing 125 is in contact with a lower end of the fourth coupling member 129, and an upper jaw surface of the second housing upper insertion part 1251 is provided in contact with a lower surface of the third coupling member 124. do. The second housing upper insertion part 1251 has an inner diameter smaller than the outer diameter of the third coupling member 124 so that the third coupling member 124 is inserted into the second housing upper insertion part 1251 by force fitting. do.

The inside of the second housing 125 is provided with a second housing protrusion 1259 spaced apart in the vertical direction from the top and bottom of the second housing 125 to protrude radially inward. The second housing protrusion 1259 is formed with a second housing part hole 1259a penetrating in the vertical direction. An operating space S1 having an operating means 150 is formed between the second housing protrusion 1259 and the third coupling member 124 in the second housing 125.

The second housing part through hole 1259a of the second housing protrusion 1259 forms an upward jaw surface and a concave second housing groove part 1257 is formed. The second housing groove part 1257 is provided with a third sealing member 1751.

The third sealing member 1751 is formed in an annular shape. The third sealing member 1751 is open upward, and the cross section is formed in the shape of “└┘”. A third sealing expansion unit 1753 is further provided inside the third sealing member 1751. The third sealing expansion means 1753 is made of a spring or the like. The third sealing expansion means 1753 is provided inside the third sealing member 1751 so that the third sealing expansion means 1753 extends the third sealing member 1751 in the radial direction and the working space S1. Seal it. The working fluid is prevented from leaking into the second housing part through hole 1259a by the third sealing member 1751 and the third sealing expansion means 1753.

The second housing 125 has a second housing side hole 1253 which penetrates laterally at a position where the second housing protrusion 1259 is formed. The second housing side hole 1253 extends from the outer surface of the second housing 125 to the second housing part through hole 1259a and is formed therethrough. The second housing side holes 1253 may be formed in plural. Through the second housing side hole 1253, it is possible to check whether the working fluid leaks between the second housing protrusion 1259 and the driving discharge member 130.

A lower jaw surface is formed below the second housing protrusion 1259 and a second housing lower inserting portion 1255 is formed below the second housing 125.

The guide member 126 is provided below the second housing 125. The guide member 126 is provided as a cylindrical hollow body opened in the vertical direction.

The upper portion of the guide member 126 is provided with a guide member insertion portion 1263 protruded upward from the outer surface of the guide member 126 radially inwardly. The guide member inserting portion 1263 has an outer diameter larger than the inner diameter of the second housing lower inserting portion 1255 and is inserted into the second housing inserting portion 1255 by interference fit.

A guide member groove 1262 is formed inside the guide member 126 to form an upward jaw surface and extend upward to an upper end of the guide member insertion part 1263. The guide member groove 1262 is provided with at least one fourth sealing member 177. The fourth sealing member 177 is made of a rubber material. The fourth sealing member 177 may be an O-ring, for example. The fourth sealing member 177 is provided between the guide member 126 and the drive discharge member 130, the fluid flowing in the flow gap (G1) between the guide member 126 and the drive discharge member 130 is upward It moves to prevent leakage to the second housing part through-hole 1259a.

A guide member extension 1265 is provided below the guide member 126. The guide member extension part 1265 is formed in a cylindrical shape open in the vertical direction. The guide member extension portion 1265 is provided with a step to form a narrower cross-sectional area as the downward.

The lower part of the guide member 126 is formed with a discharge nozzle coupling portion 1267 which is a female thread on the inner surface. A discharge nozzle unit 140 is coupled to the discharge nozzle coupling unit 1267.

The third housing 127 is provided as a hollow body that is upwardly opened. The third housing 127 is provided below the guide member 126. The guide member 126 is provided in the third housing 127. An upper end of the third housing 127 is in contact with a lower end of the second housing 125, and an inner surface thereof is provided in contact with a part of an outer surface of the guide member 126. A lower portion of the third housing 127 is formed with a third housing lower through hole 1271 penetrating in the vertical direction. A lower portion of the guide member 126 is inserted into the third housing lower through hole 1271.

A third housing coupling hole 1273 is formed in the upper portion of the third housing 127, and the guide member coupling groove 1261 is formed in the guide member 126 to be opened laterally and has an internal thread. Is formed.

The third housing 127 and the guide member 126 are coupled to the coupling bolt 180 is inserted into the third housing coupling hole 1273 and the guide member coupling groove 1261 in order and fastened by the coupling bolt 180. The guide member 126 and the third housing 127 are combined.

An auxiliary heating means 190 may be further provided between the third housing 127 and the guide member 126. The auxiliary heating means 190 is provided in contact with the inner surface of the third housing (127). The auxiliary heating means 190 may be a heater, for example.

The discharge nozzle unit 140 is provided below the guide member 126. The discharge nozzle unit 140 is provided as a hollow body opened in the vertical direction.

The discharge nozzle unit 140 includes a discharge nozzle extension unit 141, a discharge nozzle inclination unit 147, and a discharge nozzle 149.

The discharge nozzle extension 141 is provided with a cylindrical hollow body opened in the vertical direction. On the outer surface of the discharge nozzle extension 141 is formed a discharge nozzle jaw portion 145 spaced downward from the upper portion of the discharge nozzle extension 141 to protrude radially outward. On the outer surface of the discharge nozzle extension part 141, the discharge nozzle fastening part 143, which is a male screw, is formed on the upper part of the discharge nozzle jaw part 145.

The discharge nozzle unit 140 is provided with the discharge nozzle fastening portion 143 is screwed to the discharge nozzle coupling portion 1267 and coupled to the guide member 126.

The discharge nozzle inclined portion 147 is provided below the discharge nozzle extension 141. The discharge nozzle inclined portion 147 is formed to decrease in cross-sectional area toward the bottom. The lower end of the discharge nozzle inclination portion 147 is provided with a discharge nozzle 149 for discharging the fluid.

As shown in FIG. 3 and FIG. 4, the syringe part 110 is provided in the first housing 121. The syringe portion 110 is provided with a cylindrical hollow body opened in the vertical direction.

The syringe unit 110 is composed of a syringe 111 and a syringe connecting member 113.

The syringe 111 is provided as a cylindrical hollow body opened in the vertical direction. The lower end of the syringe 111 is branched in the radial direction and provided with a syringe extension extended downward. The syringe extension portion has a smaller cross-sectional area as it goes downward from the syringe.

The syringe extension part is branched in the radial direction and includes a syringe first extension part 1111 and a syringe second extension part 1113. The first syringe extension 1111 and the second syringe extension 1113 are provided to be spaced apart from each other in the radial direction. The inner diameter of the second syringe extension 1113 is larger than the outer diameter of the first syringe extension 1111.

The syringe first extension part 1111 is provided to protrude downward from the syringe second extension part 1113. In the inner diameter of the second syringe extension portion 1113, a syringe screw portion 1113a which is a thread is formed. The syringe connecting member 113 is inserted between the syringe first extension part 1111 and the syringe second extension part 1113 and fastened to the syringe screw part 1113a.

The syringe connection member 113 is provided as a cylindrical hollow body penetrated in the vertical direction. The upper jaw portion is formed inside the syringe connection member 113. On the upper outer surface of the syringe connection member 113, a threaded connection screw portion 1131 is formed.

The syringe connecting member 113 is inserted between the first screw portion 1111 and the second syringe portion 1113 and the connecting screw portion 1131 and the syringe screw portion 1113 a are screwed and inserted. The syringe connection member 113 is inserted until the lower end of the syringe first extension part 1111 is in contact with the upper jaw portion of the inside of the syringe connection member 113.

The outer surface of the syringe connecting member 113 is formed with a connecting member jaw portion 1333 downwardly spaced downward from the connecting screw portion 1131, and the connecting member screw portion 1135 which is a male screw to the lower portion of the connecting member jaw portion 1133. Is formed.

The syringe connection member 113 is inserted until the connection member screw portion 1135 is screwed to the first coupling member screw portion 1221 and the connection member jaw portion 1133 is in contact with the upper end of the first coupling member 122. .

The syringe unit 110 is coupled to the first coupling member 122 after the syringe 111 and the connection member 113 are coupled. The syringe unit 110 may be coupled to the connecting member 113 after the connecting member 113 is coupled to the second coupling member 122.

The driving discharge member 130 is provided below the syringe portion 110. The drive discharge member 130 is provided to be slidable in the vertical direction in the housing portion 120. The driving discharge member 130 is provided spaced downward from the lower portion of the syringe unit 110. The drive discharge member 130 is provided in the form of a rod extending in the vertical direction. An upper end of the driving discharge member 130 is positioned in the first coupling member 122 and extends downward to protrude downward from the third housing part 127.

The driving discharge member 130 is inserted into the lower housing of the third coupling member 124 upwardly before the second housing 125 is coupled with the third coupling member 124 and is provided.

As shown in FIG. 5, a driving member jaw portion upwardly formed on an outer surface of the driving discharge member 130 positioned in the operating space S1 formed between the second housing 125 and the third coupling member 124. 1335 is formed. The driving member jaw portion 1335 is spaced upward from the second housing protrusion 1259. A driving member screw portion 1333 is formed between the driving member jaw portion 1335 and the lower surface of the third coupling member 124. The driving member screw portion 1333 is spaced upward from the driving member jaw portion 1335 and spaced downward from the third coupling member 124.

As shown in FIG. 6, the driving discharge member 130 positioned in the guide member 126 is provided radially inwardly spaced from an inner surface of the guide member 126. That is, the inner diameter of the guide member 126 is formed larger than the outer diameter of the drive discharge member 130.

The driving discharge member 130 is formed with a discharge passage 131 upwardly opened. At the lower end of the discharge passage 131, a discharge passage extension hole 133 opened laterally is formed. The discharge passage extension hole 133 is positioned in the guide member extension part 1265 under the fourth sealing member 177.

The lower portion of the driving discharge member 130 positioned in the guide member 126 is formed with a driving member extension portion 135 that narrows in cross-sectional area. The driving member extension part 135 is provided below the discharge passage extension hole 133. The outer surface of the drive member extension portion 135 is formed to form a stage.

The lower portion of the drive member extension portion 135 is provided with a drive member discharge extension portion 137 extending downward from the drive member extension portion 135. The driving member discharge extension part 137 protrudes downward from the lower end of the third housing 127 and is provided in the discharge nozzle part 140. The driving member discharge extension part 137 has an outer diameter smaller than the inner diameter of the discharge nozzle extension 141 and is radially spaced inwardly from the discharge nozzle extension 141.

The driving discharge member 130 is provided radially inwardly spaced from the guide member 126 and the discharge nozzle extension 141, so that the driving discharge member 130 and the guide member 126 and the discharge nozzle extension 141 are provided. Between the flow gap G1 through which the fluid moves is formed.

The lower end of the driving member discharge extension unit 137 is provided with a driving member expansion unit 139 having an increased cross-sectional area. The driving member extension part 139 is located in the discharge nozzle inclination part 147. The driving member extension part 139 is formed in a convexly curved shape laterally, and is provided in contact with an inner surface of the discharge nozzle inclination part 147 when the driving discharge member 130 descends.

The lower end of the driving member extension part 139 is formed of a driving member end surface 1391 which is flat. When the driving member extension part 139 is in contact with the inner surface of the discharge nozzle inclination part 147, a discharge space S2 is formed between the driving member end surface 1391 and the discharge nozzle inclination part 147.

As shown in Figure 5, the operating member 150 is provided coupled to the drive discharge member 130 in the operating space (S1). The operation member 150 is coupled to the drive discharge member 130 before the drive discharge member 130 is inserted into the third coupling member 124. The operation member 150 is provided such that the driving discharge member 130 is inserted into and coupled to the operation member 150 and moves up and down integrally with the driving discharge member 130.

The actuating member 150 includes a driving coupling member, a driving sealing member 157, an expansion means 159, and a coupling nut 155.

The drive coupling member is provided with a hollow body opened in the vertical direction. The outer surface of the drive coupling member is provided radially inwardly spaced from the inner surface of the second housing 125. The driving coupling member is seated on the driving member jaw portion 1335 and the coupling nut 155 is fastened to the driving member screw portion 1333 to be fixed.

The drive coupling member includes a first drive coupling member 151 and a second drive coupling member 153, and the first drive coupling member 151 and the second drive coupling member 153 are provided up and down.

The first driving coupling member 151 is provided to be seated on the driving member jaw portion 1335. An outer jaw portion is formed on an outer surface of the first driving coupling member 151.

The second drive coupling member 153 is provided on the first drive coupling member 151. A lower jaw portion is formed on an outer surface of the second driving coupling member 153. The jaw portion formed on the outer surface of the second drive coupling member 153 is provided to face the jaw portion formed on the outer surface of the first drive coupling member 151.

Since the upper jaw portion of the first driving coupling member 151 and the lower jaw portion of the second driving coupling member 157 are provided to face each other, a concave groove extending along the circumferential direction is formed on the outer surface of the driving coupling member.

Grooves formed on the outer surface of the drive coupling member are provided with two annular drive sealing members 157 up and down. The driving sealing member 157 is inserted into a groove formed on the outer surface of the driving coupling member.

The cross section of the driving sealing member 157 is provided in the form of "└┘" opened to one side. The driving sealing member 157 provided at the lower side of the two driving sealing members 157 is provided such that the opening faces the upper jaw portion of the first driving coupling member 151, and the driving sealing member 157 provided at the upper portion thereof. ) Is provided such that the opening faces the downward jaw portion of the second driving coupling member 153.

Expansion means 159 is provided in the drive sealing member 157, respectively. The expansion means 159 is provided with a spring or the like. As the expansion means 159 is provided in the driving sealing member 157, the driving sealing member 157 is extended radially outward to be in contact with the inner surface of the second housing 125 and is provided to allow sliding contact movement up and down. . Since the radial outer surface of the driving sealing member 157 is provided to contact the inner surface of the second housing 125, the operation space S1 is separated into an upper space and a lower space.

When the working fluid is introduced into the working space (S1) of the lower portion of the drive coupling member in the operating space (S1), the drive discharge member 130 moves upward integrally with the drive coupling member, the upper portion of the drive coupling member When the working fluid flows into the working space S1, the driving discharge member 130 moves downward integrally with the driving coupling member.

Hereinafter, the flow of the fluid in the fluid supply mechanism 100 according to the present invention will be described.

The fluid is introduced into the syringe unit 110, and the fluid supplied to the syringe unit 110 flows along the discharge passage 131 of the driving discharge member 130 to drive the discharge member through the discharge passage extension hole 133. It flows into the flow path clearance G1 which is the outer side of 130.

When the working fluid is introduced into the operating space (S1) of the lower portion of the drive coupling member, the drive discharge member 130 moves upwardly integrally with the drive coupling member, and the fluid located in the flow gap (G1) is discharge space (S2) Flows into.

When the working fluid flows into the operating space S1 of the upper portion of the driving coupling member, the driving discharge member 130 moves downward integrally with the driving coupling member, and the fluid in the discharge space S2 moves downward. Pressurized downward by the 130 is discharged to the outside through the discharge nozzle (149).

In the fluid supply mechanism 100 according to the present invention, the fluid is repeatedly moved as described above, and the fluid is discharged through the discharge nozzle 149.

The fluid supply mechanism 100 is located in the upper portion of the discharge nozzle portion 140 in which the fluid is supplied to the syringe portion 110 is discharged fluid, the air contained in the fluid to be supplied upwards syringe portion 110 Because it flows back to) there is an effect that is prevented from being discharged downward through the discharge nozzle unit 140.

The fluid supply mechanism according to the present invention has been described with reference to the embodiments shown in the drawings, but this is merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope should be defined by the technical spirit of the appended claims.

100: fluid supply mechanism
110: syringe portion 120: housing portion
130: driving discharge member 140: discharge nozzle
150: driving means 180: coupling bolt
190: auxiliary heating means

Claims (6)

A housing part 120 which is a hollow body having a discharge nozzle coupling part 1267 which is a through hole which is opened upwardly and penetrated up and down at a lower end thereof; A driving discharge member 130 provided to be slidable in the housing part 120 in a vertical direction under the syringe part 110, a driving means 150 coupled to the driving discharge member 130, and driving An upper portion coupled to the discharge nozzle coupler 1267 to be positioned below the discharge member 130 and including a discharge nozzle part 140 that is a vertically penetrated hollow body provided in the housing part 120;
The discharge nozzle unit 140 has a discharge nozzle (149) for discharging the fluid at the lower end; The driving discharge member 130 is formed with a discharge passage 131 having a discharge passage extension hole 133 opened upwardly and laterally opened at a lower end thereof, and a driving member extension part extending below the discharge passage extension hole 133. 135 is provided;
The fluid flowing to the outside of the drive discharge member 130 through the discharge flow path extension hole 133 between the housing portion 120 and the drive discharge member 130 to the upper portion of the discharge flow path extension hole 133 The fourth sealing member 177 is provided to prevent;
The fluid introduced into the syringe portion 110 flows along the discharge passage 131 of the driving discharge member 130 to flow outward through the discharge passage extension hole 133, and the driving member extension portion 135 and the housing portion ( It flows downward along the flow gap (G1) formed between the 120, and is discharged downward through the discharge nozzle 149 provided in the lower portion passing between the drive member extending portion 135 and the discharge nozzle unit 140. Fluid supply mechanism (100). The discharge nozzle inclination part 147 of claim 1, wherein the discharge nozzle part 140 is disposed below the discharge nozzle extension part 141 and the discharge nozzle extension part 141, and the cross section decreases toward the lower part. Has; The driving discharge member 130 further extends from the lower end of the driving member extension part 135 to the discharge nozzle part 141 and further includes a driving member discharge extension part 137 having a driving member extension part 139 having an increased cross-sectional area at the lower end thereof. Including; When the drive discharge member 130 is lowered, the drive member expansion unit (139) is located in the discharge nozzle inclined portion (147), characterized in that the fluid supply mechanism (100). 3. The fluid supply mechanism (100) of claim 2, wherein the lower surface of the driving member extension portion (139) is formed in a flat surface. 2. The at least one second housing side hole 1253 of claim 1, wherein the housing part 120 penetrates to the upper side of the fourth sealing member 177 and the inner end thereof extends to the outer surface of the driving discharge member 130. Fluid supply mechanism 100, characterized in that formed. The method of claim 1, wherein the first sealing member 171 and the second sealing member 173 is spaced apart from the upper portion of the fourth sealing member 177 between the housing portion 120 and the drive discharge member 130. A fourth spaced apart from the first sealing member 171 and the second sealing member 173 through the housing portion 120 and extending to an outer surface of the driving discharge member 130. Fluid supply mechanism (100), characterized in that at least one coupling member side hole (1291) is formed. The method of claim 1, wherein the second sealing member 173 is provided between the housing portion 120 and the drive discharge member 130 spaced apart from the upper portion of the fourth sealing member 177, the fourth sealing member ( An operating space S1 is formed in the housing 120 between the 177 and the second sealing member 173;
The drive means 150 is a drive coupling member is inserted into the drive discharge member 130 to move integrally with the drive discharge member 130 and is located in the operating space (S1) and the drive coupling member is inserted into the operating space ( A driving sealing member 157 which is integrally moved with the driving coupling member in S1 and which is movable in sliding contact with the inner surface of the housing portion 120 whose outer side forms the working space S1;
When the working fluid flows into the working space S1 of the lower portion of the driving coupling member, the driving discharge member 130 moves upwardly integrally with the driving coupling member, and the working fluid moves to the working space S1 of the upper portion of the driving coupling member. When the inlet drive discharge member 130 moves downward integrally with the drive coupling member; The fluid in the discharge nozzle unit 140 under the drive discharge member 130 is pressurized downward by the downward drive discharge member 130 to be discharged through the discharge nozzle 149. ).

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