JP5127054B2 - Self-returning syringe - Google Patents

Description

  INDUSTRIAL APPLICABILITY The present invention is used for air supply / water supply using an automatic return type syringe, particularly an air supply / water supply pipe disposed in an endoscope or the like, and for suction through a suction pipe. The present invention relates to a configuration of a syringe that can be carried as a water feeding device or a suction device.

  FIG. 14 shows a configuration of a conventional endoscope apparatus. The endoscope (scope) includes, for example, a distal end portion 1A provided with a solid-state imaging device, an operation portion 1B provided via a bending portion, and the like. Have This endoscope is provided with an air / water feed pipe 3a, a water feed pipe 3b branched from the air / water feed pipe 3a, and an air feed pipe 3c in order to clean the observation window arranged on the distal end surface. In addition, a treatment instrument insertion channel 5a and a suction tube 5b connected to the treatment instrument insertion channel 5a are provided from the forceps port 4 for introducing the treatment instrument to the distal end surface of the distal end portion 1A. The treatment instrument insertion channel 5a is aspirated. It can also function as a tube.

  The operation unit 1B is provided with an air / water supply button 6a, a suction button 6b, a camera shutter button 6c, and the like for switching between the water supply tube 3b and the air supply tube 3c and performing an air supply / water supply operation. An air / water supply pump 8 is connected to the water supply pipe 3b via a water supply tank 7 containing cleaning water, and an air / water supply pump 8 is directly connected to the air supply pipe 3c. A suction pump 10 is connected to the suction pipe 5b through a suction tank 9.

  According to such an endoscope apparatus, when the water supply operation of the air supply / water supply button 6a (for example, second-stage pressing) is performed, the air supply pipe 3c is closed and the water supply pipe 3b is opened. When washing water is sprayed from the nozzle on the distal end surface of the endoscope toward the observation window and an air supply operation (for example, pushing the first stage) is performed, the water supply pipe 3b is closed and the air supply pipe 3c is opened, and air / water supply is performed. The air is supplied from the pump 8 in the same manner. By removing dirt and the like adhering to the observation window by such water supply and air supply, the observation state of the object to be observed can be kept good.

Further, when the suction button 6a is operated, the liquid (contents) of the object to be observed is sucked through the treatment instrument insertion channel 5a and the suction pipe 5b by the suction operation of the suction pump 10, and this liquid is sucked into the suction tank. 9 can be discharged. Although the above description is an example of a mechanical valve, air supply / water supply and suction can be performed using an electric button (switch) and an open / close valve.
JP 2003-135391 A

  However, when air / water / suction is performed in a conventional endoscope apparatus, the air / water pump (apparatus) 8 and the suction pump 10 are required as described above, and this air / water pump There is a problem that it is difficult to use the endoscope at a place other than the facility where the 8 and the suction pump 10 are arranged.

  The portability of the endoscope device enables use in various places other than well-equipped facilities, bedside use, emergency use, etc., and simplification of the configuration leads to cost reduction, If the equipment relating to air supply, water supply or suction can be made portable and simplified, a highly convenient endoscope apparatus can be provided.

  Moreover, in the syringe generally used, it is possible to perform air supply, water supply, or suction once by manually pushing the piston. However, continuous air supply, water supply, or suction without any limitation of the supply amount. Could not be done easily.

  The present invention has been made in view of the above problems, and its purpose is to facilitate continuous air supply, water supply or suction with no limitation on the supply amount, and to make the endoscope apparatus portable, An object of the present invention is to provide an automatic return type syringe that can facilitate the porting and simplification of equipment relating to air supply, water supply or suction, which leads to simplification.

In order to achieve the above object, the automatic return syringe according to the invention of claim 1 is formed with a plurality of space portions divided by a partition portion, and a syringe port (air supply port) is formed in each of the plurality of space portions. And a piston having a pushing portion at the rear end thereof, and a plurality of the plurality of air holes provided in the pushing portion. A piston body that has a plurality of air passages communicating with each of the space portions, and a spring that is disposed between the piston body and the cylindrical body and returns the pushed piston body to its original position. seen, the upper Symbol plurality of space portions, the series arrangement by transverse dividing the cylinder body, the space portion other than the distal-side space, provided with the syringe port on the side of the cylinder, the piston body, Reciprocating in close contact with the inner periphery of the plurality of spaces of the cylinder Piston unit which, and the piston portion supporting the, characterized in that a shaft portion than the inner diameter of the cylinder becomes smaller outer diameter.

According to a second aspect of the invention, in the configuration of the first aspect, a syringe port for air, disposed on the distal side space, the rear-side space, the position when not in operation of the piston portion Further, the present invention is characterized in that a suction port is provided on the side surface of the rear cylindrical body so that both air supply and suction can be performed.
In the invention of claim 3 , a plurality of space parts divided by the partition part are formed, and a cylinder body provided with a syringe port in each of the plurality of space parts, and a plurality of space parts in the cylinder body are reciprocated. A piston having a pushing portion at the rear end, and a piston body in which a plurality of air passages communicating with each of the plurality of space portions are formed with respect to each of the plurality of ventilation holes provided in the pushing portion; A spring disposed between the piston body and the cylindrical body and returning the pushed piston body to its original position, and the plurality of space portions are arranged in parallel by vertically dividing the cylindrical body And the piston body is in close contact with the inner periphery of the plurality of space portions of the cylindrical body and reciprocates, and supports the piston portion, and has an outer diameter smaller than the inner diameter of each space portion of the cylindrical body. A plurality of shafts that are arranged in parallel In one space portion in The inter its tip side is arranged a syringe port for air, and in the other space, in the space portion of the piston portion unactuated when the rear than the position of the A suction port is provided on a side surface of the cylindrical body so that both air supply and suction can be performed.

According to the configuration of the present invention, will be more syringes space, each independent (space part piston reciprocates) is made form in series in a cylindrical body, of a plurality of vent holes by a thumb or the like If you push the push part while closing one (or two, etc.) and move the piston body forward, the air in the corresponding space will be pushed out from each syringe port, and then the thumb etc. will be released. The piston body automatically returns (returns) to the original position by the spring while air flows into the corresponding space through the vent hole and the vent passage. Therefore, the operator can perform continuous air supply using the selected space portion among the plurality of spaces by repeating the operation of pressing and releasing the push portion.

  In the case of an endoscope apparatus, for example, a first space portion having a first syringe port and a second space portion having a second syringe port are formed in a cylindrical body, and the first and second vent holes are formed in the piston body. And the first and second vent passages, an endoscope air supply tube is connected to the first syringe port with a connecting tube or the like, and a water supply tank connected to the endoscope water supply tube is connected to the second syringe port. If connected, air can be supplied from the first syringe port via the endoscope air supply tube, and wash water or the like can be supplied from the second syringe port via the water supply tank and the endoscope water supply tube.

When applying Claims 2 and 3 to the endoscope apparatus, in addition to connecting the two syringe ports described above to the endoscope for air supply and water supply, suction ports provided on the side surfaces of the cylindrical body If a suction tank that connects an endoscope suction tube using a connecting tube or the like is connected, the liquid in the body to be observed is sucked from the suction port via the treatment instrument insertion channel and the suction tube of the endoscope. Etc. can be sucked.

  According to the automatic return type syringe of the present invention, by repeating the pushing operation, continuous air supply, water supply, or suction with no limitation on the supply amount can be easily performed with one syringe. That is, for example, in an endoscope apparatus, when air supply, water supply, or suction is performed, it is necessary to attach a syringe to each of the air supply pipe, the water supply pipe, or the suction pipe. However, in the former case, the connection configuration of a plurality of syringes is complicated, and in the latter case, the connection operation is complicated. In the present invention, by connecting each syringe port to an air supply tube, a water supply tube or a suction tube, a single syringe can execute a plurality of operations in air supply, water supply or suction.

  In addition, when applied to an endoscopic device, it is possible to carry and simplify equipment related to air / water feeding, and in turn, make it possible to carry and simplify the endoscopic device. It is easy to use the endoscope at the side or in an emergency, and there is an effect that a highly convenient endoscope apparatus can be obtained.

  FIG. 1 to FIG. 4 show the configuration of the automatic return type syringe according to the first embodiment. In the first embodiment, two syringe spaces are arranged in series. As shown in FIG. 1, the syringe according to the embodiment includes a cylindrical tube body 14, a piston body (slider) 15, and a spring (spring) 16, and the cylinder body 14 includes a first cylinder body 14 a. A short second cylindrical body 14b is attached so as to abut on the inner intermediate portion of the cylinder, and a partition plate 17 is disposed at the tip (stepped portion) of the second cylindrical body 14b. A first chamber (front chamber) 19E and a second chamber (rear chamber) 20E are formed as syringe spaces in which the section reciprocates. A first syringe port (air supply port) 19G is provided at the distal end of the first chamber 19E (cylinder body 14), and a second syringe port 20G is disposed on the side surface of the cylindrical body 14 on the distal end side of the second chamber 20E. And a vent hole 14d is formed in the side surface of the cylindrical body 14 below the partition plate 17 on the rear end side of the first chamber 19E.

  On the other hand, the piston body 15 is disposed at the rear end thereof, and is a disc-shaped pressing portion 15a for pushing with a thumb or the like to perform a piston operation, and a cylindrical rod-shaped shaft portion having an outer diameter smaller than the inner diameter of the cylindrical body 14. 15P, and a first piston portion (sliding portion) 19P that slides (reciprocates) in close contact with the inner surface of the cylindrical body 14 at the tip, and a similar second piston portion 20P at the intermediate portion. The first and second piston portions 19P and 20P are attached to a fitting portion (for example, an annular groove portion) 15e of a cylindrical rod-shaped shaft portion 15b with a ring-shaped rubber (elastic rubber) member 21 for closely contacting the inner surface of the cylinder. Formed with.

  Further, in the piston body 15, the first vent hole 19V and the second vent hole 20V are formed in the pressing portion 15a, and the shaft portion 15b penetrates from the first vent hole 19V to the tip of the shaft portion in the axial direction. The first ventilation path (pipe) 19F and the second ventilation path 20F penetrating from the second ventilation hole 20V to the side surface in the middle of the shaft portion are provided. Further, between the flange portion 14c on the rear side of the cylindrical body 14 and the pressing portion 15a of the piston body 15 (when engaged with each other), the pushed piston body 15 is biased in a direction to return to the original position. The spring 16 is provided.

  FIG. 3 shows a configuration in which the syringe of the first embodiment is applied to the endoscope apparatus to supply air / water, and in this case, the first chamber 19E of the cylindrical body 14 has a first structure. An air supply tube of an endoscope is connected to the 1 syringe port 19G via a connecting tube 23a, and a water supply tank 24 for storing cleaning water or the like is connected to the second syringe port 20G of the second chamber 20E via a connecting tube 23b. The water supply tank 24 is attached and connected to the water supply pipe of the endoscope through the connecting tube 23c.

  According to such a syringe of the first embodiment, from the basic state of FIG. 4A (during non-operation), the pressing portion 15a is closed with the thumb or the like (with the biasing force of the spring 16) while closing the first ventilation hole 19V. When pushed, the air is sucked from the vent hole 14d and the air in the first chamber 19E (tubular body 14) is pushed out from the first syringe port 19G, so that air can be supplied. When the pressing portion 15a is pushed while closing the vent hole 20V, the air in the second chamber 20E is pushed out from the second syringe port 20G and air can be supplied. On the other hand, when the pushing operation of the pressing portion 15a is released from the state of FIG. 4B, the first ventilation hole 19V and the second ventilation hole 20V are opened, and the piston body 15 is urged rearward by the spring 16. Therefore, the outside air is supplied from the first vent hole 19V and the second vent hole 20V to the first chamber 19E and the second chamber 20E through the first vent passage 19F and the second vent passage 20F, and the first chamber. The air flowing into 19E is exhausted from the vent 14d, and the piston body 15 automatically returns to the original state of FIG. Therefore, by repeatedly pressing the pressing portion 15a, it is possible to continuously supply air a plurality of times from the selected syringe ports 19G and 20G.

  As shown in FIG. 3, when applied to an endoscope, the push portion 15a is pushed while closing the first vent hole 19V, so that the first syringe port 19G is sent to the observation window via the air feeding tube of the endoscope. In addition, by pushing the push portion 15a while closing the second vent hole 20V, the air is supplied from the second syringe port 20G, and the observation window through the water supply tank 24 and the endoscope water supply tube. Water is sent to In this way, air supply or water supply with no limitation on the supply amount can be performed by the continuous operation of the pressing portion 15a.

5 and 6 show a configuration of a reference example in which two syringe spaces are arranged in parallel. As shown in the drawing, the syringe of the reference example also has a cylindrical cylinder 114 and a piston body 115. And the cylindrical body 114 is provided with a partition plate 27 so as to vertically divide the cylindrical space into two parts, thereby providing a first syringe space portion in which the piston portion reciprocates. The first chamber 29E and the second chamber 30E are formed in parallel. And the 1st syringe port 29G is provided in the front-end | tip of this 1st chamber 29E (cylinder 14), and the 2nd syringe port 30G is provided in the front-end | tip of the 2nd chamber 30E.

  On the other hand, the piston body 115 includes a disc-shaped pressing portion 115a at the rear end and two cylindrical rod-shaped shaft portions 115b and 115c, and is in close contact with the inner surface of the first chamber 29E at the tip of the shaft portion 115b. A first piston portion 29P that slides while sliding, and a second piston portion 30P that slides in close contact with the inner surface of the cylindrical body of the second chamber 30E are provided at the tip of the shaft portion 115c. The first and second piston portions 29P and 30P are formed by attaching the annular rubber members 21 for close contact with the indoor surfaces to the fitting portions (for example, annular groove portions) 115e of the cylindrical rod-shaped shaft portions 115b and 115c. The The shaft portions 115b and 115c may have a size (diameter) such that the entire outer periphery thereof is in close contact with the inner walls of the chambers 29E and 30E.

  Further, in the piston body 115, the first vent hole 29V and the second vent hole 30V are formed in the pressing portion 115a, and the shaft portion 115b penetrates from the first vent hole 29V to the tip of the shaft portion in the axial direction. The first air passage 29F and the shaft portion 115c are provided with a second air passage 30F penetrating from the second air hole 30V to the tip of the shaft portion. Further, the spring 116 for urging the piston body 115 that has moved forward to the original position is provided between the flange portion 114c on the rear side of the cylindrical body 114 and the pressing portion 115a.

According to the syringe of such a reference example, from the basic state of FIG. 5A (during non-operation), the push portion 115a is closed with a thumb or the like (blocking the biasing force of the spring 116) while closing the first vent hole 29V. When the push button 115a is pushed while closing the second vent hole 30V, the air in the first chamber 19E is pushed out from the first syringe port 29G. The air in the second chamber 30E is pushed out and air can be supplied. On the other hand, when the pushing operation of the pressing portion 115a is released from the state of FIG. 5B, the first vent hole 29V and the second vent hole 30V are opened, and the piston body 115 is urged rearward by the spring 116. Therefore, outside air is supplied from the first vent hole 29V and the second vent hole 30V through the first vent path 29F and the second vent path 30F into the first chamber 29E and the second chamber 30E, and the piston body 115 is supplied. It automatically returns to the original state of FIG. In this way, by repeatedly operating the pressing portion 115a, air can be supplied from the selected syringe ports 29G and 30G without any restriction on the supply amount.

Also in this reference example, it can be applied to an endoscope apparatus to perform air supply / water supply. In this case, for example, the first syringe port 29G is connected to the first syringe port 29G via a connection tube (23a) as in FIG. Then, the air supply pipe of the endoscope is connected, and the water supply tank 24 may be attached to the second syringe port 30G via the connection tube (23b). According to this, air is supplied from the first syringe port 29G by pushing the push portion 115a while closing the first vent hole 29V, and by pushing the push portion 115a while closing the second vent hole 30V, Water is supplied by supplying air from the second syringe port 30G.

  7 to 10 show the configuration of the third embodiment. This third embodiment has a configuration in which two syringe spaces are arranged in series as in the first embodiment, and can also perform suction. It is what I did. As shown in FIG. 7, the syringe of the third embodiment includes a cylindrical tube body 214, a piston body 215, and a spring 216. The tube body 214 is an inner intermediate portion of the first tube body 214a. The second cylinder 214b is attached so as to abut against the step, and the partition plate 17 is disposed at the tip (step part) of the second cylinder 214b, so that the piston part reciprocates in the cylinder 214. A first chamber 33E and a second chamber 34E are formed as syringe space portions. The first syringe port 33G is provided at the tip of the first chamber 33E (cylinder 214), and the second syringe port 34G is provided on the side surface of the cylinder 214 on the tip side of the second chamber 34E.

  On the other hand, the piston body 215 includes a disc-shaped pressing portion 215a at the rear end thereof and a cylindrical rod-shaped shaft portion 115b having an outer diameter smaller than the inner diameter of the cylindrical body 214, and an inner surface of the cylindrical body 214 at the distal end. A first piston portion (sliding portion) 33P that reciprocates while closely contacting the second piston portion 34P is provided at the intermediate portion. The first and second piston portions 33P and 34P are formed by attaching an annular rubber member 21 for closely contacting the inner surface of the cylindrical body to a fitting portion (for example, an annular groove portion) 215e of a cylindrical rod-shaped shaft portion 215b.

  Further, in the piston body 215, the first vent hole 33V and the second vent hole 34V are formed in the push portion 215a, and the shaft portion 215b penetrates from the first vent hole 33V to the tip of the shaft portion in the axial direction. The first air passage 34F and the second air passage 34F penetrating from the second air hole 34V to the side surface in the middle of the shaft portion are provided.

  In the third embodiment, a configuration for suction is added, and a suction port 35G is provided on the side surface of the cylindrical body 214 below the partition plate 17 on the rear end side of the first chamber 33E. One chamber 33E is also used as a space for suction. That is, the suction port 35G also functions as a vent hole (14d in the first embodiment) for reciprocating the piston body 215 during air supply using the first chamber 33E. In the piston body 215, the third vent hole 35V is formed in the push portion 215a, and the third vent passage 35F penetrating from the third vent hole 35V to the tip of the shaft portion is provided in the shaft portion 215b. Further, the spring 216 is provided between the flange portion 214c on the rear side of the cylindrical body 214 and the pressing portion 215a of the piston body 215 so as to urge the pressed piston body 215 in the direction to return to the original position. It is done.

  In addition, by providing the partition plate (17) on the rear end side of the second chamber 34E, the second chamber 34E is closed, and the suction port (35G) is provided on the rear end side of the second chamber 34E. By forming the third vent hole 35V short, the second chamber 34E may be used as a space for suction, and a fourth vent hole and a fourth vent path are provided, and this second chamber is provided. 34E can be used as a space for the second suction. Moreover, although the 1st thru | or 3rd ventilation holes 33V-35V were arrange | positioned in linear form, they can be arrange | positioned in the circumferential direction like triangular 3 vertex arrangement | positioning.

  FIG. 9 shows a configuration when the syringe of the third embodiment is applied to an endoscope apparatus. In this case, the first syringe port 33G of the cylindrical body 214 (first chamber 33E) The air supply tube of the endoscope is connected via the connection tube 23a, and the water supply tank 24 is attached to the second syringe port 34G (second chamber 34E) via the connection tube 23b. The water supply tank 24 is connected to the connection tube 23c. The water pipe of the endoscope is connected via Further, a suction tank 36 is connected to the suction port 35G via a connecting tube 23d, and this suction tank 36 is connected to a suction tube of an endoscope via a connecting tube 23e.

  According to such a syringe of the third embodiment, when the pressing portion 215a is pushed from the basic state (when not operated) in FIG. 10A while the first vent hole 33V is closed, the first syringe port 33G The air in the first chamber 33E can be pushed out and air can be supplied. When the pusher 215a is pushed while closing the second vent hole 34V, the air in the second chamber 34E is pushed out from the second syringe port 34G. Air can be sent. Further, when the pressing portion 215a is pushed while closing the third vent hole 35V, air flows into the third chamber 34E from the suction port 35G and sucks while exhausting from the first vent path 33F and the first vent hole 33V. It can be performed.

  On the other hand, when the pushing operation of the pressing portion 215a is released from the state shown in FIG. 10B, the first vent hole 33V and the second vent hole 34V are opened and the piston body 215 is moved by the spring 216. Since it is urged to the rear side, outside air is supplied from the first vent hole 33V and the second vent hole 34V through the first vent path 33F and the second vent path 34F into the first chamber 33E and the second chamber 34E. As a result, the piston body 215 automatically returns to the original state of FIG. When the third vent hole 35V related to suction is opened, the air that has flowed into the first chamber 33E is exhausted to the outside through the third vent path 35F and the third vent hole 35V, so that the piston body 215 returns to the original position. In this way, by repeatedly operating the pressing portion 215a, it is possible to perform air supply and suction with no limitation on the supply amount.

  As shown in FIG. 9, when the third embodiment is applied to an endoscope apparatus, for example, by pushing the pressing portion 215a while closing the first vent hole 33V, the endoscope is fed from the first syringe port 33G. Air is supplied to the observation window through the trachea, and the endoscope is passed through the water supply tank 24 by supplying air from the second syringe port 34G by pushing the pressing portion 215a while closing the second ventilation hole 34V. Water is supplied to the observation window through the water supply pipe, and the pushing portion 215a is pushed while closing the third ventilation hole 35V, so that the suction tank 36 and the endoscope suction pipe (and the treatment tool insertion) are inserted from the suction port 35G. A fluid or the like in the observed body is sucked through the channel), and the fluid or the like is stored in the suction tank 36. In these operations, by continuously operating the push portion 215a, air supply, water supply, or suction can be performed from the selected syringe ports 33G to 35G without any restriction on the supply amount.

  11 to 13 show the configuration of the fourth embodiment. This fourth embodiment has a configuration in which two syringe spaces are arranged in parallel as in the second embodiment, and can perform suction. It is what I did. As shown in the figure, the syringe of the fourth embodiment also has a cylindrical cylindrical body 314, a piston body 315, and a spring 316, and the cylindrical body 314 vertically divides the column space into three. By arranging the partition plate 37, a first chamber 39E (a portion hidden behind in the drawing), a second chamber 40E and a third chamber 41E are formed in parallel as a syringe space portion in which the piston portion reciprocates. Is done.

  The third chamber 41E is a closed space portion for suction by closing the upper portion of the cylindrical body 314 with a partition plate 43, and a vent 314d is formed at the distal end side of the third chamber 41E. The A first syringe port 39G is provided at the tip of the first chamber 39E (cylinder body 314), a second syringe port 40G is provided at the tip of the second chamber 40E, and an intermediate portion of the third chamber 41E. A suction port 41G is provided at a position behind a reference (non-operating) position of a piston portion (41P) described later.

  On the other hand, the piston body 315 includes a disc-shaped pressing portion 315a at the rear end thereof and three shaft portions 315b, 315c, and 315d in the form of cylindrical bars, and each chamber 39E is provided at the tip of these shaft portions 315b, 315c, and 315d. A first piston portion 39P, a second piston portion 40P, and a third piston portion 41P that slide while closely contacting the inner surface of ˜41E are provided. The first to third piston portions 39P to 41P are configured by attaching the annular rubber member 21 for close contact with each indoor surface to a fitting portion (for example, an annular groove portion) 315e of the cylindrical rod-shaped shaft portions 315b, 315c, and 315d. It is formed.

  Further, in the piston body 315, the first vent hole 39V, the second vent hole 40V, and the third vent hole 41V are formed in the pressing portion 315a, and the first vent hole 39V is axially formed in the shaft portion 315b. The first air passage 39F that penetrates from the shaft portion to the shaft tip, the shaft portion 315c has a second air passage 40F that penetrates from the second air hole 40V to the shaft portion tip, and the shaft portion 315d has a third air hole 41V. To the vent hole 45 formed on the side surface of the upper portion of the piston portion 41P. Further, the spring 316 is provided between the rear flange portion 314c and the pressing portion 315a of the cylindrical body 314 to urge the piston body 315 that has moved forward in a direction to return to the original position.

  FIG. 13 shows a configuration when the syringe of the fourth embodiment is applied to an endoscope apparatus. In this case, the first syringe port 39G of the cylindrical body 314 (first chamber 39E) The air supply tube of the endoscope is connected via the connection tube 23a, and the water supply tank 24 is attached to the second syringe port 40G (second chamber 40E) via the connection tube 23b. The water supply tank 24 is connected to the connection tube 23c. The water pipe of the endoscope is connected via Further, the suction tank 36 is connected to the suction port 41G via a connecting tube 23d, and this suction tank 36 is connected to the suction pipe of the endoscope via a connecting tube 23e.

  According to such a syringe of the fourth embodiment, when the pressing portion 315a is pushed from the basic state (when not operated) in FIG. 11A while closing the first vent hole 39V, the first syringe port 39G Air in the first chamber 39E can be pushed out and air can be supplied. When the pusher 315a is pushed while closing the second vent hole 40V, the air in the second chamber 40E is pushed out from the second syringe port 40G. Air can be sent. Further, when the push portion 315a is pushed while closing the third vent hole 41V, air can flow into the third chamber 41E from the suction port 41G while exhausting from the vent port 314d, and suction can be performed.

  On the other hand, when the pushing operation of the pressing portion 315a is released from the state of FIG. 11B, the first vent hole 39V and the second vent hole 40V are opened and the piston body 315 is moved by the spring 316 for air supply. Since it is urged to the rear side, outside air is supplied from the first vent hole 39V and the second vent hole 40V to the first chamber 39E and the second chamber 40E through the first vent passage 39F and the second vent passage 40F. As a result, the piston body 315 automatically returns to the original state of FIG. Further, when the third vent hole 41V related to suction is opened, the air flowing into the third chamber 41E is exhausted from the vent hole 45 to the outside through the third vent path 41F and the third vent hole 41V. Thus, the piston body 315 returns to the original position. In this way, by repeatedly operating the pressing portion 315a, air supply and suction can be performed from the selected syringe ports 39G to 42G with no limitation on the supply amount.

  As shown in FIG. 13, when this fourth embodiment is applied to an endoscope apparatus, for example, by pushing the pressing portion 315a while closing the first vent hole 39V, the endoscope is sent from the first syringe port 39G. Air is supplied to the observation window through the trachea, and the endoscope is passed through the water supply tank 24 by supplying air from the second syringe port 40G by pushing the pressing portion 315a while closing the second ventilation hole 40V. The water is supplied to the observation window through the water supply pipe, and the push portion 315a is pushed while closing the third vent hole 41V, so that the suction tank 36 and the endoscope suction pipe (and the treatment tool insertion) are inserted from the suction port 41G. A fluid or the like in the observed body is sucked through the channel), and the fluid or the like is stored in the suction tank 36.

  In the above embodiment, an example in which two syringe space portions related to air supply and one syringe space portion related to suction are provided, but three syringe space portions related to air supply may be provided, and syringe space related to suction is also provided. Two parts may be provided. Further, in the description of each of the above embodiments, the case where the operation is performed by closing one of the vent holes 19V to 41V has been described, but it is also possible to operate by closing two or more.

It is sectional drawing which shows the structure of the automatic reset type syringe which concerns on 1st Example of this invention. It is a disassembled perspective view of the state which cut | disconnected the syringe of 1st Example. It is a figure which shows the structure in the case of applying the syringe of 1st Example to an endoscope. The operation | movement of the syringe of 1st Example is shown, FIG. (A) is sectional drawing at the time of non-operation, FIG. (B) is sectional drawing at the time of pushing operation. The structure of the automatic return type syringe which concerns on a reference example is shown, FIG. (A) is sectional drawing at the time of non-operation, FIG. (B) is sectional drawing at the time of pushing operation. The structure of the syringe of a reference example is shown, A figure (A) is a disassembled perspective view of a syringe, and a figure (B) is a perspective view at the time of non-operation. It is sectional drawing which shows the structure of the automatic reset type syringe of 3rd Example. It is a disassembled perspective view which shows the structure of the syringe of 3rd Example. It is a figure which shows the structure in the case of applying the syringe of 3rd Example to an endoscope. The operation | movement of the syringe of 3rd Example is shown, FIG. (A) is sectional drawing at the time of non-operation, FIG. (B) is sectional drawing at the time of pushing operation. The structure of the automatic return type | mold syringe of 4th Example is shown, FIG. (A) is sectional drawing at the time of non-operation, FIG. (B) is sectional drawing at the time of pushing operation. It is a disassembled perspective view which shows the structure of the syringe of 4th Example. It is a figure which shows the structure in the case of applying the syringe of 4th Example to an endoscope. It is a figure which shows the structure of the conventional endoscope apparatus.

Explanation of symbols

14, 114, 214, 314 ... cylindrical body, 14d, 45, 314d ... vent hole,
15, 115, 215, 315 ... piston body,
15a, 115a, 215a, 315a ... push part,
16, 116, 216, 316 ... springs,
19E, 29E, 33E, 39E ... first chamber,
20E, 30E, 34E, 40E ... second chamber, 41E ... third chamber,
19F, 29F, 33F, 39F ... the first air passage,
20F, 30F, 34F, 40F ... 2nd ventilation path, 35F, 41F ... 3rd ventilation path,
19G, 29G, 33G, 39G ... 1st syringe port,
20G, 30G, 34G, 40G ... second syringe port, 35G, 41G ... suction port,
19P, 29P, 33P, 39P ... 1st piston part,
20P, 30P, 34P, 40P ... 2nd piston part, 41P ... 3rd piston part,
19V, 29V, 33V, 39V ... 1st vent hole,
20V, 30V, 34V, 40V ... 2nd ventilation hole, 35V, 41V ... 3rd ventilation hole.

Claims (3)

A plurality of space portions divided by the partition portion are formed, and a cylindrical body provided with a syringe port in each of the plurality of space portions,
A piston that reciprocates a plurality of space portions in the cylindrical body and has a pressing portion at a rear end thereof, and each of the plurality of space portions communicates with each of a plurality of vent holes provided in the pressing portion. A piston body having a plurality of air passages;
The piston body and disposed between the cylindrical body, viewed including a spring for returning the piston body which is pressed to the original position, and
The plurality of space portions are arranged in series by horizontally dividing the cylindrical body, and in the space portion other than the distal end side space portion, the syringe port is provided on a side surface of the cylindrical body,
The piston body is provided with a piston portion that reciprocates in close contact with the inner periphery of the plurality of space portions of the cylindrical body, and a shaft portion that supports the piston portion and has an outer diameter smaller than the inner diameter of the cylindrical body. Self-returning syringe. A syringe port for air supply is arranged in the front end side space, and in the rear end side space, a suction port is provided on the side surface of the cylindrical body behind the position when the piston portion is not operated. 2. The automatic return type syringe according to claim 1 , wherein both air supply and suction can be performed . A plurality of space portions divided by the partition portion are formed, and a cylindrical body provided with a syringe port in each of the plurality of space portions,
A piston that reciprocates a plurality of space portions in the cylindrical body and has a pressing portion at a rear end thereof, and each of the plurality of space portions communicates with each of a plurality of vent holes provided in the pressing portion. A piston body having a plurality of air passages;
A spring disposed between the piston body and the cylindrical body and returning the pushed piston body to its original position,
The plurality of space portions are arranged in parallel by vertically dividing the cylindrical body,
The piston body includes a piston portion that reciprocates in close contact with the inner periphery of the plurality of space portions of the cylindrical body, and a shaft that supports the piston portion and has an outer diameter smaller than the inner diameter of each space portion of the cylindrical body. Set up a section,
In one of the plurality of space portions arranged in parallel, a syringe port for supplying air is disposed on the tip side of the space portion, and in the other space portion, the piston portion in the space portion is not operated. An automatic return type syringe provided with a suction port on the side surface of the cylindrical body on the rear side of the position so that both air supply and suction can be performed .

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