CS254667B1 - Insemination large capacity hydrosensor - Google Patents

Abstract

The solution concerns an insemination large-capacity hydrosyringe. The insemination hydrosyringe consists of a body in which a working cylinder and a hydraulic cylinder are formed. An insemination needle is placed in the working cylinder by means of a replaceable extension, and in the hydraulic cylinder, by means of a system of sealing rings and a bushing, there is a modified piston, equipped at the protruding end with a thread that engages with a thread formed on the bushing. At the fitted end of the body, a venting hole closed by a valve is formed in the radial direction. The high-capacity insemination syringe is mainly suitable for technical insemination of queen bees.

Description

The solution relates to an insemination large-capacity hydrosyringe. The insemination hydrostyring consists of a body in which a working cylinder and a hydraulic cylinder are formed. An insemination needle is disposed in the working cylinder by means of a replaceable extension and a piston is provided in the hydraulic cylinder by means of a set of sealing rings and a housing, provided at the projecting end with a thread engaging the thread formed on the housing. A venting opening is formed in the radial direction at the stepped end of the housing and is closed by a valve.

Insemination large capacity syringe is suitable mainly for technical insemination of bee mothers.

<3

The present invention relates to an insemination large capacity hydrosyringer suitable for the technical insemination of bee mothers.

Various types of insemination syringes are currently used for the insemination of bee mothers. A syringe is known where the suction effect of the syringe is caused by the stretching and contraction of a flexible rubber membrane which is mechanically controlled. The theoretical volume of the insemination needle is 10 to 12 μΐ. The optimal insemination dose for the bee mating is 8 to 10 µA of semen sperm. A syringe with an open hydrosystem with a metal plunger, which is sealed with one rubber sealing ring housed in a circular groove of the syringe body. The volume of the insemination needle can be increased by the volume of the working cylinder of the insemination syringe. Syringe whose rubber plunger has two sealing rings with a smaller diameter ring. The piston is screw operated. The volume of the insemination needle after adjusting the opening can be increased by attaching a glass capillary tube using a plastic tube. A syringe where the suction effect is induced by stretching and contraction of an enlarged elastic rubber membrane mechanically actuated. The volume of the glass capillary insemination needle is about 50 µl. The glass needle is fixed to the syringe body by the adapter, the needle extending almost the entire length from the adapter body in front of the syringe. The drawbacks of the known hydrostructure designs are that the suction effect of the syringe depends only on the poor elasticity of the rubber membrane. Frequent occurrence of rubber membrane loosening or puncture will destroy the spermatozoa. The insemination needle must be cleaned and the entire sperm collection process repeated. The suction power of the larger diaphragm syringe allows about 40 μm of sperm to be aspirated, but there is a withdrawal of dosage for individually inseminated mothers. When inserting the plunger, the N insemination syringe with a rubber plunger encloses air in the annular ring of the plunger, which, under vacuum in the syringe body, penetrates into the working cylinder and causes an explosive movement of the aspirated sperm column. A metal-piston insemination syringe with one sealing ring in high-volume sperm collection suffers from a failure rate as a rubber-piston syringe. The insemination syringe, whose translucent working cylinder is inserted into the metal housing with the inspection window, is difficult to vent because the unobserved air bubble is causing malfunctions, as already mentioned in the previous types. The syringes used are structurally adapted either to needles calibrated from a threaded plastic inert material or to needles made of a glass capillary with one end adapted for insertion into the bee's genital tract. The universal clamping of various needles on one insemination syringe body has not been addressed.

The aforementioned disadvantages are overcome by the high-capacity insemination hydrostrainer according to the invention, which is characterized in that a working cylinder is formed in the body in which the insemination capillary is arranged by means of a replaceable extension screwed onto the adherent end of the body. From the opposite end, a hydraulic cylinder is formed in the body, in which a piston is provided by means of a set of sealing rings and a housing, provided with a screw at the projecting end, terminated by a control knob and embedded in a nut provided in the housing. A venting opening is formed in the radial direction at the stepped end of the body, closed by a valve. A positioning pin is formed on the control knob to meter the individual insemination doses. A further object of the invention is that an insemination needle is screwed in the removable extension in which a capillary is provided for making canned spermatozoa.

The advantages of the large-capacity insemination hydrostructuring device according to the invention are, in particular, that the working piston seal is controllable and maximally effective. Sperm dosing for one mother is controllable visually on the pin and by the touch of the piston control knob. At the option of the operator, needles can be used calibrated from plastic inert threaded or glass, protected from damage by insertion into the syringe body. Throughout the length of the syringe barrel through the translucent wall, it is possible to check for undesirable aeration of the working hydraulic cylinder as well as of the inserted needle or capillary. The large capacity syringe allows the collection of sperm from the stools in large quantities. at the optimum time of flight of the tails and at the same time making canned goods with the tails of sperm, without breaking the pinch of sperm in the needle or capillary when vacuuming or inserting it carefully into the body of the syringe.

An exemplary embodiment of the invention is shown in the accompanying drawing, in which FIG. 1 shows a longitudinal section through a large-capacity hydrotrayer, FIG. 2 shows a cross-section of a clamping collar for a threaded insemination needle, and FIG. 3 is a cross-sectional view of the clamping collar of FIG. 2 for an insemination needle with a thread and an extended glass capillary.

The body 1 can be made of block methyl methacrylate of cylindrical shape. Its outer part at the front end is of reduced diameter and is provided with a thread 30 on the surface to which the insemination needle 21 made of a large capacity insemination glass capillary or a insemination needle 24 made of a plastic inert material is fastened by screwing the replaceable extension 10. On the front smaller diameter of the syringe body 1 after the thread, a vent hole 28 is drilled from 254667 to equalize the pressure in the working cylinder 16 and atmospheric pressure while removing the insemination needle 21 made of a high capacity insemination glass capillary after filling with sperm. The breather opening 28 is closed by a flat rubber valve 14 controlled by a screw 15 in the metal sleeve 12. The other end of the body 1 is threaded in the bore 29 for fastening the piston housing 5. The inner part of the body 1 has a bore hole forming a hydraulic cylinder 17 and working cylinder 18 A set of silicone rubber sealing rings 7 divided by metal rings 6 and an end thrust ring 8 is disposed between the face of the sleeve 5 and the hydraulic cylinder 17. The position of the sleeve 5 is fixed by a nut 9. The pressure of the sleeve 5 on the sealing rings 7 should be such that it has forced air out of the sealing ring system 7 while the frictional resistances between the sealing rings 7 and the piston 2 were small, but in order to guarantee an airtight fit of the hydraulic device. At the initial setting when the syringe is filled with functional fluid, the piston platoon 2 must be flush with the sealing ring 7. On the front end of the body 1 a metal clamp 12 with yoke 13 with a flat rubber valve 14 is pushed and the working cylinder 16 is filled with functional fluid until of the front part of the body 1 without closing the air bubble. If functional fluid starts to flow through the vent 28 under the flat rubber valve 14, air is also expelled from the vent 28, which is closed by tightening the screw 15. The insemination needle 21 is inserted into the removable extension 10 so that the insemination needle 21 slid the thick-walled seal 11. The syringe bodies 1, when filled with the functional solution and insertion of the insemination needle 21, are in a vertical position so that the front end faces upward. The insemination needle 21 is inserted slowly into the body 1 to prevent the air bubble from closing in the working cylinder 16. By screwing the replaceable extension 19 at the pressure of the cylindrical end 22 on the body 1, the plastic seal 11 expands spatially thereby fastening the insemination needle 21 and sealing The excess liquid from the working cylinder 16 flows both around the plastic seal 11 and, after sealing the vent hole 28 of the body 1, the insemination needle 21. By rotating the screw 3 of the piston 2 behind the control knob 23, the piston 2 is inserted. by means of a screw 3 and a nut 4 into the hydraulic cylinder 17, the functional fluid being forced out through the opening of the insemination needle 21.

As much liquid as possible is expelled from the hydraulic cylinder 17, as much as the sperm must be sucked into the insemination needle 21. The piston 2 should be in a position in the hydraulic cylinder 17 such that the sperm is sucked up and pushed out. By reversing the control knob, and 23 on the screw 3 of the piston 2 counterclockwise, the sperm is sucked into the insemination needle 21. The air gap left prevents mixing of the functional liquid and the spermatozoa. Theoretically, the maximum power of the syringe is 471 μ1. The actual volume of aspirated sperm depends on the length and inner diameter of the inner opening of the insemination needle 21. When using a threaded insemination needle 24, the rubber seal 19 and the other threaded seal hole are inserted into the front threaded portion of the replaceable extension 10 by means of tweezers. 20. Both seals 19, 20 having a center hole are placed in a recess in the interchangeable cap 10 which is screwed onto the insemination syringe body 1 and the functional fluid is pushed through the plunger 2 up to the top of the threaded portion in the interchangeable cap 10. the insemination needle 24, the excess liquid being pushed through its opening. Sperm aspiration and extrusion are performed as for a glass insemination needle 21. An insemination needle 24 made of a plastic inert substance is calibrated in 2 µl to determine the exact insemination dose. By using an insemination needle 24 of a plastic inert material, it is possible to increase the useful volume by adjusting the capillary 26.

A plastic case 25 is inserted into the plastic insemination needle hole 24 and a capillary 26 is inserted into the plastic case hole 25 to connect it to the insemination needle 24. By loosening the rubber valve 14 by screw 15, the pressure in body 1 with atmospheric pressure is equal. thus, the insemination needle 21 or the insemination needle 24 can be unscrewed together with the capillary 26 without breaking the sperm column for the purpose of making canned sperm. Individual insemination doses of 9.42 υλ are measured with a positioning pin 27 on the control knob 23 by rotating the knob 180 ° clockwise.

The use of an open hydrosystem insemination spraying syringe is advantageous both under laboratory conditions for the production of canned spermatozoa and, in particular, for the formation of lines. Thus, one line of 12-15 bee mothers may be inseminated with sperms accumulated in a single large-capacity glass insemination capillary, or an ordinary capillary connected to a plastic inert substance insemination needle. In large-scale breeding operations, massive insemination results in large time losses due to the sucking of sperm for one mother and the re-setting of the insemination device to the mother's reinsertion and careful adjustment to suction. Using a multi-capacity syringe, sperm is collected at the optimum time of flight of the streamer and irrespective of the time of day and weather, the mothers are inseminated. For precise iaboratory work on the lower price of a glass insemination capillary glass as compared to a plastic inert substance insemination needle.

A calibrated insemination needle of plastic inert material may be used in a syringe. A significant advantage is also essential

Claims (2)

SUBJECT An in-symmetrical large-capacity hydrospray, characterized in that a working cylinder (16) is formed in the body (1), in which an insemilization capillary (21) is provided by a replaceable extension (10) screwed on the shoulder end of the body (1). 17), in which a piston (2j) is provided by means of a set of sealing rings (7) and a bushing (5), provided with a protruding end screw (3) terminated by a control knob (23) and housed in a nut (4) provided in the bushing YNALEZU (5), wherein a vent hole (28) formed in the radial direction is closed in the radial direction by a valve (14) and a positioning pin (27J) is formed on the actuator knob (27) for metering individual insemination doses. 2. The high-capacity insemination hydrostructuring device according to claim 1, characterized in that an insemination needle (24) in which the capillary (26) is provided for making canned sperm cans is screwed in the replaceable extension (10). 1 sheet of drawings Fig. 1 ‘24/920) ι Obr.Ž 24 25/9 20/0 25