DE1566580B2 - Cycle control for a ventilator - Google Patents

Description

The invention relates to a cycle control for a ventilator according to the preamble of Claim 1.

In an already known cycle control of this type (GB-PS 10 31049) the duration is the Exhalation phase and the duration of the inhalation phase by means of separate valves, but not independently controllable from each other.

It is also a servo control device for influencing a medium flow, which is a line flows through, trained cycle control device with independently controllable cycle times known. The gas flow used for control is dependent on the medium flow to be influenced completely separated (US-PS 27 60 511).

The invention is based on the object of providing a cycle control for a ventilator of the initially introduced to create named genus, in which the control of the cycles or respiratory phases with a special small number of components is effected, so that the manufacturing cost is smaller, the maintenance requirements are lower and the reliability is greater.

This object is achieved according to the invention by the Features of claim 1 solved.

Possibilities for an advantageous further embodiment are given in claims 1, 3 and 4.

A cycle control according to the invention has the advantage that it is of relatively inexperienced Personnel can be operated and has a small number of adjustment knobs.

In the description below is a preferred one Embodiment of a ventilator with the described with the banspruchtsn cycle control and are illustrated in the drawings

F i g. 1 is an elevation view of a ventilator according to the invention,

F i g. Figure 2 is an elevation cross-section taken along line 2-2 of Figure 1;

Fig. 3 An enlarged, schematic representation of the in FIG. 1 and 2 shown ventilator.

In general, the cycle control consists of a first and a second cartridge. Each of the cartridges consists of a body with a flow channel located therein and one in relation to this Flow channel between an open and a closed position adjustable valve in this Body. In the open position, the valve allows fluid to pass through Flow channel and prevents this in the closed position. A device is provided which pushes the valve in a yielding manner into the closed position. Is inside the body a diaphragm mounted and connected to the valve. The body has a chamber that extends on a Side of the membrane is located and serves to accommodate a fluid that is one of the yielding Device in the opposite direction; Can exert force on the membrane. The body wears one Adjustment device to control the flow of pressurized fluid into the chamber control which pressure exert on the diaphragm and the valve against the force of the yielding Can push device into an open position. The ventilator is also provided with devices provided for a pressurized fluid to the flow channel of the first cartridge and to to direct the adjuster of the first cartridge. A line connects the chamber of the first cartridge with one end of the flow channel in the second cartridge. The other end of the flow channel in the The second cartridge can be vented to the open atmosphere through a device. An adjustment device for the fluid pressure is through a line to the other end of the flow channel in of the first cartridge and connected to the adjustment device of the second cartridge. In the second cartridge there is a vent valve in communication with the chamber of the second cartridge. One line connects the other end of the flow channel in the first cartridge to the vent valve around the latter to keep closed during the time in which pressurized air or gas passes through the Flow channel in the first cartridge flows.

The ventilator consists of the

gen shown way from an outer housing II Metal formed by a rectangular box 12 with a rear wall 13 secured by screws 14 with connected to the box.

Inside the housing is an inhalation cartridge 16, an exhalation cartridge 17 and an adjustment device attached for the fluid pressure 18 Also located in the housing 11 is a Setting unit 19 for the inhalation time and a setting unit 21 for the exhalation time 23 with a porous filter cone 20 made of brass is also attached to the housing 11 and can with a source of pressurized fluid, e.g. B. compressed air with a pressure of 3.5 at get connected. Furthermore, there is an outlet connection 24 on the housing U. The supply of air A shut-off valve 26 controls the inlet connection

The inhalation cartridge 16 and the exhalation cartridge 17 are designed essentially the same. Both have a body 31 in which a plunger 32 is displaceably guided. One side of a membrane

33 rests against a membrane plate 27, which in turn pushes against the punch 32 and moves it can. The annular outer edge of the membrane 33 is clamped between the body 31 and an attachment, which is screwed onto the body. The attachment 34 is designed so that between the Membrane 33 and the attachment 34 a chamber 36 is formed. The chamber 28 on the other side of the Membrane 33 is in communication with the atmosphere via a vent 29. The membrane 33 and the plungers 32 are resiliently moved in the direction of the attachment 34 by a spring 37 pressed. One end of the spring 37 pushes against the valve member 38, which is arranged on the plunger 32, and the other end of the spring abuts a cap 39 which is screwed into the body 31 at the other end is. The valve member 38 carries an O-ring seal which is mounted on a smooth compartment or a valve seat 40 which is a part of the body 31. In body 31 there is a pair of threaded bores 41 and 42, which are in communication with a flow channel 43 which leads past the bores 41 and 42 is. The flow channel 43 is sealed off from the chamber 28 by an O-ring seal. How out the drawing can be seen, the flow through the flow channel 43 is controlled by the valve member 38, which can come into engagement with the valve seat 40 and with respect to this between an open and is slidable to a closed position. In the attachment 34 is a pair of threaded holes 44 and 46 arranged. The bore 44 is with a passage 47 in the attachment 34, and the bore 46 is with a passage 48 in the attachment 34 in communication. The passage 48 is through an opening 49 in the Attachment 34 with the chamber 36 in connection.

The setting unit 19 for the inhalation time and the setting unit 21 for the exhalation time are the same essentially identical in design and serve as adjustment devices, as explained below is. Each of these two units consists of a body 51 which is screwed into the attachment 34. In a needle valve 52 is screwed into the body 51 and is inserted into a passage 53 of the body 51. Of the Passage 53 stands with passage 47 in the essay

34 in connection. The body 51 has a cavity or chamber 56 which communicates with the passage 54 is connected which in turn opens into an annular space 55 with the passage 48 of the attachment 34 in Connection is the valve passage 53 forms a connection between the passage 47 and the Chamber 56. When needle valve 52 is moved to an open position, passages 53 and 54 are closed via the chamber 56 in communication with one another. A nut 57 is screwed onto the body 51 this nut 57 is an adjustment knob 58 attached, the

ι »is firmly connected to the needle valve 52, which is on one side with the nut 57 and on the other side with the adjustment knob 58 engaged The cartridge, together with the associated setting unit, is attached to the housing 11 by a nut 62

η attached

There are nozzles 66 and 67 on the exhalation cartridge 17 into the threaded bores 41, or 42 and connecting pieces 68 and 69 into the threaded bores 44, or 46 are screwed into the inhalation cartridge 16

2n nozzles 71 and 72 screwed into the threaded bores 41 and 42 and a nozzle 73 screwed into the threaded bore 46 A vent valve 74 is screwed into the threaded bore 44 of the inhalation cartridge 16. This vent valve consists of a valve body 76 which is screwed into the bore 44. The valve body 76 has a passage 77 which is in communication with the opening 49 and the passage 48 in the attachment 34. The passage 77 opens into a central bore 78 in the valve body 76. This

jo bore is open to the atmosphere through a passage 79 in the valve body. A valve 81 is guided in the valve body 76 displaceably and with respect to the passage 77 between an open and a closed position slidable to the

J5 connection from the passage 77 to the bore 78 and the passage 79 to open or close. The valve 31 is provided with a sealing ring 84 which has a smooth valve seat 85 in the valve body 76 can come into engagement. A diaphragm 86 is through a vent 90 in the valve body held. The ventilation attachment 90 is screwed onto the valve body 76. The membrane 86 can come into contact with a top flange 82 of valve 81 to close the valve.

Between the venting attachment 90 and the membrane 86 is a chamber 87, which with a Passage 88 in the vent 90 is connected. The ventilation attachment 90 has a nipple 89 which a hose can be connected to the valve body.

The adjustment device 18 for the fluid pressure consists of a valve body 91 into which a Needle valve 92 is screwed in. The needle valve is used to block a flow channel 93 through extends the valve body and opens into the threaded bores 94 and 96 in the valve body. In the Bores 94 and 96 are screwed in connection pieces 97 and 98, respectively. The needle valve 92 is with a Adjustment knob 101 provided for its setting, the

bo is the same as the adjustment knob 58 already described. The valve body 91 is fixed to the housing 11 by a nut 102.

The hose or pipe used to connect the various nozzles is in

f> 5 of the illustration of FIG. 3 by dash-dotted lines Lines indicated schematically.

The mode of operation and use of the ventilation device will now be briefly described. Be it

Assume that air or oxygen under a suitable pressure, for example 3.5 at, is passed to the shut-off valve 26 and this valve is open so that the pressurized air enters the inlet port 23. From this inlet port the air goes to the supports 67 and 68 of the exhalation cartridge 17. It is also assumed that at this point in time the exhalation cartridge 17 and the inhalation cartridge 16 are both in the closed position and the exhalation phase ι »is given. First, the exhalation cartridge 17 is actuated. The setting unit 21 for the exhalation time allows the gas entering through the port 68 in a certain, adjustable amount through the passage 47, the chamber 56, the annular space 55, the passage 48, r> the passage 49 into the chamber 36 on one side of the Flow in membrane 33. The time required to fill the chamber 36 and to move the plunger 3'Λ through the membrane so that the valve member 38 located on the plunger is lifted from the valve seat 40 against the force of the spring 37 is determined by the flow velocity into the chamber 3 (i determines which, in turn, can be determined by the position dej; needle valve 52. The position de ·; needle valve 52 in turn is predetermined by the setting 2Ί of the setting knob 58.

After the end of the exhalation time, the plunger 32 is relieved by the pressure of the gas on the Diaphragm 33 shifted and lifts the valve member from its valve seat 40, so that the through the connection 67 κ> inflowing gas can flow into the flow channel 43 and pass through this to the nozzle fifi The nozzle 66 delivers the gas to three different locations. Once the gas reaches the port 98 of the Adjustment device 18 for the fluid pressure ir si which it enters through the connection 98. When open Needle valve 92 goes through the connection 97 to the outlet connection 24 located on the container 11 and through through this to the desired place of use. For example, the gas, according to the ■ »< > Proposals of the simultaneously filed, based on the priority from the US application, Ser.No. 6 01 769 of Anrr.Jdung based on December 14, 1966 to operate an / enturi arrangement to initiate the Ventilation can be used with an anesthesia machine or a resuscitation machine. That of Stutzen 66 released gas also reaches the nozzle 73 of the inhalation cartridge 16. It also becomes a nipple 89 of the vent valve 74 led to the memgran 86 to pressurize and hold the valve 81 in the closed position as long as the valve of the The exhalation cartridge is open.

The gas reaching the nozzle 73 goes through the setting unit 19 for the inhalation time in which the The amount of gas allowed through is adjusted and in which it passes through the passage 47, the passage 53, the Chamber 56, passage 54, annulus 55 and passage 48 into chamber 36 on one side of the Membrane 33 arrives. The rate at which the cavity or chamber 36 is filled depends on the setting of the adjusting knob 58. As soon as the pressure within the chamber 56 is high is enough to overcome the pressure of the spring 37, the valve member 38 is removed from its valve seat 40 lifted and allows a connection between the nozzle 71 and 72, whereby the chamber 36 in the Exhalation cartridge 17 via the connector 69 and 72 with the connector 71 leading to the free atmosphere connected and vented in this way. The spring 37 presses the plunger 32 again immediately right, with respect to the illustration of FIG. 3, so that the valve member 38 again engages the valve seat 40 comes and the connection between the nozzle 66 and 67 is interrupted and thus the inhalation phase is ended.

As soon as the exhalation cartridge is closed, no more gas can reach the port 66 and the Adjustment device 18 for the fluid pressure is no longer supplied with gas. Also no More gas to port 73 or vent valve 74. The pressure in chamber 36 of the inhalation cartridge 16 is through the vent valve 74, the adjustment device 18 for the fluid pressure and delivered through the outlet port 24 to the device connected to the outlet port, such as B. a ventuir arrangement. The pressure within the chamber 36 is high enough to move the valve 81 into a to move the open position, so that the gas located within the chamber 36 through the vent valve 74 can escape. As soon as the chamber 36 of the inhalation cartridge 16 to the free atmosphere is vented, the spring 37 immediately brings the valve member 38 back into engagement with its valve seat. Then the inhalation cartridge 16 and the exhalation cartridge 17 are both in the closed position and the cycle described above is repeated.

In the ventilator described, the inhalation time and the exhalation time can be easily adjusted Way can be adjusted by operating the adjustment knobs 58, which are used to fill the Chambers 36 to set the time required in the corresponding cartridges. Thus, three simple Settings, one for inhalation time, one for exhalation time, and the third for controlling the Flow pressure, or the amount of fluid dispensed through the outlet port 24 all for one Achieve any desired determinable breathing course desired possibilities. The ratio of inhalation time at exhalation time can be changed by simply turning the setting knobs. The maximum Inhalation pressure can easily stand through a certain breathing width of the lungs Turn the adjustment knob to adjust the fluid pressure adjuster. the Use of the vent valve 74, which is only in a relatively short time interval of, for example a few milliseconds allows the inhalation and exhalation times to coincide work together to obtain the desired inhalation and exhalation times. The device works completely in a pneumatic way and can therefore also be used for explosive gases. That under Pressurized gas actuates the cartridges.

1 sheet of drawings

Claims (4)

Patent claims: 1. Cycle control for a ventilator with a source of pressurized ventilation gas, from which a line to the patient, the gas flow rate of which is adjustable by means of a valve for the ventilation pressure, is released and closed, and with pneumatic control elements in which one is prestressed by spring pressure , a chamber closing membrane actuates a control valve, the cycle time being predetermined by adjusting valves in the lines leading to the membrane chamber, characterized in that two essentially identical control members, an inhalation cartridge (16) and an exhalation cartridge (17), are provided, wherein the inlet (67) of the control valve (35, 38, 40} and the inlet (68) of the setting valve (28) of the exhalation cartridge are connected to the gas source (inlet port 23) , the outlet (66) of the control valve on the one hand to the patient connection (24) ) and on the other hand with the input (73) of the adjusting valve (19) and with the control input ang (88) of a vent valve (74) is connected to the outlet of the diaphragm chamber of the inhalation cartridge (16), and the diaphragm chamber (36) of the exhalation cartridge (17) is vented via the control valve in the inhalation cartridge (16). 2. Cycle control according to claim 1, characterized by an adjusting device (18) for the Gas pressure or for the amount of gas released by the device during the inhalation phase in the Line between the inhalation and exhalation cartridges (16 or 17) and the outlet port (24) of the device, which has an adjustable valve (92) in a flow channel (93). 3. cycle control according to claim 1, characterized in that each of the Beirlen control members (16 or 17) a membrane chamber (36) within an assembled cylindrical body (31, 40), at one end of which is actuated by the membrane (33) via a plunger (32) Control valve (38) with a tensioning device (37) and the adjustable valve at the other end (92) is arranged. 4. Zyklusstei'.erung according to claim 2 or 3, characterized in that the adjustable valve is designed as a needle valve (92).