RU196412U1 - Device for synchronizing the operation of the destructor and the pump for supplying coolant - Google Patents

Abstract

The device relates to medical equipment, in particular, to means for supplying coolant to medical devices and installations and can be used to ensure synchronous operation of destructors with an open cooling circuit and pumps for supplying coolant. The device comprises a pump status sensor, a destructor status sensor, a control pedal state sensor and a control signal generating unit, the first, second and third inputs of the control signal generating unit being connected to the outputs of, respectively, a pump status sensor, a destructor status sensor and a control pedal state sensor, and the first and second outputs are configured to supply control signals to the control inputs of the destructor and pump, respectively. The device achieves the required technical result, which consists in expanding the arsenal of technical means used to ensure synchronous operation of destructors with an open cooling circuit in order to increase the reliability of their work and pumps for supplying coolant in order to economically spend their resources. 3 s.p. f-ly, 1 ill.

Description

The device relates to medical equipment, in particular, to means for supplying coolant to medical devices and installations and can be used to ensure synchronous operation of destructors with an open cooling circuit and pumps for supplying coolant.

The task of developing a device for synchronizing the operation of a cryodestructor and a pump for supplying coolant occurs during the operation of various types of cryodestructors, for example, MedtronicCryoCath, which does not have synchronous control using a pedal, which significantly affects the usability.

The proposed technical solution is applicable to various devices for this purpose and is implemented for the MedtronicCryoCath cryodestructor using a pump status sensor, a cryodestructor status sensor and a control pedal state sensor configured to synchronously supply control signals to the control inputs of the cryodestructor and pump.

A device for supplying a cooling solution to a medical instrument [RU 65376, U1, A61C 19/06, 08/10/2007], comprising a container with an ozonized solution, a channel for supplying an ozonized solution to a dental tip and a channel for supplying compressed air to a container made of an elastic tube, one end of a hermetically sealed container lowered into the gas atmosphere, and the other end connected through a check valve, pressure gauge, tee and control valve with a centralized compressed air system in the stom apparatus of the treatment center, the channel for supplying the ozonated solution to the dental handpiece is also made of an elastic tube, one end immersed in the container and the other through the solenoid valve of the membrane type connected to the dental handpiece, while the device is additionally equipped with a pipe, one end connected to the channel compressed air through a tee, and the second coupled to a membrane valve, mechanically closing and opening the electric circuit, to the cat A power supply and a membrane-type solenoid valve are connected to regulate the supply of ozonated liquid from the tank through the channel for supplying the ozonated solution under the pressure of the air entering the tank.

The disadvantage of this device is the relatively low quality control of the supply of coolant from a limited-capacity tank, since it is not synchronized with the tool, which can cause the solution to cease to be supplied during use.

A device is also known [RU 86454, U1, A61C 19/06, 09/10/2009] containing a container with an ozonized solution, a channel for supplying an ozonized solution to the dental tip and a channel for supplying compressed air to the container made of elastic tubes, while the tube of the channel for supplying compressed air to the container is lowered at one end into the gas atmosphere of a hermetically sealed container, and connected at the other end through a valve to control the supply of ozonized solution to the dental handpiece with a centralized supply system with of compressed air in the equipment of the dental unit, the tube of the channel for supplying the ozonized solution to the dental tip is immersed at one end in the ozonated solution of the container, and the other also through the valve for regulating the supply of ozonized solution to the dental tip, with a dental tip, while the device is equipped with an additional channel for the simultaneous supply of compressed air to the additional channel of the valve from the channel for supplying compressed air to the tank.

The disadvantage of this device is the relatively low reliability of the supply of the solution for cooling the tool, since the solution is not used in a closed cycle, which reduces the reliability of the supply of the solution for cooling the tool, due to the limited volume of the tank, which can cause the supply of the solution to stop during use of the tool.

The closest in technical essence to the proposed one is a device included in the pump control system of a medical device [RU 2618909, C2, А61М 1/10, 05/10/2017], containing a local processing terminal and a remote processing terminal, in which the local processing terminal is configured to transmit collected parameters about the current state of the pump to the remote processing terminal, set in motion and control the pump in accordance with pump control parameters received from the remote processing terminal , in which the remote processing terminal is configured to receive current pump control parameters in accordance with the current state parameters received from the local processing terminal and established control conditions and transmit pump control parameters back to the local processing terminal, in which the local processing terminal further comprises a source power supply, local low battery warning module, configured to generate local information warning of a low battery level warning or confirmation request low battery, if the total value of the charge or voltage DC power source and AC power source is lower than the set value of the charge or voltage level.

The disadvantage of the closest technical solution is the relatively narrow functionality, which does not allow it to be used not only in a single technological chain of control not only of the pump, but also of a medical device (device, instrument) functionally associated with it, which reduces the arsenal of technical means that can be used to ensure the synchronous operation of medical installations, in particular, destructors, and pumps for supplying coolant.

The task, which is solved in a utility model, is the creation of a device that ensures the synchronous operation of destructors with an open cooling circuit and pumps for supplying coolant.

The required technical result consists in expanding the arsenal of technical means used to ensure the synchronous operation of destructors with an open cooling circuit and pumps for supplying coolant.

The problem is solved, and the required technical result is achieved by the fact that, according to the utility model, a destructor status sensor, a control pedal state sensor and a control signal generating unit are introduced into the device containing the pump status sensor, the first, second and third inputs of the control signal generating unit connected to the outputs, respectively, of the pump status sensor, the state sensor of the destructor and the state sensor of the control pedal, and the first and second outputs are configured to feed control signals to the control inputs of the destructor and pump, respectively.

In addition, the required technical result is achieved by the fact that the control signal generation unit when operating in automatic mode generates a pump on signal when the control pedal switches to the depressed state and, after a delay, generates a destructor enable signal and when the control pedal changes from the pressed state, it generates the destructor deactivation signal and after a delay it generates a pump shutdown signal.

In addition, the required technical result is achieved in that the delay is 1-2 s.

In addition, the required technical result is achieved by the fact that the control signal generation unit when operating in manual mode upon the first short-term pressure on the control pedal generates a pump enable signal, when the second pressure on the control pedal generates a destructor enable signal, upon transition of the control pedal from the pressed state forms a deactivation signal for the destructor and, upon subsequent second short-term pressing the control pedal, generates a pump-off signal, moreover, short-term pressing the ped Control l is 1-2.

The drawing shows a device for synchronizing the operation of the destructor and the pump for supplying coolant in conjunction with the control pedal, destructor, pump and pedal.

In the drawing are indicated:

1 - a device for synchronizing the operation of the destructor and the pump for supplying coolant;

2 - a destructor;

3 - pump for supplying coolant;

4 - control pedal;

5 - pump status sensor;

6 - sensor status of the destructor;

7 - sensor status of the control pedal;

8 - block generating control signals.

The device 1 for synchronizing the operation of the destructor and the pump for supplying coolant contains a sensor 5 for the state of the pump, a sensor 6 for the state of the destructor, a sensor 7 for the state of the control pedal and the block 8 for generating control signals.

In the device 1 for synchronizing the operation of the destructor and the pump for supplying coolant, the first, second and third inputs of the control signal generating unit 8 are connected to the outputs, respectively, of the pump state sensor 5, the destructor state sensor 6 and the control pedal state sensor 7, and the first and second outputs made with the possibility of supplying control signals to the control inputs of the destructor 2 and pump 3, respectively.

Block 8 of the generation of control signals is made in the form of a programmable automation device and computer technology and the algorithms for its operation presented below are sufficient for its technical development and programming.

The device for synchronizing the operation of the destructor and pump for supplying coolant as follows.

The device can operate in two main modes - automatic and conditionally “manual”.

When the unit 8 generating control signals in automatic mode, unit 8 generates a signal to turn on pump 3 when the control pedal 4 switches to the depressed state and, after a delay, generates a turn-on signal of destructor 2, and when the control pedal 4 passes from the depressed state, it generates a turn-off signal of destructor 2 and through the delay is generated by the pump shutdown signal 3. The delay is adjustable and is 1-2 s.

When the control signal generation unit 8 is operated in manual mode, when the first short-term pressure is pressed on the control pedal 4, block 8 generates a pump 3 on signal, when the second pedal 4 is pressed on, the destructor 2 is turned on, and when the control pedal 4 switches from the pressed state, it generates a signal switching off the destructor 2 and the subsequent second short-term pressing the control pedal 4 generates a signal to turn off the pump 3. The recommended short-term pressing the control pedal is 1-2 s.

Thus, thanks to the introduced improvements in the device, the required technical result is achieved, which consists in expanding the arsenal of technical means used to ensure synchronous operation of destructors with an open cooling circuit and pumps for supplying coolant. The implemented synchronous operation algorithms provide an increase in the reliability of the destructor (due to the exclusion of its operation without supplying coolant) and the economical use of the pump resource, since its idle operation is practically eliminated.

Claims (4)

1. A device for synchronizing the operation of the destructor and the pump for supplying coolant, comprising a state sensor for the pump, characterized in that the state sensor of the destructor, the state sensor of the control pedal and the block generating control signals, the first, second and third inputs of the block generating control signals are connected to outputs, respectively, of the pump status sensor, destructor status sensor and control pedal state sensor, and the first and second outputs are configured to supply control si signals to the control inputs of the destructor and pump, respectively. 2. The device according to claim 1, characterized in that the control signal generating unit during automatic operation generates a pump on signal when the control pedal switches to the depressed state and, after a delay, generates a destructor enable signal and when the control pedal transitions from the depressed state, it forms an off signal destructor and after a delay generates a signal to turn off the pump. 3. The device according to p. 2, characterized in that the delay is 1-2 s. 4. The device according to claim 1, characterized in that the control signal generation unit when operating in manual mode when the first short-term pressure on the control pedal generates a pump on signal, when the second pressure on the control pedal generates a destructor enable signal, when the control pedal is pressed the state generates a shutdown signal to the destructor and, upon subsequent second short-term pressing the control pedal, generates a pump shutdown signal, moreover, short-term pressing the control pedal is m 1-2.

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