FI126277B - Valve arrangement for individual instrument seats in a dental care unit - Google Patents

Description

INSTRUMENT LOCATION VALVE SYSTEM IN DENTAL MACHINE TECHNOLOGY

The present invention relates to a valve arrangement in accordance with the preamble of claim 1 in connection with a dental machine, in particular with a dental apparatus provided with a plurality of instrument positions.

BACKGROUND OF THE INVENTION

A variety of rotating and other hand instruments are used in dental work, which are powered by so-called. from a dental appliance or other external source. In addition to electricity, such instruments are commonly powered by compressed air. Instruments, as well as the objects to be treated with them, must typically be cooled, for which it is known to use compressed air and / or water. Control of dental instruments typically involves not only controlling their actual function but also controlling the cooling of the instrument or workpiece.

Typically, a dental appliance has a foot controller that provides air travel to the instruments and so-called. the pressure of the cooling spray (air and water) is controlled either by means of valves arranged in the foot controller or indirectly, for example, by an electronic control system and solenoid valves.

Because the foot control typically has only one foot control and multiple instruments, a valve arrangement is required to control multiple instruments. For this purpose, e.g. arrangements based on individual flow channel solenoid / spool valves, pressure-controlled diaphragm valves, and combinations thereof.

Flow channel-specific solenoid / spool valve arrangements are proven solutions, but when required one per channel, the arrangement becomes relatively expensive.

Diaphragm valve arrangements are significantly less expensive than solenoid / spindle valve arrangements. The diaphragm valves are controlled, for example, by pressure controlled by valves arranged in connection with the instrument holders and foot control or by solenoid valves controlled by the treatment machine control system.

However, diaphragm valves have certain problems, especially when used to control water flow. For example, if only a small pressure is to be applied to the waterline to provide a small flow of liquid, there is a risk that this pressure will not be sufficient to open the diaphragm valve. On the other hand, when closed, the diaphragm valve causes a pumping effect in the waterline, which can result in water dripping from the tip of the instrument - possibly with a delay - for example, after the instrument is discontinued and placed on the dental instrument table. The diaphragm valve arrangements are also typically implemented such that, when the system is shut down, the diaphragm valve remains open, which may result in undesired, uncontrolled dripping of water as the trapped water flows out of the system, e.g., to the treatment room floor.

In some cases, the instrument's water channels are provided with their own water valves, other than diaphragm valve technology. However, in a dental machine environment with multiple instrument locations, such solutions are relatively expensive when three valves may be required for each instrument location, e.g., a diaphragm valve for pneumatic lines, a second valve for controlling diaphragm valve operation, and a third for a water line. On the other hand, if the water valve has metal components, the water may, over time, cause its own problems with valve operation.

US 5,201,899 discloses an arrangement using a pressure-controlled disc valve for controlling the flow of water, which is moved directly by the air pressure and piston at the back of the diaphragm. In this solution, the flow of water is prevented by the loss of control pressure, a desirable feature for uncontrolled dripping of water from the instrument. On the other hand, when the control pressure is required to open the water valve and when the diaphragm valves used to control the air pressure of the arrangement require the control pressure to be released to open in order to open the control valve, this arrangement requires two inverse control pressures. The arrangement employs moving and sliding sealing solutions which, in order to function properly, require strict manufacturing tolerances and are susceptible to wear.

SUMMARY OF THE INVENTION

It is an object of the present invention and its preferred embodiments to provide a novel solution for a dentist instrument-type valve arrangement. The object is a valve arrangement, one component of which is an inexpensive diaphragm valve structure, and in which the structure of the valve arrangement and its control as a whole have been implemented with particular regard to e.g. water dripping and arrangement sealing problems. In the arrangement, the supply of compressed air to the instrument can be controlled by an inexpensive diaphragm valve structure and, on the other hand, a separate and expensive valve is not required for water supply only, but the control of diaphragm valve operation and possible water supply to the instrument and / or workpiece with a defined multifunction valve structure.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 shows a typical dental machine comprising a plurality of instrument positions for dental instruments.

Figure 2 shows the selection valve blocks according to the invention as part of a dental pneumatic diagram.

Figures 3a and 3b show a selector valve block according to one embodiment of the invention in two different modes of operation.

DETAILED DESCRIPTION OF THE INVENTION

Embodiments of the invention shown in the accompanying figures will now be described. A list of components with reference numerals in the figures is found at the end of this specification.

Figure 1 shows dental instruments arranged in a typical dental machine. The dental appliance of Fig. 1 comprises a frame (2), a patient chair (3) and a cantilever arm (4) extending from the frame (2). At the end of the bracket arm (4) is arranged an instrument bracket (6) in which are placed handpieces or instruments (301), such as, for example, toothpicks and other hand instruments used in dental care. The handpieces or instruments (301) are connected to the instrument console (6) via instrument tubes (7). The physical quantities required for operating the instruments are obtained from the treatment machine through the connections through the instrument hoses (7) and the cantilever arm (4). In one embodiment of the invention, the selection valve blocks, which will be described in more detail below, are provided in the instrument console (6) at each of the instrument locations.

Fig. 2 is a pneumatic diagram illustrating an arrangement for implementing a preferred embodiment of the invention, and Figs. 3a and 3b are a cross-sectional view of the selector valve block (200, 300) available in the solution of Fig. 2 in two different operating steps. In Fig. 3a, the valve block (300) is shown in an operating state in which its actuator (305) is not activated and in Fig. 3b in an operating state in which the actuator (305) is activated.

Thus, the term selector valve block herein refers to a dental machine instrument (location) specific distribution channel arrangement and associated valve arrangement. Typical basic functions of such an arrangement are (i) opening and closing the flow connection between the spray water supply channel (250, 350) of the handpiece / instrument (201, 301) and the adjustable pressure water supply channel (50) of the entire pneumatic arrangement; , 301) between the air channels (220, 320, 230, 330) and the air supply channels (20, 30) of the entire pneumatic arrangement; and iii) open and close the flow connection of the handpiece / instrument (201, 301) without the return channel (240, 340) drive air return, in the case of a micromotor, cooling air return) and all pneumatics between the return air duct (40) of the arrangement. To provide these functionalities, the arrangement of the attached figures includes a rocker valve type valve (202, 302) arranged in a water line, a diaphragm operated airline valve valve (203, 303) and a spool valve (204, 304) arranged to control its control pressures. The arrangement further comprises an actuator such as a solenoid or an electromagnet (205, 305).

The accompanying figures also show a static control air pressure conduit (10, 360) and a control air pressure conduit (260, 360) to the rear of the diaphragm valve structure (203, 303) relative to the instrument air channels (220, 320, 230, 330, 240, 340). a silencer duct (209, 309), instrument / control air (drive air) and water control / proportional valves (21, 31, 51) for the entire pneumatic arrangement, and a return air silencer and oil separator / collector (49).

In the embodiment of Figures 3a and 3b, the valve block (300) further comprises the valve components (302.N, 303.N, 304.N) listed at the end of this specification. The reference numeral (310) in turn refers to the interior of the spindle valve (304) in these figures.

When the actuator (305) is inactive (i.e., in practice when the instrument (301) at the instrument position associated with the block (300) is not in use, cf. Fig. 3a) the spool valve (304) is open (so-called normally open operation). the pressure of the pressure supply channel (10) is applied to the diaphragm (303.3) of the diaphragm valve (303). The design return spring (304.1) of the main spindle valve spindle (304.2) is arranged stronger than the return / close spring (304.6) of the spindle auxiliary spindle (304.5), whereby the inlet port stop seal (304.4) provided on the auxiliary spindle (304.5) 310) and the air pressure supply duct (10). On the other hand, the shutoff seal (304.3) of the spool valve outlet port in this situation closes the flow connection to the control air pressure sound attenuation channel (309), whereby in this mode of operation the air channels (320, 330, 340) 40) the connection is closed.

On the other hand, the force of the selective (swing) valve (302) closing spring (302.1) keeps the arrangement in its lower (normally closed) position of the rocking lever (302.2) and its associated sealing / closing diaphragm (302.3), thereby causing water (pressure) ) access from the supply channel (50) to the handpiece / instrument water supply channel (250, 350) is prevented.

When actuated, such as a solenoid (305), it overcomes the force of the return spring (304.1) and the main spindle (304.2) of the spindle valve structure (304) moves to the right (Fig. 3b). At the same time, the supply port sealing gasket (304.4) shifts to the right from the auxiliary spindle return / closing spring (304.6), closing the control air pressure channel (360) connection to the static pressure supply channel (10). Further, as the main spindle (304.2) moves to the right, the outlet port sealing gasket (304.3) also moves to the right, whereby the connection from the spool valve interior (310) to the control air pressure silencer channel (309) is opened and control pressure affecting the diaphragm valve diaphragm (303.3). Thus, the diaphragm valve diaphragm (303.3) is free to succumb to possible pressures in the air passages (20, 30, 40) and thereby open the connection to the air passages of the handpiece / instrument (320, 330, 340).

On the other hand, as the main spindle (304.2) moves to the right, it captures the rocker valve rocker lever (302.2) which thus rotates about its shaft (302.4) and opens the connection between the water supply channel (50) and the handpiece / instrument water supply channel (350).

If the actuator (305) of the valve arrangement described above is arranged to be actuated, for example, in response to lifting the handpiece / instrument (301) from the instrument table (6) comprising a plurality of instrument positions of the dental unit, water and / or air can now be delivered to said handpiece / instrument. 2, through the proportional valves (21, 31, 51) according to what is required to operate the instrument provided in said instrument compartment.

The functionality of the valve arrangement described above may be conceivable by other structural details than those set forth above. For example, the actuator can be arranged to move the rocker valve instead of the rocker valve and the movement of the rocker valve is executed as a function of the rocker valve movements. However, the arrangement thus essentially comprises flow channels (220, 320, 230, 330, 250, 350) for water and air leading to the handpiece / instrument (201, 301), supply or discharge channels (20, 30, 40, 50) of said flow channels, a diaphragm valve structure (203, 303) and means for controlling the diaphragm valve structure, the means including an air pressure channel (10, 360) leading to the diaphragm valve structure. In the arrangement, at least one of the flow channels (10, 20, 30, 40, 50, 220, 320, 230, 330, 240, 340, 250, 350, 260, 360) is arranged to be closed by a diaphragm valve structure (203, 303) and a diaphragm valve structure (203, 303). 203, 303) is arranged as a functional part of the multi-function valve structure (300). The multifunctional valve structure further comprises a spindle valve structure (204, 304) and a rocker valve structure (202, 302) comprising means (304.2, 304.5, 302.2) for opening and closing flow connections, wherein the movements of said means (304.2, 304.4, 302.2) are arranged. and by means of the same actuator (205, 305).

In various embodiments, the operation of the rocking valve structure (202, 302) of the valve arrangement may be arranged to depend on the operation of said spindle valve structure (204, 304), or vice versa. The operation of the rocker valve structure (202, 302) relative to the spindle valve structure (204, 304) may be arranged such that the rocker valve structure (202, 302) is closed when the spindle valve body (304.2, 304.5) is in an inactive state. The power transmission structure included in the rocking valve structure (202, 302), such as the rocking lever (302.2), may be arranged to be movable controlled by the movements of the spindle valve structure (304.2, 304.5) and the actuator (205, 305) to move the spindle valve structure (204, On the other hand, the spindle (304.2, 304.5) of the spindle valve structure (204, 304) may be arranged to be movable controlled by the movements of the rocking valve power transmission structure (302.2) and the actuator (205, 305) to move said rocking valve structure (202, 302). The spindle valve structure (204, 304) may form a 3/2 valve and the rocker valve structure (202, 302) a 2/2 valve, or vice versa.

On the other hand, with respect to the flow channels (220, 320, 230, 330, 240, 340, 250, 350) leading to the handpiece / instrument (201, 301), at least one may be a flow channel for water (50, 250, 350) specifically, a rocking valve structure (202, 302) is provided. The diaphragm valve structure (203, 303), in turn, may be arranged to comprise at least two diaphragm valves, each of which is arranged to close one airline passage (220, 320, 230, 330, 240, 340). One of the air channels may be a spray air channel (220, 320) for the handpiece / instrument (201, 301), one drive or cooling air channel (230, 330) for the handpiece / instrument (201, 301) and one return air channel (240, 340), wherein said diaphragm valve structure (203, 303) may comprise a diaphragm valve provided on each of these channels (220, 320, 230, 330, 240, 340).

Operation of the spindle valve structure (204, 304) with respect to said diaphragm valve structure (203, 303) may be arranged such that, when the spindle valve structure is in an unactivated state, each valve of the diaphragm valve structure (203, 303) maintains its respective channel (220, 320, 230). , 240, 340) closed. The arrangement may thus include a first control air duct (10) in connection with the interior space (310) of the spindle valve structure (204, 304), which communication between the interior space (310) of the spool valve structure (204, 304) and the first control air channel (10) 305), and a second control air duct (360) between the interior space (310) of said spindle valve structure and the diaphragm valve structure (203, 303), the connection from said first control air duct (10) to the interior space (310) of the spool valve structure (204, 304); 203, 303) is arranged to be open when the actuator (205, 305) is inactive, and closed when the actuator (205, 305) is active.

One of the advantages of the above arrangement is that the flow of water to the instrument is prevented whenever the actuator of the arrangement is not activated. Thus, no typical malfunction, such as loss of pressure, can cause unwanted water leakage.

On the other hand, there is no need to use sliding sealing surfaces in the solution, whereby seals are not the most critical components of the structure in terms of manufacture and wear. Implementing seals with rocking and spindle valves with compressible seals as described above provides a solution in which the fabrication tolerances of the structure can be loose and where wear and deformation of the seals are compensated. The arrangement is economically advantageous when only one 3/2 solenoid valve and a rocking valve functionally connected thereto are required to control it per instrument package. Inexpensive diaphragm valves can be used to supply compressed air to the instruments and control of the diaphragm valve operation on the one hand and water to the instrument can be implemented by a valve structure whose operation is based on spindle and rocker valve principles which have proven to work in other contexts. The arrangement is also directly applicable to a conventional pneumatic control system and can be implemented completely or almost completely without metal components.

REFERENCE NUMBERS USED IN THE FIGURES 1 Air Pressure Supply (eg 5 bar) 5 Water Pressure Supply (eg 3.5 bar) 10 Static Pressure Supply Channel (Air) 20 Adjustable Pressure Supply Channel (Air Instrument Spray) 21 Adjustable / Proportional Valve (Air Instrument Spray) 30 Adjustable Supply duct (drive air) 31 Adjustment / proportional valve (drive air) 40 Return air duct 49 Return air muffler and oil separator / collector 50 Adjustable pressure supply duct (water instrument sprayer) 51 Adjustment / proportional valve (water instrument sprayer) 200.3 Valve valve1.300 Valve valve 200.3 micromotor, turbine, light cure 202.302 Rocker valve type selector valve (water-instrument spray) 203.303 Diaphragm selector valve (spray, drive and return air) 204.304 Control pressure spindle valve for diaphragm valve (air) 205.305 actingOne, 20mm, 30mm, 30mm actuator / instrument feeder (air instrument spray) 230,330 Handpiece / instrument feeder (turbine drive air; micromotor cooling air) 240,340 Handpiece / Instrument return duct (turbine driven air; micromotor cooling air) 250,350 Handpiece / Instrument Inlet duct (Water Instrument Spray) 260.360 Keyless airflow 302.1 Keivent Rocker Valve Shaft 303.1 Diaphragm Valve Top 303.2 Diaphragm Valve Diaphragm 304.1 Diaphragm Valve Main Spindle Return Spring 304.2 Spindle Valve 304.3 Spindle Valve 304.4 Shaft Valve 304.4 Shaft Valve 304.4 Shaft Valve

Claims (13)

1. Etc for individual instrument sites intended for valve ranking in a dental care unit, which arrangement includes flow channels {220, 320, 230, 330, 240, 340, 250, 350} for the air and air that lead to your toothpick / instrument (201, 301), the flow or dissolution channels (20, 30, 40, 50) of the flow channels in question, a diaphragm valve structure (203, 303) and means for controlling the diaphragm valve structure, to which means an air pressure duct (10, 360) leading to the diaphragm valve structure, and in which at least one of said flow channels (10, 20, 30, 40, 50, 220, 320, 230, 330, 240, 340, 250, 350, 260, 360) is arranged closable with said diaphragm valve structure (203, 303), characterized in that said diaphragm valve structure (203, 303} is arranged as a functional part of a multifunction valve structure (200, 300), to which belongs a further piston valve structure (204, 304) and a flip-flop valve. il construction (202, 302) comprising means (304.2, 304.4, 302.2) for opening and closing flow channels and in which the movements of said means (304.2, 304.5, 302.2) are arranged to be realized by means of one and the same actuator (205, 305). 2. A valve arrangement according to claim 1, characterized in that the operation of said rocker valve structure (202, 302) is arranged to be dependent on the operation of said piston valve structure (204, 304), or vice versa. 3. A valve arrangement according to claim 2, characterized in that the operation of said rocker valve structure (202, 302) in relation to the operation of said piston valve structure (204, 304) is arranged so that when the piston of the piston valve structure (304.2, 304.5) is inactive. position, the rocker valve assembly (202, 302) is closed. A valve arrangement according to any one of claims 1-3, characterized in that a piston (304.2, 304.5) is included in said piston valve structure (204, 304) and in said said pivot valve structure (202, 302) a pivot valve or other power supply structure (302.2). f) which is arranged movable, controlled by the piston (304.2, 304.5) piston movements. A valve arrangement according to any one of claims 1 to 4, characterized in that said actuator (205, 305) is arranged to touch the piston (304.2, 304.5) of said piston valve assembly (204, 304). 6. A valve arrangement according to claim 1 or 2, characterized in that said rocker valve art structure (202, 302) includes a rocker valve or other power transmission structure (302.2) and said coil valve structure (204, 304) a piston (3C4.2, 304.5). , which is arranged to move when guided by the movements of said power transmission structure (302.2). A valve arrangement according to claim 6, characterized in that said actuator (205, 305) is arranged to touch said rocker valve structure (202, 302). A valve arrangement according to any one of claims 1 to 7, characterized in that at least one of said flow channels (220, 320, 230, 330, 240, 340, 250, 350) leading to a handpiece / instrument (201, 301) is intended for water (50, 250, 350), in functional connection with which said rocker valve structure (202, 302) is arranged. A valve arrangement according to any one of claims 1 to 8, characterized in that said diaphragm valve structure (203, 303) is arranged to include at least two diaphragm valves, each of which is arranged to close an air duct (220, 320, 230, 330). , 240, 340). A valve arrangement according to claim 9, characterized in that one of said channels is the handpiece / instrument (201, 301) spray air duct (220, 320), one is the handpiece / instrument (201, 301) drive or cooling air duct (230, 330). ) and a return air duct (240, 340), and said membrane valve assembly (203, 303) includes a diaphragm (3G3.3) arranged in conjunction with each of these ducts (220, 320, 230, 330, 240) , 340}. 11. Your valve arrangement according to claim 9 or 10, characterized in that the operation of said piston valve construction (204, 304} in relation to said diaphragm valve structure (203, 303) is arranged so that when the piston valve structure is in non-activated position, each valve keeps each in the diaphragm valve structure its channel (220, 320, 230, 330, 240, 340; closed). 12. A valve arrangement according to any one of claims 1 to 11, characterized in that the arrangement is included in) a first control air duct (10) which communicates with the inside (310) of the cylinder (204, 304), which interconnects the said valve valve structure ( 204, 304) inside (310) and said first control air duct (10) is arranged closable by said actuator (205, 305), and ii) a second control air duct (360) between the inside (310) of said piston valve construction and said diaphragm valve assembly (203, 303), which connection from said first control air duct (10) to the inside (310) of said piston valve assembly (310) and further to the diaphragm valve assembly (203, 303) is arranged to be open when the actuator (205), 305) is inactive, and closed when the actuator (205, 305) is active. A valve arrangement according to any one of claims 1 to 12, characterized in that said piston valve structure (204, 304} constitutes a 3/2 valve and said rocker valve structure (202, 302) a 2/2 valve.