DE302073C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The invention relates to a device for measuring the amount flowing through a line Amount of liquid or vapor.

This measurement is done in a known manner by measuring the pressure in the line and the pressure difference upstream and downstream of a throttle point switched on in this line with the help of plate springs, which by mechanical links their movements on the Transfer display device.

Now the device according to the invention differs from the other known ones Devices characterized in that the mentioned mechanical members one through the plate springs for measuring the pressure difference have a rotated shaft with a slotted member in front of and behind the throttle point, a sliding block plays in the slot. This sliding block is supported by a plate spring, the measures the line pressure, depending on this pressure approximated to or from the axis of the shaft removed so that the arc described by the sliding block about the shaft axis the product the pressure on the first diaphragm times the pressure difference on the other two is equivalent to,.

When it comes to measuring quantities of superheated steam, the Device a fourth plate spring, which the pressure of the gas in the line arranged gas thermometer is subjected and on the mechanical links in the reverse See how the first diaphragm works.

The accompanying drawings show an embodiment of the device which is used for It measures and records the amount of superheated steam that flows through a pipe.

Fig. Ι is a schematic view showing this embodiment and those in relation to it standing devices illustrated.

Figures 2, 3 and 4 are an end view, a plan view, a partial cross-section thereof Embodiment.

In the line α (Fig. 1) through which the superheated steam flows, there is a nozzle δ which forms the throttle point mentioned in the introduction. In front of and behind the nozzle 5, tubes c, d branch off, which lead to pipe sockets e, f (FIGS. 2 and 3) of a common cylindrical housing g (see also FIG. 4), in which the plate springs h, i, j are arranged; the tubes c, d are bent over part of their length to form serpentine ^{tubes c 1} , d ^{1 in} order to cause condensation of the steam, for the purpose that the plate springs h, i,} are not subjected to the high heat of steam. The circular

Plate springs are arranged horizontally and at their circumference between one of the covers g \ g ² and annular intermediate parts g ^s , g ⁴ . g ^{5 of} the housing g pinched. The first and second springs h and i, which are directly above one another, are subjected on their sides facing one another to the pressure prevailing in the line in front of the nozzle b , since the ίο pipe socket β connected to the pipe c opens between them; on the other hand, atmospheric pressure acts on its other sides. The pipe socket f opens into a chamber located above the third plate spring j , the lower side of this plate spring j being subjected to air pressure. In this way, the pressures prevailing in the line α in front of and behind the nozzle b act on the plate springs i, j in opposite directions, and since these springs are connected by an intermediate member k , their movements correspond to the difference between these two pressures. In the middle part of the plate spring h , a member / having an opening / ^{1 is} fastened, the opening of which is delimited at the top and bottom by cylindrical surfaces; An arm m ^{1 of} a shaft m resting in bearings m ² passes through this opening. The shaft m is provided with a second arm m ³ ; which is connected to a rod 0 by a rod n, the length of which is adjustable. This rod 0 is articulated on the one hand with an arm φ ¹ , a shaft φ and on the other hand is provided with a sliding block φ ³ , which moves in a circular arc-shaped slot of a slot member q ¹ , which is wedged on a shaft q rotating in bearings q ² . The shaft q carries an arm q ³ which passes freely through an opening in the intermediate member k and is carried along by this member with the aid of a pin k ^s which passes through an opening k ^{l of} the arm q ^s . The shaft φ is provided with a second arm φ ² · whose movements have a magnitude proportional to the product: pressure in the pipe times the difference in pressures upstream and downstream of the nozzle thanks to the mechanical links chosen in a manner explained later. At the free end of the arm φ ² , a rod r is articulated, the length of which is adjustable and acts ^{on a non-circular disk s 1.} The latter rotates with a horizontal shaft s and acts on a roller i ^{1 supported} on its circumference. The roller t ¹ is carried by an arm t ² which rotates with a shaft t having a second arm t ^3; this arm t ³ takes by means of a screw t ^l a · with a writing. feder t ^e arm t ⁶ with. The pen t ⁶ is pressed with a pressure adjustable by the screw t ⁴ · on a paper strip u ¹ , which is arranged on the drum u ^{2 of} a writing unit u ; the drum is set in motion by a clockwork u ³ and makes z. B. one revolution in 24 hours.

For reasons explained later, the amount of liquid flowing through the line α is in reality not proportional to the product of the pressure difference times the pressure, but rather ηο the square root of this product. In order to obtain a uniform division of the paper strip u ¹ on which the recording takes place, the non-circular disc s ^{1 is given} a special shape. The distance between, on the one hand, any point of its circumference s ³ and, on the other hand, the circular arc s ^a , which is drawn with the axis of the shaft s as the center and passes through the upper end of the circumference s ³ , is proportional to the square root of the arc which lies between the radii passing through that point and that end. When the roller f ¹ moves on the circumference s ³ from the said end to the point under consideration, it is therefore forced to turn around the axis of the shaft t by an angle which is proportional to the square root of the above product; the same thing happens with arm f ³ . This and the arm t ⁵ are balanced by a counterweight ν; the non-round disk is also compensated for by a counterweight w.

By means of a device 10, the pen t ^e can be removed from the drum u ^% for the purpose of replacing the paper strip w ^1. The density of the superheated steam changes in the opposite sense as the temperature of the superheat. To take this into account, the embodiment shown has a fourth circular plate spring x, which is located in the lower part of the housing g and is attached to the intermediate member I in its central part. It is subjected to the air pressure on its upper side and to the pressure of the gas of the gas thermometer y (air or nitrogen thermometer) on the lower side, which is arranged in a chamber a ^{1 of} the line a above the nozzle δ. The space between the wall of the chamber and the thermometer housing is z. B. filled with mercury or an oil with a high boiling point, so that a good heat transfer is ensured between the wall and the housing. In order to avoid errors as much as possible, the chamber x ¹ below the diaphragm χ has an extremely low height and is connected to the thermometer housing by a capillary tube ζ which leads to a pipe socket x ² . Because these parts form harmful spaces

for the expansion of the gas, since they are not subject to overheating like the housing. The two plate springs h, χ act in opposite directions on the link I and therefore on the arm m ^s . This arm is connected at its free end to a pressure loaded and upwardly limiting spring ι; the compression of the spring ι can

ίο can be adjusted by means of a screw i ¹ and a counter nut i ² . This spring ι. serves to absorb that part of the force originating from the plate springs k, χ which is not used by the bending of these plate springs; namely, this force can be great if the steam is not overheated.

When this embodiment is put into operation, it can happen; that the not shown, the tubes c, d controlling slide are not opened at the same time. In this case, the whole formed by the two plate springs i, j would be subjected to a one-sided pressure "which would be able to damage it. To avoid this, a safety device is provided; it has a" housing 2, which is secured by screw caps 2 ¹ , 2 ^{2 is} closed and into which channels 3, 4 open, one of which comes from the chamber located above the plate spring j , the other from the chamber located between the plate springs i, h. These channels are connected within the housing 2 by a zigzag channel 5. In the intermediate pieces 6, which separate the horizontal parts of this channel 5, a slide 7 can move, in which two channels 7 ¹ coming into connection with the mentioned channel parts are provided. Between the slide 7 and each of the covers 2 ¹ , 2 ^a , a spring 8 is arranged, which is chosen so that it allows the slide to return a whole stroke for a pressure difference between the channels 3, 4 prevailing. which is only slightly greater than the normal pressure difference on the upper and lower sides of the plate springs /, i. In the rest state, the slide 7 is held in such a central position by the springs 8 that its channels 7 ^{1 are} not connected to the horizontal parts of the channel 5. If it happens that the slide controlling the tube d is opened before the same happens for the slide switched on in the tube c , the pressure above the diaphragm / is many times greater than that which prevails below the diaphragm i; the slide 7 is lowered immediately, although the lower spring counteracts this; its upper channel 7 ¹ comes to lie opposite the horizontal parts of the channel 5 and thus establishes the connection between the chamber delimited by the plate springs h, i and that above the plate spring . j chamber existing ago this avoids damage to the apparatus the operation of the device is similar, if the slide of the tube is open c before this happens d in the tube;., the slider 7 is then in height, and its lower Channel 7 ¹ establishes the connection.

The slide 7 can, for. B. come into effect as soon as the pressure difference is equal to 0.3 kg / cm ² , if the assumed normal ^{pressure difference is equal to 0.2 kg / cm 2} .

^{A stop g 6} provided on the cover g ^{1 of} the housing g also limits the movement from bottom to top of the two plate springs i, j. These occupy the same diameter and are corrugated. In contrast, the diaphragm springs h, χ have different diameters; the first has a smaller diameter than the second and is wavy, while the diaphragm χ is flat.

The mode of operation of this embodiment is as follows:

It is known that the amount of steam Q flowing through line a per unit of time is approximately the same:

where C is a constant, ⁹ ^

d is the pressure difference between the pipe parts upstream and downstream of the nozzle b,

γ is the vapor density.

Now the vapor density is almost exactly proportional to the vapor pressure ft when the vapor is saturated; then γ can be replaced by ft . So

Q = C

Here, however, we are dealing with the measurement of an amount of superheated steam, the density of which changes quite precisely in the opposite sense as the temperature T (absolute temperature) of the superheat, so that

Q = cj /

The plate springs h, χ are calculated in such a way that for the minimum pressure ft _m - _in and the maximum overheating T _max , for which this embodiment is set up, that is, for the ■ minimum density y _m h, of the steam, they assume such a position that the Sliding block ft ^{s is} located at the very lower end of the slot. ;. ■

When the slides controlling the tubes c, d are opened, the whole formed by the two oppositely acting plate springs A, χ gives the sliding block p ³ in the slot of the slotted member q ¹ a corresponding position through the intermediary of the intermediate member /, the arms ¹ , m ³ , the hamlet and the rod n. The higher the pressure. the higher the sliding block p ³ goes in the slot;

ίο the greater the overheating, the more it descends in the slot. On the other hand, the more the central part of the whole formed by the two plate springs i, j rises, the higher the pressure difference between the line parts located in front of and behind the nozzle b; the arc described by the slotted member q ¹ rotating with the shaft q is all the greater. As just explained, the position of the sliding block p ³ changes proportionally to the pressure and in the opposite sense as the overheating. It follows that the sliding block p ³ executes a movement whose deflection is proportional

and that it transmits this movement through rod 0, arm p ¹ , shaft p, arm p ² , rod r to the non-circular disk s ^1. As a result of the shape chosen for this, the roll t ¹ , the arms t ² , t ³ , fi now describe arcs around the axis of the shaft t which are proportional to the square root of this expression. So the nib moves t ⁶ on the

"35 paper strips u ¹ by a length that

proportional, d. H. proportional to the amount of steam.

The use of the four diaphragm springs h, i, j, χ to measure the various variables to be determined, including overheating, results in a simple, very robust, little space-consuming device whose mode of operation is reliable.

It should be noted that instead of the device in which the thrusts on the plate springs h, χ are subtracted from one another, it would be better to use a device in which the thrust on A is divided by the thrust on χ . Because of the great inconvenience, this device was not used in the embodiment shown. On the other hand, if this division is desired, it can be achieved in place of subtraction.

When it comes down to it, no longer the amount of superheated steam, but the amount of a gas, an amount of air z. B. to measure the flow through a line, the diaphragm χ is omitted.

If it is a question of only measuring a quantity and not registering it, the non-circular disk s ¹ and the register u are no longer applicable; arm p ² can then become a pointer and move in relation to a dial which has an unequal division to take into account the fact that the pointer deflections correspond to the squares of the set.

Depending on the case, the plate springs cannot be arranged horizontally. The members used for the mechanical connection of these plate springs can have any arrangement different from that illustrated in the drawing. The non-circular disk s ¹ , which gives the square root of the deflections of the slide block movements, can be replaced by another device by which the same goal is achieved.

The device can also be used to measure the amount of a liquid that can be dripped.

Claims (4)

Patent Claims: 1. Device for measuring the amount of liquid flowing through a line by measuring the pressure in the line and the pressure difference before and after a throttle point switched on in this line with the help of plate springs which transmit their movements to the display device through mechanical members, characterized in that the The mentioned mechanical members have a shaft (q) rotated by the diaphragm springs (i, j) to measure the pressure difference in front of and behind the throttle point with a slotted member (q ¹ ) , in whose slot a sliding block (p ³ ) through a diaphragm spring measuring the line pressure (A) depending on this pressure, the axis of the shaft (q) is approached or removed from it, so that the arc described by the sliding block (p ³ ) around the shaft axis is the product . '' of the pressure on the first diaphragm (A) times the pressure difference on the other two (i, j) . 2. Apparatus according to claim 1, characterized in that for measuring superheated steam a fourth plate spring (x) is subjected to the pressure of the gas of a gas thermometer (y) arranged in the line («) and is subjected to the mechanical members in the opposite sense as - the diaphragm (A) acts. 3. Apparatus according to claim 1, characterized in that it has a security device in the form of one of the pressures in front of and behind the nozzle (b) has a standing slide (7) held in its central position by springs (8), which is intended to apply the same pressure to the second (i) and third diaphragm (/), if these are not at the same time, the one before the pressures prevailing at the nozzle, which others are subjected to the pressure behind this nozzle. 4. Apparatus according to claim 1, characterized in that the movement of the sliding block {f ^z ) apf a non-circular disc (s ¹ ) is transmitted which, when moving, a display element resting on its circumference (t, t ¹ , t ² , t ^3. t *, V ·, P) is moved in such a way that its deflections are proportional to the square root of the deflection of the slide block movements. For this purpose 2 sheets of drawings.