RU2065580C1 - Multipurpose integrating scales - Google Patents

Abstract

FIELD: instrumentation. SUBSTANCE: invention deals with counting of numbers of objects identical by mass and with static weighing of various weights. Integrating scale have platform to position unknown number of objects, pans to accommodate individual objects, transmission mechanism coupled with the aid of tie-rod to force-measuring transducer generating electric signal proportional to measured mass and transmitting it into information processing unit, comparator manufactured in the form of two levers which supporting prims are located along axis of tie-rod. Supporting prims are coupled with the use of mobile shackle. Tie-rod can be separated over section between support of levers. EFFECT: simplified design, improved operational reliability. 2 cl, 1 dwg

Description

 The alleged invention relates to a weighing technique, and more specifically to universal electromechanical counting scales, which can be used both for counting the number of objects of uniform mass and for ordinary static weighing of various loads.

It is known that when the weight of the weighed cargo approaches the smallest weighing limit (NmPV) of the balance, the relative weighing error δ _G increases and when the mass of the load is equal to NmPP, it reaches 5%. The relative error in determining the number of parts using counting weights is equal to the difference in the relative errors in determining the lot weight products placed on the main platform of the counting weights, and the weight of one part, i.e.

N = δ _G -δ _g . (one)
It follows that if the mass of one part, determined using the same weights on which a batch of parts is weighed, is close to the NmPP of the weights, the relative error in determining the number of parts in this case can reach 5% or more. The consequence of this is the fact that on a counting scale of the middle class of accuracy the number of parts determined in one weighing usually does not exceed several hundred.

 Therefore, to increase the accuracy of the calculation in this case, it is necessary either to reduce the price of the calibration division, i.e. at the same NPP of the scales, increase the number of calibration divisions (increase the accuracy of the scales), or determine the weight of one part or the average weight of the part by weighing the part or sample on separate scales whose NPP is close to the measured mass. Both methods lead to a sharp increase in costs. The most rational is to equip counting scales, having a relatively small number of calibration divisions, with an integrated device for determining the mass of one part or sample of parts with the necessary accuracy.

 The present invention addresses this issue.

 Electromechanical calculating scales are known, containing a main platform for placing an unknown amount of objects of uniform mass, an auxiliary platform for placing a known number of the same objects, a linkage mechanism with a built-in weight balancing the maximum load of the scales, a common force transducer into an electric signal and a control unit and information processing (see. "Devices and means of automation and control systems". TS-7 "Machines and devices for measuring mechanical x values. "Counting scales means automating processes including parts and small parts in the industry. Overview Issue 3. M. 1987 p. 47).

 The determination of the number of objects on the scales in question can be carried out in two ways.

 According to the first method, an unknown number of objects are placed on the main platform and the first measurement result is stored in the memory of the information processing unit. Then, a known number of objects is transferred from the main to the auxiliary platform and the result of the second measurement is also stored in memory, after which the computing device of the information processing unit subtracts the results of two measurements taking into account the transfer coefficient and gives information about the total number of objects placed on both platforms.

 According to the second method, counting the number of items is as follows.

 An unknown number of items is placed on the main platform, and information on the theoretical weight of one item or its actual weight, measured on separate, more accurate scales, is entered into the memory of the information processing unit from the keyboard of the operator control unit. Then, weighing is performed, after which the computing device of the information processing unit divides the total measured mass by the mass of one object and provides information on the number of objects located on the main platform.

 The most accurate determination of the number of objects is provided by the introduction into the memory of the computing device of the actual weight of one object determined with the necessary accuracy. The considered scales do not have a built-in device for accurately determining the mass of one item, which is a drawback of their design, which reduces the consumer properties of the scales.

 This drawback is partially eliminated in the counting electromechanical scales described in US patent G 01 G 19/00 N 4014397, which are adopted as a prototype.

 The scales of this patent contain a platform for placing a batch of items, the number of which must be determined, a transmission mechanism connected by means of a connecting rod to the lever of the first ratio and then through the second rod with a rigidly mounted force sensor and the lever of the second ratio connected to this rod. On the levers of the first and second ratios, having different transmission coefficients, bowls are hung on certain shoulders to accommodate both a known and an unknown number of objects. From the output of the force sensor, the measuring signal is supplied to the control and information processing unit.

 Counting the number of objects on these scales can be carried out both in the first and in the second methods described above.

 The presence in the design of the scales of the lever of the first ratio with a high gear ratio and the lever of the second ratio with a lower gear ratio, transmitting the measured force directly to the force sensor, provides the ability to directly measure the mass of one item or determine the average weight of one item when weighing several items, which can then be recorded by the operator in the memory of the computing device of the information processing unit.

 However, the resolution of the sensor and the information processing unit has certain physical limitations, which does not allow to measure the unit mass of small items having a weight comparable with the calibration of the scales. In this case, the determination of the number of objects is carried out according to the first method or by entering into the processing unit the theoretical weight of the object, thereby reducing the accuracy of counting the number of objects. This is a design flaw in the balance in question.

 Another serious drawback of the known designs of countable electromechanical scales (including analogues and prototype), which in most cases are used in the process stream of large-scale and mass production, as well as in warehouses where they receive, store and send a large number of various small parts and purchased products, lack of reliability due to the low probability of uptime.

 The latter is explained by the presence in the secondary equipment of such weights of a large number of components that have limited MTBF, as well as insufficient reliability and durability of the force sensors. The operability of the electromechanical balance also directly depends on the presence of the mains voltage and its parameters (deviations from the nominal value and frequency).

 As a result, the time between failures of electromechanical scales is almost an order of magnitude less than the time between failures of purely mechanical scales that are similar in purpose, and the cost is almost an order of magnitude higher. With intensive loading of the scales, failure can lead to large economic losses due to the forced downtime of the electromechanical scales to restore their performance.

 Of the known methods for improving the reliability of products, the most common in instrumentation is redundancy. The application of this method to increase the reliability of the sensor and secondary equipment is often unacceptable both because of the increased consumption of expensive components, which increases the cost of the balance, and because the dependence of the operation of the balance on the availability of mains power remains. The greatest effect is obtained by the use of an energy-dependent (mechanical) backup measuring channel in the balance.

 The purpose of the proposed technical solution is to increase the accuracy of counting the number of homogeneous items by determining the weight of one such item (or the average weight of the item) with the necessary accuracy, as well as to increase the reliability of counting weights.

 This goal is achieved by the fact that a counting scale containing a platform for placing an unknown quantity of objects, a bowl for placing single objects, a transmission mechanism connected by a thrust to a force measuring sensor that generates an electrical signal proportional to the measured mass and transmits it to the information processing unit, is equipped with an integrated comparator a device made in the form of two levers, the supporting prisms of which are located along the axis of the thrust connecting the sensor to the transmission mechanism, and will connect flax movable prisms associated lug, wherein the locking movement limited by stops earrings, and the split rod is formed in the area between the supports levers.

 In FIG. 1 shows a kinematic schematic diagram of the proposed universal counting weights.

 The balance contains a load receiving platform 1 mounted on a linkage gear 2, a detachable link 3, consisting of two parts connected by a rod 4. The lower part of the link 3 is connected to the transmission 2, and the upper one is supported by a load cell 6, which is rigidly fixed to the bracket 5, which transmits a measuring electrical signal proportional to the measured force to the information processing unit 7.

 Lever 9 rests on the upper part of the split rod 3 along its vertical axis 8. On the load arm “a” of this lever, a bowl 10 is hung to accommodate single items, and the transfer arm “b” is connected to the movable earring 11 and to the transfer arm “ b "of the lever 12, mounted by the supporting prism 13 also along the axis of the lower part of the rod 3. On the load shoulder" c "of the lever 12, a second bowl 14 is suspended.

 The lever 12 on the load arm "d" has an additional prism 15 for attaching a removable bowl 10, and also has a scale 16, graduated in weight units, and a mobile weight 17 to balance the force coming to the lever from both taring and payload.

 The lever 9 with the cup 10 suspended on the shoulder “a” and the lever 12 with the cup 14 suspended on the shoulder “c” connected by the movable earring 11, due to the equality of the transmission shoulders “b” and the alignment of the supports 8 and 13, form a comparing device that provides comparison with high precision masses placed on the bowls of goods. To control the equilibrium position of the comparing device, a fixed pointer 18 is installed on the scale body 18. The mobility of the earring 11 is limited by two adjustable stops 19 with the possibility of its complete blocking.

 Scales made according to the proposed technical solution can work both in the mode of automatic balancing and reading the weighing results from the display or digital display of the information processing unit, and in the mode of manual balancing and summing up the weighing results by the weighing operator.

 When the scales are in automatic balancing mode, the proposed design allows you to choose the most accurate way to calculate the number of homogeneous objects, which, depending on the size of their unit mass, can be divided into commensurate and incommensurable with the price of calibration of the scales.

When determining the number of homogeneous objects, the unit weight of which is incommensurable with the price of the calibration of the scales (less than the calibration), the scales work using a comparator according to the following scheme:
1) a well-known number of homogeneous objects (one or several, preferably a multiple of 10) is placed on the bowl 10, and standard weights or general-purpose weights in the bowl 14 in the amount necessary to establish the equilibrium of the comparator device, which is observed by coincidence of the movable the end of the lever 12 with a fixed equilibrium indicator 18, and thus the unit weight of the object is determined with high accuracy. The obtained value of the weight of the item is entered by the operator from the keyboard of the information processing unit 7 into its random access memory.

(2)
где: N-количество однородных предметов, помещенных на грузоприемную платформу 1;
G-результат взвешивания этих предметов;
g-единичный вес предмета, введенный оператором в блок обработки информации.The balancing of the items placed on the bowl 10 can be done without the use of weights by moving the moving weights 17 on a graduated scale 16;
2) after determining the unit weight, an unknown quantity of homogeneous objects to be counted is placed on the platform 1 of the scales and weighing is performed. In this case, the force of the weight of objects through the transmission mechanism 2 and the thrust 3 is transmitted to the load cell 6 and then converted into a proportional electric signal enters the information processing unit, where the number of objects is automatically calculated according to the formula

(2)
where: N is the number of homogeneous objects placed on the loading platform 1;
G-result of weighing these items;
The g-unit weight of the item entered by the operator in the information processing unit.

По аналогичной схеме работают также при использовании чаши 10 вместо чаши 14 для размещения известного количества предметов. В этом случае точность подсчета количества предметов несколько выше вследствие того, что коэффициент передачи рычага 9, к которому подвешена чаша 10, больше коэффициента передачи рычага 12 и составляет K1=(a+b)/b. В связи с тем, что рычаг 9 в отличие от рычага 12 дополнительно нагружает силоизмерительный датчик 6, расчетная формула для подсчета количества однородных предметов для этого варианта имеет вид

Предлагаемая конструкция весов с целью повышения надежности обладает дополнительным свойством, а именно может работать в режиме ручного уравновешивания и суммирования результатов подсчета оператором весов. Такая необходимость возникает при отсутствии электропитания или временной неработоспособности электрической схемы из-за выхода из строя отдельных элементов.When determining the number of items, the unit weight of which is comparable to the price of calibrating the scales (greater than or equal to), the comparator is blocked by moving the stops 19 until the mobility of the earring 11 is completely limited. When calculating the number of items of this class, the scales work according to the following scheme:
1) an unknown number N of homogeneous objects to be counted with mass g is placed on platform 1 and the first weighing is performed, the result of which GI = N • g is automatically entered into the storage device of the computing device of the information processing unit 7. Then, a known number of homogeneous objects γ is removed from platform 1 placed on the bowl 14, suspended from a lever 12 having a gear ratio K = c / b, as a result of which the force coming to the load sensor 6 decreases by an amount ggK due to squashing items on the bowl 14 and an additional reduction by an amount due to the removal of objects from the platform 1;
2) the result of the second measurement
G2 = G1-γ • g • K-γ • g (3)
it is also automatically entered into the storage device of a computing device, where by comparing the results of two measurements, the number of objects located on platform 1 is determined by the calculation formula

A similar pattern also works when using the bowl 10 instead of the bowl 14 to accommodate a known number of items. In this case, the accuracy of counting the number of items is slightly higher due to the fact that the gear ratio of the lever 9 to which the bowl 10 is suspended is greater than the gear ratio of the lever 12 and is K1 = (a + b) / b. Due to the fact that the lever 9, in contrast to the lever 12, additionally loads the load sensor 6, the calculation formula for counting the number of homogeneous objects for this option has the form

The proposed design of the scales in order to increase reliability has an additional property, namely, it can work in the mode of manual balancing and summing up the results of calculation by the operator of the scales. Such a need arises in the absence of power supply or temporary inoperability of the electrical circuit due to the failure of individual elements.

 For the scales to work in this mode, the position of the earring 11 is rigidly fixed by the stops 19, the detachable rod 3 is divided into components with a guaranteed gap between them by removing the rod 4, and the bowl 10 is removed from the lever 9 and suspended on the prism 15 of the load-bearing arm "d" of the lever 12 .

Counting the number of items in this case is as follows:
1) an unknown number of items to be counted is placed on platform 1, and they are balanced by a known number of the same items by placing them in a bowl 14 suspended from a lever 12 on the shoulder “c” and a second bowl suspended on the shoulder “d”.

 The shoulders "c" and "d" of the lever 13 are selected in such a way that the objects placed in their bowls comprise 1/100 and 1/10 of the number of homogeneous objects located on the platform 1, respectively.

The total number of items is calculated according to the formula
N = 100γ ₁ + 10γ ₂ + γ ₃ , (6)
where: γ _{1 is the} number of objects placed in the bowl of hundreds;
γ _{2 is the} number of objects placed in the dozens;
γ ₃ = γ ₂ + γ _{1 is the} number of objects removed from platform 1 in the process of balancing.

 The universality of this design of the scales is determined by their ability not only to count the number of objects of uniform mass, but also simply to weigh the various loads placed on the platform 1.

 In this case, in the automatic balancing mode, the force from the mass of the cargo placed on the platform 1 is converted by the force measuring sensor 6 into an electrical signal and then reproduced in digital form on the reading device of the information processing unit 7.

 When the scales are in manual mode, balancing the weight of the load is carried out by moving the weight 17 on a scale 16 calibrated in weight units with the determination of the equilibrium position by the coincidence of the movable end of the lever 12 with the fixed pointer 18.

 Thus, the proposed universal calculating scales, in contrast to the known ones, contain an integrated comparator made in the form of two levers, the supporting prisms of which are located on the axis of the detachable link connecting the transmission mechanism with the load sensor, and the transmission shoulders are connected by a movable earring with the possibility of blocking it possess additional properties, namely the ability to determine the weight of single objects, weighted with the resolution of the load cell, and produce s count in the automatic balancing mode or in manual mode equilibration.

 The application of the proposed design of universal counting scales in the production process or in warehouses where there are massive cargo flows of homogeneous items (hardware, bearings, components, etc.) will significantly reduce unaccounted losses by improving accuracy and reliability.

 The specific economic effect of the use of weights will be determined in the production environment, depending on the current technological process of manufacturing products, their volume of production and cost.

Claims (2)

 1.Universal calculating scales containing a platform for placing an unknown amount of homogeneous objects or cargo, bowls for placing single objects, suspended from levers, a transmission mechanism connected by a thrust to a force measuring sensor, and an information processing unit, characterized in that they are equipped with a built-in comparator a device made in the form of two levers, the supporting prisms of which are located along the axis of the link connecting these levers with a load sensor, and the transmission arms are connected by slides hydrochloric earring, wherein the lever arm correspond comparator device according to a + b, where a and a length gruzopriemnyh lever arms, b the length of the transfer arm levers.  2. The balance according to claim 1, characterized in that the connecting ear of the levers of the comparator device is equipped with locking stops, and the thrust of the force measuring sensor in the section between the supports of the levers is detachable.