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LONDON--(BUSINESS WIRE)--Technavio has been monitoring the industrial food cutting machines market and it is poised to grow by USD 82.51 million during 2020-2024, progressing at a CAGR of 3% during the forecast period. The report offers an up-to-date analysis regarding the current market scenario, latest trends and drivers, and the overall market environment.
A USB driver for the isolated USB interface adapter (for Type 373x-x) and SAMSON USB devices (TROVIS 6495-2 and TROVIS 5610) is integrated into the installation file of TROVIS-VIEW version 4.42 and higher. This driver is automatically installed under Windows® 8 and higher on installing TROVIS-VIEW. Title: TeleScout Installationsanweisung Author: Gerdes Aktiengesellschaft Created Date: 3/17/1999 9:48:34 AM. Adapters from AVM (driver release 3.08 and higher), Scitel (autumn 2000 or later) or Gerdes/Primux are suitable. CapiDog will not work after you start another application which monitors the D. Thade Gerdes GmbH: 'APB's innovative nature has always been a key driver for selection.' For more than 115 years Thade Gerdes has been a well-known family company from Norden, Germany. The company highly values innovation and has walked hand in hand with the developments in Cone Penetration Testing over the years.
Technavio suggests three forecast scenarios (optimistic, probable, and pessimistic) considering the impact of COVID-19.Please request Latest Free Sample Report on COVID-19 Impact
The market is fragmented, and the degree of fragmentation will accelerate during the forecast period. Brunner-Anliker AG, Buhler AG, EMURA FOOD MACHINE Co. Ltd., GEA Group Aktiengesellschaft, Hifferman NV, Jaymech Food Machines Ltd., KRONEN GmbH, Illinois Tool Works Inc., Urschel Laboratories Inc., and Weber Maschinenbau GmbH Breidenbach are some of the major market participants. The rising number of product launches will challenge the growth of the market participants. To make the most of the opportunities, market vendors should focus more on the growth prospects in the fast-growing segments, while maintaining their positions in the slow-growing segments.
Industrial Food Cutting Machines Market 2020-2024: Segmentation
Industrial Food Cutting Machines Market is segmented as below:
- Product
- Industrial Food Slicers
- Industrial Food Dicers
- Industrial Food Millers
- Industrial Food Shredders
- Geography
- Europe
- North America
- APAC
- MEA
- South America
To learn more about the global trends impacting the future of market research, download a free sample: https://www.technavio.com/talk-to-us?report=IRTNTR45450
Industrial Food Cutting Machines Market 2020-2024: Scope
Technavio presents a detailed picture of the market by the way of study, synthesis, and summation of data from multiple sources. Our industrial food cutting machines market report covers the following areas:
- Industrial Food Cutting Machines Market size
- Industrial Food Cutting Machines Market trends
- Industrial Food Cutting Machines Market industry analysis
This study identifies the rising demand for processed meat and poultry products, such as bacon, hot dogs, sausage, and other deli meats as one of the prime reasons driving the industrial food cutting machines market growth during the next few years.
Industrial Food Cutting Machines Market 2020-2024: Vendor Analysis
We provide a detailed analysis of around 25 vendors operating in the industrial food cutting machines market, including some of the vendors such as Brunner-Anliker AG, Buhler AG, EMURA FOOD MACHINE Co. Ltd., GEA Group Aktiengesellschaft, Hifferman NV, Jaymech Food Machines Ltd., KRONEN GmbH, Illinois Tool Works Inc., Urschel Laboratories Inc., and Weber Maschinenbau GmbH Breidenbach. Backed with competitive intelligence and benchmarking, our research reports on the industrial food cutting machines market are designed to provide entry support, customer profile and M&As as well as go-to-market strategy support.
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Industrial Food Cutting Machines Market 2020-2024: Key Highlights
- CAGR of the market during the forecast period 2020-2024
- Detailed information on factors that will assist industrial food cutting machines market growth during the next five years
- Estimation of the industrial food cutting machines market size and its contribution to the parent market
- Predictions on upcoming trends and changes in consumer behavior
- The growth of the industrial food cutting machines market
- Analysis of the market’s competitive landscape and detailed information on vendors
- Comprehensive details of factors that will challenge the growth of industrial food cutting machines market vendors
Table Of Contents :
Executive Summary
Market Landscape
- Market ecosystem
- Value chain analysis
Market Sizing
- Market definition
- Market segment analysis
- Market size 2019
- Market outlook: Forecast for 2019 - 2024
Five Forces Analysis
- Five forces summary
- Bargaining power of buyers
- Bargaining power of suppliers
- Threat of new entrants
- Threat of substitutes
- Threat of rivalry
- Market condition
Market Segmentation by Product
- Market segments
- Comparison by Product
- Industrial food slicers - Market size and forecast 2019-2024
- Industrial food dicers - Market size and forecast 2019-2024
- Industrial food millers - Market size and forecast 2019-2024
- Industrial food shredders - Market size and forecast 2019-2024
- Market opportunity by Product
Market Segmentation by Application
- Market segments
- Comparison by Application
- Fruits and vegetables - Market size and forecast 2019-2024
- Meat - Market size and forecast 2019-2024
- Potatoes - Market size and forecast 2019-2024
- Cheese - Market size and forecast 2019-2024
- Others - Market size and forecast 2019-2024
- Market opportunity by Application
Customer landscape
Geographic Landscape
- Geographic segmentation
- Geographic comparison
- Europe - Market size and forecast 2019-2024
- North America - Market size and forecast 2019-2024
- APAC - Market size and forecast 2019-2024
- MEA - Market size and forecast 2019-2024
- South America - Market size and forecast 2019-2024
- Key leading countries
- Market opportunity by geography
- Market drivers
- Market challenges
- Market trends
Vendor Landscape
- Overview
- Vendor landscape
- Landscape disruption
Vendor Analysis
- Vendors covered
- Market positioning of vendors
- Brunner-Anliker AG
- Buhler AG
- EMURA FOOD MACHINE Co. Ltd.
- GEA Group Aktiengesellschaft
- Hifferman NV
- Jaymech Food Machines Ltd.
- KRONEN GmbH
- Illinois Tool Works Inc.
- Urschel Laboratories Inc.
- Weber Maschinenbau GmbH Breidenbach
Appendix
- Scope of the report
- Currency conversion rates for US$
- Research methodology
- List of abbreviations
About Us
Technavio is a leading global technology research and advisory company. Their research and analysis focuses on emerging market trends and provides actionable insights to help businesses identify market opportunities and develop effective strategies to optimize their market positions. With over 500 specialized analysts, Technavio’s report library consists of more than 17,000 reports and counting, covering 800 technologies, spanning across 50 countries. Their client base consists of enterprises of all sizes, including more than 100 Fortune 500 companies. This growing client base relies on Technavio’s comprehensive coverage, extensive research, and actionable market insights to identify opportunities in existing and potential markets and assess their competitive positions within changing market scenarios.
We claim:1. A chopper circuit for the driving of electromagnetic coils and/or step motor coils such as employed in a matrix printer, comprising
finally controlled element having an inductivity and having an input;
a final control circuit having an input and an output, where the output of the final control circuit is connected to the input of the finally controlled element;
a current data acquisition circuit including a current shut-off for shutting off a current and the current shut-off connected to an input of the final control circuit;
a frequency generator having an output for providing a clock cycle signal;
a digital control logic having an input connected to the output of the frequency generator generating a control signal with the clock cycle of the frequency generator, which control signal is present as input or as output signal at the input of the final control circuit alternating with the shut-off of the current.
2. The chopper circuit according to claim 1 wherein the finally controlled element comprises a coil having an inductivity and where the inductivity of the coil in connection with the applied voltage generates a maximum current, which current is set lower by a desired factor and where current ripples are generated by chopping.
3. The chopper circuit according to claim 1
wherein the digital control logic comprises a reset/set flip-flop having a reset input and having a single output line; and
wherein the single output line is coupled back to the reset input.
4. The chopper circuit according to claim 1 further comprising
a reference voltage generator for generating a reference voltage;
a sensor resistor;
wherein the current data acquisition circuit comprises a comparator having an output, having a positive input and having a negative input;
wherein the positive input of the comparator is connected to the reference voltage;
wherein the negative input of the comparator is connected to the sensor resistor; and
wherein the output of the comparator is connected to the digital control logic and to the input of the final control circuit.
5. The chopper circuit according to claim 1
wherein the digital control logic forms part of an integrated circuit, and
wherein the final control circuit, the current data acquisition circuit, and the current shut-off are separately disposed.
6. The chopper circuit according to claim 5
wherein the digital control logic and the current data acquisition are bidirectionally connected to each other and
wherein the current shut-off and the final control circuit are bidirectionally connected to each other.
7. The chopper circuit according to claim 1
wherein the final control circuit is a driver circuit for the finally controlled element.
8. The chopper circuit according to claim 1
wherein the final control circuit is a bridge circuit for a step motor coil.
9. The chopper ciruit according to claim 8
wherein the bridge circuit comprises freewheeling diodes and
wherein amplifiers are connected in each case between output lines of the digital control logic and transistors of the final control circuit.
10. A chopper circuit for the driving of electromagnetic coils and/or step motor coils such as employed in a matrix printer, where the inductivity of the coils in connection with the applied voltage generates a maximum current, which current, however, is set lower by a desired factor, where the current ripples can be generated by chopping, the improvement comprising a driver circuit (9) having an input (13) and for driving an electromagnetic coil (8) or, respectively, a bridge circuit (27) for a step motor coil (26) in each case coordinated to a current data acquisition (10) with a current shut-off (11) connected to the input (13) of the driver circuit (9),
wherein a digital control logic (12) is provided, which generates a control signal (2) in the cycle of a frequency generator (3), which control signal (2) is present as input signal or as output signal at the input (13) of the driver circuit (9) or, respectively of a bridge circuit (27), alternating with the current shut-off (11).
11. The chopper circuit according to claim 10,
wherein the digital control logic (12) comprises a reset/set flip-flop (14), where a single output line (15) of the reset/set flip-flop (14) is coupled back to a reset input (16).
12. The chopper circuit according to claim 10,
wherein the current data acquisition (10) comprises a comparator (17), where a positive input (18) of the comparator (17) is connected to a reference voltage (19), and where a negative input (20) of the comparator (17) is connected to a sensor resisitor (21), and where an output (22) of the comparator (17) is connected to the digital control logic (12) and to the input (13) of the driver circuit (9).
13. The chopper circuit according to claim 10,
wherein the digital control logic (12) forms part of an integrated circuit, and
wherein the driver circuit (9), and the current data acquisition (10) as well as the current shut-off (11) are separately disposed.
14. The chopper circuit according to claim 13,
wherein the digital control logic (12) and the current data acquisition (10) are bidirectionally connected to each other and
wherein the current shut-off (11) and the driver circuit (9) are bi-directionally connected to each other.
15. A chopper circuit for the driving of electromagnet and/or step motor coils such as employed in a matrix printer, comprising
a third gate having a first input, a second input and an output, where a first input is provided for a pulse chain;
a frequency generator having an output;
a first gate having a first input, a second input and an output, where the first input of the first gate is connected to the output of the frequency generator and where the output of the first gate is connected to the second input of the third gate;
a second gate having a first input, a second input and an output where the first input of the second gate is connected to the output of the first gate and where the output of the second gate is connected to the second input of the third gate and to the second input of the first gate;
a fourth gate having a first input, a second input and an output where the output of the second gate is connected to a second input of the second gate and where a first input of the fourth gate is connected to the frequency generator;
a sixth amplifier having an input and an output, where the input of the sixth amplifier is connected to the output of the third gate;
a fifth amplifier having an input and an output, where the input of the fifth amplifier is connected to the output of the sixth amplifier and where the output of the fifth amplifier is connected to a second input of the fourth gate ;
a step motor including an electromagnetic coil connected to the output of a sixth gate.
16. The chopper circuit according to claim 15 further comprising
an inverter connected in series with the fifth amplifier.
17. A chopper circuit for the driving of electromagnet and/or step motor coils such as employed in a matrix printer, comprising
a third gate having a first input, a second input and an output, where a first input is provided for a pulse chain;
a frequency generator having an output;
a first gate having a first input, a second input and an output, where the first input of the first gate is connected to the output of the frequency generator and where the output of the first gate is connected to the second input of the third gate;
a second gate having a first input, a second input and an output where the first input of the second gate is connected to the output of the first gate and where the output of the second gate is connected to the second input of the third gate and to the second input of the first gate;
a fourth gate having a first input, a second input and an output where the output of the second gate is connected to a second input of the second gate and where a first input of the fourth gate is connected to the frequency generator;
a sixth amplifier having an input and an output, where the input of the sixth amplifier is connected to the output of the third gate;
a fifth amplifier having an input and an output, where the input of the fifth amplifier is connected to the output of the sixth amplifier and where the output of the fifth amplifier is connected to a second input of the fourth gate;
a transistor having a base, an emitter and a collector, where the base is connected to the output of the sixth amplifier;
a comparator having a first input, a second input and an output, where the output of the comparator is connected to the base of the transistor and where an output of the transistor is connected to a first input of the comparator and where a reference voltage is connected to the second input of the comparator; and
an electromagnetic coil connected to the collector.
18. The chopper circuit according to claim 17 further comprising
an inverting amplifier having an input and having an output connected to the base of the transistor;
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a free-wheeling diode connected to the output of the comparator and to the input of the inverting amplifier.